JP2001059253A - Human-body washing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a human-body washing device, by which a human body can be washed diversely and properly while water-saving efficiency can be improved. SOLUTION: A bidet KS2-1 has an inhalant-side valve unit WP2-1, a heat exchanging unit TH1-1, a flow-control changeover valve WP2-2 and a wave generating unit WP2-3 from the water supply source side on the outside. Flush water changed into hot water at a set temperature by the heat exchanging unit TH1-1 receives flow-rate control by the flow-control changeover valve and flows into the wave generating unit WP2-3. A wave generating apparatus forwards and pulls in flush water by reciprocating a plunger in a cylinder and generates a pulsation in which pressure fluctuates at various values periodically, flush water is flowed to the downstream side under the state of a pulsation flow, and flush water in the pulsation flow is discharged from a flush nozzle WN2-1. Thus, the wave generating unit WP2-3 sets the frequency of the pulsation in the deadband of a human body in the case of the discharge of flush water in the pulsation flow.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a human body cleaning apparatus for cleaning a human body by discharging cleaning water from a water discharge hole.

[0002]

2. Description of the Related Art Conventionally, of this kind of human body washing apparatus, for example, in a sanitary washing apparatus mounted on a toilet, a washing form in which a washing range is widened or a defecation action is promoted by soft washing or strong stimulation. Is being considered. As one of such techniques, a technique disclosed in Japanese Patent Application Laid-Open No. 61-53929 is known. In this technique, a cleaning element draws a predetermined trajectory, that is, discharges water while swinging the cleaning water so as to widen a cleaning range, thereby switching a flow direction.

[0003]

However, the cleaning water spouted by the conventional fluid element mechanism has a moving speed (oscillation frequency) of a predetermined locus and an amplitude (cleaning area) of the predetermined locus.
It increases or decreases according to the increase or decrease of the instantaneous water discharge amount. For this reason, when cleaning a wide range, it is necessary to increase the instantaneous water discharge amount, while when cleaning a narrow range, it is necessary to reduce the instantaneous water discharge amount.

In addition, when a wide range of cleaning and a narrow range of cleaning are performed variably, the amplitude of the predetermined trajectory (cleaning area) cannot be largely changed due to the characteristics of the fluid element, so that the change range of the cleaning area is small. Further, when cleaning a wide range, the moving speed (oscillation frequency) of the predetermined locus is high (high frequency), while when cleaning a narrow range, the moving speed (oscillation frequency) of the predetermined locus is low (high frequency). Low frequency) and cannot be cleaned at a moving speed that matches the cleaning surface. Further, when the feeling of washing becomes a problem in washing the human body, it is not possible to effectively cope with changing the moving speed of the predetermined locus and the washing area without changing the instantaneous water discharge amount.

[0005] In addition, there is also known a massage cleaning in which the discharge of the cleaning water is intermittently spouted so that the cleaning water is intermittently jetted out. However, in this massage washing, the frequency of intermittent water discharge is usually set to 1 to 3 Hz in order to promote defecation by intermittent water discharge. When such intermittent spouting is applied to normal ass washing or bidet washing, the washing water becomes spouting water in intermittent flow, which causes an unpleasant feeling that the washing intensity varies with time.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and a human body washing apparatus capable of variously and suitably washing a human body and improving water saving efficiency. The purpose is to provide.

[0007]

A human body cleaning apparatus according to the present invention is a human body cleaning apparatus for cleaning a human body by discharging supplied cleaning water, the cleaning apparatus including a cleaning water discharge hole. A nozzle that discharges the cleaning water from the water discharge port toward the human body, and a method that changes the flow rate of the wash water discharged from the water discharge port with time while changing the flow rate of the wash water with time. A water discharge means for discharging water so that the human body does not recognize the pressure change.

In the human body cleaning apparatus according to the present invention, while the flow rate and the flow velocity of the washing water spouted from the spouting hole are temporally changed by the water spouting means, the pressure change of the washing water due to the temporal fluctuation of the washing water is changed. Spout water so that it does not recognize.

[0009] Here, the phrase "the human body does not recognize the temporal variation of the spouting water" means that the cleaning surface of the human body cannot recognize the fluctuation of the water pressure because the fluctuation speed of the flow rate or the flow velocity of the cleaning water is large or minute. Say.

As described above, if the water is spouted so that the human body does not recognize the pressure change of the washing water due to the temporal fluctuation of the washing water, the flow rate can be changed without causing the human body to feel that the feeling of washing or comfort based on the pressure change has changed. Alternatively, the flow rate can fluctuate over time. Therefore, even if the flow rate of the washing water is periodically reduced at a fluctuation cycle that cannot be recognized by the human body, the feeling of washing and the feeling of comfort can be maintained, and the effectiveness of water saving can be enhanced.

[0011] Further, the water discharging means may change the water discharging in the water discharging mode, which is generated in a cycle shorter than the temporal fluctuation cycle that can be recognized by the human body, according to the time transition in the cleaning period. . This makes it possible to change the washing feeling obtained in each of the water discharge modes during the washing operation, so that various washing feelings can be experienced.

As means for preventing the washing surface of the human body from recognizing fluctuations in the water pressure, means for changing the period at which the washing water is applied to the human body can be used. The fluctuation cycle of washing water is about 3
If the frequency is lower than Hz, the human body can recognize the change in water pressure. This will be described in more detail below.

When the pressure change of the washing water occurs at a cycle of about 0.3 seconds, the human body can clearly recognize the change as a stimulus change. Therefore, it is preferable that the flow rate fluctuation causing the pressure change of the cleaning water occurs in a short cycle of about 0.2 seconds or less. Fluctuation of flow rate of washing water is about 3
If the change occurs at a frequency of less than or equal to Hz, the change can be clearly recognized by the human body as a stimulus change. Therefore, it is preferable that the above-described change in the cleaning area occurs at a frequency of 5 Hz or more. In this case, the meaning of preventing the human body from recognizing a stimulus change means intentionally causing the human body not to recognize the stimulus change. Therefore, when compared with massage washing in which the human body recognizes any stimulus change (for example, stimulus change based on temperature change or flow rate change) in order to promote convenience during local cleaning, it is not recognized that stimulus change is recognized. Although different,
This is common in that intentional water discharge control is performed. In other words, the stimulus change referred to here is a stimulus change inevitably occurring in washing water spouting or continuation of washing water spouting in any form of washing water spouting. It does not include the stimulus change of the frequency and the cycle that occurs inevitably just by being touched.

Here, as a preferable embodiment of the water discharging means, water discharging such that the minimum flow rate is zero in the transition of the cleaning water flow rate due to the temporal fluctuation of the flow rate or the flow rate of the cleaning water, in other words, from the water discharging hole. Intermittent water discharge means that completely eliminates the flow rate of the flushing water that is discharged, and pulsating water discharge means that temporally varies the flow rate by preventing the situation where the minimum flow rate is zero in the transition of the flush water flow rate Can be taken. Also, the upper limit of the frequency of the intermittent / pulsating means can take various values corresponding to the intermittent / pulsating means. By setting the frequency of the power supply to 50 Hz or 60 to 70 Hz, the control can be facilitated. Further, the frequency may be set so as not to change its value, may be changed according to a human body part to be cleaned, a cleaning form, or the like, or may be changed according to a value such as a flow rate. For example, in a human body cleaning device for cleaning a local part of the human body, a buttock cleaning is performed at 50 Hz and a soft cleaning is performed at 60 Hz.
The frequency can be changed according to the cleaning site and the cleaning mode, such as setting the z and bidet cleaning to 70 Hz. Further, the frequency may be set in accordance with the characteristics of various cleaning modes.

In performing the water discharge according to the cleaning part, the nozzle is provided with a plurality of water discharge holes for discharging the wash water to different areas to be cleaned and cleaning the areas. From at least one of the holes, the water spouting means can perform the spouting of the wash water with a temporal variation. Further, the nozzle is provided with a plurality of nozzles for ejecting washing water to different washing target areas to wash the areas, and at least one of the plurality of nozzles ejects washing water with temporal variation by the ejecting means. You can do it. By doing so, it is possible to perform flush water discharge with temporal variation only for one or a plurality of specific cleaning target areas.
In particular, in the case of the one provided with a plurality of nozzles, an existing nozzle which does not involve the temporal variation according to the present invention may be used, so that the manufacturing is simplified.

Further, as an example of the mode, a period during which the human body is not cleaned, for example, a period of nozzle cleaning for cleaning the periphery of the water discharge hole of the cleaning nozzle at the beginning of cleaning or after the cleaning is completed, or an intermittent period for cleaning the cleaning nozzle. A configuration in which the dead band frequency of the intermittent / pulsating flow can be adopted only when the surface to be cleaned is landed without using the pulsating flow. Also, in the case where nozzle cleaning is performed before the start of human body cleaning, the frequency of the intermittent / pulsating flow is set to be smaller than the dead band frequency during this nozzle cleaning, and then the intermittent / pulsating flow is created. By adopting a configuration in which the frequency is increased to a dead zone when water is applied, comfortable cleaning by intermittent or pulsating flow can be reliably performed.

In the case of pulsating spouting, not only does the water amount fluctuate less than intermittent spouting but also the water pressure does not become zero or negative pressure even at the minimum water pressure. As a result, the impact on other devices can be reduced, and since it is close to continuous water discharge, irritation to the human body is reduced and the feeling of washing is excellent. Further, since the discharged water does not flow backward or stagnate, the control of the heat exchanger, which is a heating means for heating the cleaning water, can be relatively easily performed.

According to another preferred embodiment of the present invention, there is provided a human body cleaning apparatus for cleaning a human body by discharging supplied cleaning water, comprising a water discharging hole for cleaning water, wherein the cleaning water is discharged from the water discharging hole. A nozzle that discharges water toward the human body from the nozzle, and while temporally varying the flow rate or flow velocity of the cleaning water discharged from the water discharge hole, the pressure change due to the temporal fluctuation of the cleaning water and the water discharge associated with the pressure change. It is characterized by including a water discharging means for changing the aspect in a cycle shorter than a temporal variation cycle that can be recognized by the human body.

Here, as a mode of the water discharge control by the water discharge means, in addition to a case where the temporal variation of the water discharge mode is not recognized by the human body, a change of the water discharge mode, a pressure change due to scanning,
This includes the case where only the accompanying water pressure fluctuation among the water pressure fluctuations due to water discharge, such as a pressure change in which the washing position is sequentially changed, a pressure change due to a flow rate fluctuation, and a pressure change due to a flow velocity, can be recognized. In other words, in the water discharging means, even if the water discharging control is performed in a fluctuation cycle that is not recognized by the human body, the low frequency component is additionally sensed by the human body. Since there is no great difference, such water pressure does not have a great effect as an unpleasant washing feeling (stimulus). Therefore, if the frequency to be controlled is a frequency that cannot be recognized by the human body, a suitable washing feeling can be obtained. In addition, here, the flow velocity in the intermittent / pulsating discharge water may be the same as the average flow velocity,
The average flow velocity itself may be pulsated.

In a preferred aspect of the present invention, there is provided a commanding means for instructing the start of washing of the human body, and controlling the water discharging means in synchronization with the washing start command from the commanding means. And a fluctuation control executing means for executing the flush water discharge with the above. In this way, when a washing start command is issued, the washing water is always spouted with temporal fluctuations by the spouting means, and the spouting water is spouted while the flow rate, spouting form, etc. are temporally varied as described above. To clean the human body. Further, according to this aspect, no extra control is required compared to a case where additional washing is performed during execution of the washing water spouting, and a large water saving effect can be obtained from the beginning of the washing start. In addition, the washing water spouting that involves temporal fluctuations in the flow rate and the like is performed not only in special washing such as massage washing but also in regular washing operations such as butt washing and bidet washing that are frequently used. And can be. Therefore, at the time of such a normal cleaning, since the flow rate of the cleaning water fluctuates over time immediately and immediately from the beginning of the cleaning, the water saving efficiency is significantly improved with respect to the conventional continuous discharge of the cleaning water. .

Further, it is more preferable to change the flow rate of the washing water in a short cycle in which the temporal change of the flow rate of the washing water is not recognized by the human body, in order to enhance the marketability. Conventionally, fixed-point washing using a continuous flow is generally used as a human body washing, and there is a possibility that the user may feel uncomfortable with a water discharge mode that fluctuates with time. Therefore, by executing the temporal variation at a higher frequency than the variation perceived by the human body,
The high cleaning efficiency can be kept as it is, and a feeling of strangeness to the human body can be avoided.

As another control mode of the human body cleaning apparatus, the intermittent / pulsation means is provided with an intermittent / pulsation control unit for changing the frequency, and the intermittent / pulsation control unit is provided with a cleaning water discharged from a water discharge hole. Based on the set values such as water force and cleaning intensity of
It can be configured to change the frequency. This makes it possible to increase / decrease the force applied to the human body without increasing / decreasing the flow rate of the washing water, so that control can be performed as if the water force and the feeling of washing were different.

[0023]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, an embodiment in which the human body cleaning apparatus according to the present invention is applied to a human body local cleaning apparatus will be described based on examples. An embodiment of the present invention will be described later, and a reference example having a configuration related to the embodiment will be described first. FIG. 1 is a schematic perspective view showing a local cleaning device KS1-1 of a reference example mounted on a toilet, and FIG. 2 is an explanatory diagram for explaining a remote control device RC1-1 of the local cleaning device. 3 is a schematic perspective view around the sleeve for explaining the auxiliary operation unit KS1-9 of the local cleaning device. FIG. 4 is a block diagram showing a schematic configuration of the local cleaning apparatus mainly on a water channel system, and FIG. 5 is a block diagram showing a schematic configuration of a control system.

A1 / Overall configuration; As shown, the local cleaning device KS1-1 includes a main body KS1-2 fixed to the rear upper surface of the toilet BT, and a remote control for remotely controlling a cleaning operation and a drying operation. And an operation device RC1-1. The main body KS1-2 includes a toilet seat KS1-3 and a toilet lid KS1-4 on the toilet opening side so as to be freely opened and closed. The main body has a sleeve portion KS1-5 on the side of the toilet and a nozzle device NS1-1 (see FIG. 6) having a cleaning nozzle WN1-1 for discharging cleaning water to a cleaning local portion, as described below. Various functional parts are stored.

As shown in FIG. 2, the remote control device RC1-1 has various operation buttons commonly used for defecation.
That is, the remote control device is provided at the top of the front surface thereof with a stop button SWa operated when stopping operations such as washing and drying of the local cleaning device, and a stop button SWa operated when normal anal cleaning is desired. Ass washing button SWb, soft washing button SWc operated when anal washing by soft water spouting is desired compared to normal anal washing, and bidet washing button SWd operated when bidet washing is desired. And a drying button S operated when local drying by warm air is desired.
Wz. In addition, the anal washing with the soft washing button SWc is a washing mode in which a person having hemorrhoids and a person with sensitive epidermis around the anus do not irritate as much as possible. The anus is washed by gently spouting the washing water. Butt cleaning button SWb, soft cleaning button SWc, bidet cleaning button S included in the uppermost button group
When each button of Wd is operated, each washing described above is started.

A remote control device is provided below the uppermost button group to change the state of water discharge at the time of the above-mentioned both hips cleaning, and to change the state of water discharge at the time of bidet cleaning. Button group. That is, this remote control device
A move setting button SW for discharging cleaning water to give a wide range of cleaning feeling while reciprocating the cleaning nozzle WN1-1 back and forth so as to correspond to the both-side cleaning button.
fa, a massage setting button SWea for regularly changing the area (washing area) to which the washing water is applied over the water discharging period to promote a feeling of defecation, and changing the washing area irregularly over the water discharging period. It has a fluctuation setting button SWta for giving a sense of comfort and comfort, a spot setting button SWua for reducing the cleaning area, and a wide setting button SWva for increasing the cleaning area. In addition, a move setting button SWfv, a fluctuation setting button SWtv, a spot setting button SWuv, and a wide setting button SWvv, which are similar to those of the hips cleaning, are provided below the bidet cleaning button. Further, the optical signal transmitting unit RC1-
Below 2, there is a deodorization setting button SWy for setting on / off of deodorization in the toilet bowl, and a room warming setting button SWw for setting on / off of a mode for automatically performing indoor heating at low room temperature to prevent cooling. . Further, below the setting buttons, a display section RC1-3 for displaying the cleaning water force and the nozzle position is sandwiched, and the water pressure strong setting button SWhu, the water pressure weak setting button SWhd, and the nozzle position advance setting button SW
xf and a nozzle position retreat setting button SWxb. The state of water discharge when these buttons are operated will be described later.

The sleeve portion KS1-5 has, on its upper surface, a display portion KS1-6 for displaying the operation status of the local cleaning device and a cover KS1-7 which can be opened and closed to cover an auxiliary operation portion described later. The display unit includes the optical signal transmitting unit R described above.
A light receiving unit for receiving an optical signal emitted from C1-2 is incorporated. In addition, a part of the cover has a light transmitting window KS1 colored so as to selectively transmit light from a seat sensor SS10 (see FIG. 3) for detecting a seated human body.
−8.

As shown in FIG. 3, the sleeve has an auxiliary operation section KS1-9 below the cover. The auxiliary operation unit is covered with a cover because the operation frequency is low, and includes a plurality of operation buttons and operation knobs around the seat sensor SS10. Among these buttons, a button in front of the seating sensor includes a main power button SWp for turning on / off the power of the entire local cleaning apparatus, and a button for cleaning / cleaning the cleaning nozzle WN1-1.
A nozzle cleaning button SWk for moving the cleaning nozzle WN1-1 forward and backward for maintenance and the like, a bottom cleaning button SWb for turning on and off the bottom cleaning, and a bidet cleaning button SWd for turning on and off the bidet cleaning. With these two cleaning buttons,
Local cleaning can be performed even when the remote operation device cannot be operated due to battery exhaustion or the like. The buttons on the side of the seating sensor are a deodorizing setting button SWy and a room warming setting button SWw similar to those of the remote control device. Further, each knob behind the seating sensor is a hot water knob for turning on / off the hot water heater and setting the hot water temperature, a toilet seat knob for turning on / off the heating toilet seat and setting the toilet seat temperature, a drying knob for setting the drying temperature, and an indoor heating temperature. Set the room warming knob.

B1 / water channel system / control system configuration: The local cleaning apparatus of this reference example has the following water channel system configuration and control system configuration in order to perform cleaning operation, drying operation, etc. corresponding to the above-mentioned buttons. As shown in FIG. 4, the water channel system of the local cleaning device includes an inlet valve unit WP1-1, a heat exchange unit TH1-1, and an outlet valve unit WP1-3 from an external water supply source (not shown). . Then, the washing nozzle WN1-1 of the nozzle device NS1-1 is supplied from the water discharge side valve unit.
The cleaning water is guided to the nozzle, and the cleaning water is discharged from the nozzle as described later. Further, from the water discharge side valve unit, the cleaning water is also guided to the functional water units WP1-4, and the functional water is discharged from the unit toward the cleaning nozzle WN1-1. These units are connected by upstream and downstream water supply lines across the heat exchange unit. That is, the water inlet side valve unit and the heat exchange unit are connected to the upstream water supply line WP.
Each unit and the nozzle device downstream of the heat exchange unit are connected by a downstream water supply line WP1-6. In this case, four water supply pipelines are branched from the water discharge side valve unit WP1-3, three of which are connected to the nozzle device NS1-1, and the other are connected to the functional water unit WP1-4. These branch pipes also form part of the downstream pipe.

The upstream water supply pipe line WP1-5 is connected to the water inlet valve unit WP1-1 to supply cleaning water (tap water) directly from a water supply source (water pipe) to the local cleaning device. The washing water guided to the upstream water supply pipe flows into the check valve WP1-8 and the constant flow valve WP1-9 after catching dust and the like by the strainer WP1-7 of the water inlet valve unit. Then, when the conduit is opened by the solenoid valve WP1-10 downstream of the constant flow valve, the washing water flows into the heat exchange unit TH1-1 of the instantaneous heating method in a state where the flow rate is set to a predetermined flow rate by the constant flow valve. . In this reference example, about 500 to
The cleaning water flow rate is set to about 1000 cc / min. The upstream water supply pipe WP1-5 may be branched from a flush water tank (not shown) for storing flush water for flushing the toilet and piped to the water inlet valve unit WP1-1.

A relief valve WP1-1 is provided on the upstream water supply line between the water inlet valve unit and the heat exchange unit.
1 and a second washing water outlet pipe WP branched directly from the upstream water supply pipe.
1-13 are provided. The first washing water outlet pipe draws out the washing water in the upstream water supply pipe when the pipe pressure on the upstream side of the relief valve rises for some reason and the pipe is opened by the relief valve. As a result, it is possible to avoid an increase in the tank internal pressure in the upstream water supply pipe, and hence the heat exchange unit. You don't have to. Further, the second washing water outlet pipe is connected to a set flow rate at the constant flow valve and a flow regulating pump WP1-14 described later in the downstream water supply pipe WP1-6.
The cleaning water with a flow rate that is different from the adjusted flow rate in step (1) is led out. Thus, it is possible to omit useless washing water hot water in the heat exchange unit, and it is possible to reduce power consumption.

The first and second washing water outlet pipes are arranged such that their ends face the deodorizing air inlet and the local drying outlet. Therefore, the washing water derived from the two conduits is discharged to these intake ports and exhaust ports. Since the intake port and the exhaust port face the bowl portion of the toilet bowl, they may be contaminated by splashing water of dirt disposed on the ball portion. However, since the intake port and the exhaust port are washed with the washing water from both the above-mentioned outlet pipes, it is preferable from the viewpoint of hygiene and cleanliness. Note that the flush water spouted from the outlet pipe flows down to the bowl bowl portion and does not stain the periphery of the toilet bowl.

The heat exchange unit TH1-1 downstream of the water inlet valve unit includes a tank TH1-3 containing a heater TH1-2. This heater is configured by spirally winding a nichrome wire having good thermal responsiveness. Therefore, the tank only needs to have a capacity capable of instantaneously heating the washing water by the heater, so that the size of the tank and thus the entire heat exchange unit can be reduced. Further, since the structure of the heat exchange unit is simplified, there are advantages in manufacturing such as reduction in the number of assembling steps and cost reduction. A bimetal or a thermal fuse (not shown) that mechanically shuts off abnormal heating is attached to the heater or its vicinity.

The heat exchange unit measures the temperature of the washing water flowing into the tank and the temperature of the washing water flowing out of the tank by using an inlet water temperature sensor SS16a and an outlet water temperature sensor SS16b.
The heater is used to warm the cleaning water to the cleaning water at the set temperature while detecting the temperature. In this case, if the heat exchange unit is covered with a heat insulating material such as a foam material, the power consumption of the heater for warming the washing water can be reduced in combination with the effect of keeping the washing water warm by the heat insulating material. That is, the energy saving effect increases.

This heat exchange unit has a float switch SS18 for detecting the water level in the tank. This float switch is configured to output a signal to that effect when the temperature of the heater becomes equal to or higher than a predetermined water level at which the heater is submerged.
Then, since the electronic control unit CT1-1 controls the energization of the heater under the condition that this signal is being input, it is possible to avoid a situation in which energization of a heater that is not submerged, that is, a so-called empty heating of the heater. . The heater of the heat exchanger unit is optimally controlled by a later-described electronic control device while combining feed-forward control and feedback control.

Further, this heat exchange unit is provided with a vacuum breaker TH1-4 at the outlet of the washing water from the tank, that is, at the tank connection point of the downstream water supply line WP1-6. This vacuum breaker introduces air into the pipe to cut off the washing water in the downstream water supply pipe, and prevents backflow of the wash water from the downstream side of the downstream water supply pipe.

The water discharge side valve unit WP1-3 downstream of the heat exchange unit has a flow regulating pump WP1-14 composed of a gear pump and the like, and a switching valve WP1-15 having a five-way valve structure. This switching valve directs the supply destination of the washing water to the ass washing flow path, the soft cleaning flow path, the bidet cleaning flow path, and the flow path to the functional water unit WP1-4 to the cleaning nozzle WN1-1 (function). Water channel). Therefore,
Wash water that has been heated by the heat exchange unit and flow-adjusted by the flow control pump is discharged from the water supply destination switched by the switching valve. At this time, the flow adjustment and the water supply destination switching will be described later.

As shown in FIG. 5, the control system of the local cleaning apparatus of this embodiment is mainly composed of an electronic control unit CT1-1 mainly including a microcomputer. This electronic control device includes various sensors such as the above-mentioned seating sensor, incoming / outgoing water temperature sensor, and a float switch, swing detection circuits NH1-39 and NH40 described later, a fall detection sensor SS30,
In addition to the signal from the washing water amount sensor SS14, the operation status of the various operation buttons in the remote operation device, the various operation buttons in the auxiliary operation unit on the main body side, and the knob are transmitted via an input circuit via a wired or wireless (optical signal). ). In this case, the washing water amount sensor detects the amount of washing water in the downstream water supply pipe, and outputs the detection result to the electronic control unit. The fall detection sensor detects the inclination state of the main cleaning unit and outputs the result to the electronic control unit.
The electronic control device controls the solenoid valve on / off valve of the water inlet side valve unit WP1-1, energization control of the heater of the heat exchange unit TH1-1, and the flow control pump of the water outlet side valve unit WP1-3 based on the input signal. Control, switching control of the switching valve, display control of the main body sleeve display, energization control of the drying unit KK1-1 including a drying heater and a fan motor for local drying, deodorization including an ozonizer for removing odors and a suction fan motor, etc. In addition to executing the energization control of the unit DS1-1 and the energization control of the heating unit DB1-1 including a heater for indoor heating, a fan motor, and the like, a functional water unit WP1 to be described later based on the signal.
-4 electrode control for chlorine generation electrode, nozzle device NS1-1
Of the nozzle drive motor and the energization control of the swing coil group of the nozzle head NH1-1. Note that the drying heater for local drying can be shared with a heater for indoor heating, and the fan motor for local drying can be shared with a fan motor for odor removal or indoor heating.

For example, when the local cleaning device is removed from the toilet for cleaning or the like and leans against the toilet, the signal of the float switch may be normal. In such a case, the heater may be exposed, but the signal from the float switch may be normal, and the heater may be idle. However, the tilt detection sensor detects this inclination by leaning on the toilet, and upon receiving the signal, the electronic control unit stops energizing the heater to prevent empty heating. In addition, the solenoid valve and the like are controlled to be closed so that the water is stopped, and various functions such as drying and deodorizing are stopped. That is, the fall detection sensor can detect the normal mounting state of the local cleaning device on the toilet, and as a result, the functions (cleaning, drying, deodorizing, and room warming) of the local cleaning device can be temporarily stopped. Other device controls will be described later. A limit sensor consisting of a thermistor or a temperature-sensitive reed switch is provided at the tip of the cleaning nozzle and connected to the electronic control unit. It can be in water. This is preferable because it is possible to more effectively avoid discharging the cleaning water having an inadvertent temperature to the local area.

C1 / Nozzle Device NS1-1: Next, the nozzle device NS1-1 of the local cleaning device of this reference example will be described. FIG. 6 is a schematic perspective view showing the nozzle device NS1-1, FIG. 7 is an explanatory diagram for explaining how the cleaning nozzle WN1-1 moves forward and backward, and FIG. 8 is at a standby position in the local cleaning device main body. It is explanatory drawing showing the periphery of a washing | cleaning nozzle front-end | tip part.

As shown, the nozzle device NS1-1
Is stored and installed in the main body KS1-2 (see FIG. 1) of the local cleaning device. The nozzle device includes a base NS1-2 fixedly installed on the main body, and a gantry N on an upper surface of the base.
Nozzle drive motor NS1 incorporated in S1-3
-4, a transmission mechanism NS1-5 for converting the forward / reverse rotation of this motor into a forward / backward movement and transmitting the forward / backward movement to the washing nozzle WN1-1, and a washing nozzle erected on the upper surface of the base so that the washing nozzle is slidable on the toilet bowl side. It has a nozzle holding portion NS1-6 for holding, and a guide rail portion NS1-7 for guiding the cleaning nozzle along a nozzle advance / retreat trajectory described later.

The transmission mechanism NS1-5 includes a drive pulley NS1-8 fixed to the rotation shaft of the nozzle drive motor NS1-4.
And driven pulleys N before and after along the nozzle advance / retreat trajectory.
S1-9, a timing belt NS1-10 stretched over these pulleys, and a tension roller NS1-11 for applying tension to the belt. The timing belt is engaged with and fixed to the cleaning nozzle WN1-1 via a belt holding body WN1-2 extending from the cylindrical portion WN1-4 of the cleaning nozzle WN1-1. Therefore, this cleaning nozzle
The timing belt is driven forward and backward according to the forward and reverse rotation of the timing belt.

The guide rail portion NS1-7 is curved so as to coincide with the arc-shaped nozzle advance / retreat trajectory NS1-12 shown in FIG. 7, and the track gripper W extending from the above-mentioned cylindrical portion.
It is engaged with the nozzle via N1-3. The track gripper has a track gripping surface having the same radius of curvature as the nozzle advance / retreat track, and the track gripping surface is slidable with respect to the guide rail. In addition, the above-described nozzle holding unit NS
1-6 slidably holds the cleaning nozzle. Therefore,
When the cleaning nozzle WN1-1 is driven forward and backward by the timing belt, the cleaning nozzle WN1-1 is driven forward and backward along the guide rail portion NS1-7, and its movement trajectory coincides with the arc-shaped nozzle forward and backward trajectory NS1-12. In this case, even in the case of the washing nozzle, the cylindrical portion WN1-4 has a curved radius along the axial direction with the same radius of curvature as the nozzle advance / retreat trajectory.
For this reason, the cleaning nozzle moves back and forth between the standby position HP in the main body and the cleaning position (butt cleaning position AWP, bidet cleaning position VWP) in the toilet bowl portion in accordance with the arc-shaped nozzle advance / retreat trajectory. Drive. The nozzle holding unit NS1
No. -6 is configured to only partially contact the nozzle outer wall in order to reduce the sliding resistance of the cleaning nozzle.

As a result, as shown in FIG.
The cleaning nozzle WN1-1 of P can be mounted on the nozzle device NS1-1 so as to approach the upper surface of the toilet bowl along its axial direction. Therefore, the height of the rear end of the washing nozzle (nozzle height) from the upper surface of the toilet can be made lower than when the cylindrical washing nozzle advances and retreats along an inclined straight orbit. Therefore, the body portion KS1-2 (see FIG. 1) is reduced by the reduction in the nozzle height.
And the size of the local cleaning device itself can be reduced. Further, since the angle of the upper surface of the nozzle head changes due to the advance of the nozzle, and the angle of spouting the washing water from the head changes, the washing range can be largely moved with a small nozzle movement. Specifically, even if the reciprocating range of the nozzle during the move cleaning described below is narrowed, the cleaning water can be discharged over the cleaning range required for the move cleaning. Alternatively, even if the nozzle moving distance from the buttocks washing position AWP to the bidet washing position VWP is short, the washing location with the washing water can be changed from the buttocks to the bidet.

D1 / functional water unit WP1-4;
Functional water unit W prior to description of washing nozzle WN1-1
P1-4 will be described. FIG. 9 shows the functional water unit W
FIG. 10 is a schematic cross-sectional view taken along the line 10-10 in FIG.

As shown, the functional water units WP1-4
Is a functional water generation tank WP1-16 fixedly installed in the nozzle device NS1-1 (refer to FIG. 6), and a pair of flat-plate-like chlorine generation electrodes WP1-1 opposed to each other in the tank.
And 7. The functional water generation tank is a resin tank having chemical resistance (free chlorine resistance), and the washing water flowing into the tank from the inner pipe WP1-18 flows into the outer pipe WP1-19. . As shown in FIG. 6, FIG. 8 and FIG.
It is fixed to the chamber NS1-14 at the tip of 1-6. In addition, the in-side pipeline and the out-side pipeline are arranged facing each other,
The cleaning water may flow efficiently in the tank.

Here, the chlorine generation electrode is an electrode capable of inducing a chlorine generation reaction, and has an electrode structure in which an electrode shape is formed of a conductive base material and a chlorine generation catalyst is supported on the surface thereof. And a structure in which an electrode is formed using a conductive material composed of a chlorine generation catalyst. Electrodes for chlorine generation of this latter structure are variously referred to depending on the type of catalyst for chlorine generation, for example, iron-based electrodes such as ferrite, palladium-based electrodes, ruthenium-based electrodes, iridium-based electrodes, platinum-based electrodes, ruthenium-tin. System electrode, palladium-platinum system electrode, iridium-platinum system electrode, ruthenium-platinum system electrode, iridium-platinum-tantalum system electrode and the like. In the case where the chlorine-generating catalyst is supported on the conductive base material, the base material for the structure can be made of inexpensive materials such as titanium and stainless steel, which is advantageous in manufacturing cost. In particular, when using tap water having a chlorine ion content of only about 3 to 40 ppm in the chlorine ion-containing water, an iridium-based electrode supporting iridium and an iridium-platinum alloy in order to improve the generation efficiency of free chlorine. An iridium-platinum-based electrode carrying iridium, a iridium-platinum-tantalum-based electrode carrying an iridium-platinum-tantalum alloy, and the like are suitable. In addition, when using a catalyst in which a chlorine-generating catalyst is supported on a conductive base material as described above, when a platinum-containing alloy catalyst is supported, the fixing strength to the base material is increased, so that desorption does not easily occur. It is preferable because the life can be improved.

A DC voltage is applied to the chlorine generating electrode such that one is an anode and the other is a cathode. Wash water supplied to the functional water unit is tap water containing chlorine ions that is a source of free chlorine generation. Therefore, by applying a DC voltage in a state where the washing water is stored in the tank of the functional water unit, free chlorine is generated on the anode side. Since free chlorine has a bactericidal effect on bacteria such as Escherichia coli adhering to the cleaning nozzle, the cleaning water enriched with free chlorine in the functional water unit (hereinafter referred to as functional water) is supplied to the cleaning nozzle in the nozzle holding section. By spouting the water, the propagation of bacteria can be prevented, which is sanitary. The state of the functional water spouting will be described later.

In the above functional water unit, about 50 cc of tap water is stored in the tank, and when a voltage of 24 VDC is applied to the chlorine generating electrode for about 1 minute, functional water having a free chlorine concentration of about 1.5 ppm is generated. The electrode area and the distance between the electrodes are determined so as to make it possible, and the electronic control unit controls the current supply to the chlorine generation electrode (constant voltage control). In this case, when the electric conductivity of the washing water is high and the current flows too much between the electrodes, the applied voltage is set to a low value to extend the life of the electrodes and prevent heat generation in the current-carrying part. Further, the applied voltage may be changed as needed in accordance with the electric conductivity of the washing water, and the control of energization to the chlorine generation electrode may be controlled by constant current control or constant power control. The electronic control unit performs a certain period of time (approximately 1
Minutes), the power supply is stopped. As a result, it is possible to avoid problems such as excessive generation of free chlorine, an inadvertent increase in free chlorine concentration, a reduction in electrode life, and generation of bubbles due to excessive electrode heating.

The functional water generated by the functional water unit is discharged to the nozzle head NH1-1 for nozzle cleaning in pre-nozzle cleaning and post-nozzle cleaning (see FIGS. 25, 26, and 30) described later. In addition, to fulfill the sterilization function,
Water is discharged at the following timing. That is, a timing based on the detection of the use state of the user (for example, detection of a seating sensor or a cleaning operation), a periodic timing every predetermined time,
For example, at the timing of a timer such as 6:00 in the morning, 12:00 in the daytime, and 11:00 at night, the functional water is discharged from the out-side pipe line WP1-19 to the nozzle head NH1-1. Even with the functional water spouting performed at each of these timings, in the case of a storage type that is used after the functional water is generated in advance, the timing of generating the functional water is the same as the timing described above, and The energization for generating functional water is stopped when a certain time has elapsed from the start of energization. In this case, the execution timing of the periodic discharge of the functional water performed at the above-described regular timing can be set arbitrarily, such as every two hours or every four hours. When the functional water spouting is performed at these timings, the flow control pump WP1 suitable for the functional water spouting is used.
The flow rate is adjusted by -14 and the flow path is switched to the functional water flow path by the switching valve WP1-15. Further, as described above, the tank of the functional water generation unit is not limited to the storage type (50 cc storage), but may be a type in which the water passage is sandwiched between chlorine generation electrodes. In this type, the above-described electrode energization control is executed at each of the above-described timings, and each time functional water is discharged through flow path switching.

E1 / cleaning nozzle WN1-1 and nozzle head NH1-1; Next, the cleaning nozzle WN1-1 will be described. 11 is a schematic sectional view taken along line 11-11 of FIG. 8, FIG. 12 is an enlarged schematic perspective view of the nozzle head NH1-1 at the tip of the cleaning nozzle, and FIG. 13 is a schematic sectional view taken along line 13-13 of FIG. 14 is a plan view of the nozzle head base NH1-2.

As shown in FIGS. 6 to 8, the cleaning nozzle WN1-1 has a curved cylindrical portion WN1-4 and a nozzle head NH1-1 at the tip thereof. This cylindrical part is shown in FIG.
As shown in FIG. 1, storage chambers WN1-5 divided vertically are provided in the longitudinal direction of the nozzle. The upper and lower storage chambers are shut off (separated) from each other by a central wall, and are closed by a cover portion WN1-6 at an appropriate position on the outer peripheral wall of the tubular portion. A flat cable NH1-42 to be described later is stored in the upper storage chamber. The flat cable NH1-42 is taken out from the end of the cleaning nozzle and connected to the electronic control device described above. The flat cable and a flexible tube to be described later are stored and assembled in the storage room without any trouble with the cover part removed.

In the lower storage room, three flexible tubes are stored, and each flexible tube is
First nozzle flow path WN1- serving as a bottom cleaning nozzle flow path
7. Second nozzle flow path W to be a soft cleaning nozzle flow path
N1-8 and a third nozzle channel WN1-9 serving as a bidet cleaning nozzle channel. These flexible tubes are connected via a tube connecting portion (not shown) at the end of the nozzle to a flow path for cleaning the tail, a flow path for soft cleaning, and a flow path for bidet cleaning downstream of the switching valve WP1-15 in FIG. . Each flexible tube is shown in FIGS.
As shown in (1), the first base channel NH1-3 serving as a base cleaning channel for the tail end of the nozzle head base NH1-2 projecting from the distal end of the cylindrical portion, and the second base channel serving as a base channel for soft cleaning. NH1-4 and a third base channel NH1-5 serving as a bidet cleaning base channel. Therefore, when the switching valve WP1-15 (see FIG. 4) switches the supply destination of the washing water to any one of the downstream buttocks washing channel, the soft washing channel, and the bidet washing channel, the washing water is supplied. The water flows into the nozzle flow path / base flow path through the switched flow path, and is discharged from each of the water discharge holes described later of the nozzle head. The first to third nozzle channels WN1-7 to WN9 may be formed in the cylindrical portion WN1-4 at the time of molding.

The nozzle head NH1-1 has a nozzle passage
The following configuration is provided to discharge the washing water flowing into the base flow channel toward a local portion. This nozzle head is configured by mounting a head cover NH1-6 on a nozzle head base NH1-2. This head cover includes a buttocks movable body NH1-9 having a buttocks spout NH1-7 used for normal ass washing and a soft spout NH1-8 used for soft washing of the buttocks, and a bidet spouting hole used for bidet washing. NH1-
And a bidet movable body NH1-11 having the front and rear surfaces 10 on the upper surface of the cover. As shown in FIG. 13, the head cover has an engaging claw NH1 on the upper edge of the nozzle head base.
It has a cover-side engaging claw portion NH1-13 that engages with -12, and an engaging protrusion NH1-14 protruding from the rear peripheral wall. The cover-side engaging claw portion is formed over the front side peripheral wall excluding the rear peripheral wall. Further, since the leading end of the engaging protrusion is formed with a cross-shaped slit, the engaging protrusion can be contracted or expanded at the leading end to form the cylindrical portion WN1-4.
Can be inserted into and removed from the through hole of the front end wall. Therefore,
The head cover NH1-6 is attached to and detached from the nozzle head base NH1-2 via a slide along a white arrow in FIG. That is, this head cover is replaceable.

Here, the movable body will be described.
FIG. 15 shows a bidet movable body NH1-11 used for bidet cleaning.
FIG. 16 is a schematic plan view for explaining the bidet movable body and its related members, and FIG. 17 is a schematic perspective view for explaining the bidet movable body and the related members.

As shown in FIGS. 12, 13 and 15, the bidet movable body NH1-11 is provided with a head cover NH1.
-6, a flange portion NH1-15 fixed to the upper surface of the cylinder -6, a cylindrical portion NH1-16 at the center thereof, and a water discharging piece NH1- located at a central through hole of the cylindrical portion and having a bidet water discharging hole NH1-10 at the center. 17 and a magnetic driver NH at the lower end of the water discharge piece.
1-18. The flange portion NH1-15 and the cylindrical portion NH1-16 are made of an elastic material such as rubber, elastomer, or the like that exhibits a deformation restoring property. In order to prevent sewage from adhering to the elastic material or prevent the elastic material from deteriorating due to functional water spouting, the surface of the elastic material is subjected to a water repellent treatment (for example, a fluorine coating treatment).
And hydrophilic treatment (for example, coating of titanium oxide). The water discharge piece NH1-17 is a resin molded product, and the lower end of the bidet water discharge hole of the water discharge piece is a large-diameter water discharge guide hole NH1-19. Magnetic driver NH1-
Reference numeral 18 denotes a press-formed product of a water-resistant and rust-proof magnetic material, for example, an electromagnetic stainless steel plate, which is integrally formed with the water discharging piece NH1-17 by an insert molding method or the like. In general, the material of the magnetic driver may be a soft magnetic material that is a high magnetic permeability material, and examples thereof include silicon steel, ferrite, and pure iron. The surface treatment such as electroless Ni plating is performed to prevent rust. It is preferable to aim. Since this water discharge piece is fitted and fixed in the central through hole of the cylindrical portion, the bidet movable body NH1
Reference numeral -11 denotes a sub-assembly made of the above members. And this movable body for bidet, at the peripheral edge of the flange,
It is fixed to the head cover by an appropriate method such as an adhesive, welding, or screwing. For this reason, the bidet movable body NH1-11
Can be swung in each direction by deforming and restoring a connecting portion between the flange portion and the cylindrical portion while being supported by the flange portion and hung down.

The magnetic driving body NH1-18 has magnetic operating portions NH1-18a-18c on the periphery. Therefore, when a magnetic attraction force acts on each magnetic acting portion, the corresponding magnetic acting portion moves downward, and the bidet discharge hole is inclined in accordance with the downward movement of the magnetic acting portion. Then, by energizing and sequentially energizing an electromagnetic coil, which will be described later, which is disposed circumferentially at a predetermined interval corresponding to each magnetic acting portion in a counterclockwise or clockwise direction, the magnetic coil attracted by the energized electromagnetic coil Since the action portion sequentially moves, the bidet discharge hole also moves three-dimensionally in a counterclockwise and clockwise order while being inclined accordingly. The swing angle of the bidet spout hole (spout angle of the spout hole α: see FIG. 16) adjusts the strength of the suction force, that is, adjusts the voltage value (ie, current value) of the energizing voltage of the electromagnetic coil. It can be changed by adjusting the duty ratio of the energizing voltage. Further, since it is sufficient to apply a suction force enough to cause deformation at the flange connecting portion, the bidet movable body NH1-11 easily swings.

The buttocks movable body NH1-9 is different from the above-mentioned bidet movable body in its shape because it has the above-mentioned two water discharge holes, but a member which has the same function as this bidet movable body is used. Have. Therefore, the description thereof will be omitted, and the drawings will be given only reference numerals.

If the magnetic driver is made of a hard magnetic material, not only the attractive force but also the repulsive force can be applied to the magnetic driver by the magnetic force exerted on the magnetic driver. On the other hand, in the case of a soft magnetic material as in this reference example, an attractive force can be applied to the magnetic driving body by a magnetic force.

Next, the magnetic force generator NH1-26 which swings the movable body as described above will be described. FIG.
19 is a schematic exploded perspective view for explaining the magnetic force generator NH1-26, FIG. 19 is a plan view of an electromagnetic coil installation substrate NH1-28 of the magnetic force generator, and FIG. 20 is a circuit configuration formed on the upper surface of the substrate. FIG.

As shown in FIGS. 12 and 13, the magnetic force generator NH1-26 is in a state of non-contact with the two movable bodies, that is, in a state where a gap is secured between the lower end of the movable bodies.
Further, with a gap left between the front and left and right side walls of the nozzle head base, the nozzle head base NH1-
2 is fixedly installed on the upper surface. In the front and left and right side walls of the base, a gap between the side wall and the magnetic force generating body is provided with an outside air suction hole NH1-2 communicating with the outside of the nozzle head.
7 is empty. In this case, the opening area of each outside air suction hole is determined as follows. When the cleaning water is discharged from each of the water discharge holes of the buttocks, the soft, and the bidet, as shown in FIG. In this case, an ejector action occurs. Therefore, air is entrained in the washing water and is mixed in a foamy state. At this time, the air mixing rate is about 50-100.
%, The opening area of the outside air suction hole is determined in consideration of the flow path diameter before and after the gap. The opening position of each outside air suction hole on the side wall of the nozzle head base is lower than the lower surface of the magnetic force generator, and the front wall of the base is a sloped front end. Therefore, even if the cleaning water rebounds to the nozzle head during the cleaning operation, it is possible to prevent the repelling cleaning water from entering the nozzle head through the outside air suction hole. Further, it is possible to prevent the dirty washing water during the head washing with the brush or the like from entering the inside of the nozzle head. Further, the cleaning water leaked from the gap at the lower end of the movable body during the discharge of water from the water discharge holes of both movable bodies,
It is transmitted to the top and side surfaces of the magnetic force generator and discharged from each outside air suction hole. For this reason, the magnetic force generator, and furthermore, an electromagnetic coil described later therein can be cooled by the discharged washing water, so that a change in coil characteristics due to heat generation can be suppressed. In addition, since the outside air suction holes are provided corresponding to the respective movable bodies, there is no stagnation of the discharged washing water, and the cooling effect can be enhanced. The outside air suction hole may be provided only on the front wall of the base.

As shown in FIG. 18, the magnetic force generator NH1-
26 has an electromagnetic coil installation substrate NH1-28 on which various members described later are installed, and a frame NH1-29. This substrate is resin-molded by pouring a thermosetting resin into the frame of the frame, and is a sub-assembly integrated with the frame. In this case, the tip of each of the coil cores described later installed on the substrate and each of the water discharge holes NH1-46 to
48 are exposed to the outside. Therefore, there is no inconvenience due to leakage of coils, circuits, and the like, which will be described later, provided on the substrate.

The electromagnetic coil installation board NH1-28 is used to swing the hip swing coil group NH1-30 for swinging the hip swing body NH1-9 and the bidet movable body NH1-11. Rocking coil group NH1-31 for bidet. Each oscillating coil group includes a magnetic operating portion NH1-18a of a magnetic driver NH1-18, 23 of each movable body.
To 18c, 23a to 23c, and three electromagnetic coils NH1-32a to 32c, 33a to 33c. The respective electromagnetic coils are disposed and fixed to the substrate so as to face the respective magnetic action portions of the magnetic driving body.

Each of the electromagnetic coils has the same configuration, is provided with two coil cores NH1-35 standing upright on a plate NH1-34, and one coil core has a coil. Therefore, when the coil is energized, the electromagnetic coil is excited to form a magnetic flux (see FIG. 17) looping between the plate and the two coil cores. In this case, when the nozzle head is completed,
Since the two coil cores and the corresponding magnetically acting portions are opposed to each other, the above-described magnetic flux loops using the magnetically acting portion of the magnetic drive as a magnetic path. Then, the electromagnetic coil exerts an attractive force based on a magnetic force in accordance with the energization of the coil, on the opposing magnetic action portion. In other words, when the electromagnetic coil is excited, a magnetic flux passing through the opposing magnetic action portions is formed, and the magnetic action portions have opposite poles corresponding to the respective coil cores, that is, the S poles are applied to the magnetic action portions on the N pole iron cores. Since the poles are formed on the magnetic core in the core of the S pole and the N pole is formed in the magnetic core, the operating part is attracted to the respective coil cores. Even if the direction of the flowing current is changed, the polarity is N
The suction force acts in the same manner simply by reversing the steps S and S.
Moreover, the strength of the attraction force due to the magnetic force can be controlled through the control of energization of the coil. This plate and 2
Since both coil cores are made of ferromagnetic material,
The formation of the magnetic poles described above becomes remarkable, and an attractive force based on a strong magnetic force can be exerted on the magnetic action portion. Due to the action of the magnetic force of the electromagnetic coil, the two movable bodies and the water discharge holes thereof swing as described above. Is controlled as described later. In the following description,
For the sake of convenience, as shown in FIG.
The coils in each of the electromagnetic coils 1-30 are NH1-30
a to 30c, and the coils of the bidet swing coil group NH1-31 are represented by NH1-31a to 31c.

The circuit shown in FIG. 20 is formed on the electromagnetic coil installation substrate NH1-28 by a printing method in order to excite the respective electromagnetic coils in the rocking coil group for the buttocks and the bidet. . That is, this substrate is provided with a power supply line and a ground line of a predetermined DC voltage, and coils NH1-30a to 30c of the hip rocking coil group NH1-30.
And coil NH1-31 of bidet movable body NH1-11
transistors Tr1 to Tr6 connected to a to 31c to turn on and off the current to each coil; a base line for adjusting a base voltage via resistors R1 to R6 to turn on and off each of the transistors Tr1 to Tr6; It has output lines NH1-36 and 37 for outputting the state of current supply through the resistors R7 and R8 for voltage adjustment.
The resistors R7, R8 and the output lines NH1-36, 37 constitute swing detection circuits NH1-39, NH40 shown in FIG. Is detected. Each line in this circuit is connected to a flat cable NH1-42 at a terminal at the end of the board, and is connected to the electronic control unit CT1-1 via the cable. In this case, the transistors Tr1 to Tr6 and the resistors R1 to R8 can be installed as a coil control circuit (not shown) in the electronic control device, so that the magnetic force generator and thus the nozzle head can be downsized. Also, the resistors R7 and R8 and the output line NH
The swing detection circuit NH1-3 composed of 1-36 and 37
9 and 40 are for detecting the occurrence of an abnormality in coil energization, and therefore can be configured as follows. That is, a position detection device such as a Hall IC or an optical sensor is used in place of the two resistors, and the movement of the object to be driven (such as a magnetic acting portion) by the electromagnetic coil is detected by the position detection device. Then, a swing detection circuit is configured to detect the occurrence of coil energization abnormality based on the detection result of the position detection device. When the substrate is installed on the nozzle head base NH1-2, as shown in FIG. 13, a flat cable is assembled with a rubber bush NH1-43 interposed.

The electromagnetic coil installation substrate NH1-28
Has the following configuration in order to supply the cleaning water to the movable body, in addition to the swing coil group for swinging the movable body. That is,
As shown in FIG. 13 and FIG. 18, this substrate has a first protruding portion NH1-4 surrounded by a hip rocking coil group NH1-30.
4 and the second surrounded by the bidet swing coil group NH1-31.
It has a protrusion NH1-45. The first protruding portion has an inner bottom water discharge hole NH1-46 communicating with the first base flow path NH1-3 of the nozzle head base NH1-2, and a soft water discharge inside the head communicating with the second base flow path NH1-4. Hole NH
1-47. The second protruding portion is provided in the third base flow path N
It has a bidet water discharge hole NH1-48 in the head communicating with H1-5. The water discharge holes in each of these heads are
Bottom spout hole NH1 of 1-9 or movable body NH1-11 for bidet
-7, soft water discharge hole NH1-8, bidet water discharge hole NH1-
10 are opposed to each other with the gap described above. Therefore, when the switching valve WP1-15 (see FIG. 4) switches the supply destination of the washing water to any one of the downstream buttocks washing channel, the soft washing channel, and the bidet washing channel, the washing water is supplied. The water is supplied to the movable body through the nozzle flow path, the base flow path, and the above-described water discharge holes in the heads via the switched flow paths, and water is discharged from the water discharge holes of the movable bodies. In addition, during the flushing of the wash water from each of the water discharge holes, the above-described air entrapment at the time of passing through the gap between the base flow path and the water discharge hole occurs, and the cleansing water contains air in a foamy state. It is spouted.

In this case, each of the water discharge holes NH1 in the head
-46 to -48 are smaller than or equal to the diameter of the tail water discharging hole, the soft water discharging hole or the bidet water discharging hole of each movable body (the same diameter as the opposed water discharging hole in this embodiment). Therefore, the spouting speed of the washing water spouted locally is determined by the diameter of the bottom spout hole, the soft spout hole, or the bidet spout hole of each movable body. Each of the water discharge holes of each movable body has the smallest diameter of the bottom water discharge hole, and the diameter of the bidet water discharge hole is softer than that of the bottom water discharge hole. Therefore, if the water force is set to be constant by the water force setting buttons SWhu and SWhd of the remote control device RC1-1 (see FIG. 2), the flush water is discharged from each water discharge hole of each movable body. The speed is the fastest in the buttocks spout, and slower in the bidet and soft spouts than in the buttocks spout. As described above, in the soft cleaning using the soft water discharge hole having a low water discharge speed, the washing feeling received from the water discharge is made at least softer by the lower water discharge speed than in the case of the normal butt cleaning at the bottom water discharge hole. In addition, the bidet water discharge hole and the soft water discharge hole are not limited to a single hole as in this reference example, and a plurality of small-diameter pores are arranged to form a bidet water discharge hole and a soft water discharge hole as a whole. You can also. In this case, if the total area of the water discharge holes, which is the sum of the areas of the plurality of pores, is equal to or more than the area of the bottom water discharge holes, the water discharge becomes softer as a whole of the pores than in the case of the bottom cleaning.

Next, taking the bidet movable body NH1-11 as an example, how the wash water is discharged from the bidet discharge holes NH1-10 of the movable body will be described. FIG. 21 shows an electromagnetic coil NH1-33 when driving the bidet movable body NH1-11.
FIGS. 22A to 22C are explanatory diagrams for explaining the states of excitation of a to 33c.
FIG. 23 is an explanatory view schematically illustrating the state of the wash water spouting from the bidet spout NH1-10, FIG. 23 is an explanatory view schematically illustrating the instantaneous state of the wash water spouting, and FIG. It is another explanatory drawing for demonstrating the aspect of excitation of NH1-33a-33c.

The electronic control unit CT1-1 generates a pulse signal (transistor ON signal) and sequentially applies the pulse signal to the bases of the transistors Tr4 to Tr6 corresponding to the electromagnetic coils NH1-33a to 33c. I do. Therefore, the electromagnetic coils NH1-33a to 33c turn ON / OFF the respective transistors in accordance with the pulse signal, and
As shown in FIG. By such repeated excitation of each electromagnetic coil, the bidet movable body NH1-
The eleven magnetic action parts NH1-18a to 18c exert an attractive force by coil excitation (hereinafter, this force is referred to as a coil action force).
Are sequentially received. Therefore, this movable body is
As shown in (2), the coil is inclined in accordance with the magnetic acting portion that has received the coil acting force, and the inclined portion is shifted along the excitation direction of the electromagnetic coil. As a result, the bidet spout NH1-10
Is tilted together with the movable body at the water discharge hole swing angle α (see FIG. 16), and swings and rotates in accordance with the tilt position transition of the movable body while maintaining the tilted posture. Thus, when the cleaning water is supplied to the movable body as described above, the cleaning water is discharged in the following water discharge form.

Since the spouting hole of the washing water is inclined at the spout angle α, the spouting water from the spouting hole is schematically represented as a water column as shown in FIG. 22.
Is inclined at the above-described water discharge hole swing angle α. In addition, since the water discharge hole is oscillatingly rotated, the schematic water discharge column RT moves in accordance with the swing rotation of the water discharge hole with the water discharge hole swing angle α, and the schematic water discharge column continues one after another. Therefore, the wash water is discharged in a water discharge form such as a conical shape as illustrated in which the schematic water discharge columns RT are arranged (hereinafter, this water discharge form is referred to as a pseudo-conical water discharge form). When this state is captured instantaneously, as shown in FIG.
It can be simulated that the washing water is spouted spirally on the side wall of the cone defined by When the washing water is discharged in such a mode, the movable body does not rotate because the movable body is fixed at the periphery of the flange. That is, only the water discharge hole is pivotally rotated at the water discharge hole swing angle α without causing the movable body to rotate. In addition, the movable body does not cause the swing rotation, but merely causes the inclination position transition.However, the movement of the movable body associated with the swing rotation of the water discharge hole is referred to as a pseudo oscillation It is called rotation.

The tail water discharge hole NH1-7 which swings and rotates at the water discharge hole swing angle α inclines with respect to the head water discharge hole NH1-46 below the head. Then, in such a positional relationship, the washing water is supplied from the bottom water discharge hole in the head to the bottom water discharge hole NH1-7 of the movable body. In this case, since the lower end of the bottom water discharge hole of the movable body is a large-diameter water discharge guide hole NH1-24, the washing water from the rear water discharge hole in the head is guided by the water discharge guide hole without any trouble. Water is spouted from the ass spout.

In this reference example, when exciting each electromagnetic coil, the generation cycle (pulse cycle) of the pulse signal
, And the duty ratio (t / T) when the ON time of the pulse signal is represented by t is variably controlled. By this duty ratio control, the magnetic action portions NH1-18a to 18c of the movable body
Can be controlled to increase or decrease as follows. For example, as shown in FIG. 21A, the excitation period Tc (= Tc1) and the pulse period T (= T1) of each electromagnetic coil are fixed, and the pulse ON time t is set to t1.
(Duty ratio: t1 / T1) and the pulse ON time t is set to t2 (t2 <t1, duty ratio: t)
2 / T1), the water discharge hole swing angle α can be increased in the control period A and decreased in the control period B according to the duty ratio. For this reason, as shown in FIG. 22, the range in which the wash water spouted in the above-described pseudo-conical spout form is spouted, in other words, the washing area is widened based on the large spout angle α in the control period A as shown in FIG. The cleaning area AS can be obtained. In the control period B, a smaller cleaning area BS can be obtained. That is, in this reference example, through the variable control of the duty ratio, the water discharge hole swing angle α, that is, the cleaning area can be controlled to be wide and narrow. In this case, the excitation order of the electromagnetic coils is changed from the order of the electromagnetic coils NH1-33a → 33b → 33c → 33a... To the order of the electromagnetic coils NH1-33a → 33c → 33b → 3.
3a... Can be reversed.

In this embodiment, the excitation cycle Tc of each electromagnetic coil is variably controlled. For example, as shown in FIG. 21B, the duty ratio is constant in the control periods C and D ((t3 / T2) = (t4 / T3), t3 ≠ t4, T2
{T3), the excitation cycle Tc of each electromagnetic coil can be changed in each control period (Tc1> Tc2). This excitation cycle Tc is the same as the typical individual water spouting column R shown in FIG.
The interval at which T strikes the part to be cleaned (local part of the human body) to stimulate the human body is determined.

In general, when a stimulus that can be sensed (in this reference example, a stimulus by the schematic water discharge column RT) is repeatedly applied to the same portion of the human epidermis, if the repetition interval is long and the repetition frequency is low, the person repeats the repetition. The sensed stimulus is sensed each time as a vibration stimulus. On the other hand, if the repetition interval is short and the repetition frequency is high, a person cannot perceive this intentionally repeated stimulus as a vibration stimulus but perceives it as a continuous stimulus. In other words, there is a dead band frequency that cannot be sensed as a vibration stimulus for a repetitive stimulus to the human epidermis. Here, assuming that the magnitude of the flow rate or flow velocity of the washing water is repeatedly discharged (hereinafter, referred to as repeated water discharging) in the washing of the local area and its surroundings from the stimulus of the human epidermis, the magnitude of the stimulation from the discharged water is repeated. This repeated spouting appears as a vibratory stimulus on the epidermis of the washed area. If this is a repetition frequency of about 5 Hz or more, the perception cannot follow the vibration based on this intentional repeated water discharge. For this reason, it becomes impossible to be conscious of the water discharge mode of intentional repeated water discharge, and discomfort due to unnecessary vibration is reduced. As the repetition frequency of the repetitive water discharge increases, it becomes more difficult for the perception to follow the vibration based on the intentional repetition of the water discharge. Therefore, when the repetition frequency becomes a repetition frequency of about 10 Hz or more, the majority having the normal perception This person can hardly perceive the vibration based on intentional repeated water discharge. Therefore, it is difficult to recognize a water discharge mode that is intentional repeated water discharge, and discomfort due to unnecessary vibration is further reduced. Further, at a repetition frequency of about 15 Hz or more, even the average part of the human epidermis exceeds the vibration recognition frequency, so that most people having ordinary perception do not feel discomfort. Furthermore, at a repetition frequency of about 20 Hz or more, even a sensitive part of the human epidermis exceeds the vibration recognition frequency, so that a large number of people with normal perception can surely feel continuous and good washing feeling. it can. In addition, at a repetition frequency of about 30 Hz or more, even in a sensitive part where nerves of the human epidermis are particularly concentrated, the frequency exceeds the vibration recognition frequency. be able to. When the repetition frequency is made to coincide with the commercial frequency (50 Hz in the commercial frequency region of 50 Hz, and 60 Hz in the commercial frequency region of 60 Hz), an effect that driving becomes easy is added. The higher the frequency, the more
It is possible to perform the washing while feeling the continuous washing feeling more reliably, and it is possible to sufficiently cope with a user who desires a softer washing feeling.

From the viewpoint of the dead band frequency, in this reference example, the excitation cycle Tc of each electromagnetic coil is determined by its excitation frequency f
(= 1 / Tc) is variably controlled so as to be in a range of about 5 Hz or more, and a stimulus to a local part of a human body by the schematic water discharge column RT is sensed as a continuous stimulus. In other words, the cleaning water is only intermittently discharged at a certain point in the human body part (for example, the cleaning point SP1 shown in FIG. 22) at the excitation cycle Tc.
Make them feel that they are receiving continuous flushing. Since this occurs at each of the washing water spouting points, the user can be given a washing feeling as if the washing water is uniformly and continuously being spouted over the washing area described above. This means the following.

In order to provide the above-described continuous washing feeling over a certain range of washing area, the existing washing nozzle having the washing water spouting hole fixed has a conical spread of the spouted washing water itself. I need. Therefore, it is necessary to supply a considerable amount of washing water at all times.
Wash water was spouted at a flow rate of about cc / min. In such water spouting, the washing water is constantly spouted at all the washing water spouting points. However, in the local cleaning device of this reference example, the cleaning nozzle WN1-
In giving a continuous washing feeling like the existing one by the above-mentioned pseudo-conical spouting form from 1 above, actually,
Intermittent water discharge at the excitation frequency f is merely performed. In other words, at each of the washing water spouting points,
In this reference example, since the discharge of the cleaning water is intermittently thinned out, the amount of the cleaning water can be reduced. Therefore,
In this reference example, the flow rate of the washing water is set to about 500 cc / min by the constant flow rate valve as described above, and it is only necessary to discharge the washing water at the maximum flow rate.

As described above, in order to prevent the water from being sensed as intermittent water discharge, the excitation frequency may be set to about 5 Hz or more.
The frequency was set to ６０60 Hz so that the feeling of continuous washing water spouting could be obtained more reliably.

Even if the excitation frequency f is set to the above-mentioned dead band frequency, it can be said that the sense of continuous spouting received from the continuous spouting of the wash water tends to be weaker as the excitation frequency f is lower.
Therefore, the excitation frequency f can be lowered within the above range to give a good stimulating feeling to the user's cleaning feeling, or the excitation frequency f can be raised to give a soft or mild stimulating feeling to the cleaning feeling.

Further, under the condition that the uniform continuity of washing water is provided over the washing area as described above, the size of the washing area can be controlled as described above. Therefore, when the washing area is narrowed and the user receives the washing water spouting in the narrow washing area, the washing water spouting point is concentrated and the washing area is widened to spread the washing water spouting point. Thus, a different feeling of washing can be given to the user who has received the spouting of the washing water. For example, since the pain point distribution is more dense around the anus than in the center of the anus, in the ass washing, a soft feeling of washing is given when the spouting point is concentrated, and hard when the spouting point is diffused. It can give a feeling of washing. Although the cleaning feeling can be changed by controlling the cleaning area in a wide or narrow manner, a case where the cleaning area is intentionally variably controlled through variable control of the duty ratio will be described later.

In FIG. 21, the case where one of the duty ratio and the excitation frequency is fixed and the other is controlled has been described. However, in the present embodiment, as shown in FIG. 24, the excitation frequency f can be controlled to increase or decrease according to the duty ratio. In FIG. 24A, a soft or mild stimulus can be given by increasing the excitation frequency f while increasing the duty ratio to increase the cleaning area. In other words, this is good when a large cleaning area is to be cleaned with a more continuous cleaning feeling. Conversely, while reducing the duty ratio to reduce the cleaning area, the excitation frequency f can be lowered to reduce the continuous sensation of water discharge and provide a good stimulus sensation.

On the other hand, in FIG. 24B, the excitation frequency f is lowered while increasing the duty ratio to increase the cleaning area. Therefore, in the case of ass cleaning, the excitation frequency f is lowered while giving a hard washing feeling due to a large washing area, and the sense of continuous water discharge is weakened. be able to. In addition, since the high excitation frequency f does not give an intermittent stimulus feeling while giving a soft washing feeling due to a small washing area, the soft washing feeling can be made more continuous. That is, by controlling as shown in FIG. 24, it is possible to further diversify the feeling of cleaning. Note that the excitation frequency f can be increased or decreased stepwise instead of linearly increasing or decreasing as shown in FIG.

Even if the excitation cycle Tc of each electromagnetic coil is changed while the duty ratio is kept constant as shown in FIG. 21 (b), the water discharge hole deflection angle α (wash area) is varied as follows. Can be set. If the excitation cycle Tc is shortened, the time during which the above-described coil acting force acts on the magnetic acting portion is shortened, so that the water discharge hole deflection angle α is reduced and the cleaning area is reduced.
Further, if the excitation cycle Tc is made longer, the operating time of the coil acting force becomes longer, so that the water discharge hole swing angle α becomes larger and the cleaning area becomes larger. Then, even in a situation where the excitation cycle Tc is fixed with a small value, if the duty ratio Dt is increased, the water discharge hole swing angle α can be increased to increase the cleaning area as described above. Similarly, in a situation where the excitation cycle Tc is fixed while being large, the duty ratio Dt can be reduced to reduce the water discharge hole swing angle α and the cleaning area. In other words, even if the excitation cycle Tc is fixed at the above value so that the dead band frequency becomes the above-mentioned value, the cleaning area can be set to be wide or narrow by the variable control of the duty ratio.

Further, in this reference example, the coil excitation control is performed such that all the electromagnetic coils are kept de-energized or all the electromagnetic coils are excited at the same time under the continuation of the washing water spouting. You can do it too. In this case, when all the electromagnetic coils are de-energized, the cleaning water is discharged from the water discharging hole of the movable member in a free state to one point with air mixing. On the other hand, when all the electromagnetic coils are excited at the same time, the wash water is discharged from the water discharge hole of the movable body adsorbed to the magnetic force generator at one point without air mixing. The coil excitation control for causing such one-point concentrated water discharge is not performed continuously, but is performed in combination with the above-described control of the cleaning area through the duty ratio control. In other words, when the excitation of each electromagnetic coil is sequentially controlled at a duty ratio that results in a certain cleaning area, the simultaneous excitation of all the electromagnetic coils is intermittently incorporated and executed, and the execution cycle of the simultaneous excitation of all the electromagnetic coils is set as described above. Of the excitation frequency f. In this manner, the human body local range determined by the cleaning area and one point within the range can be washed while the user has a continuous sense of spouting of the washing water.

F1 / Washing / Drying Operation Routine Next, the washing / drying operation performed by the local cleaning apparatus of this embodiment having the above-described configuration will be described. FIG. 25 is a flowchart showing a butt and bidet cleaning and drying operation routine executed by the electronic control unit CT1-1, and FIG.
It is a flowchart of the nozzle pre-wash routine showing the details of the nozzle pre-wash process in the drying operation routine. FIG.
FIG. 7 is an explanatory view schematically showing the state of cleaning water spouting in nozzle pre-washing prior to the cleaning water spouting at the time of local cleaning, and FIG. Flowchart of cleaning routine, FIG. 2
FIG. 9 is an explanatory diagram for explaining the processing content of the main cleaning routine and the processing content of the operation stop routine.

The washing / drying operation routine of FIG. 25 is executed when one of the washing buttons (bottom, soft, bidet buttons) or the drying button is operated. In this cleaning / drying operation routine, FIG.
As shown in the flowchart of FIG.
By scanning S10, it is determined whether the user is seated on the toilet seat (step S100). If it is determined that it is not in the seated state, the local cleaning device is not used, so that the subsequent processing is unnecessary and this routine is terminated without performing any processing. If it is in a seated state, the local cleaning device is being used, so that either the cleaning button (the button for the bottom, the soft, or the bidet) or the drying button is used to perform the cleaning operation or the drying operation. It is determined whether the operation has been performed during execution of the routine (step S105). In the following description, the remote control device RC1-1 is used.
It is assumed that each of the buttons has been operated.

In the above step S105, the drying button SW
If it is determined that z has been operated, the drying operation inhibition flag FKsto stored at a predetermined address of the backup RAM is determined.
The state of p is read, and it is determined whether or not FKstop = 1 (step S110). The drying operation prohibition flag FKstop indicates that a power supply abnormality has occurred in the drying unit KK1-1 (see FIG. 5) such as a drying heater for local drying or a fan motor. Further, if FSstop = 1, it indicates that cleaning or the like should not be executed for a coil abnormality (drying is not related). Then, the drying operation prohibition flag FK
In the stop, a value 1 or a value “0” is set in a drying failure detection routine and a recovery routine (not shown). Therefore, if an affirmative determination is made in step S110, this routine ends without performing any processing. If a negative determination is made in step S110, the above-described power supply control to the drying unit KK1-1 (step S115) is executed irrespective of the prohibition state of the cleaning operation as described later, and this routine ends. By this step S115, warm air is blown toward the local area, and local drying is performed. At this time, the power supply to the drying unit is controlled so that the hot air temperature becomes the drying temperature set by the drying knob of the auxiliary operation unit KS1-9 (see FIG. 3). The power supply to the drying unit is stopped in an operation stop routine described later.

On the other hand, if it is determined in step S105 that one of the buttocks, soft, and bide washing buttons has been operated, the state of the washing operation inhibition flag FSstop stored at a predetermined address in the backup RAM is read, and FSstop = 1. Is determined (Step S
120). The cleaning operation prohibition flag FSstop is determined by the coils NH1-30a to 30c and 31a to 31c of the electromagnetic coils in the swinging coil groups for the hips and the bidet (FIG. 1).
9, FIG. 20) shows that coil energization abnormality such as disconnection or contact failure has occurred. That is, FSstop = 1 means that the cleaning operation should not be performed for the coil abnormality, but the cleaning operation should be prohibited. The cleaning operation prohibition flag FSstop is set to a value of 1 in a swing detection routine to be described later and to a value of 0 (zero) in an abnormality recovery routine. Therefore, step S
If an affirmative determination is made in 120, this routine ends without performing any processing.

If a negative decision is made in step S120,
Prior to the cleaning water spouting for the local cleaning, nozzle pre-cleaning for cleaning the nozzle head NH1-1 (see FIGS. 5, 6, and 12) is executed (step S130).

As shown in the flowchart of FIG. 26, in the pre-nozzle cleaning routine, the solenoid valve WP1-10 of the water inlet valve unit WP1-1 shown in FIG. 4 is controlled to open (step S131). Next, the switching control of the switching valve WP1-15 to the flow path for functional water is performed, and the flow control pump WP1-14 is controlled.
The drive control to the function water discharge flow rate is performed (step S1).
32). Thereby, functional water (free chlorine solution) is discharged toward the nozzle head at the standby position HP shown in FIG. 8, and the head is sterilized and washed. As described above, in the functional water unit, since the functional water has already been generated in the tank at each of the above timings, the generated functional water is discharged by the tank storage amount (about 50 cc).

Next, in order to stop the functional water discharge, the switching control of the switching valve WP1-15 from the functional water flow path to the buttocks cleaning flow path and the nozzle cleaning flow rate of the flow control pump WP1-14 are performed. Is performed (step S133). Thus, in a state where the nozzle head is at the standby position HP shown in FIG. 8, the cleaning water is discharged from the tail water discharge port NH1-7 of the nozzle head toward the chamber NS1-14. At this time, since the above-described coil excitation is not performed, the ass movable body NH
1-9 is a free state in which no swing rotation occurs. Therefore, as shown in FIG.
The washing water is spouted at one point. In addition, since the bottom water discharge hole NH1-7 has a small diameter, the water discharge speed is high. For this reason, the cleaning water rebounds vigorously in the chamber, and the nozzle head is cleaned with the repelling cleaning water.
This makes it possible to preferably clean the nozzle head, more specifically, the water discharge holes of the nozzle head and the periphery thereof. In addition, the functional water (free chlorine solution) applied to the nozzle head in step S132 can be washed away. If the functional water generation unit is of the type in which the water passage is sandwiched between the chlorine generation electrodes, the power supply control to the chlorine generation electrodes WP1-17 (see FIG. 9) for generating the functional water is performed in step S132. May be executed, and the energization of the chlorine generating electrode may be stopped in the subsequent step S133.

When the steps S132 and S133 in the nozzle pre-washing routine are executed, the ass movable body NH1-
9. It is also possible to simultaneously and continuously excite all the electromagnetic coils of the bidet movable body NH1-11. In this way, the buttocks movable body NH1-9 is added to the magnetic force generator NH1-26.
And the bidet movable body NH1-11 is adsorbed, and the gap between the lower ends of both movable bodies and the magnetic force generator NH1-26 is closed.
Corrosion promotion of the magnetic driving body NH1-18 and the coil core NH1-35 due to functional water scattering can be suppressed.

Further, when the above-described step S133 is executed, it is also possible to continuously excite only the electromagnetic coil NH1-32a on the front side of the buttocks movable body NH1-9. In this way, the washing water can be concentrated and discharged at one point in a state where the buttocks movable body (butt water discharging hole) is inclined toward the bidet movable body NH1-11. Therefore, even though the water is discharged from the bottom water discharge hole, it is possible to surely splash back and apply the cleaning water to the soft water discharge hole, the bidet water discharge hole, and the vicinity thereof. For this reason, each water discharge hole and its periphery can be reliably washed. In addition, the bidet spout hole and its surroundings, which require the user to have a sense of cleanliness for the purpose of bidet washing, can be washed with high washing ability, and the sense of cleanliness can be enhanced.

Note that the washing water spouting at the time of the nozzle pre-washing is performed by the soft spouting hole NH1-of the buttocks movable body NH1-9.
8 and bidet discharge hole NH1-1 of bidet movable body NH1-11
It may be performed from 0. At this time, when flush water is discharged from the soft water discharge hole NH1-8, the excitation of the front electromagnetic coil NH1-32a and the simultaneous excitation of the two rear electromagnetic coils NH1-32b and 32c are repeated. The washing water may be discharged while swinging the buttocks movable body (soft water discharging hole) in the front-rear direction. By doing so, the water can be surely washed by splashing the cleaning water to the water discharge holes before and after the water discharge holes and the periphery thereof.
When the cleaning water is spouted at the time of pre-nozzle cleaning at the bidet spout NH1-10, the operation is the same as that of the buttocks spout.

Further, at the time of execution of the above-mentioned step S133, the buttocks movable body NH1-9 can be pseudo-oscillatingly rotated at a predetermined water discharge hole swing angle α. That is, a pulse signal for sequentially exciting each electromagnetic coil is output based on the duty ratio Dt that determines the water discharge hole swing angle α and the excitation cycle Tc of each electromagnetic coil (see FIG. 21). As a result, the buttocks movable body NH1-9 performs a pseudo swing rotation at the water discharge hole swing angle α and the excitation frequency f (= 1 / Tc), and the buttocks water discharge holes N
H1-7 also swings and rotates with this. Therefore, FIG.
As shown in (b), the flush water is discharged from the hip water discharge hole NH1-7 in a pseudo-conical water discharge form shown in FIGS. By doing so, the range of spouting of the washing water in the chamber NS1-14 is expanded, so that not only the buttocks spouting holes but also the soft spouting holes, the bidet spouting holes and the periphery thereof can be reliably washed with the washing water. In this case, since the washing water is discharged from the chamber and not the human skin, the excitation frequency f (= 1 / Tc) does not need to be set to the above-mentioned dead band frequency, and may be appropriately determined.

The processing in step S133 is performed for a predetermined time.
For example, after continuing for about 1 second, stop control of the flow regulating pump (zero flow) and closing control of the solenoid valve are sequentially performed (steps S134-135), and the process proceeds to step S140 in FIG.

Subsequent to the above-described nozzle pre-cleaning, the nozzle drive motor NS1-4 is controlled to rotate in the normal direction, and the cleaning nozzle WN1-1 is moved to a cleaning position corresponding to the cleaning button (butt, soft, bidet). It is advanced from the standby position HP in the main body (step S140; see FIG. 7). The cleaning nozzle WN1-1 advances to the hip cleaning position AWP if the cleaning button is a soft bottom and the cleaning button, and advances to the bidet cleaning position VWP if the bidet cleaning button.

When the advance of the cleaning nozzle to the cleaning position is completed, the following main cleaning operation corresponding to the cleaning button (buttock, soft, bidet) is executed (step S150).
This routine ends. This main cleaning operation is stopped by an operation stop routine described later.

In this main cleaning operation, the movable body to be used differs depending on the cleaning button. Therefore, in the following description, the butt cleaning will be described as an example, and the soft cleaning and the bidet cleaning will be described only on the different points. I do.

As shown in the flowchart of FIG. 28, in the present cleaning routine, the solenoid valves WP1-10 are controlled to open so as to start the supply of the cleaning water that has been temporarily stopped during the nozzle advance to the buttocks cleaning position AWP. (Step S151). Next, the switching valve WP1-15 is switched to the buttocks cleaning flow path, and the flow control pump WP1-14 is driven to a predetermined weak water discharge flow rate (for example, flow rate level 1) (step S152). . As a result, the washing water having the above-described weak water discharge flow rate is discharged from the tail water discharge hole NH1-7 of the nozzle head toward the buttocks. The processing in step S152 in the case of soft cleaning and bidet cleaning is as described above, except that the flow path is switched by the switching valve to the soft cleaning flow path or the bidet cleaning flow path.

Thus, the flow rate of the weak water discharge at the time of the initial water discharge was determined as follows. Now, it is assumed that the flow rate can be adjusted to other levels, for example, levels 1 to 7 in the adjustable range (for example, 500 cc / min) by the flow regulating pump. In the above step S152, the ass movable body N
The washing water is discharged in a state where H1-9 is not movable (non-rotating rotation). Since the water spouting at the above-described excitation frequency f due to the swinging rotation does not occur, the water spouting water has a one-point concentrated water spouting form, and the water spouting speed is large because the bottom spout hole NH1-7 has a small diameter. . Therefore, step S
If the weak water discharge flow rate at 152 is, for example, the flow rate of the lowest level 1 in the above range, even if the speed is high and the water discharge is concentrated at one point, the user does not need to feel any particular discomfort or discomfort. Note that the washing water spouting in step S152 is as follows.
This is only a short period (less than about 0.5 seconds) at the beginning of the main cleaning. Also from this, the user does not have to feel any particular discomfort or discomfort. Hereinafter, a case will be described in which the flow rate of the weakly spouted water to be initially spouted is set to the flow rate level 1.

Following the flush water spouting at the weak spout flow rate (flow level 1) in step S142 (see FIG. 29), the habituation of the buttocks movable body NH1-9 during the pseudo swing rotation described above is performed. The buttocks movable body NH1-9 is initially driven for driving and swing abnormality detection (step S).
143). The swing abnormality detection will be described later in detail.

In the initial driving process, first, the duty ratio Dt for determining the water discharge hole swing angle α is set to an initial value α0 such that the water discharge hole swing angle α becomes the initial value α0 at which the running-in operation of the movable body and the detection of the abnormal swing can be performed. The duty ratio is set to Dt0. Since the initial duty ratio Dt0 is stored in the backup RAM, it is set by reading the value. Then, based on the initial duty ratio Dt0 and the excitation cycle Tc of each electromagnetic coil, a pulse signal for sequentially exciting each electromagnetic coil is output (see FIG. 21). As a result, the buttocks movable body NH1-9 quasi-oscillately rotates at the water discharge hole swing angle α0 and the excitation frequency f (= 1 / Tc), and the buttocks water discharge holes N
H1-7 also swings and rotates with this. Therefore, as shown in FIG. 29, the wash water having the weak water discharge flow rate (flow level 1) set in step S142 is discharged in the pseudo-conical water discharge form shown in FIGS. 22 and 23. It should be noted that even in this initial drive, only a short period (about 0.5 seconds or less) before the main cleaning drive in the next step is performed. The user does not have to feel uncomfortable or uncomfortable.

In this initial drive process, the water discharge hole deflection angle α
0 is only required to be able to detect swing abnormality and the like, and the water discharge flow rate at this time is also a weak water discharge flow rate (flow level 1).
There is no need to increase it carelessly. Therefore, a low value (for example, a value of about 10% of αmax or the minimum water discharge hole deflection angle αmi) in the range of the water discharge hole deflection angle α that can be adjusted in the present reference example.
n). The excitation frequency f (= 1 / Tc) is set to a predetermined value of the dead band frequency. Hereinafter, a case will be described in which the water discharge swing angle α0 at which water is initially discharged is set to αmin.

Next, following the above-described initial driving process,
The main body is driven for main cleaning (step S154). In the main cleaning driving process, the butt water discharge holes NH1-7 are oscillated and rotated in the practical range through the butt movable body NH1-9 to perform cleaning water discharge, and the pseudo cone shown in FIG. 22 and FIG. This is for actually performing local cleaning in the form of a spout. In the main cleaning drive process, first, the duty ratio Dt that determines the water discharge hole swing angle α is changed to an appropriate duty ratio Dt1 corresponding to a predetermined value of the adjustable water discharge hole swing angle α. Since the proper duty ratio Dt1 is stored in the backup RAM, it is set by reading the value. The proper duty ratio Dt1 is the first duty ratio D in the actual local cleaning by the main cleaning driving process.
Since it is t, a value corresponding to a predetermined value (for example, an intermediate value αmid) in the range of the water discharge hole swing angle α that can be adjusted in the present reference example (see FIG. 29). Hereinafter, a case will be described in which the predetermined water discharge swing angle α at the start of the main cleaning is αmid.

The appropriate duty ratio D thus read
t1 is written and stored in the RAM in order to deal with updating / setting in the spot-wide cleaning routine described later. If the duty ratio Dt is not updated / set in the spot / wide cleaning routine, the appropriate duty ratio Dt1 remains stored in the RAM. If the duty ratio Dt is newly updated / set in the spot / wide cleaning routine, , The appropriate duty ratio Dt1 of the RAM is rewritten with this new updated / set value. Therefore, after updating and setting of the duty ratio Dt during the continuation of the cleaning, the movable body and the tail water discharge hole are swung and rotated based on the rewritten duty ratio Dt.

The rewritten duty ratio Dt and the proper duty ratio Dt1 stored and retained without being rewritten are reset by the OFF signal of the seating sensor when the user rises from the toilet seat. .
Accordingly, when the user repeats the cleaning operation while sitting, the updated / set duty ratio Dt is used in the main cleaning driving process of the second and subsequent steps in step S154 instead of the appropriate duty ratio Dt1. be able to. Therefore, in the case of repeated use, the duty ratio Dt
(I.e., the water discharge hole swing angle α) is the same as the previous time, so that a sense of incongruity at the time of repeated use can be eliminated. In the cleaning operation performed again after the user leaves the toilet seat, the appropriate duty ratio Dt1 is used as described above.

When the proper duty ratio Dt1 is set in this way, a new pulse signal for sequentially exciting each electromagnetic coil is generated based on the proper duty ratio Dt1 and the excitation cycle Tc of each electromagnetic coil. Output (Fig. 21
reference). As a result, under the weak water discharge flow rate (flow rate level 1), the buttocks movable body NH1-9 quasi-oscillates and rotates at the discharge hole swing angle αmid and the excitation frequency f (= 1 / Tc), The tail water outlet NH1-7 also swings and rotates with this.

Then, following this pulse signal output,
The flow control pump WP1-14 is driven so as to have a proper water discharge flow rate (for example, flow rate level 4) in the adjustable range shown in FIG. 29 (step S155). This proper water discharge flow rate is set and stored in the same manner as the above-described proper duty ratio Dt1. Hereinafter, a case will be described in which the appropriate water discharge flow rate at the start of the main cleaning is set to flow rate level 4.

By the pulse signal output and the water supply with the proper water discharge flow rate, at the start of cleaning, the cleaning water having the proper water discharge flow rate (flow rate level 4) is in an appropriate state (water discharge hole swing angle αmi).
d, water is discharged from the hip water discharge holes NH1-7, which swing and rotate at the excitation frequency f (= 1 / Tc)). After that, the user changes the water pressure and the swing angle α
If the (washing area) is changed, the flush water of the changed water force swings and rotates at the changed water discharge hole swing angle α.
Water is discharged from 1-7. The washing water at this time is ejected toward the human body part in the form of a pseudo-conical spout shown in FIGS. 22 and 23, and the excitation frequency f that causes this spouting is included in the dead band frequency. Therefore, to the user,
An unprecedented superior effect of giving a continuous washing feeling of the washing water and giving no uncomfortable feeling or discomfort can be achieved. In addition, as described above, the cleaning water is supplied in the excitation cycle T
By oscillating and discharging water at c, the effectiveness of water saving can be enhanced.

Further, the flow rate of the washing water can be reduced by improving the efficiency of water saving, and in some cases, the flow rate can be reduced to about half of the conventional flow rate. Therefore, the tank capacity of the heat exchange unit TH1-1 can be reduced. In addition, since it is only necessary to heat the cleaning water with a heater in a tank having a small flow rate and a small capacity, it is possible to further promote power saving and downsizing of the heater TH1-2.

When the buttocks movable body NH1-9 is quasi-oscillatingly rotated in the cleaning drive processing, the cleaning water is supplied in advance at a weak water discharge flow rate (flow level 1) in the initial drive processing immediately before. . Therefore, the quasi-oscillating rotation of the movable body is started in a state of receiving the pressure of the feed water at the weak water discharge flow rate (flow rate level 1). For this reason, the pseudo-oscillating rotation of the movable body in the no-load state is not caused, so that careless force is applied.
Flange NH1-2 of elastic material such as rubber or elastomer
Never multiply by zero. As a result, inadvertent damage to the flange portion can be avoided, and the movable body can be appropriately pseudo-oscillatingly rotated from the beginning, which is preferable.

As shown in FIG. 29, the duty ratio Dt is changed from the initial set value Dt0 to an appropriate value Dt1 so that the water discharge hole swing angle α gradually increases from the initial value α0 to the intermediate value αmid, and the water discharge flow rate is increased. Initial value (flow level 1)
The water discharge flow rate is changed and set so as to gradually increase to the appropriate water discharge flow rate (flow level 4). Therefore, there are the following advantages. First of all, at the beginning of the first cleaning to receive the flush water spout, unintended multi flow rate of the flush water is not received over an unintended wide cleaning area, so that a sense of incongruity can be avoided. In addition, since the movable body is not suddenly quasi-oscillated at a large water discharge hole swing angle α, no overload is applied to the supporting portion (flange connecting portion) and the coil of the movable body, and the movable body in step S153 is not rotated. In conjunction with the initial drive, it is possible to reliably avoid inadvertent damage due to the running-in operation.

Steps S153 to S153 for Soft Cleaning
The process at 154 is not different from hip cleaning.
In the case of bidet cleaning, the apparatus control is performed as described above except that the movable body is the bidet movable body NH1-11.
The proper duty ratio Dt1 at 154 can be different from that of the tail cleaning. That is, at the time of bidet cleaning, the appropriate duty ratio Dt1 is set to the water discharge hole swing angle α at the time of the hip cleaning.
(= Αmid) is set to be larger than the appropriate duty ratio Dt1, and the water discharge hole swing angle α at the time of bidet cleaning is made larger than the water discharge hole swing angle α (= αmid) of the tail cleaning. As a result, at the time of washing the buttocks and the bidet, step S154-1
The cleaning area of the cleaning water discharged by the cleaning water 55 can have a wide or narrow difference. More specifically, the cleaning area at the time of ass cleaning can be set to the cleaning area BS shown in FIG. 22, and the cleaning area at the time of bidet cleaning can be set to a larger cleaning area AS. As a result, while cleaning both the buttocks and bidets, the above-mentioned water-saving effect is ensured together, and at the time of bidet cleaning, a large amount of washing water is spouted with a large amount of washing water to satisfactorily receive local washing. Can give a feeling.

Note that the above-mentioned step S154- with the proper duty ratio Dt1 and the proper water discharge flow rate (flow rate level 4) is performed.
After the execution of 155, the water strength setting buttons SWhu, SW
In response to the operation of each of the hd and spot-wide setting buttons (see FIG. 2), the water discharge flow rate (flow rate level) and the cleaning area (water discharge hole swing angle α, duty ratio Dt) are variously changed.
Then, at the changed flow rate and cleaning area (water discharge hole swing angle α), the above-described pseudo-conical water discharging form of the cleaning water is discharged (see FIG. 29). The water discharge flow rate (flow rate level) and the duty ratio Dt thus set are stored in the RAM and reset via the OFF signal of the seating sensor, as described above.

G1 / operation stop routine; Next, an operation stop routine executed by the local cleaning apparatus of this embodiment will be described. FIG. 30 is a flowchart showing the operation stop routine.

The operation stop routine shown in the flowchart of FIG. 30 is for stopping the washing operation and the drying operation performed in the above-described washing / drying operation routine, and is therefore executed at the following timing. . The first interrupt timing is when the stop button SWa for stopping various operations of the local cleaning device is operated. The second interrupt timing is when the user moves away from the seat sensor, which is equivalent to leaving the toilet seat, since the subsequent washing and drying operations are unnecessary if the user leaves the toilet seat. The third interrupt timing is when the operation is switched from the cleaning operation to the drying operation or from the drying operation to the cleaning operation, and is when the drying button is operated during the cleaning operation and when the cleaning button is operated during the drying operation. When the operation stop routine is executed at these interrupt timings, first, as shown in FIG. 30, it is determined whether the current operation state of the apparatus is a cleaning operation or a drying operation (step S160). Here, when it is determined that the drying operation is being performed, the power supply to the drying unit is stopped (step S162), and this routine ends. The operation state of the apparatus is determined based on the operation state of the cleaning or drying button before the start of this routine.

On the other hand, when it is determined that the cleaning operation is being performed, the flow control pump WP1-14 is controlled to drive the flow rate to zero (step S164), and thereafter, the solenoid valve WP1-10 is controlled to close (step S165). ). As a result, the supply of the washing water is cut off, and the washing water spouting that has been performed until then is stopped. In addition, with the closing of the solenoid valve, the switching valve WP1-15 can be controlled to return to the origin position (for example, the hip channel switching position).

Subsequent to the stoppage of the washing water spouting, the output of the pulse signal (see FIG. 21) for making the washing water spouting into a pseudo-conical spouting form (see FIGS. 22 and 23) is stopped (step S1). S166) The movable body is stopped. As described above, since the swinging rotation is stopped after the water discharge is stopped, the cleaning water is not discharged toward the human body part with the movable body stopped when the cleaning operation is stopped. Therefore, FIG.
Since one-point concentrated washing water as shown in (a) is not applied to the local area, there is no sense of discomfort or discomfort.

When the washing water discharge stops, the movable body stops, but other control such as stopping the movable body based on a timer may be added. By providing a timer synchronized with the cleaning or independent of the cleaning, a safe operation of the movable body and each coil can be performed.

Following the stoppage of water discharge and swing,
The nozzle drive motor NS1-4 is controlled to rotate in the reverse direction, and the cleaning nozzle WN1-1 is retracted from each cleaning position to the standby position HP in the main body (step S168; see FIG. 7). After the nozzle is returned to the standby position HP, post-nozzle cleaning is performed to clean each water discharge hole and its surroundings, which has been used for the local cleaning, and furthermore, the nozzle head (step S169). This post-nozzle cleaning is performed in the same manner as the above-described pre-nozzle cleaning, that is, cleaning with functional water, and cleaning with bounce water that has been discharged from a water discharge hole. Note that the pre-nozzle cleaning and post-nozzle cleaning may be different in the processing content. For example, in the pre-nozzle cleaning, since the local cleaning is to be performed, the nozzle head is sterilized and cleaned by functional water spouting just before the local cleaning so as to give the user a sense of hygiene and cleanness of the nozzle head. Alternatively, the functional water spouting may be omitted. The pre-nozzle cleaning and post-nozzle cleaning may be reversed. If sterilization cleaning is performed immediately after the bacteria adhere to the nozzle head, the bactericidal effect will be enhanced. it can. At the time of both washings, the one-point concentrated water discharge shown in FIG.
The conical water discharge shown in (b) can be used in combination. It is also possible to perform one-point concentrated water discharge in pre-nozzle cleaning and to perform conical water discharge in post-nozzle cleaning. The pre-nozzle cleaning and post-nozzle cleaning can be reversed.

H1 / Move Cleaning Routine Next, a description will be given of a move cleaning routine executed by the local cleaning apparatus according to the reference example in conjunction with the above-described local cleaning. FIG.
FIG. 32 is a flowchart showing the move cleaning routine.
FIG. 4 is an explanatory diagram for explaining a state of move cleaning.

The move cleaning routine shown in the flow chart of FIG. 31 is for giving a wide range of cleaning feeling by discharging cleaning water while reciprocating the cleaning nozzle WN1-1 back and forth. The move cleaning routine is interrupted by the operation of the move setting buttons SWfa and SWfv (see FIG. 2) during the execution of the local cleaning of the hips and bidet.

As shown in FIG. 31, when this move cleaning routine is executed through the operation of the button, the nozzle drive motors NS1-4 are controlled to rotate forward and reverse to set the respective cleaning positions of the buttocks and bidets. Washing nozzle WN1-
1 is reciprocated back and forth (step S170). This reciprocating motion of the nozzle is continued until the move setting button is operated again to turn off the move cleaning (step S172). In this way, even while the nozzle is reciprocating back and forth, the main cleaning operation described above (step S1)
40) has been performed. Therefore, by simultaneous execution of the nozzle reciprocating motion and the flush water spouting in the pseudo-conical spouting mode (see FIGS. 22 and 23), the cleaning water spouting in the pseudo-conical spouting mode causes the nozzle movement as shown in FIG. It moves back and forth accordingly. For this reason, the local move cleaning is performed in such a manner that the cleaning water spouting in the form of a pseudo-conical spouting water continues over the reciprocating range of the nozzle. As a result, it is possible to create a new washing feeling that the local part is washed over an extremely wide range, and to give the user this new washing feeling.

If it is determined in step S172 that the move cleaning has been stopped, the nozzle drive motor NS1-4 is rotationally controlled to return the cleaning nozzle WN1-1 to the bottom or bidet cleaning position (step S174). This routine ends. When the stop button is operated, the operation stop routine of FIG. 30 is executed prior to the process of step S174, and the water supply is stopped and the nozzle is returned to the standby position.

I1 / Spot / Wide Cleaning Routine Next, a spot / wide cleaning routine executed by the local cleaning apparatus according to the reference example in conjunction with the above-described local cleaning will be described. FIG. 33 is a flowchart showing this spot-wide cleaning routine, and FIG. 34 is an explanatory diagram for explaining the state of spot-wide cleaning.

The spots shown in the flowchart of FIG.
In the wide cleaning routine, the cleaning area of the cleaning water spout is adapted to the user's request for the cleaning area of the human body part, thereby giving the user a feeling of satisfaction and irritation for cleaning. And
This spot / wide cleaning routine is performed during spot cleaning of the buttocks and the bidet while the spot setting button SWu is being executed.
a, SWuv and wide setting buttons SWva, SWvv
The interrupt is executed in accordance with the operation (see FIG. 2).

As shown in FIG. 33, when the spot / wide cleaning routine is executed through the operation of each button, the current duty ratio Dt at the time of button operation is read (step S176). The water discharge hole swing angle α and the cleaning area (see FIG. 22) by the water discharge in the form of the pseudo-conical water discharge are defined by the duty ratio Dt as described above. Therefore,
By reading the current duty ratio Dt, the current water discharge hole swing angle α, that is, the cleaning area can be determined. Since the duty ratio Dt is stored in the RAM when the pulse signal is output, its value may be read.

In this embodiment, as described above, the water discharge hole swing angle α (wash area) can be variously set through the duty ratio control (see FIG. 21). However, in the following description, for the sake of convenience, spot-wide button operation
Practical setting range of duty ratio Dt (Dtmin to Dtmin)
tmax; αmin to αmax: refer to FIG. 29) and duty ratio Dt (Dtmin <Dt) in three stages of large, medium and small
It is assumed that S <DtM <DtL <Dtmax). That is, by setting the duty ratio Dt in three stages, the water discharge hole swing angle α (washing area) is increased or decreased in three stages.
Note that the cleaning area at the time of washing the buttocks is denoted as SMA, and the cleaning area at the time of bidet cleaning is denoted as SMV.

Following reading of the current duty ratio Dt, the type of button operated (spot or wide)
The duty ratio Dt is increased or decreased stepwise according to (step S178), and this routine ends. Hereinafter, a state of the change of the cleaning area due to the increase and decrease of the duty ratio Dt will be specifically described.

[0130] Now, the wide setting button SWv
It is assumed that a is operated. By this button operation, the current duty ratio Dt is read in step S176,
It is assumed that the result is the duty ratio DtS. Then, in the following step S178, the current duty ratio DtS is set to the duty ratio DtM. Therefore, FIG.
As shown in FIG. 4, the cleaning area SMAS before the button operation based on the duty ratio DtS becomes the cleaning area SMAM corresponding to the duty ratio DtM, and the cleaning area increases. Further, when the wide setting button SWva is operated, the duty ratio DtM is set to the duty ratio DtL, and the cleaning area increases from the cleaning area SMAM to the cleaning area SMAL. That is, every time the wide setting button SWva is operated, the cleaning area is expanded and changed in the order of the cleaning area SMAS → the cleaning area SMAM → the cleaning area SMAL. When the spot setting button SWua is operated, the reverse is true. Each time the button is operated, the cleaning area is changed to the cleaning area SMAL.
→ Cleaning area SMAM → Cleaning area SMAS. Note that the duty ratio DtS (the cleaning area SM
When the spot setting button is operated at the time of AS) or the wide setting button is operated at the duty ratio DtL (cleaning area SMAL), the duty ratio Dt and the cleaning area are maintained.

The same applies to the bidet cleaning. Each time the wide setting button SWvv is operated, the cleaning area expands in the order of the cleaning area SMVS → the cleaning area SMVM → the cleaning area SMVL. Also, spot setting button SWu
Every time the operation v is performed, the cleaning area is reduced and changed in the order of the cleaning area SMVL → the cleaning area SMVM → the cleaning area SMVS.

Accordingly, the user operates each spot-wide setting button according to his / her own intention to arbitrarily expand / contract the cleaning area at the time of local cleaning, and the cleaning area (the cleaning area) with the spouting water. Can be fulfilled to one's will. Therefore, it is possible to give the user a feeling of satisfaction in cleaning. In addition, if the cleaning area is expanded, the user receives a large amount of cleaning water spouting, so that a soft feeling can be obtained. Conversely, if the washing area is reduced,
The user can get a feeling of irritation by flushing water into a narrow area. For this reason, according to this reference example, various washing feelings can be created.

Moreover, such a feeling of sufficient cleaning and various feelings of cleaning can be obtained by controlling the width and width of the cleaning area, that is, by controlling the duty ratio, and there is no need to use special flow rate adjustment control. Therefore, a feeling of sufficient cleaning and various feelings of cleaning can be created by simple control, which is preferable. In addition, flow control devices (for example,
Since it is not necessary to drive a flow control pump or a flow control valve, vibrations and operating noises associated with driving these devices are preferably suppressed.
Moreover, since there is no need to sharply adjust the flow rate, water hammer can be effectively avoided.

The duty ratio Dt control and the flow rate adjustment control that cause the change in the cleaning area can be performed simultaneously. For example, at the time of the reduction control of the duty ratio Dt, it is determined that the user wants a stimulating feeling, and the flow rate of the washing water is controlled to be increased. Conversely, at the time of increasing control of the duty ratio Dt,
Decrease and control the flow rate of the wash water as a soft feeling is desired. In this case, the feeling of cleaning can be further diversified.

In this reference example, as shown in FIG. 34, the cleaning area (SMA, SM
V) was different. Therefore, a feeling of washing satisfaction and a feeling of washing (soft feeling,
Irritation).

In the spot-wide cleaning shown in FIG.
The duty ratio Dt set by each spot-wide setting button is the same as the rewritten duty ratio Dt described above.
It is. Therefore, the duty ratio Dt is reset by the OFF signal of the seating sensor when the user rises from the toilet seat. Thus, if the user repeats the cleaning operation while sitting, in the second and subsequent cleaning operations, in the main cleaning driving process in step S144, the duty ratio set by each spot-wide setting button is used. The cleaning water is discharged at Dt. Therefore, in the case of repeated use, the local cleaning can be performed with the duty ratio Dt (that is, the cleaning area) set by each spot-wide setting button at the time of the previous cleaning. it can. In this reference example, the configuration in which the water discharge hole swing angle α (cleaning area) is increased or decreased in three stages has been described. However, the configuration may be increased or decreased in two stages, or may be increased or decreased in four or more stages. But good.

J1 / Massage Cleaning Routine Next, a massage cleaning routine executed by the local cleaning device of this reference example in conjunction with the above-described local cleaning will be described. FIG. 35 is a flowchart showing this massage cleaning routine, FIG. 36 is an explanatory diagram for explaining the state of massage cleaning, and FIG. 37 is an explanatory diagram for schematically explaining effects obtained by massage cleaning. .

The massage cleaning routine shown in the flow chart of FIG. 35 is for promoting a feeling of defecation by changing the cleaning area regularly over the period of the buttocks cleaning. This massage washing routine is interrupted during the operation of the buttocks washing by operating the massage setting button SWea (see FIG. 2).

As shown in FIG. 35, when this massage washing routine is executed through the operation of the massage setting button, the current duty ratio Dt at the time of button operation is read (step S180), and then the duty ratio Dt is set as described above. Three stages of duty ratio (DtS, DtM, Dt
L) is increased or decreased at a predetermined massage cycle TM (step S182). Then, the periodic increase / decrease of the duty ratio Dt is continued until the massage setting button is operated again to turn off the massage cleaning (step S18).
4). On the other hand, if the massage cleaning is turned off, the duty ratio Dt read in step S180 is set to return to the state before performing the massage cleaning (step S18).
6), end this routine. When the stop button is operated, the operation stop routine of FIG. 30 is executed prior to these processes, and the water supply is stopped and the nozzle is returned to the standby position.

While the duty ratio Dt is periodically increased or decreased in this way, as shown in FIG. 36, the duty ratio Dt is DtS → DtM → DtL → DtS → DtM.
A constant massage cycle TM as shown (subscript 1,
2, 3...). Therefore, along with this change in the duty ratio, the cleaning area also becomes SMAS → SM
It changes at a constant massage cycle TM such as AM → SMAL → SMAS → MASM. In this case, the above-described massage cycle TM in which the duty ratio Dt and the cleaning area are changed is a frequency ftm (= 1/1) determined by this cycle.
TM) is set to have a frequency (less than about 5 Hz) in a range that can be perceived as an intermittent stimulus to a repetitive stimulus to the human epidermis. Thus, when the cleaning area changes as described above, the user clearly senses this regular cleaning area change. Since the feeling of irritation received from the spouting water is different depending on the size of the washing area, the user is periodically subjected to strong and weak stimulation by this massage washing, and the feeling of defecation is promoted.

Note that the excitation cycle Tc of the electromagnetic coil at each duty ratio Dt is equal to its excitation frequency f (= 1 / T
c) is the dead band frequency described above (about 5 Hz or more;
60 Hz). Therefore, during the cleaning period (massage cycle TM) in each cleaning area, the user experiences a continuous flushing sensation as described above.

As described above, in the massage cleaning of this reference example, the defecation sensation can be promoted by periodically changing the cleaning area related to the intensity of the stimulus through the periodic increase / decrease control of the duty ratio. There is no need to use flow rate control together. Therefore, a feeling of defecation can be given by simple control, which is preferable. In addition, since it is not necessary to drive a flow control device (for example, a flow control pump or a flow control valve), vibration and operation noise and water hammer associated with driving these devices are preferably suppressed. Furthermore, problems such as a problem of durability of the flow control device and an increase in size of the entire local cleaning device due to installation of the flow control device do not occur.

On the other hand, the duty ratio Dt increase / decrease control and the flow rate adjustment control for massage cleaning can be performed simultaneously. For example, at the time of the reduction control of the duty ratio Dt, the washing water flow rate is increased to increase the stimulation, and at the time of the increase control of the duty ratio Dt, the washing water flow rate is reduced to reduce the stimulation. In this way, the intensity of the stimulus can be amplified and the defecation can be effectively promoted. Further, if the adjustment control of the flow rate of the washing water, the swing rotation speed, the temperature, etc. is linked and synchronized with the duty ratio Dt increase / decrease control, the feeling of defecation can be more effectively promoted.

In the above-described massage cleaning, the duty ratio Dt, and thus the cleaning area increase / decrease change cycle (massage cycle TM), was kept constant. However, if the frequency f (= 1 / TM) determined by this cycle is within a frequency range (less than about 5 Hz) that can be sensed as an intermittent stimulus to the repetitive stimulus to the human epidermis, the above-described increase / decrease change cycle is used. (Massage period TM) can be changed each time the duty ratio Dt is increased or decreased. For example, in FIG. 36, the massage period with the duty ratio DtS (massage period TM1), the massage period with the duty ratio DtM (massage period TM2), and the massage period with the duty ratio DtL (massage period TM3) are different from each other. In this way, each cleaning area (SM
(AS, SMAM, SMAL), the recognition time of the stimulus is changed, so that the stimulus sensation is diversified and the defecation sensation can be more effectively promoted. In particular, the cleaning area SMA
When the time distribution of S is lengthened, a feeling of defecation can be promoted by an enema effect. This is because a large amount of water is injected into the anus for a long time in the washing area SMAS when the anus is relaxed in the washing area SMAL. In addition, by synchronizing with the five senses such as music, light, and odor (aromatherapy), a relaxing space can be provided, and further a feeling of defecation can be further promoted.

If this massage cleaning is performed not for promoting defecation but for local cleaning after defecation, the following advantages can be obtained. First, since the user receives a strong stimulus due to the change in the cleaning area, the monotonous feeling at the time of local cleaning is eliminated or awakened. Second, as shown in FIG. 37, when the duty ratio Dt changes from large DtL to DtS, the schematic water discharge water column RT moves toward the center as indicated by a white arrow in the figure. Therefore, waste OB around the local area
Is effectively separated by this schematic water discharge column RT.
Moreover, the filth OB is gathered toward the center side, and the rebound water RTH of the spouting wash water exhibiting the model water discharge column RT is collected, so that the collected filth OB is reliably removed. Therefore, according to the massage cleaning of this reference example,
Local cleaning can be performed with high cleaning ability. In this reference example, a configuration in which the cleaning area is increased or decreased in three stages has been described. However, a configuration in which the cleaning area is increased or decreased in two stages or a configuration in which the cleaning area is increased or decreased in four or more stages may be employed. In addition, these multi-step area differences may be synchronized with the five senses such as music, light, and smell.

K1 / fluctuation cleaning routine: Next, a description will be given of a fluctuation cleaning routine executed by the local cleaning apparatus of this reference example in conjunction with the above-described local cleaning. FIG.
FIG. 39 is a flowchart showing the fluctuation cleaning routine.
Is an explanatory diagram for explaining the processing content of the fluctuation cleaning routine, and FIG. 40 is an explanatory diagram for explaining the state of the fluctuation cleaning.

The fluctuation cleaning routine shown in the flowchart of FIG. 38 is for changing the cleaning area irregularly to give a sense of comfort, comfort, and the like. In the fluctuation cleaning routine, the fluctuation setting buttons SWta and SWtv (see FIG. 2) during the execution of the hip and bidet cleaning.
Is executed by the operation of.

As shown in FIG. 38, when this fluctuation cleaning routine is executed through the operation of the fluctuation setting button, the current duty ratio Dt at the time of button operation is read in order to return to the cleaning state before the fluctuation cleaning (step S190). . Next, the duty ratio Dt is irregularly increased or decreased at the predetermined fluctuation period TY to the above-described three-stage duty ratios (DtS, DtM, DtL) (step S192). And
The irregular increase / decrease of the duty ratio Dt is continued until the fluctuation setting button is operated again to turn off the fluctuation cleaning (step S194). On the other hand, if the fluctuation cleaning is turned off, the duty ratio Dt read in step S190 is set (step S196), and this routine ends. Thereby, it returns to the state before the execution of the fluctuation cleaning. When the stop button is operated, the water supply is stopped and the nozzle is returned to the standby position as in the case of the massage cleaning described above.

Here, an example of a method of irregularly increasing and decreasing the duty ratio Dt in step S192 will be described. The electronic control unit CT1-1 has a random number generation program in the ROM. Then, at the time of execution of step S192, the random number generation program is loaded every fluctuation period TY to generate a random number. On the other hand, the electronic control device C
T1-1 stores a duty ratio table in which random numbers are associated with duty ratios Dt, as shown in FIG. Therefore, the generated random numbers are checked against the duty ratio table, the duty ratio Dt is determined for each fluctuation period TY, and the duty ratio Dt is irregularly increased and decreased.

While the duty ratio Dt is irregularly increased or decreased in this way, as shown in FIG. 40, the duty ratio Dt is, for example, DtM → DtS → DtM → DtL →
A constant fluctuation period TY, such as DtS → DtS → DtL...
It transits. Therefore, with this duty ratio change,
Butt washing area is SMAM → SMAS → SMAM → SM
AL → SMAS → SMAS → SMAL ...
The bidet cleaning area is SMVM → SMVS → SMVM → SM
... VL → SMVS → SMVS → SMVL... In this case, the above-described fluctuation cycle T in which the duty ratio Dt and the cleaning area are changed
Y also has a frequency f determined by the fluctuation cycle TY.
(= 1 / TY) has the same frequency (less than about 5 Hz) as in the massage cycle TM. Accordingly, when the cleaning area changes as described above, the user clearly senses the cleaning area change. And since the sensation of stimulus received from the spouting water is different depending on the size of the washing area, and the change in the size of the washing area is also irregular, the user can receive the strong and weak stimulus irregularly by this fluctuation washing. Become. This has the following advantages.

The internal anal sphincter that opens and closes the anus for defecation is an involuntary muscle of the autonomic nervous system, which contracts and relaxes unconsciously. In the above-mentioned massage washing, since the washing area that affects the feeling of irritation changes regularly, if this massage washing is continued for a long time,
There is a case where the brain predicts the timing at which the cleaning area changes narrowly. For this reason, a change in stimulus change accompanying a small change in the washing area is also predicted, and the sympathetic nerve is dominant, which may cause contraction of the internal anal sphincter. On the other hand, in the fluctuation cleaning in which the cleaning area changes irregularly, it is difficult to predict the timing of the narrow change of the cleaning area, so that the stimulus change transition accompanying the narrow change of the cleaning area is not predicted. For this reason, the monotonous feeling at the time of washing is eliminated, and the parasympathetic nervous system becomes dominant, and the internal anal sphincter is easily unconsciously relaxed. As a result, according to the fluctuation massage washing described above, defecation can be more effectively promoted.

There is an external anal sphincter as a muscle that opens and closes the anus. The external anal sphincter is a voluntary muscle of the somatic nervous system. By the way, inside the anus, there is a receptor that is sensitive to a stimulus. When water is delivered to the receptor and the stimulus is sensed, the external anal sphincter contracts by the action of the receptor. In a situation where the water discharge location (wash area) of the wash water changes regularly and repeatedly, that is, in the massage washing described above, the timing at which the wash area changes into a small area and the wash water spout enters the anus and reaches the receptor (water spout). The brain predicts the entry timing). Therefore, according to this prediction, the external anal sphincter is contracted in advance to close the anus, and it may be difficult for the flush water to enter the anus. On the other hand, in the fluctuation cleaning in which the cleaning area changes irregularly, the timing of the narrow change of the cleaning area is difficult to predict, so that the brain cannot predict the above-mentioned water discharge entering timing. For this reason, while the external anal sphincter is not contracted, the chance of performing the flush water discharge in a small flush area increases, so that the flush water discharge easily enters the anus, and the flush water discharge enters the rectum. become. In general, the entry of washing water or the like into the rectum causes an enema effect, so that the above-mentioned fluctuation washing can promote defecation more effectively.

Further, if this fluctuation cleaning is performed for local cleaning after defecation, it is difficult to predict a strong stimulus due to a change in the cleaning area, so that the monotonous feeling at the time of local cleaning can be further eliminated.

The excitation cycle Tc of the electromagnetic coil at each duty ratio Dt is the same as in the massage cleaning described above, and the user has already described in the cleaning period (fluctuation cycle TY) in each cleaning area. As a result, a continuous feeling of flushing water is felt.

As described above, in this reference example, when performing the above-described fluctuation cleaning, the cleaning area related to the intensity of the stimulus is merely changed irregularly through the irregular increase / decrease control of the duty ratio. At this time, it is not necessary to use special flow rate adjustment control. Therefore, it is possible to facilitate the above-mentioned defecation with a simple control, which is preferable. In addition, since it is not necessary to drive a flow control device (for example, a flow control pump or a flow control valve), vibration and operation noise and water hammer associated with driving these devices are preferably suppressed. Furthermore, problems such as a problem of durability of the flow control device and an increase in size of the entire local cleaning device due to installation of the flow control device do not occur.

On the other hand, the duty ratio Dt increase / decrease control and the flow rate adjustment control for fluctuation cleaning can be performed simultaneously. For example, when a smaller duty ratio Dt is determined by a generated random number than before (at the time of transition from the fluctuation period TY1 to TY2, at the time of transition from TY4 to TY5 shown in FIG. 40, etc.), the flow rate of the washing water is increased in order to increase stimulation. Increase the duty ratio and increase the duty ratio Dt by using the generated random number.
Is determined (from the fluctuation period TY2 to TY3 in FIG. 40).
During the transition from TY3 to TY4, the flow rate of the washing water is controlled to decrease in order to weaken the stimulation. This makes it possible to more effectively promote defecation due to the strong amplification of the stimulus and the difficulty in predicting the stimulus.

In the above-described fluctuation cleaning, the duty ratio Dt, and hence the cleaning area increase / decrease change cycle (fluctuation cycle TY), was kept constant. However, if the frequency f (= 1 / TY) determined by this cycle is within the range of frequencies (less than about 5 Hz) that can be sensed as intermittent stimuli with respect to the repetitive stimulus to the human epidermis, the above-described increase / decrease change cycle (Fluctuation cycle TY) can be changed each time the duty ratio Dt is increased or decreased, as in the case of massage cleaning. In this way, each cleaning area (SMAS, SMAM,
SMAL) changes the recognition time of the stimulus associated with
Prediction of irritability becomes more difficult. Therefore, defecation can be promoted more effectively.

The power spectrum of the physical quantity such as the cycle TY or the instantaneous flow rate which determines the transition width of the cleaning area and the transition timing of the cleaning area is the same as the biological rhythm of the human body such as the heart rate and the rhythm of the natural world. Alternatively, it may be proportional to the reciprocal of the frequency. In this way, it becomes possible to give a sense of relaxation to the user, so that the parasympathetic nerve becomes dominant, causing relaxation of the internal anal sphincter,
The effect of promoting defecation is enhanced.

The massage cleaning and the fluctuation cleaning described above can be executed simultaneously with the move cleaning. That is, when the move setting button SWfa and the massage setting button SWea are successively operated, the reciprocating movement of the nozzle back and forth and the periodic increase and decrease of the duty ratio Dt are simultaneously executed. Therefore, the cleaning mode is such that the cleaning area periodically changes while the water discharge position (cleaning position) of the cleaning water changes in the front-back movement range of the nozzle. Then, the user receives local cleaning while recognizing the change in the cleaning position and the periodic change in the cleaning area.
For this reason, the new washing feeling that the local part is washed over an extremely wide area and the repetition of periodic strong and weak stimulation stimulate more effectively the defecation feeling, the elimination of the monotonous feeling at the time of the local washing, and the feeling of comfort. And satisfaction can be provided.

When the move setting button and the fluctuation setting button SWta, SWtv are operated one after another,
The nozzle reciprocating movement and the irregular increase / decrease of the duty ratio Dt are simultaneously executed. Accordingly, the cleaning mode is such that the water discharge position (the cleaning position) of the cleaning water changes in the range in which the nozzle moves in the longitudinal direction, and the cleaning area irregularly increases and decreases in an unpredictable state. Then, the user undergoes local cleaning in a situation where a change in the cleaning position and an unpredictable irregular change in the cleaning area occur. For this reason, the new washing feeling that the local part is washed over a very wide area and the repetition of unpredictable and irregular strong and weak stimuli further promote the more effective defecation feeling and the monotonous feeling at the time of the local washing. It is possible to achieve the cancellation and the addition of a feeling of comfort and a feeling of satisfaction.

In the above-described massage washing and fluctuation washing, controlling the washing area and the washing strength to promote comfort and convenience is mainly mentioned here. In addition to this, the temperature of the washing water is also controlled. Of course, it may be changed.

L1 / Rotation Detection Routine and Abnormality Recovery Routine Next, a description will be given of a movable body fluctuation detection routine and an abnormality recovery routine performed by the local cleaning device of this reference example.
FIG. 41 is a flowchart showing the swing detection routine, and FIG. 42 is an explanatory diagram for explaining the processing contents of the swing detection routine. FIG. 43 is a flowchart showing the abnormality recovery routine.

The swing detection routine shown in the flowchart of FIG. 41 is based on the above-mentioned movable body NH1-
This is to detect a swing abnormality when the coils 9 and 11 are swung by energization excitation of the electromagnetic coils, that is, an energization abnormality.
This swing detection routine is executed with priority at predetermined time intervals. In the following description,
Electromagnetic coil NH1-33a of bidet movable body NH1-11
33c will be described as an example.

As shown in FIG. 41, in this swing detection routine, it is determined whether or not the washing operation is being performed based on the operation state of the washing button of the buttocks and bidet (step S20).
0), if a negative determination is made, it is determined that swing detection is not necessary, and this routine is once ended. On the other hand, if it is determined that the cleaning operation is being performed, it is determined that the swing abnormality needs to be detected, and the process from step S205 is performed.

First, following the affirmative determination in step S200, the input waveform from output line NH1-37 shown in FIG. 20 is scanned (step S205), and the presence or absence of an abnormality in this input waveform is determined as follows. (Step S2
10). If each of the electromagnetic coils NH1-33a to 33c has no abnormality such as disconnection or contact failure, each pulse of the pulse output of the coil excitation output as shown in FIG. 21 includes an output line NH1-37 (see FIG. 20). Input pulses correspond one to one. Therefore, this input pulse has a pulse waveform without tooth missing (see FIG. 42A). On the other hand, if there is an abnormality such as disconnection or contact failure, the input pulse from the output line corresponding to the pulse output to the coil in which the abnormality has occurred is lost, so that the input pulse has a pulse waveform in which tooth missing has occurred. (See FIG. 42 (b)). Therefore, in step S210, the presence or absence of an abnormality is determined based on the waveform of the input pulse.

If a negative determination is made in step S210 that there is no abnormality, it is determined that the subsequent processing is unnecessary, and this routine is ended once. On the other hand, if it is determined that there is something abnormal,
In order to stop the swinging of the movable body and the discharge of the washing water while the abnormality is still present, the following processes from step S215 are executed.

That is, the above steps S154 to S155
The washing water is stopped in accordance with the same procedure (stopping the flow regulating pump and closing the solenoid valve), the output of the pulse signal for exciting the coil is stopped, and the washing nozzle is forcibly returned to the standby position (step S215). . Next, based on the input pulse waveform, an abnormal electromagnetic coil is determined, and the result is written and stored in the backup RAM (step S).
220). At the time of this writing, a value of 1 is set to the coil determination result (in the case of FIG. 42B, the electromagnetic coil NH1-33c) and the previously described cleaning operation prohibition flag FSstop. Thus, the cleaning operation inhibition flag FSsto
When the value 1 is set to p, the cleaning operation is not performed in the cleaning / drying operation routine after the execution of the swing detection routine (see FIG. 25; step S120). in this case,
Since the state of the cleaning operation prohibition flag is maintained even after the power is turned off, the cleaning operation is not executed even when the apparatus is turned off and then turned on. That is, irrespective of whether the apparatus power is on or off, if the value of the cleaning operation prohibition flag FSstop is set to zero in the abnormality recovery routine described later, the cleaning operation cannot be performed.

Then, following step S220, a notification to that effect is issued to prompt the recovery of an abnormality such as a disconnection or a contact failure (step S225), and this routine ends. Upon notification of this abnormality, blinking display is performed on the display section KS1-6 of the sleeve section KS1-5 shown in FIG. In order to distinguish the blinking display accompanying the abnormality notification from the display of the normal operation status, all the lighting devices (lamps, LEDs, etc.) may blink simultaneously.

When a swing abnormality is detected in the swing detection routine, the cleaning operation prohibition flag FSstop is set to a value of 1, and the cleaning operation is not executed in the subsequent washing / drying operation routine. However, the following configuration is also possible. Subsequent to the affirmative determination (FSstop = 1) in step S120 shown in FIG. 25, in a state where only the energization to each electromagnetic coil is prohibited, steps S130 to S130 are performed.
The process of 50 is executed. That is, at the time of detecting a swing abnormality, at least the pseudo swing rotation operation of the movable body is not performed. In this case, the local cleaning can be performed by spouting the cleaning water in a state where the pseudo swing rotation of the movable body is prohibited, that is, in a state where the movable body is free. In this case, if the flow rate of the cleaning water in the main cleaning operation (step S150) is fixed at a smaller flow rate than the flow rate of the cleaning water at the time of execution of step S150 in the case where the movable body has the pseudo swinging rotation, the concentration is increased It is possible to prevent the user who receives the spontaneous water discharge from giving an inadvertent feeling of incompatibility.

Next, an abnormality recovery routine after the occurrence of the swing abnormality will be described. As shown in FIG.
In this abnormal recovery routine, first, it is determined whether or not there is a recovery completion command from a maintenance inspector or the like (step S300).
This determination is made as follows. The maintenance and inspection person completes the abnormality recovery by the above-mentioned abnormality notification. Specifically, the head cover NH1 in which the abnormality shown in FIG.
-6 is removed from the nozzle head base NH1-2, and a normal head cover is replaced by an external inspection device (not shown). When the parts replacement is completed in this way, the maintenance inspector performs button operations that are not operated during normal use of the apparatus, for example, simultaneous operation of a plurality of buttons or long-time operation of a specific button. If there is no such special button operation, the routine is terminated since it is determined that the abnormal recovery has not been completed and the subsequent processing is unnecessary. On the other hand, if the above-mentioned special button operation is performed, in step S300, it is determined that a command to complete abnormality recovery has been issued, and the subsequent processing is executed.

First, the result of abnormality recovery is stored in the backup RAM.
Is written and stored (step S305). That is, the coil determination result stored in the above-described swing abnormality detection routine is reset, and the value of the cleaning operation inhibition flag FSstop is set to zero. As a result, after the execution of the abnormality recovery routine, the washing and drying operations can be executed according to the button operation. That is, the local cleaning device can be reused.

Subsequent to step S305, the abnormality notification is canceled upon completion of abnormality recovery (step S31).
0), end this routine. Specifically, the display unit KS
1-6 is returned to the display state of the normal operation status.

M1 / Nozzle Cleaning Routine Next, a description will be given of a nozzle cleaning routine performed by the local cleaning device of this embodiment. FIG. 44 is a flowchart showing this nozzle cleaning routine. This nozzle cleaning routine is executed in response to the operation of the nozzle cleaning button SWk on the sleeve KS1-5 (see FIG. 3) of the main body.

When the nozzle cleaning routine shown in the flowchart of FIG. 44 is executed, first, nozzle pre-cleaning is executed (step S400). That is, step S already described
Similarly to 120 (see FIGS. 25 and 26), nozzle head cleaning with functional water and nozzle head cleaning with splash cleaning water in the chamber are performed. Next, in order to prepare for the nozzle head cleaning by the user using a brush or the like, the cleaning nozzle WN1-1 advances to the buttocks cleaning position AWP (step S405), and waits until the user inputs a signal to end the nozzle cleaning. (Step S410). During this time, the user actually cleans the nozzle head with a brush or the like. After the cleaning is completed, the user operates the nozzle cleaning button SWk again or operates the stop button SWa to input the nozzle cleaning end signal.
Alternatively, an elapsed time after the operation of the nozzle cleaning button SWk is operated may be measured by a timer, and when the elapsed time becomes about 5 minutes, a signal indicating the end of the nozzle cleaning may be input. In addition,
From step S405, the washing nozzle may be advanced to the buttocks washing position to the end of the nozzle cleaning, a small amount of washing water may flow from the buttocks discharge hole. The washing water spouting at this time is sufficient if the washing water drips from the nozzle head to the toilet bowl portion.

When the nozzle cleaning is completed in this way, the cleaning nozzle is retracted to the standby position of the main body (step S415), and then the above-described step S160 (see FIG. 30) is performed.
The post-nozzle cleaning is performed in the same manner as described above (step S420), and this routine ends.

By executing this nozzle cleaning routine, in addition to the user cleaning the nozzle with a brush or the like, before and after the cleaning, the nozzle is cleaned twice with functional water, and the nozzle head is washed twice with bouncing water in the chamber. Cleaning is performed. Therefore, it is possible to clean the nozzle head, and furthermore, the water discharge holes of the cleaning water and the periphery thereof.

Next, a modification of the above-described local cleaning device KS1-1 will be described. Note that, for members performing the same function, the member names and symbols used in the above reference example are used as they are, and description thereof will be omitted.

A1-1 / Modification of Overall Configuration; In the remote control device RC1-1, the spot setting button and the wide setting button are provided for each of the bottom cleaning and the bidet cleaning. And bidet cleaning. In this case, the number of buttons is reduced, and there are advantages in manufacturing such as a reduction in the number of assembling steps and a reduction in cost.

B1-1: Modification of Channel System Configuration; FIG.
It is a block diagram showing the waterway system structure of a modification.

(1) In the waterway system, the second washing water outlet pipe WP1-13 is provided upstream of the heat exchange unit TH1-1, but the pipe is provided downstream of the heat exchange unit. You can also. In this case, the flow rate of the cleaning water flowing into the heat exchange unit is stabilized, and therefore, it is preferable to easily control the heater for maintaining the temperature of the cleaning water. In addition, the washing water that has been warmed in the heat exchange unit can be discharged from the second washing water outlet pipe to the deodorizing intake port and the local drying exhaust port to clean the intake port and the exhaust port. This is preferable because dirt on the intake port and the exhaust port can be more effectively washed off with warm water.

(2) In the water channel system, the water outlet side valve unit WP1-3 downstream of the heat exchange unit TH1-1 is composed of the flow regulating pump WP1-14 and the switching valve WP1-15. It is also possible to use a flow control switching valve (not shown) having a two-way valve structure and capable of flow control. In this case, a smaller and less expensive structure can be obtained, and problems of vibration and noise can be eliminated because no pump is used.

(3) In the water channel system, a flow regulating pump is used for the water outlet side valve units WP1-3 or a flow regulating switching valve is used to perform flow regulation.
The water channel configuration shown in FIG. That is, as shown in the figure, the bypass flow control valve W that can make the water passage area variable in the middle of the second washing water outlet pipe WP1-13.
P1-20 is provided. Therefore, the flow rate of the difference between the flow rate adjusted by the bypass flow control valve WP1-20 and the set flow rate by the constant flow rate valve WP1-9 is determined by the water discharge side valve unit WP1.
Water is discharged from the nozzle through -3. In this case, since no pump is used, there is no problem of vibration and noise, and there is no need to use a complicated structure such as a flow control switching valve.

(4) Although the heat exchange unit TH1-1 has a heater made of a spiral nichrome wire built in a small-capacity tank, the following can be adopted. That is, if the heater is a laminated cylindrical ceramic heater, the leakage detection circuit and the overheat prevention circuit can be printed on the green sheet before firing, and each circuit can be formed on the heater surface by firing.
Therefore, an external leakage detection / leakage protection circuit becomes unnecessary, and an overheat prevention device such as a bimetal is also unnecessary. The heat exchange unit can be reduced in size by stacking and omitting the equipment. Further, the heater may be an electromagnetic induction heater that causes electromagnetic induction in the resistor by a change in magnetic flux linked to the high-frequency current and generates the resistor by Joule heat. In this case, since it is not necessary to dispose the heater in the tank, the leakage protection circuit becomes unnecessary, and the size can be reduced accordingly. Further, since the degree of freedom of the shape of the heater is high, the shape of the heater can be formed along the meandering channel, and the washing water can be efficiently heated.

(5) The heat exchange unit TH1-1 may be of a hot water storage type instead of an instantaneous type. This makes it possible to extend the continuous water discharge time of the cleaning water at the predetermined temperature. In addition, warming of the washing water in the tank can be performed when the toilet is not used, such as at midnight, and in that case, a heater with low power consumption can be used. In this way, the maximum power consumption of the entire local cleaning device can be reduced, so when installing the local cleaning device in an existing toilet, the indoor wiring capacity may be insufficient or the capacity contract may be changed. Is reduced.

(6) The functional water units WP1-4 are configured to generate free chlorine by applying a DC voltage while washing water is stored in the tank. However, the water passage is sandwiched by chlorine generating electrodes. When a sufficient free chlorine generating ability is obtained by, for example, increasing the surface area of the chlorine generating electrode, a direct current voltage can be applied in a water-flowing state. In this case, the functional water can be continuously discharged for a long time, and the cleaning nozzle can be kept more hygienic.

C1-1 / Modification of Nozzle Device; FIG.
FIG. 47 is a schematic perspective view showing a nozzle device NS1-20 of a modified example, and FIG. 47 is a schematic sectional view taken along line 47-47 in FIG.

As shown, the nozzle device NS of the modified example is
1-20 is an arc-shaped nozzle advance / retreat trajectory NS for cleaning nozzles.
It is common to the above-described nozzle device NS1-1 in that it is advanced and retracted by the transmission mechanism NS1-5 along 1-12 (see FIG. 7), but the configuration related to the guide rail of the nozzle is different.
That is, the nozzle device NS1-20 of this modified example includes an arc-shaped nozzle advance / retreat trajectory NS1- extending between the pedestal NS1-3 on the rear end upper surface of the base NS1-2 and the nozzle holding portion NS1-6 on the front end side of the base. 12 has a guide rail portion NS1-21 which is formed to be curved so as to coincide with the same. As shown in FIG. 47, the cleaning nozzle WN1-20 guided by the guide rail portion has a timing belt NS1-1 at its rear end side.
And a track gripper WN1-21, which grips and holds the guide rail portion NS1-21 up and down on the right and left rail portions. The track gripper has upper and lower track gripping surfaces having the same radius of curvature as the nozzle advance / retreat track, and the track gripping surface is slidable with respect to the guide rail. That is, the cleaning nozzle WN1-20 and the guide rail portion NS1-21 are disposed in a vertical positional relationship, and the cleaning nozzle is engaged with the guide rail portion by the track gripping body only on the rear end side. ing. Note that, even in the cleaning nozzle WN1-20, the cylindrical portion is formed to have the same radius of curvature as the nozzle advance / retreat trajectory and to be curved along the axial direction.

Therefore, the nozzle device NS1-
20, the standby position HP and the cleaning position (the butt cleaning position AW) coincide with the arcuate nozzle advance / retreat trajectory.
P, bidet cleaning position VWP; see FIG. 7). For this reason, the nozzle device NS of this modified example
According to 1-20, advantages such as a reduction in the height of the chirping can be exhibited similarly to the above-described nozzle device NS1-1. In addition, in the nozzle device of this modified example, the positional relationship between the cleaning nozzle and the guide rail portion makes it possible to make the nozzle device compact in the width direction and to allow the nozzle device and other devices to be arranged close to each other.

F1-1: Modification of Cleaning Operation: In this modification of the cleaning operation, the excitation order of each electromagnetic coil is reversed at predetermined intervals while local cleaning of the buttocks and bidet is performed. That is, while keeping the duty ratio Dt the same, the electromagnetic coils NH1-33a → 33b → 33c → 33
coil excitation in the order of a... and electromagnetic coil NH1-3
The coil excitation in the order of 3c → 33b → 33a → 33c... Is repeated. In this case, the direction of spouting of the spouting wash water is switched, so that the inside of the wrinkles of the epidermis around the local area can be more effectively washed, which is preferable.

H1-1 / Modification of move cleaning; FIG.
It is an explanatory view for explaining a situation of move cleaning of a modification.

In the move cleaning of this modification, step S170 in the flow chart of the move cleaning routine shown in FIG. The variable control is executed. For example,
When the nozzle head is near the center position (washing position WPc) of the nozzle front-back movement range, the duty ratio Dt is set to the maximum duty ratio Dtmax of the practicable setting range. Then, the nozzle head is moved from the center position to the forward end position W.
As the distance from Pf / retreat end position WPb increases, the duty ratio D
t is reduced from the duty ratio Dtmax so that at the forward end position WPf and the backward end position WPb, the minimum duty ratio Dtmin in the practicable setting range is set. In this case, the cleaning area is large near the center position, and the cleaning area is narrowed toward the forward end or the retreat end, so that the local periphery can be move-cleaned (see FIG. 48A). Therefore,
Various washing feelings can be provided in which the washing area increases or decreases in accordance with the change in the washing position, that is, the stimulus sensation changes in intensity according to the washing position change. Further, since the entire cleaning area shape over the range of the reciprocating movement of the nozzles can be widened at the center position and narrowed at the front and rear ends, the cleaning area is adapted to the shape of the local area to be cleaned to be cleaned. For example, there is an advantage that the local part of the bidet can be reliably washed.

In variable control of the duty ratio Dt according to the nozzle position, the center position (the cleaning position WP)
c) When it is near, the duty ratio Dt is set to the center duty ratio Dtmid of the practicable setting range, and the duty ratio Dtmax is set at the forward end position WPf and the backward end position WPb.
And Then, from the center position to each end position, the value is increased or decreased in the order of Dtmid → Dtmin → Dtmax. In this case, the cleaning area is medium around the center position and large at the advancing end and retreating end positions, and the cleaning area is increased or decreased during that time, so that the local area can be move-cleaned (FIG. 48B). reference). Therefore, in addition to various washing feelings in which the stimulus sensation changes in accordance with the change in the washing position, the effect of being able to carefully wash the front and rear of the local area to be washed with a large washing area can be obtained.

Further, since the front and rear portions of the local portion to be cleaned can be cleaned with a large cleaning area as described above, the periphery of the local portion to be cleaned can be cleaned without any trouble even if the moving range of the cleaning nozzle is narrowed. For this reason, the number of nozzle reciprocations can be increased, and the cleaning effect can be improved accordingly.

The variable control of the duty ratio Dt in accordance with the nozzle position is performed by changing the duty ratio (D
tS, DtM, DtL). By doing so, it is only necessary to switch the duty ratio Dt in accordance with the nozzle position, so that the control is facilitated and the calculation load on the electronic control unit can be reduced.

J1-1: Modification of Massage Cleaning; In this modification of massage cleaning, the periodic increase / decrease control of the duty ratio Dt in step S182 of the massage cleaning routine (see FIG. 35) described above is performed as follows. That is,
The massage period TM of the duty ratio Dt shown in FIG.
(= 1 / TM) is set to the dead band frequency (about 5 Hz or more; about 10 to 60 Hz). In this case, the cleaning area can be quickly changed in size without making the user sense the transition of the cleaning area. Therefore, the movement toward the center of the schematic water discharge column RT shown in FIG. 37 and the spread from the center are repeated at a high speed, so that the effect of removing the dirt OB around the local area is enhanced, and the repelling water RTH of the water discharge cleaning water.
The garbage OB gathering effect due to is also increased. Therefore, according to the massage cleaning of this modified example, it is possible to perform the local cleaning with higher cleaning performance and the elaborate local cleaning. In this case, the massage cycle TM in this modified example of the massage cleaning is excited so as to be longer than the excitation cycle Tc of the electromagnetic coil at each duty ratio Dt, that is, the frequency ftm (= 1 / TM) determined in each cycle. The frequency is set to be lower than the frequency f (= 1 / Tc).

In this modification of the massage washing,
Through the operation of a special operation button such as a careful cleaning provided in a remote control device or an auxiliary operation unit, or through the simultaneous operation of a massage setting button and other operation buttons, the processing of the modified example of the massage cleaning may be performed. I just need.

E1-1: Deformation of the washing nozzle; the washing nozzle is provided with a first washing nozzle having a buttocks movable body NH1-9 and a second washing nozzle having a bidet movable body NH1-11. The first and second cleaning nozzles may be arranged in parallel. In addition, the ass spout NH1
A first cleaning nozzle having a movable body for buttocks of only -7, a second cleaning nozzle having a movable body for softness only of the soft water discharge holes NH1-8, and a movable body for bidet only of the bidet water discharge holes NH1-10. And a third cleaning nozzle provided separately, and the first to third cleaning nozzles may be installed in parallel. Further, a first cleaning nozzle having a buttocks movable body having only the buttocks water discharge port NH1-7 and a soft water discharge port NH1
-8 and a second cleaning nozzle having a movable body of the bidet discharge port NH1-10 may be separately provided, and the first and second cleaning nozzles may be installed in parallel. In addition, in these modified examples and the above-mentioned reference examples, it is also possible to not have the soft water discharging holes NH1-8 for soft cleaning.

E1-2 / Deformation of Nozzle Head; FIG.
Is a plan view of an electromagnetic coil installation substrate NH1-50 of a nozzle head according to a modification, and FIG. 50 is a plan view of an electromagnetic coil installation substrate NH1-60 of a nozzle head of another modification.

(1) As shown in FIG. 49, the electromagnetic coil installation board NH1-50 of the modified example includes a hip rocking coil group N
H1-51 and a bidet swing coil group NH1-52. The butt swing coil group NH1-51 includes an electromagnetic coil N
H1-32b and 32c are connected to a bidet swing coil group NH1-
52 has electromagnetic coils NH1-33a and 33c, and both coil groups share one electromagnetic coil NH1-53. This electromagnetic coil NH1-53 has two coil cores NH1-54 and 55, similarly to the electromagnetic coil described above.
And one coil core 55 has a coil NH1-56. The electromagnetic coil NH1-53 is provided in the bidet swing coil group so that the coil core NH1-54 corresponds to the magnetic action portion NH1-23a of the magnetic driver NH1-23 in the hip swing coil group. Iron core NH1-55
Is the magnetic action part NH1-18b of the magnetic driver NH1-18
It is arranged and fixed to correspond to. In this case, the number of electromagnetic coils provided is reduced, and there are advantages in manufacturing such as a reduction in the number of assembling steps and a reduction in cost. Further, the two coil groups can be arranged close to each other, and the size of the nozzle head can be reduced accordingly.

(2) As shown in FIG. 50, another modification of the electromagnetic coil installation board NH1-60 has two coils of a hip rocking coil group NH1-61 and a bidet rocking coil group NH1-62. For each group, a coil core NH1-
There are provided electromagnetic coils NH1-65a to 65c and 66a to 66c each including a coil 63 and a coil NH1-64 wound therearound. Then, the electromagnetic coil NH1 of the two rocking coil groups
-65a to 65c and 66a to 66c are disposed and fixed on the substrate so as to face the magnetic action portions NH1-18a to 18c and 23a to 23c of the magnetic drivers NH1-18 and 23 in the buttocks and bidet movable bodies. Have been. In this case, the number of components of the electromagnetic coil is reduced, and there are advantages in manufacturing such as reduction in the number of assembling steps and cost reduction. Further, since the size of the electromagnetic coil itself is reduced, the two coil groups can be arranged closer to each other, and the nozzle head can be further reduced in size.

E1-3 / Another Modification of Nozzle Head; FIG.
FIG. 1 is an explanatory diagram for explaining a nozzle head of still another modified example.

As shown in the drawing, the nozzle head NH1-70 of this modification has a bidet movable member NH1 having four magnetic action portions NH1-18a-18d formed at equal pitches.
1-11, and a bidet swing coil group NH1-71 having four electromagnetic coils NH1-33a to 33d arranged and fixed to face the respective magnetic action portions. And
In this modification, each of these electromagnetic coils is replaced by an electromagnetic coil NH
The magnets are sequentially excited in the order of 1-33a to 33d or in the reverse order to rotate the bidet movable body NH1-11 in a pseudo swinging manner, as described above, and eventually swing the bidet discharge hole NH1-10 (see FIG. 22, see FIG. 23). According to the nozzle head NH1-70 of this modification, the magnetic action part NH1-
Since the number of inclined portions of the bidet movable body due to the coil acting force on 18a to 18d increases, the trajectory of the pseudo swinging rotation of the movable body and the swinging rotation of the bidet discharge hole is approximated to a circular locus due to the increase of the inclined portion. Then, the cleaning water can be spouted. In addition, the movable body may have a multi-divided magnetic action portion such as a five-split or six-split portion, or the buttocks movable body may have such a multi-split magnetic action portion.

F1-2 / Modification of cleaning operation; FIG. 52 is an explanatory view for explaining a cleaning operation of a modification using the nozzle head NH1-70 of the above modification, and FIG. 53 is a diagram of this modification. It is explanatory drawing for demonstrating the state of washing water spouting by a washing | cleaning operation typically. In the following description, the bidet cleaning will be described as an example, but the same applies to the bottom cleaning.

In this modification of the cleaning operation, the duty ratio Dt (Dta, Dtc) of the electromagnetic coils NH1-33a, 33c located in the front-rear direction of the nozzle is set to the same value when the respective electromagnetic coils are sequentially excited, and In the electromagnetic coils NH1-33b and 33d located in the left-right direction,
The duty ratios Dt (Dtb, Dtd) were the same. Moreover, the former duty ratio Dt (Dta, Dtc) is different from the latter duty ratio Dt (Dtb, Dtd). That is, as shown in FIG. 52, in the cleaning period TA, the duty ratios Dta and Dtc of the electromagnetic coils NH1-33a and 33c are changed to the values of the electromagnetic coils NH1-33b and 33d.
Duty ratios Dtb and Dtd. With this, when the electromagnetic coils NH1-33a and 33c exert a coil acting force on the magnetic acting portions NH1-18a and 18c to tilt the bidet movable body, the water discharge hole swing angle αac is large and the electromagnetic coils NH1-33b , 33d, the water discharge hole swing angle αbd becomes smaller. Therefore, as shown in FIG. 53A, the cleaning area SMTA in this cleaning period TA
Has an elliptical shape whose major axis is in the front-back direction of the nozzle.

In the cleaning period TB, the duty ratio Dta,
Dtc is made longer than the cleaning period TA. Therefore, FIG.
As shown in (a), the cleaning area SMTB in the cleaning period TB has an elliptical shape whose major axis is in the front-rear direction of the nozzle similarly to the cleaning area SMTA, but the major axis extends and the cleaning area increases.

In the cleaning period TC, contrary to the cleaning period TA, the duty ratios Dta and Dtc are changed to the duty ratio Dt.
b, smaller than Dtd. Thereby, the electromagnetic coil N
When the movable body for bidet tilts due to H1-33a, 33c, the swing angle αac of the water discharge hole is small, and the electromagnetic coil NH1-3
In the cases of 3b and 33d, the water discharge hole swing angle αbd becomes large. Therefore, as shown in FIG. 53 (b), the cleaning area SMTC during the cleaning period TC has an elliptical shape whose major axis is in the left-right direction of the nozzle. And the duty ratio Dt
If b and Dtd are increased, as in the case of FIG. 53 (a), the cleaning area can be enlarged to an elliptical shape having the major axis extending in the left-right direction of the nozzle and extending with the major axis.

According to the modification of the cleaning operation, the following advantages can be obtained.

(1) As in the cleaning periods TA and TB, local cleaning is performed in an elliptical cleaning area having a long axis in the front-rear direction of the nozzle. In addition, a wide range of local cleaning along the front-rear direction of the nozzle is possible. Therefore, the move cleaning can be executed in a quiet state without any operation noise due to the forward / reverse rotation of the motor, and the user can be given a sense of relaxation. Further, since the forward / reverse rotation control of the motor is not required, the control load on the electronic control device can be reduced. Furthermore, since the nozzle drive motor does not need to have high responsiveness to repetition of forward and reverse rotation, a high-performance motor is not required, and cost reduction and downsizing of the motor can be achieved. In addition, the wear of the guide rail portion NS1-7 (see FIG. 6) due to the repetition of the nozzle reciprocation can be suppressed, and the durability of the rail portion can be improved.

(2) Cleaning Period When the move cleaning is performed by reciprocating the nozzle back and forth while making the cleaning area of an elliptical shape like TA and TB, the interval between the front and rear movements of the nozzle can be shortened.

(3) It is also possible to perform move cleaning by reciprocating the nozzle back and forth while keeping the cleaning area in an elliptical shape as in the cleaning period TC. In this case, the move cleaning can be performed in a wide range in the left-right direction of the nozzle. In this case, as described with reference to FIG. 48, if the duty ratios Dtb and Dtd are increased or decreased according to the nozzle head position in the nozzle longitudinal movement range,
The elliptical shape of the cleaning area can be deformed long and short in the left-right direction of the nozzle according to the position of the nozzle head. Therefore, it is possible to provide various washing feelings in which the stimulus sensation changes in accordance with the change in the washing position.

(4) If the duty ratios Dta and Dtc are equal to the duty ratios Dtb and Dtd, the water discharge hole swing angles αac and αbd become the same, and the cleaning area can be made circular. Therefore, through the variable control of the duty ratio Dt, in the execution period of the local cleaning, a cleaning period in which a circular cleaning area is used, a cleaning period in which the elliptical cleaning area in which the longitudinal direction of the nozzle takes a long axis, The cleaning period in which the direction takes a cleaning area having an elliptical shape whose major axis is a long axis can be expressed in an arbitrary order. In addition, in changing each cleaning area at this time, the frequency f determined by the cycle of each cleaning period (for example, the cleaning periods TA, TB, and TC in FIG. 52) is used as an intermittent stimulus with respect to the repetitive stimulus to the human body epidermis. The frequency should be within a perceptible range (less than about 5 Hz). In this way, the user can clearly recognize the change in the shape of each washing area and give a strong stimulus according to the change in the washing area, so that the way of receiving the stimulus diversifies and effectively promotes a feeling of defecation. , A monotonous feeling can be eliminated.

F1-3 / Another Modification of Cleaning Operation; FIG.
FIG. 55 is an explanatory diagram for describing a cleaning operation of another modified example using the nozzle head NH1-70 of the above modified example, and FIG.
FIG. 56 is an explanatory diagram for schematically explaining the state of water discharge of cleaning water by the cleaning operation of another modification. FIG. 56 is a diagram showing the discharge of cleaning water when the cleaning operation of another modification is applied to move cleaning. FIG. 4 is an explanatory diagram for schematically explaining the state of FIG.

In this other modification, when the respective electromagnetic coils are sequentially excited, the remaining three electromagnetic coils except one of the electromagnetic coils NH1-33a and 33c located in the front-back direction of the nozzle, or the left-right direction of the nozzle are used. In order to sequentially excite the remaining three electromagnetic coils except one of the located electromagnetic coils NH1-33b and 33d, first, in the first method, as shown in FIG.
As shown in FIG. 4 (a), the electromagnetic coils other than the electromagnetic coils NH1-33c are replaced by 33b → 33a → 33d → 33a → 3
Are sequentially excited in the order of 3b → 33a. In the second method, as shown in FIG. 54 (b), 33a → 33b → 33
Excitation is performed in the order of d → 33a → 33b → 33d. In the third method, as shown in FIG.
b → 33c → 33d → 33c → 33b → 33c... In the fourth method, as shown in FIG. 54 (d), 33b → 33c → 33d → 33b → 33c →
33d... Are sequentially excited.

In the case of excitation by the above-described first method, FIG.
As shown by an arrow Ha in FIG. 5A, the water discharge hole swings and rotates along an arc-shaped trajectory on the front side of the nozzle head. Water is discharged in an arc. In the case of excitation by the second method, as shown by an arrow Hb in FIG. 55B, the water discharge hole swings and rotates in a semicircular locus on the front side of the nozzle head. Water is discharged at the front side of the nozzle head following the trajectory, and the cleaning area at that time becomes a semicircular shape. As shown in FIG. 55 (c), the cleaning water spouting in both methods takes a water spouting form directed toward the front of the nozzle head.

On the other hand, when the excitation is performed by the third method,
As shown by an arrow Hd in FIG. 5D, the water discharge hole swings and rotates on an arc-shaped trajectory behind the nozzle head, and the cleaning water is discharged in an arc shape behind the nozzle head. In the case of excitation by the fourth method, as shown by an arrow He in FIG. 55E, the water discharge hole swings and rotates with a semicircular locus on the rear side of the nozzle head, and the cleaning area becomes a semicircular shape. Thus, the cleaning water is discharged at the rear side of the nozzle head. As shown in FIG. 55 (f), the cleaning water spouting in both methods takes a water spouting form directed toward the rear of the nozzle head. When exciting each electromagnetic coil in the excitation order of each of the above methods, the duty ratio Dt is controlled to increase or decrease to change the water discharge hole swing angle α, change the water discharge angle of the forward / rearward water discharge, or wash the semicircular shape. It is also possible to make the area semi-elliptical.

According to the modification of the cleaning operation, there are the following advantages.

(1) Through the duty ratio control shown in FIG. 54, as shown in FIG. 55, it is possible to arbitrarily change the washing water direction to the front or rear of the nozzle head and change the arc-shaped or semi-circular cleaning area. Can be taken in order. In addition, in changing the direction of water discharge and the washing area at this time, the frequency f determined by the change cycle is set to a frequency (approximately 5
(Less than Hz). In this way, the user can clearly recognize the change in the water discharge direction and the change in the shape of the washing area, and gives a strong stimulus accompanying the change in the water discharge direction and the change in the wash area. It is possible to promote a defecation feeling and to eliminate a monotonous feeling.

(2) Move cleaning can be performed by reciprocating the nozzle back and forth while taking the form of water discharge directed toward the front of the nozzle head shown in FIGS. 55 (a) to (c). In this case, the cleaning water can be spouted from the direction toward the front side of the nozzle head to the local waste. In addition to the fact that the trajectory of the reciprocating movement of the nozzle back and forth is directed obliquely downward as shown in FIG. 7, dirt can be effectively peeled downward.

(3) Conversely, move cleaning can be performed by reciprocating the nozzle back and forth while taking the form of water discharge toward the rear of the nozzle head shown in FIGS. 55 (d) to (f). In this case, the cleaning water can be spouted from the direction toward the rear side of the nozzle head to the local waste. In addition to the fact that the trajectory of the reciprocating movement of the nozzles in the forward and backward directions is directed downward, it is possible to make it difficult for the spouted washing water and the dirt separated by the washing water to flow forward. Therefore, when the bidet cleaning is performed by this move cleaning, the cleanliness around the local area is enhanced, which is preferable.

(4) The nozzle moving direction and the water discharge direction can be matched. That is, at the time of the nozzle forward movement from the retreat end to the forward end of the nozzle back-and-forth reciprocal movement range, the nozzle head is in the form of water spray toward the front, and at the time of the nozzle retreat movement from the forward end to the backward end, The water discharge mode is directed toward the rear of the nozzle head. In this way, the waste can be effectively peeled downward when the nozzle advances, and it is difficult for the waste to flow forward when the nozzle moves backward, so that the cleanliness around the local area can be improved.

(5) Reciprocating the nozzles back and forth between the water discharge form shown in FIGS. 55 (a) to 55 (c) toward the front of the nozzle head and the water discharge form shown in FIGS. 55 (d) to (f). It is also possible to execute move cleaning in which switching is performed according to the moving nozzle head position. That is, as shown in FIG. 56 (a), when the nozzle moves toward the center position from the retreat end of the nozzle back-and-forth reciprocation range, the nozzle head is in a water-spouting form toward the front of the nozzle head. The electromagnetic coil is sequentially excited with a uniform duty ratio Dt to form a water discharge mode in which the water is directed upward to the water discharge hole. Further, when the nozzle is moved from the center position toward the forward end, a water discharge form directed toward the rear of the nozzle head is adopted. In this way, local cleaning can be performed while collecting dirt in front of and behind the local part to be cleaned at the local skin position corresponding to the center position. Moreover, when the nozzle is advanced to the center position, the dirt can be effectively peeled downward, and when the nozzle is retracted to the center position, the dirt is less likely to flow forward and the cleanliness around the local area can be enhanced.

(6) As shown in FIG. 56 (b), when the nozzle is moved from the retreat end toward the center position, the water discharge form toward the rear of the nozzle head, and before and after the center position, the water discharge form that faces upward is referred to as the center position. When the nozzle moves toward the forward end from the nozzle head, a water discharge form directed toward the front of the nozzle head is adopted. With this configuration, the cleaning area during the move cleaning can be enlarged in the front-rear direction of the nozzle, so that a sufficient cleaning feeling can be provided over a wide range. Further, since the cleaning area can be increased in this manner, the reciprocating range of the front-rear movement of the nozzle can be narrowed. In the case of adopting the water discharge form shown in FIGS. 55 (a) and (d), when the wash water is discharged following the arc-shaped trajectory,
Since the switching of the water discharge direction of the water discharge at the end of the arc occurs, it is possible to more effectively clean the inside of the wrinkles of the epidermis around the local area, which is preferable.

(7) When performing the above-described move cleaning while adopting the water discharge form shown in FIGS. 55 (b) and (e), the excitation order of the electromagnetic coil is determined between when the nozzle moves forward and when it moves backward. It may be reversed. That is, 33a in FIG.
Excitation in the order of → 33b → 33d → 33a → 33b → 33d... And reverse 33d → 33b → 33a → 33d
The excitation in the order of → 33b → 33a... Is switched between forward and backward of the nozzle. Also, 33b → 33c in FIG.
Excitation in the order of → 33d → 33b → 33c → 33d... And the reverse 33d → 33c → 33b → 33d → 33
Excitation in the order of c → 33b... is switched between forward and backward of the nozzle. In this case, the direction of spouting of the spouting wash water is switched, so that the inside of the wrinkles of the epidermis around the local area can be more effectively washed, which is preferable.

F1-4 / Another Modification of Cleaning Operation: The cleaning operation of this modification is the same as that of the modification (F1-3) shown in FIG.
As shown in FIG. 4, one electromagnetic coil N in the front-rear direction of the nozzle
While the H1-33a and 33c are not excited, one of the electromagnetic coils NH1-33b and 33d in the lateral direction of the nozzle is not excited, and the remaining electromagnetic coils are sequentially excited. According to this modification, the following water discharge form can be adopted.

That is, since the excitation is performed in accordance with the above-described first to fourth methods, the cleaning water is discharged in an arc shape on the left or right side of the nozzle head, It is possible to adopt a water discharge mode in which the cleaning water is discharged so as to have a semicircular cleaning area on the right or right side. Further, a water discharge mode facing the left or right side of the nozzle head can be adopted. Furthermore, through the duty ratio increase / decrease control at the time of sequential excitation of each electromagnetic coil,
It is also possible to change the spouting angle of the spouting water to the left or right and to make the semi-circular cleaning area semi-elliptical. As described above, since the water can be dispensed to one side of the left and right, if there is a hemorrhoid or a laceration on the left or right side of the local part, the local water is washed so that the water does not hit the hemorrhoid or the like. It can be performed. Further, by combining with the move cleaning, the diversification of the cleaning feeling can be achieved as in the above-described modification.

F1-5: Still Another Modification of Cleaning Operation: The cleaning operation of this modification is the same as that of the above modification (F1-3, -4).
Does not excite one of the electromagnetic coils in the front-rear direction of the nozzle or the left-right direction of the nozzle, while setting the duty ratio Dt of this one electromagnetic coil to a duty ratio Dt different from the remaining electromagnetic coils to sequentially excite all the electromagnetic coils. There is a feature in the point.

That is, as for the non-excited electromagnetic coils in FIG. 54, for example, the electromagnetic coils NH1-33c in FIG.
b, the excitation is performed, and then the electromagnetic coils NH1-33d
To excite. The excitation in this order is repeated, and the duty ratio Dtc of the electromagnetic coil NH1-33c is changed to the duty ratios Dta, Dtb, Dtc of the other electromagnetic coils.
Make it smaller or larger. In this case, since the excitation is performed sequentially, the cleaning water can be spouted in the cleaning area having the irregular shape in the area corresponding to the electromagnetic coil NH1-33c while taking a closed cleaning area. At this time, the degree of the irregularity of the area contour of the portion corresponding to the electromagnetic coil NH1-33c can be variously changed by the duty ratio Dt of this coil. Therefore, it is possible to perform the cleaning water spouting with various cleaning area shapes, and it is possible to diversify the feeling of cleaning. It should be noted that, when sequentially exciting each electromagnetic coil, it is also possible to modify the duty ratio Dt of each coil randomly so as to sequentially excite it. In this case, since the shape of the cleaning area becomes more diversified, the diversification of the cleaning feeling is also increased.

As described above, by controlling the excitation of each coil, the cleaning position and shape can be freely set.
For example, a touch panel is provided on a remote control device (not shown), and a user touches a position indicated on the panel to specify a cleaning part or a shape, or a stick-like operation lever is used to specify a cleaning part. In addition to being able to follow quickly when performing operations such as moving, there is little (or no) movement of the nozzle, so there is little (or no) noise, making it possible to use it comfortably. Become.

Here, a description will be given of a modified example of the movable body that causes the above-described oscillating rotation water discharge of the washing water, taking a bidet movable body as an example. FIG. 57 is an explanatory view for explaining the manufacturing process of the bidet movable body NH1-11, FIG. 58 is an explanatory view for explaining the manufacturing process of the bidet movable body of the modification, and FIG. It is an explanatory view for explaining a manufacturing process of the movable body for use.

Movable body NH1-11 for bidet of the above reference example
Then, as described above, the magnetic action parts NH1-18a-18
The magnetic driving body NH1-18 having c at the periphery is integrated with a resin-made water discharging piece NH1-17 by an insert molding method or the like. At this time, as shown in FIG. 57 and FIG. 13, the magnetic driving body has a peripheral portion NH1-18x connecting the magnetic action portions.
The lower end portion of the resin water discharge piece is integrated with the upper and lower surfaces so as to go around. At this time, the anchor hole N
Since the resin also enters the H1-18y, stronger integration is achieved by the anchor effect. In this method, since a member to be handled at the time of manufacturing, specifically, a member to be set on a mold is one magnetic driving body, the working process is simplified, and there are advantages in manufacturing such as cost reduction.

In the modification movable body NH1-75 for bidet,
The three magnetic action parts NH1-18a-18c were separately integrated with the resin-made water discharge piece NH1-76 by insert molding or the like. That is, as shown in FIG. 58, each magnetic action portion is individually embedded in the flange portion NH1-77 of the water discharge piece. Therefore, in this movable body, the rust preventive treatment of the magnetic action part is not required, and there is an advantage in manufacturing to that extent. In addition, the respective magnetic action parts are arranged independently of each other, and are magnetically separated from each other by a water discharge piece made of resin.
That is, it is difficult for a magnetic flux to be formed over the adjacent magnetic action part. For this reason, when each electromagnetic coil is excited and a coil acting force is exerted on each magnetic acting portion, the magnetic flux having the magnetic acting portion as a magnetic path does not leak to the adjacent magnetic acting portion. Therefore, the magnetic acting portion can be efficiently attracted, and the attracting force based on the coil acting force does not decrease. As a result, it is only necessary to excite each electromagnetic coil so that a small coil attraction force can be exerted, and it is possible to reduce the size and power consumption of the electromagnetic coil.

In the bidet movable body NH1-80 of another modified example, the three magnetic action parts NH1-18a to 18c are separately arranged and are made magnetically independent by a resin water discharging piece. In common with the bidet movable body NH1-75. In the bidet movable body NH1-80, as shown in FIG. 59, each magnetic action portion has an inner edge NH1-18w.
Flange portion NH1-8 of water discharge piece NH1-81 on upper and lower surfaces
2 are wrapped around and are individually fixedly arranged on the water discharge piece. Like the magnetic driving body NH1-18, each magnetic acting portion is firmly fixed by the anchor effect of the anchor hole NH1-18y. Therefore, even with the movable body of this modified example, the magnetic flux having the magnetic action portion as the magnetic path is generated by the independent arrangement of each magnetic action portion and the magnetic separation through the resin water discharge piece of each magnetic action portion. It can be prevented from leaking to the adjacent magnetic action part. For this reason, by improving the attraction efficiency of the magnetic action portion and avoiding a decrease in the attraction force, not only the movable body of the above-described modified example, but also the same effect as the movable body of the above-described modified example can be exhibited, and the movable body is composed only of the soft magnetic material necessary for attraction. The weight of the bidet movable body NH1-80 can be reduced, and the size and power consumption of the electromagnetic coil can be reduced.

In addition, the following modifications are possible.
For example, in the above reference example, the cleaning area is changed through variable control of the duty ratio Dt at the time of exciting the electromagnetic coil, but the following method can be adopted. In exciting the electromagnetic coil, the applied voltage value to the electromagnetic coil is adjusted by a method such as phase angle control to increase or decrease the coil acting force on the magnetic acting portion, and as described above, the water discharge hole swing angle α is extended. The washing area can be variously adjusted.

In the above reference example, when the washing water flows into the washing water spout hole of the movable body from below, the movable body receives a constant force from the inflow washing water, and the force from the inflow washing water is reduced. Although not considered, the following can also be performed. This inflow washing water hits the tapered surface of the large-diameter water discharge guide hole on the lower end side of the water discharge hole inclined with the movable body from below, so that the force from the inflow cleaning water acts in a direction to return the inclination of the movable body. I do. Therefore, as the water amount of the inflow cleaning water, that is, the water force set by the water force setting button increases, the force for returning the movable body to the inclination increases. For this reason, when a predetermined washing area, that is, a water discharge hole swing angle α (duty ratio Dt) is set by the spot / wide setting button, if the strength of the water force is used together, the setting is completed by the spot / wide setting button. Is changed in accordance with the set water force. For example, if the water force is set high, the duty ratio Dt already set by the spot / wide setting button is controlled to increase according to the water force high setting, and if the water force is low, the duty ratio Dt is set according to the setting degree. Control to decrease. In this way, even when the water force is set, the movable body and the water discharge hole swing angle α of the water discharge hole can be maintained in the same manner as before the water force setting, and it is possible to prevent a feeling of incongruity due to an inadvertent change in the cleaning area. it can.

Further, the following fine adjustment function at the time of shipment can be provided. There is a possibility that the water discharge hole swing angle α may vary due to the variation of the magnetic acting force due to the electromagnetic coil or the variation of the elastic force of the movable body flange such as rubber or elastomer. Therefore, it is more preferable to provide a function for fine-tuning this (variation absorption function) and fine-tune it at the time of product inspection before product shipment. To briefly describe a specific method, for example, a knob such as a variable resistor is provided on an auxiliary operation unit or the like of the sleeve, and the knob is adjusted. The value of the variable resistor sets a duty value or a reference value of the voltage to the electromagnetic coil. At the time of product shipment inspection, the knob is adjusted so that the water discharge hole deflection angle α becomes a constant reference value under certain conditions. Further, the timing of the adjustment is not limited to the time of product shipment inspection, may be after the product is mounted, and may be adjusted not only by the manufacturer but also by a maintenance person or user.

Next, examples of the present invention will be described.
FIG. 60 is a block diagram showing a schematic configuration of the local cleaning apparatus of this embodiment, focusing on a water channel system. FIG. 61 is a cross-sectional view showing a schematic configuration of an accumulator WP2-7 provided in the water channel system. 62 is a cross-sectional view illustrating the configuration of the wave generation device WP2-8 similarly arranged in the waterway system. FIG.
FIG. 3 is an explanatory diagram for explaining the flow of the washing water by the wave generation device WP2-8, and FIG.
FIG. 65 is a schematic diagram schematically showing the state of installation of 2-8.
FIG. 3 is a block diagram illustrating a schematic configuration of a control system. In addition,
The same members and the same reference numerals are used for the same members as those of the above-described reference example or its modified example, and the same member names are used for members performing the same function.

A2 / Overall configuration: Even in the local cleaning apparatus KS2-1 of this embodiment, the above-described local cleaning apparatus KS1-1 is used.
It has the same appearance as that of, and has a main unit KS1-2 and a remote control device RC1-1 (see FIGS. 1 and 2). In the remote control device RC1-1 of the present embodiment, each of the buttocks cleaning button SWb, the soft cleaning button SWc, and the bidet cleaning button SWd included in the uppermost button group is
After the operation of the button, each of the above-described washings is started. Therefore, each of these buttons of the remote control device RC1-1 functions as "instruction means" according to the present invention. In addition, the same as the local cleaning device KS1-1 in that the main body has a nozzle device and the like.

B2 / Waterway system / control system configuration: As shown in FIG. 60, the waterway system of the local cleaning device KS2-1 receives water from the external water supply side and receives the water inlet side valve unit WP2-1 and heat exchange unit TH1- 1 and a flow control switching valve WP2-2 and a wave generation unit WP2-3. And the flow path switching valve WN2-2 of the washing nozzle WN2-1 is provided from the wave generation unit.
The washing water is guided to the washing nozzle WN2-1 through the nozzle, and the washing water is discharged from the nozzle as described later. These units are connected by upstream and downstream water supply lines across the wave generation unit. That is, the water inlet side valve unit and the heat exchange unit are connected by the upstream water supply line WP2-5, and the nozzle device downstream of the wave generation unit is connected by the downstream water supply line WP2-6.

The water inlet valve unit WP2-1 differs from the water inlet valve unit WP1-1 of FIG. 4 in that a pressure regulating valve WP2-4 is provided instead of the constant flow valve WP1-9 (see FIG. 4).
For this reason, the cleaning water is supplied at a predetermined pressure (primary pressure: about 0.098 MPa @ about 1.0 kgf / cm) by the pressure regulating valves WP2-4.
After the pressure is adjusted to ²に), the air flows from the water inlet valve unit WP2-1 to the heat exchange unit TH1-1 through the opening of the solenoid valve. Then, as described above in the heat exchange unit, the washing water that has been heated to the set temperature based on the temperature on the inlet / outlet side is subjected to flow adjustment by the flow control switching valve WP2-2, and then subjected to the wave generation unit. Flows into the functional water units WP1-4. Since the generation of functional water by this functional water unit is the same as that of the above-described reference example, description thereof will be omitted. In addition, the flow control switching valve WP2-2 is changed by changing the opening ratio of the pipeline leading to the wave generation unit and the pipeline leading to the functional water unit.
You may comprise so that the flow volume (wash water discharge flow volume) to a wave generation unit may be adjusted. In this case, the flush water having the difference between the flush water flow rate that has reached the flow control switching valve and the flush water spout flow rate is sent to the functional water unit, and as described above, the flush water is spouted from the chamber to the nozzle and the toilet bowl section. run down. In other words, the flow rate of the flush water spout is adjusted via the flush water derivation other than the nozzle.

The wave generation unit WP2-3 includes an accumulator WP2-7 and a wave generation device WP from the upstream side.
2-8. As shown in FIG. 61, the accumulator includes an upstream water supply line WP upstream of the wave generation device.
2-5 connected to a housing WP2-9 and a damper WP2 arranged in a damper chamber WP2-10 in the housing.
-11 and a spring WP exerting a biasing force on the damper.
2-12. Therefore, the accumulator reduces the water hammer of the upstream water supply pipeline WP2-5 upstream of the wave generation device. Therefore, the effect of the water hammer on the temperature distribution of the cleaning water in the tanks TH1 to TH3 can be reduced, and the temperature of the cleaning water discharged can be stabilized. In this case, the accumulator WP2-7 may be disposed close to or integrally with the wave generation device WP2-8, so that the pulsation generated by the wave generation device propagates upstream as described later. This is preferable from the viewpoint that this can be quickly and effectively avoided. In this case, the accumulator is configured to have only a damper chamber as a mere air chamber without a damper and a spring for energizing the damper, or an air reservoir that intentionally inflates the upstream water supply line partially upward. It can also be formed as

As shown in FIG. 62, the wave generator WP2-8 includes a cylinder W connected to an upstream / downstream water supply line.
A plunger WP2-14 is slidably provided on P2-13. Then, the plunger is moved forward and backward by the excitation control of the electromagnetic coil (pulsation generating coil) WP2-15. The plunger WP2-14 moves to the downstream side from the illustrated original position by the excitation of the pulsation generating coil WP2-15. However, when the coil excitation disappears, the plunger WP2-14 receives the urging force of the upstream and downstream springs WP2-16 and WP17. Return to the original position. Since the plunger WP2-14 has a check valve WP2-18 formed of a steel ball and a spring inside the plunger WP2-14, when moving from the original position to the downstream side, the cleaning water in the cylinder is pressurized to supply water to the downstream side. Flush into conduit. On this occasion,
Since the plunger original position is constant, a fixed amount of washing water is sent to the downstream water supply line. After that, when returning to the original position, the flush water flows into the cylinder via the check valve, so the next time the plunger moves downstream, a certain amount of flush water is sent again to the downstream water supply line. become. In addition, when the plunger returns to the original position, the washing water is drawn in the plunger downstream side, that is, in the downstream water supply pipe.
Causes a pulsation in which the pressure periodically fluctuates up and down with the reciprocation of the plunger, and causes the washing water to flow to the downstream water supply pipe in a pulsating flow state. As described later, the washing water in the pulsating flow having the periodic fluctuation of the pressure is discharged from the discharging hole of the washing nozzle.
2-8 functions as "water discharging means" in the present invention.

In this case, the above-mentioned primary-pressure washing water is supplied to the wave generator WP2-8 via the upstream water supply line. Therefore, as described above, the plunger WP2-14
Although the washing water that has flowed into the cylinder via the check valve during the return to its original position does not remain at the primary pressure due to the pressure loss due to the check valve and the suction of the washing water on the downstream side,
It is sent to the downstream water supply line. When this state is represented by a diagram, as shown in FIG. 63, the cleaning water is supplied from the wave generator WP2-8 to the downstream water supply line at a pressure pulsating around the primary pressure, and thus the cleaning nozzle WN2-. 1 and discharged to a local area as described later. Moreover, the wave generation device WP2
The flushing water pressure sent downstream from -8 does not become zero due to the flushing water flowing into the cylinder via the check valve when the plunger returns to the original position as described above. The pulsation transition of the washing water pressure is reflected in the transition of the washing water flow rate.

The pulsation cycle MT shown in FIG. 63 is synchronized with the excitation cycle of the pulsation generation coil WP2-15, and can be variously set as described later through control of changing the excitation cycle. In addition, since only the coil excitation for reciprocating the plunger is required to generate the pulsating flow of the washing water, the configuration of the wave generating device can be simplified.

In this embodiment, as shown in FIG. 60, since the wave generating device WP2-8 is disposed downstream of the tank TH1-3 of the heat exchange unit, the pulsating flush water is supplied to the water supply pipe. Because it has a larger diameter than the road, it does not pass through a tank that tends to cause pulsation damping. Therefore, pulsating flush water can be sent to the downstream water supply pipe, and thus to the washing nozzle WN2-1, without being affected by pulsation damping by the tank.

Further, when installing the wave generator WP2-8, a so-called anti-vibration rubber was interposed. Therefore,
Due to the vibration damping action of the vibration isolating rubber, the vibration accompanying the generation of pulsation can be suppressed, and the generation of abnormal noise due to the vibration can also be suppressed. In this case, the wave generating device is installed on a resin plate (not shown) having a high specific gravity by mixing a powder or a granular material having a high specific gravity such as a metal, and the resin plate is interposed with an anti-vibration rubber. Can also be arranged on the bottom plate of the main body. By doing so, the vibration source mass itself is increased as the sum of the wave generation device and the resin plate, so that the vibration caused by the pulsation can be made less likely to occur. it can. In order to increase the vibration source mass in this way, instead of installing the wave generation device on the resin plate having a high specific gravity as described above, the wave generation device is attached to a member or unit having a large mass of the local cleaning device. Can also be installed. In this case, since no resin plate is required, there is an advantage in manufacturing such as a reduction in cost due to a reduction in the number of members, and the size of the apparatus can be reduced. Further, if a vibration isolating rubber is provided between the wave generating device and the resin plate, the vibration isolating rubber of the two-degree-of-freedom system as shown in FIG. Can be configured.
For this reason, by selecting an anti-vibration rubber so that the spring constants k1 and k2 and the damping coefficients c1 and c2 are effective to reduce vibration, a high damping effect can be exhibited, and vibration can be propagated to a toilet seat or the like. Can be effectively avoided. It should be noted that such vibration suppression can also effectively suppress the generation of abnormal noise due to vibration.

The wave generator WP2-8 and the tank T
Unnecessary pulsating pressure is not applied to the tank in combination with the arrangement of the accumulator between H1 and H1-3.
For this reason, an inadvertent increase in the tank internal pressure can be avoided, so that fatigue due to deformation and contraction / expansion of the tank can be avoided, which is not only preferable, but also does not require a tank having an unnecessarily high pressure resistance.

In this embodiment, the following was used to construct the above-mentioned waterway system. That is, both the upstream and downstream water supply lines are made of high-hardness flexible piping,
The hardness of the above-mentioned downstream water supply line was made larger than that of the upstream water supply line. Also, coupler type joints were used for these pipe lines and the pipe connection portions of the respective units. Furthermore, each unit was arranged close to each other to shorten the length of the water supply pipe between the units. As a result, expansion and contraction, expansion and contraction of the water supply pipe itself are less likely to occur, and the effect of pulsation damping due to this expansion and contraction can be suppressed. 1 can be sent. In particular, since the wave generation device WP2-8 and the flow path switching valve WN2-2 are arranged close to each other, the pulsation attenuation when the washing water passes through the downstream water supply line therebetween is high, and the downstream water supply line is high. Combined with the flexibility of the flexible piping, it can be suppressed more effectively.

As shown in FIG. 65, the control system of the local cleaning device of this embodiment is mainly composed of an electronic control unit CT2-1. And this electronic control device, like the above-mentioned reference example, based on the input of various buttons and sensors,
In addition to control of the solenoid valve on / off valve of the water inlet side valve unit, control of heater energization of the heat exchange unit, etc., the pulsation generating coil WP2-15
The above-mentioned pulsation frequency control is executed through the excitation control.
This pulsation frequency control will be described later in detail.

C2 / Nozzle Device NS2-1: Next, the nozzle device NS2-1 of the local cleaning device of this embodiment will be described. FIG. 66 is a schematic perspective view showing the nozzle device NS2-1, and FIG. 67 is a schematic sectional view taken along line 67-67 in FIG.

As shown, the nozzle device NS2-1 of this embodiment has substantially the same configuration as the nozzle device NS1-20 of the modified example of the above-described reference example. That is,
The nozzle device NS2-1 is a modified nozzle device NS.
1-20, the nozzle advance / retreat trajectory NS1-12 (FIG. 7)
Guide rail portion NS1-21 having a curved shape that matches
, A cleaning nozzle WN2-1 which is also curved is provided. And the track gripper WN below the nozzle rear end side
The cleaning nozzle WN2-1 moves along the arc-shaped nozzle advance / retreat trajectory NS1-12 because the nozzle 1-21 slides along the guide rail while holding the rails left and right of the guide rail NS1-21 up and down. Along the path, the transmission mechanism NS1-5 advances and retreats. Since the cleaning nozzle is slidably held by the nozzle holding portion NS1-6 on the toilet bowl portion side (see FIG. 8), the nozzle holding portion and the track holding body are separated from each other. It will be slidably held in several places. In addition, the washing nozzle may be formed in a straight conduit shape.

A grip portion WN2-3 having a slidability with respect to the rail portion and a vibration absorbing function is provided at a position where the guide rail portion of the track gripper WN1-21 is gripped. The grip portion having such properties is made of a rubber-based material that has been subjected to a material blending process such as oil impregnation and WAX blending, or a rubber-based material that has undergone a surface treatment such as Teflon (registered trademark) coating, halogen treatment, and satin finish. Manufactured. Therefore, even if the pulsating flow of washing water flows from the wave generation device WP2-8 into the cleaning nozzle as described later, and the vibration due to the pulsating flow occurs in the cleaning nozzle, the vibration is prevented from propagating to other members. it can. For this reason, generation of abnormal noise due to vibration can also be suppressed. In this case, if the rubber-based material that exhibits the slidability and the vibration absorbing function after being subjected to the above-described compounding treatment or surface treatment is disposed on the inner wall of the nozzle holding hole in the nozzle holding portion on the toilet bowl portion side, the vibration described above can be obtained. The effect of preventing propagation and the effect of avoiding generation of abnormal noise can be enhanced.

In the nozzle device NS2-1 of this embodiment,
From the positional relationship between the washing nozzle and the guide rail as described above,
Compact in the width direction. Therefore, the nozzle device and the wave generation device WP2-8 can be arranged closer to each other, and the effect of suppressing pulsation attenuation in the downstream water supply pipe can be enhanced. When installing this nozzle device, the base NS1-2 (see FIG. 66)
Was disposed on the bottom plate of the main body with an anti-vibration rubber therebetween. Therefore, even if the vibration due to the pulsation propagates to the nozzle device, the vibration can be effectively suppressed by the vibration damping rubber and the generation of abnormal noise due to the vibration can be suppressed.

E2 / Washing nozzle WN2-1: Next, the washing nozzle WN2-1 will be described. FIG. 68 is a schematic cross-sectional view of a main part for describing a configuration of a flow path switching valve WN2-2 of the cleaning nozzle, and FIG. 69 is an exploded perspective view of a main part of the flow path switching valve. FIG. 70 shows the nozzle head NH.
FIG. 71 is a plan view showing 2-1 in a plan view and partly broken around the head, and FIG. 71 is a plan view showing a modification of the nozzle head.

As shown in FIGS. 66 to 68, the flow path switching valve WN2-2 is located at the rear end of the washing nozzle WN2-1, and the pulsating washing water sent from the wave generator WP2-8. The following configuration is provided to switch the water supply destination to each nozzle flow path for cleaning the bottom of the cleaning nozzle, for soft cleaning, and for bidet cleaning.

The flow path switching valve WN2-2 includes a casing WN2-4 having a switching mechanism described below. The passage switching valve is integrated with the cleaning nozzle by welding the casing to the rear end face of the cylindrical portion WN2-5 of the cleaning nozzle WN2-1. Therefore, it advances and retreats along the track as described above together with the cleaning nozzle.

A stator WN2-6 having a communication hole communicating with each flow path in the nozzle is provided on the casing from the nozzle side.
A rotor WN2-7 that rotates for switching the flow path and selectively opens each communication hole of the stator, a coupling WN2-8 for transmitting rotation to the rotor, and a rotatable coupling. A housing WN2-9 housed in the housing,
Spring WN2- urging rotor toward stator
And 10. As shown in FIG. 69, each communication hole WN2-11 to 13 of the stator is equally opened on the side facing the rotor, and on the nozzle side, the flow path in the nozzle shown in FIG. First nozzle channel WN of the nozzle channel
1-7, second nozzle channel W of the nozzle channel for soft cleaning
N1-8, third nozzle channel WN of bidet cleaning nozzle channel
It is open so as to communicate with each flow path of 1-9. That is, the communication hole is curved in the stator. These communication holes may be arranged alongside the openings of the nozzle flow paths at the rear end of the washing nozzle. In this case, the communication holes may be straight holes. In addition,
The first to third nozzle flow paths WN1-7 to WN9 are:
Until the nozzle head NH2-1 at the tip of the nozzle, the cylindrical portion WN
2-5 are formed in the longitudinal direction.

The rotor WN2-7 has a notch WN2 capable of opening one of the communication holes equally opened on the upper surface of the stator.
The communication hole is opened by overlapping the notch with the communication hole opening. In this case, the rotor can shield each communication hole by locating the notch between the adjacent communication holes. That is, if the rotor is slightly rotated from the position where the notch is between the adjacent communication hole openings, the washing water can be sent to the above-described respective nozzle flow paths via the communication hole.
In addition, for the convenience of discharging (draining) water remaining in the nozzle, this rotor is provided with a notch that can overlap with all the communication hole openings. The communication hole can be opened.

The coupling WN2-8 has a flow path switching valve W
N2-2 is mounted on the rotation shaft of the drive motor WN2-15, and the rotation shaft pin WN2-1 is inserted into the slit WN2-16.
Position 7. In addition, this coupling connects the rotary key WN2-18 to the slit WN2-1 of the rotor WN2-7.
9 is located. Therefore, when the drive motor rotates forward and backward, the rotation is transmitted to the coupling by the rotation shaft pin and to the rotor by the rotation key. Then, since the notch selectively opens one of the communication holes as described above due to the rotation of the rotor, the pulsation from the wave generation device WP2-8 is supplied to the nozzle flow path corresponding to the selected communication hole. Stream wash water is supplied.

In this case, the washing water from the wave generator WP2-8 is supplied to the downstream side water supply pipe WP2-6 (see FIG. 60) and the connection joint WN2-20 provided on the casing of the flow path switching valve WN2-2. After that, it flows into the flow path switching valve. In connecting the downstream water supply line from the wave generating device to the connection joint, measures such as disposing the wave generation device below the connection joint are taken so that air cannot be trapped in the middle of the downstream water supply line. I made it. For this reason, during the time when the pulsating flow of the washing water reaches the flow path switching valve from the wave generation device, since there is no air pool and the pipe has a high hardness as described above, the pulsation attenuation is further reduced. It can be suppressed effectively. Further, the only pipe line from which the washing water pulsated by the wave generating device reaches the nozzle device is the downstream water supply pipe line to the wave generating device and the flow path switching valve. Then, a buffer material such as a vibration-proof rubber was disposed in a place where the downstream water supply pipe could come into contact with surrounding members. Specifically, the vibration-proof rubber was attached to the surrounding member side, or the vibration-proof rubber was wound around the water supply pipe. Therefore, coupled with the fact that the downstream water supply pipe is of high hardness as described above,
The pulsation can be suppressed more effectively.

Each member such as a casing of the flow path switching valve WN2-2 is made of polyphenylene sulfide (abbreviated as PP).
S), durability of polyacetal (abbreviated POM), polybutylene terephthalate (abbreviated PBT), glass fiber reinforced polybutylene terephthalate (abbreviated GF / PBT), etc.
It is formed using engineering plastic with high heat resistance. Therefore, the washing water flow path in the flow path switching valve is
Since it functions as a high-strength pipeline, pulsation attenuation due to pipeline expansion and contraction does not occur. When supplying the pulsating flow washing water from the wave generation device WP2-8 to the nozzle flow path, the flow path switching valve is integrated with the cleaning nozzle and there is no piping therebetween, so that the pulsation is attenuated. Hardly ever happen. Further, when switching the water supply destination as described above, the rotation of the rotor WN2-7 is used, so that the pulsation damping can be reduced more than the flow path switching valve using the elasticity of an elastic body such as a diaphragm. It can be suppressed effectively.

According to the flow path switching valve WN2-2, there are the following advantages. The flow path switching valve is a wave generation device WP2
It is integrated with the cleaning nozzle WN2-1 downstream of -8 instead of -8, and is separated from a wave generation device that can be a vibration source due to generation of a pulsating flow. Therefore, the vibration source can be only the wave generation source. In addition, the flow path switching valve,
It moves forward and backward together with the cleaning nozzle, but the drive motor WN2-1
In No. 5, since the coil winding portion is resin-molded, there is no problem in driving the motor even if the washing water scatters on the drive motor when entering the washing position. Furthermore, since the number of downstream water supply pipes leading to the nozzle device can be reduced to one, it is possible to reduce the degree to which the pipes become a load when the nozzle moves forward and backward. Therefore, the load torque on the nozzle driving motor can be reduced.

The nozzle head NH of the cleaning nozzle WN2-1
Even if it is in 2-1, the normal buttocks spout hole NH for ass washing
2-2 and a soft spout hole NH for soft cleaning of the buttocks
2-3, and a bidet discharge hole NH2-4 for bidet cleaning. The nozzle head has a cylindrical portion WN2-
5, a first head passage NH2-5 and a second head passage NH2 formed inside the nozzle head in a watertight manner.
-6, the third head flow path NH2-7, and the first nozzle flow path WN1-7 and the second nozzle flow path WN of the cleaning nozzle, respectively.
1-8, connected to the third nozzle channel WN1-9. As shown in the drawing, these nozzle flow paths reach the above-described water discharge holes on the upper surface of the nozzle head. Therefore, the flow path switching valve WN
When 2-2 (see FIG. 66) switches the supply destination of the cleaning water to any of the first to third nozzle channels WN1-7 to 9 at the rear end of the nozzle, the cleaning water is switched. Water is discharged from each of the water discharge holes through the nozzle flow path and the head flow path. In this case, the pulsating flush water is supplied from the wave generation device WP2-8, so that pulsating flush water is discharged from each water discharge hole.

In this case, in each of the water discharge holes NH2-2 to NH4 of the nozzle head NH2-1, the bottom water discharge hole has the smallest diameter, and the bidet water discharge hole and the soft water discharge hole have a smaller diameter than this water discharge hole. Has been enlarged. For this reason, the water pressure setting button SWh of the remote control device RC1-1 (see FIG. 2).
In a situation where the water force is set to be constant by u and SWhd, as described in the reference example above, the water discharge speed of the wash water from each water discharge hole is the highest at the bottom water discharge hole, and the bidet water discharge speed is high. It is slower than the butt spout in the hole and the soft spout. Then, in the soft cleaning with a low water discharge speed, the washing feeling received from the water discharge is made at least softer by the low water discharge speed than in the case of the normal butt cleaning. Note that the bidet water discharge hole and the soft water discharge hole are not limited to a single hole as shown in the figure, and a plurality of small-diameter fine holes are arranged as shown in FIG. It can also be formed as a water discharge hole. In this case, if the total area of the water discharge holes, which is the sum of the areas of the plurality of pores, is equal to or more than the area of the bottom water discharge holes, the water discharge becomes softer as a whole of the pores than in the case of the bottom cleaning.

Next, taking the ass washing as an example, the state of spouting of washing water by the local washing apparatus of this embodiment will be described. FIG. 72 is an explanatory diagram illustrating the state of excitation of the pulsation generating coil WP2-15 of the wave generation device WP2-8 that generates a pulsation at the time of flushing water discharge. FIG. FIG. 74 is a timing chart showing the amount of water and the flow velocity of the nozzle head NH2-
It is explanatory drawing which illustrates typically the state of washing water spouting from one buttocks spout NH2-2.

The electronic control unit CT2-1 outputs a pulse signal when exciting the pulsation generating coil WP2-15 to generate a pulsation in the wave generation device WP2-8. Then, the pulse signal is output to a switching transistor (not shown) connected to the pulsation generating coil and turned on. Therefore, the pulsation generating coil
ON / OFF of the switching transistor according to the pulse signal
Excitation is repeatedly performed by turning OFF, and the plunger WP2-14 is periodically reciprocated as described above. This allows
Wash water is supplied from the wave generator WP2-8 to each of the water discharge holes of the nozzle head in a pulsating flow in which the pressure periodically fluctuates up and down, and the pulsating flow of the wash water is discharged from each of the water discharge holes. At this time, the electronic control unit variably controls the frequency of the pulse signal in a predetermined frequency range and controls the duty ratio of the on / off of the coil excitation pulse. Thereby, various pulsations can be caused. Therefore, the electronic control device that controls the energization of the electromagnetic coil functions as the “water discharge control unit”, the “control unit”, or the “variation control execution unit” according to the present invention. In this case, a pressure sensor for detecting the pressure of the pulsation caused by the wave generating device may be provided on the downstream side immediately after the wave generating device, and the duty ratio control may be fed back by the detection value of the sensor. The position of the sensor is not limited as long as it can reflect the pulsating pressure. For example, it may be provided in the vicinity of the cleaning nozzle, or may be provided in the vicinity or substantially integrally by using the mechanism of the wave generation device.

As shown in FIG. 72, the pulsation cycle MT shown in FIG. 63 is set to a cycle T1, and the ON time of the pulse signal is set to t1.
Then, the duty ratio is (t1 / T1) × 100
(%). When the pressure pulsation as shown in FIG. 63 occurs, the amount of the washing water decreases to a value represented by the duty ratio as compared with the continuous flow. As shown in FIG. 73, the amount of water of such a pulsating flow increases and decreases in the range from the maximum flow rate Qmax to the minimum flow rate Qmin, and the flow rate also increases and decreases in the range from the maximum flow rate Vmax to the minimum flow rate Vmin. In FIG. 73, the reason why the minimum flow rate Qmin and the minimum flow velocity Vmin are not zero is that the pulsation pressure by the wave generator WP2-8 is not zero even at its minimum as described above.

When the continuous flow of cleaning water is discharged from the water discharge hole (for example, the tail water discharge hole NH2-2) as in the conventional case, the cleaning water from the water discharge hole is continuously discharged as shown in FIG. In contrast, when the pulsating flow of the washing water is discharged as shown in FIG. 74 (B), the washing water is discharged in a discrete or water mass state as shown in FIG. 74 (B). Is done. As described above, when the washing water pulsated by the wave generation device WP2-8 is jetted from the water discharge hole of the washing nozzle,
The reason for the discrete or water mass state will be described with reference to FIGS. 73 and 75.

FIG. 75 is an explanatory view for explaining a process in which, when the pulsating flow of cleaning water is discharged from the water discharge hole, the discharged cleaning water is amplified into a pulsating flow. As shown in FIG. 73 (A), when the amount of washing water is pulsated by the wave generation device WP2-8, the flow velocity V is similarly changed to be pulsating. That is, the amount of the flushing water discharged is the maximum flow rate Qmax.
, The flow velocity also reaches the maximum velocity Vmax, and the instantaneous flow velocity and flow rate fluctuate with time. Further, each part of the pulsating flow of the washing water in FIG. 73 is represented by Wp1, Wp2, Wp3, Wp.
4, Wp5, the amount of each part is Wp1 (= Wp
5) <Wp2 (= Wp4) <Wp3, and the respective flow rates also satisfy V1 (= V5) <V2 (= V4) <V3. Therefore, as soon as the state shifts from (A) to (C) in FIG. 75 immediately after the water discharge, Wp3 has a higher speed than Wp2. As described above, when the maximum flow velocity Wp3 is sequentially merged with the preceding Wp2 and Wp1, a large lump is formed, and the water reaches the local part of the human body (cleaning surface). As described above, when the washing water hits a local body part, the washing water is in a state of a water mass having a large collision energy (washing strength). This flow velocity V3 is the maximum flow velocity Vma shown in FIG.
Since it is x, the wash water spouted by the pulsating flow is spouted from the spout hole in a spout form in which the state of the combined water mass appears at each pulsation cycle MT. In addition, since such a phenomenon occurs in the pulsation cycle, the water mass that has passed through the coalescence of the maximum flow velocity Wp3 as described above repeatedly appears, and the water mass at a certain water discharge timing and the water mass at the next water discharge timing merge. Will be moved (spouted) at substantially the same speed (maximum speed) as the water mass that has passed.

Next, the difference in cleaning intensity between the case where the washing water is ejected as a continuous flow from the tail water discharge port NH2-2 and the case where the washing water is ejected as a pulsating flow will be described. The pulsating flow has twice or more the cleaning intensity at the same amount of water as compared with the conventional continuous flow. This is considered as the following reason. The energy E when the washing water having the mass m collides with the wall surface at the speed V is represented by the equation (1). E = (1/2) mV ² (1) Further, the force at the time of collision with the wall surface is represented by f, and the time required for the washing water flow at the speed V to be reduced to 0 and disappear is Δ.
Assuming that t, the energy E is represented by the impulse by equation (2), and the force at that time is represented by equation (3), where α is the deceleration. E = fΔt (2) f = mα (3) FIG. 76 is an explanatory diagram illustrating a state in which the washing water stream collides with the wall surface. In FIG. 76, the water masses are W1, W2, and W3.
Assuming the following three forms, the cleaning strength of the cleaning water flow of each of these forms will be examined. Here, the water body W1 has a long shape with a cross-sectional area S1, and the water body W2
Is a form in which the cross-sectional area S2 is twice as long as S1 and is short, and the water body W3 is a form having a cross-sectional area of S1 and a half length of the water body W1. In these embodiments, the water mass W1 corresponds to a continuous flow, and the water mass W3 corresponds to a pulsating flow. At this time, the water mass W
Time Δ until water 1 and water mass W2 collide with the wall and disappear.
t1 and Δt2 satisfy Δt1> Δt2. This means
Equation (3) indicates that the deceleration α is large and the water mass disappears with a large force in a short time, and the force f1 of the water mass W1 and the force f2 of the water mass W2 satisfy f1 <f2. Therefore, it can be understood that the force f2 applied to the human body local part is larger in the water body W2 that disappears in a short time than in the continuous water body W1. For this reason, the water mass W3 corresponding to the pulsating flow has a mass of m / 2 as compared with the water mass W1, but the force f3 does not decrease much as compared with f1. Therefore, when jetted as a pulsating flow, the amount of water can be made smaller than that of the continuous flow, and the force at the time of colliding with the human body local part does not decrease so much. Can be removed.

Next, the relationship between the washing intensity, which is an index indicating the feeling of washing of a human body part, and the feeling of washing will be described. FIG. 77 is an explanatory diagram illustrating a state in which the pressure sensor plate Ps is installed at a predetermined distance La so as to face the buttocks discharge hole NH2-2. The predetermined distance La is set at a position where the human body part is cleaned. The pressure sensor plate Ps is a sensor that includes detection units in a two-dimensional matrix and outputs the detection values of each detection unit independently. Using such an apparatus, the peak value of the pressure output from each detection unit when the cleaning water was discharged from the tail water discharge port NH2-2 of the cleaning nozzle WN2-1 was measured. FIG. 78 shows the result. FIG. 78 is an explanatory diagram three-dimensionally expressing the position on the pressure sensor plate Ps and the peak value of the pressure. The XY plane is the pressure sensor plate Ps.
The position of s, that is, the position of the object to be detected, is shown, and the Z axis represents the peak value of the pressure at each position. FIG. 78 (A)
Indicates that the cleaning water reaching the water discharge hole has a flow rate of 1.1 L / min. FIG. 78 (B) shows the measurement result at the time of the continuous flow of 0.5 L / min. 5 shows the measurement results at the time of the pulsating flow. In FIG. 78, the cleaning intensity, which is a factor that affects the feeling of cleaning, is represented by the peak value of the pressure, while the feeling of volume is represented by the volume of the mountain, which is the overall pressure distribution.

When these are compared, the peak value of the pressure in the pulsating flow shown in FIG. 78 (B) is greatly increased, although the amount of washing water is halved as compared with the continuous flow in FIG. 78 (A). ing. This indicates that the washing pressure on the water body is large, that is, the washing strength is large.
FIG. 79 is a timing chart showing a detection signal detected from one of the detection units. FIG.
FIG. 79 (B) shows a pulsating flow. It can be seen that the pulsating flow has a higher peak value and a higher intensity than the continuous flow. Also, the volume of the peak, which is the overall pressure distribution, is much larger in the pulsating flow of FIG. 78B than in the continuous flow of FIG. 78A. As described above, the pulsating flow has an extremely large volume as compared with the continuous flow, and it can be understood that the pulsating flow has excellent detergency when the sensual element of the cleaning feeling is embodied in a numerical value.

FIG. 80 shows the result of examining the actual cleaning amount by such a pulsating flow in comparison with a continuous flow. FIG.
It is a graph showing the relationship between the average amount of water discharged and the amount of cleaning, that is, when removing dirt attached to the human body part with cleaning water,
The average required water discharge is shown. As can be seen from FIG. 80, in order to remove the dirt of the cleaning amount D1 adhered to the human body part, it was found that the pulsating flow had a water amount of about ４ as compared with the conventional product which can only discharge the continuous flow of cleaning water. . As described above, by the method of discharging the pulsating flow of the cleaning water from the water discharge holes, the cleaning intensity and the user's cleaning feeling can be significantly improved.

Further, when the pulsating flow of the washing water is spouted, the washing intensity is increased and the stimulation to the human body part is increased. This can be explained as follows as in the above-mentioned reference example. When a stimulus that can be sensed at the same location on the human epidermis (in this embodiment, a stimulus due to collision of water masses W1, W2, and W3 shown in FIG. 76) is intentionally repeatedly applied, the repetition interval (pulsation in this embodiment) If the period MT) is long and the repetition frequency is low,
The human perceives this repeated stimulus as a vibration stimulus each time. On the other hand, if the repetition interval is short and the repetition frequency is high, a person cannot perceive this intentionally repeated stimulus as a vibration stimulus but perceives it as a continuous stimulus.
In other words, there is a dead band frequency that cannot be sensed as a vibration stimulus for a repetitive stimulus to the human body epidermis, and this dead band frequency is a repetition frequency of about 5 Hz or more as in the case of the above-described reference example. Therefore, in performing the intentional repetitive water discharge of the pulsating flow of the wash water, as the repetition frequency increases, it becomes more difficult to follow the perception of the vibration based on the intentional repetitive water discharge. And
If this repetition frequency is about 10 Hz or more, most people who have a normal perception will hardly be able to perceive the vibration due to intentional repeated water discharge. Therefore, it is difficult to recognize a water discharge mode (washing water of a pulsating flow) which is intentional repetitive water discharge, and in this embodiment, a user who receives a collision of a water mass shown in FIG. Most people cannot perceive the impact of this body of water as intermittent, but can make it feel as if it is a continuous flow of wash water.

The following is a description with reference to the drawings. FIG. 81 is an explanatory view for explaining the reason why the cleaning intensity varies depending on the increase and decrease of the frequency. FIG. 81 (A) is determined by this period because the pulsation period MT is large even with the same amount of cleaning water than FIG. 81 (B). This shows a state where the pulsation frequency fmt (= 1 / MT) is small. In FIG. 81 (A) and FIG. 81 (B), the size can be made as large or small as the above-mentioned body of water due to the length of the cycle. Therefore, in the case of FIG. 81A in which the pulsation cycle MT is large and the pulsation frequency is small, the mass of the water mass in one collision increases, the collision energy increases, and the human body is strongly stimulated. That is, in the case of FIG.
The human body receives a large stimulus at once and feels a strong stimulus.
Further, as shown in FIG. 81 (A), when the pulsation frequency fmt falls below the above-described dead band frequency or becomes a frequency close to this frequency, the human body repeatedly receives a strong stimulus while sensing the stimulus in each case. feel. On the other hand, as shown in FIG. 81 (B), if the pulsation frequency fmt is large and is within the above-mentioned dead band frequency, a small stimulus is received as a continuous stimulus as described above, so that the stimulus is not felt much. From this, even with the same amount of water,
The higher the frequency and the larger the water mass, the stronger the stimulus (cleaning intensity) to the human body. FIG. 82 is a graph showing the relationship between the pulsation frequency and the washing intensity of the pulsating flow and the discomfort caused by the stimulation of the human body local part. When the frequency exceeds 5 Hz, the human skin approaches a continuous flow and can be felt as soft washing, and when the frequency exceeds about 30 Hz, it is almost indistinguishable from the continuous flow. Therefore, the frequency of the pulsation flow is preferably 5 Hz or more. Further, considering that the frequency of the commercial power supply is used as it is for the excitation control of the pulsation generation coil WP2-15 of the wave generation device WP2-8, 50 to 60 Hz Is set as the upper limit, the configuration for control can be simplified.

From the viewpoint of the dead band frequency, also in this embodiment, the excitation cycle of the pulsation generating coil WP2-15,
That is, the pulsation cycle MT is changed to the pulsation frequency ftm (= 1 / M
T) is variably controlled so as to be in the range of about 5 Hz or more, so that the stimulus to the local part of the human body by the water body is sensed as a continuous stimulus. In other words, despite the fact that the flush water volume is reduced only by intermittently discharging the flush water to the flush portion of the human body part at the pulsation cycle MT, the user is continuously provided with the flush portion. It is possible to give a feeling of washing as if the washing water is being spouted. Therefore, even in this embodiment, the flow rate of the washing water is controlled by the flow control switching valve W.
Even if it is reduced to about 500 cc / min by P2-2, the cleaning ability and the feeling of cleaning can be improved, so that it is only necessary to discharge the cleaning water at the maximum flow rate. In other words, it is possible to give the user the feeling of receiving continuous water spouting while improving the effectiveness of water saving.

Even if the pulsation frequency ftm is set to the above-mentioned dead zone frequency, it can be said that the sense of continuous spouting water received from the continuous spouting of the wash water tends to be weaker as the pulsation frequency ftm is lower. Therefore, the pulsation frequency ftm can be intentionally lowered within the above range to give the user a slight intermittent feeling of washing (stimulation).

Also, pulsation frequency control and coil excitation duty ratio control can be performed as follows. FIG.
FIG. 84 is an explanatory diagram illustrating a control example in which the pulsation frequency in the pulsating flow of the washing water is made different between the butt cleaning and the bidet cleaning. FIG. 84 is an explanatory diagram illustrating a control example of the pulsating frequency ftm and the duty ratio Dtm. is there.

As shown in FIG. 83, the pulsation periods MTA and MTV in the ass washing and in the soft and bidet washing are set to be large and small, so that the respective pulsation frequencies ftm can be different. In addition, the pulsation frequency ftmA at the time of ass washing was set lower than the pulsation frequency ftmV at the time of soft / bidder washing. In this case, both frequencies are within the above-mentioned dead band frequency range. For example, by changing the frequency such as 50 Hz for butt cleaning, 60 Hz for soft cleaning, and 70 Hz for bidet cleaning, as described below, bidet cleaning or the like can be a cleaning form with less water than butt cleaning. May be set to the frequency. As described above, the pulsation frequency is set by the "cycle setting means" or the "setting means" of the present invention for setting the time-varying cycle of the flow rate or the flow rate of the washing water.
The electronic control unit CT2-1 corresponds to "periodic water discharge control means" or "control means" according to the present invention.

By frequency control according to the object to be cleaned as shown in FIG. 83, as described with reference to FIG. 81, at the time of washing the buttocks, a water discharge form similar to FIG. 81 (A) is obtained.
It becomes a washing that receives a sufficient stimulus continuously,
A hard washing feeling can be obtained. Also, soft
At the time of bidet cleaning, the water is discharged as shown in FIG. 81 (B), so that the cleaning is such that a relatively weak stimulus is continuously received, and a soft cleaning feeling can be obtained. In particular, in the soft bidet cleaning, the pulsation frequency ftm is increased to prevent an intermittent stimulus feeling, so that the soft cleaning feeling can be made more continuous. Moreover, in achieving such various washing feelings, the flow rate can be reduced as described above.

Further, as shown by a dotted line or a dashed line in the drawing, the pulsation frequency ftm can be set to be the same for each cleaning, and the duty ratio Dtm can be changed and controlled for each cleaning. The duty ratio Dtm is the coil exciting force, that is, the plunger WP2- in the wave generator WP2-8.
Since the moving speed and the moving amount of 14 are determined, the amplitude of the pulsation can be controlled to increase or decrease. Therefore, the washing water amount and the flow velocity shown in FIG. 73 can be controlled according to the duty ratio Dtm. As a result, in each washing, the mass of the water mass shown in FIG. 81 can be changed and controlled, and the intensity of the stimulus and the adjustment of the washing power can be adjusted while having a hard and soft washing feeling. In addition, the strength of the water can be adjusted based on the change in the flow velocity. In other words, since the user's desired washing feeling and water force can be secured by the duty ratio control and the frequency control of the pulsating flow, the amount of washing water can be significantly reduced as described above. Moreover, both the duty ratio control and the frequency control are
Since it is unrelated to the flow rate adjustment by the flow control valve, the water pressure adjustment that cannot be adjusted by the flow rate adjustment by the flow control valve can be realized through the above two controls. That is, the flow rate adjustment of the flow regulating valve can be complemented by the duty ratio control and the frequency control. Fine adjustment of the water force and the like can be performed by using both the adjustment of the water force and the like through the flow rate adjustment by the flow regulating valve and the adjustment of the water force and the like through the above two controls.

As shown in FIG. 84, the pulsation frequency ftm can be controlled, or the pulsation frequency ftm and the duty ratio Dtm can be controlled simultaneously. That is, as shown in FIG. 84 (a), each cleaning period TA, TB, TC.
In step (1), the duty ratio Dtm is set to a value DtmL, and the pulsation frequency ftm is controlled to increase or decrease in each cleaning period. For example, as shown, the pulsation frequency ftm is set to ftmS, ftmM, ftmL (ftmS <ftmM <
ftmL). Or 2
The increase / decrease control may be performed stepwise, four or more steps, or steplessly. In this way, it is possible to achieve a change in the cleaning sensation of the hardware and the software for each cleaning period and a change in the stimulus sensation, thereby making it possible to diversify the cleaning sensation. Further, if the frequency is different, since the continuous interval of the collision of the water mass is different, the strength of the water obtained by the collision of the water mass can be adjusted by the frequency control. That is, the cleaning period is TA, T while the cleaning is continued.
As the flow transitions to B, TC,..., The flush water discharge in each water discharge mode obtained through the pulsation frequency increase / decrease control is changed. By doing so, various washing feelings can be experienced during the execution of the washing. Moreover, since the frequency control is not related to the flow rate adjustment by the flow control valve, the water pressure adjustment that cannot be adjusted by the flow control by the flow control valve can be realized through the frequency control. In other words, by frequency control,
The flow adjustment of the flow control valve can be complemented. Fine adjustment of the water force and the like can be performed by using both the adjustment of the water force and the like through the flow rate adjustment by the flow control valve and the adjustment of the water force and the like through the frequency control. In this case, if a water pressure setting button for setting the water pressure is provided, these buttons set the above water pressure, and the water pressure also affects the feeling of washing. For this reason,
The electronic control unit CT2-1 which performs the frequency control as described above according to the setting by setting the water force and the washing feeling with the strength setting button is used to set the water force and the washing intensity of the washing water spouted from the spout hole. And the like, which corresponds to an intermittent / pulsation control unit that changes the frequency based on the set values such as.

In this case, each cleaning period may have the same time interval, or may have different time intervals for each cleaning period. In addition, when different time intervals are used, the time intervals may change regularly or irregularly. For example, the time interval and tS, tM, tL (tS <tM
<TL), tS → tM → tL → tS → tM ·
・ ・ It may change regularly like tL → tS → t
It may change irregularly as S → tM → tL → tM. It should be noted that such an irregular time interval change can be achieved by loading a random number generation program and determining each time interval according to the generated random number.

As shown in FIG. 84 (b), the duty ratio Dtm is controlled to increase or decrease in each of the cleaning periods TA, TB, TC,. For example, as shown, the duty ratio Dtm is set to DtmS, Dtmm, DtM.
mL (DtmS <Dtmm <DtmL). Alternatively, increase / decrease control may be performed in two steps, four or more steps, or steplessly. In addition, the pulsation frequency f
tm is controlled to increase or decrease for each cleaning period as described above.
In this case, the feeling of cleaning can be further diversified. Even in this case, each cleaning period may be set to the same time interval, or may be changed regularly or irregularly.

F2 / Cleaning operation: Next, the cleaning operation performed by the local cleaning apparatus of the embodiment having the above-described configuration will be described. FIG. 85 is a time chart showing the cleaning operation of the local cleaning device of this embodiment.

As shown, when the user sits on the toilet seat KS1-3 (see FIG. 1) and the seating sensor SS10 (see FIG. 65) is turned on, the main cleaning unit receives this ON signal and firstly, , Solenoid valve W of inlet side valve unit WP1-1
P1-10 (see FIG. 60) is controlled to open. As a result, the supply of the cleaning water into the apparatus is started, so that the heater TH1-2 is fully energized for preliminary heating of the cleaning water prior to the cleaning, and the supply destination of the cleaning water is set to the flow control switching valve. WP
At 2-2, the function water unit WP1-4 is switched. Therefore, functional water (free chlorine solution) from the functional water unit is discharged to the nozzle head NH2-1 (see FIG. 8), and the nozzle head is sterilized and cleaned. In this manner, the water supply, hot water supply, and functional water spouting performed immediately after the seating is performed after a predetermined time has elapsed since the sensor was turned on, or when the water discharge temperature sensor SS16b has reached a predetermined temperature (for example, a temperature that is about 2 to 3 degrees lower than the hot water temperature during washing). Stopped when detected. That is, the solenoid valve is closed, the flow control switching valve is switched off, the heater power is reduced (for example, about 30% of full power), and the operation of the cleaning button is awaited thereafter. As described above, since the heater is fully energized for a short time after seating and then the energization is reduced, the washing water is preliminarily heated and the temperature is maintained, so that rapid energization control of the heater is not required during the subsequent washing. Further, as described above, in the present embodiment, since the effect of reducing the flow rate of the cleaning water is high, it is possible to save power when energizing the heater.

Thereafter, when the washing button, for example, the buttocks washing button SWb (see FIG. 2) is turned on, the solenoid valve WP1-
The valve 10 is controlled to open to supply water for washing the tail, and the heater TH1-2 is fully energized. The heater is
Full energization is continued until the stop button SWa is operated. The closing of the solenoid valve will be described later.

By opening the electromagnetic valve, pre-nozzle cleaning for self-cleaning the nozzle head is performed prior to local cleaning. That is, following the opening of the solenoid valve, the cleaning nozzle WN2
The water supply destination of the washing water at -1 is switched from the flow path switching valve WN2-2 to the butt flow path, and then the cleaning water supply destination is set to the cleaning nozzle side by the flow control switching valve WP2-2, and the flow rate at that time is adjusted. Set. As a result, the adjusted flow rate of the washing water is sent to the washing nozzle at the standby position, and the tail water outlet NH2-2.
, The nozzle head is washed by the rebound water in the chamber NS1-14 (see FIGS. 8 and 10). Due to the water flow in the pre-nozzle cleaning, the cleaning water that has already been heated to an appropriate temperature by the full energization of the heater is distributed to the pipeline leading to the nozzle head. For this reason, from the beginning of the main cleaning, which will be described later, the cleaning water at an appropriate temperature can be discharged to a local portion, and the discharge of the low-temperature cleaning water does not give any discomfort. Further, following the flow path switching of the flow path switching valve downstream of the flow control switching valve, the water supply destination of the flow control switching valve and the flow rate setting are performed. Therefore, since the flow path switching valve can be driven in a state close to a no-load state where the water pressure of the washing water is hardly applied, it is preferable that the drive motor is not overloaded. It should be noted that even during the pre-nozzle cleaning, it is also possible to drive the wave generation device WP2-8 to self-clean the nozzle head with pulsating cleaning water. In this case, the pulsation frequency ftm of the coil may be inside the dead zone or outside the dead zone.

This pre-nozzle cleaning is stopped when a predetermined time has elapsed. That is, as shown in the figure, first, the flow control switching valve on the upstream side is switched to the functional water unit side so that the cleaning water does not flow toward the cleaning nozzle. After that, the flow path switching valve is stopped, and the pre-nozzle cleaning is stopped. As described above, even when the pre-nozzle cleaning is stopped, the flow path switching valve can be driven in a state close to no load, so that the drive motor is preferably not overloaded.

Following the pre-nozzle cleaning, the nozzle drive motors NS1-4 are controlled to rotate in the forward direction to control the cleaning nozzle WN.
2-1 is advanced from the standby position to the buttocks washing position. Even during this nozzle advance, the solenoid valve is in the open state, and the flow control switching valve uses the functional water unit as the water supply destination, so that the functional water is discharged from the chamber. Therefore, the functional water can sterilize and clean the cylindrical portion of the cleaning nozzle. In the operation up to the nozzle advance, only the switching destination of the flow path switching valve and the advance destination of the cleaning nozzle (the bidet cleaning position in the case of a bidet) differ depending on the operated cleaning button. The same is true for the bidet cleaning button.

When the advance of the cleaning nozzle to the cleaning position is completed in this way, the main cleaning of the local part (the butt cleaning, the soft cleaning,
Is performed according to the operation button. As shown in the figure, in the butt washing, the following soft start is performed in order to start washing water spouting of the pulsating flow from the butt spout NH2-2. First, the flow path switching valve WN2-2 is switched to the butt flow path, and then the washing water supply destination is set to the washing nozzle side by the flow control switching valve WP2-2, and the flow rate at that time corresponds to the set water force that has been set. Adjust gradually from zero up to the flow rate. It should be noted that the flow rate corresponding to the set water force may be gradually increased from a flow rate smaller than the flow rate corresponding to the set water force by a predetermined amount to the flow rate corresponding to the set water force.

In this soft start, the wave generator W
The generation of the pulsating flow by P2-8 also starts. That is, the pulse signal is output to repeatedly excite the pulsation generating coil WP2-15, and the plunger WP2-14 is reciprocated. Thereby, a pulsating flow is generated as described above. In the case of bottom cleaning, coil excitation is repeated at a pulsation frequency ftm lower than that of bidet / soft cleaning as shown in FIG.
Even in this coil excitation, the duty ratio Dtm of the pulse signal is gradually increased so as to gradually approach the duty ratio corresponding to the set water force that has been set. By such a soft start, even when the set water force is large, the water discharge amount is small, and the water can be gradually discharged from the soft water discharge, which is a pulsating flow based on the small duty ratio Dtm, to the set water force. It is preferable because it does not cause discomfort or discomfort. When such a soft start is completed, the water discharge at the set water force is performed by the pulsating flow of the cleaning water, and the process proceeds to the main cleaning. In this main cleaning, if the water force is changed and set thereafter, the flow rate is adjusted by the flow control switching valve or the pulsation flow control (duty ratio control, pulsation control) by the wave generation device WP2-8 so that the water force is changed. Frequency control).

In general, when adjusting the flow rate of a low flow rate of washing water, fine adjustment of the flow rate lacks the reliability of the adjustment accuracy. This is one of the reasons that the flow rate cannot be reduced with the conventional local cleaning device in which the water force is adjusted by the flow rate. However, in the local cleaning device of this embodiment, since the water pressure can be adjusted as described above through the pulsation flow control (duty ratio control, pulsation frequency control), there is an advantage that the water pressure can be adjusted while the flow rate of the cleaning water is reduced. is there. Therefore, in the local cleaning device of the present embodiment, when a large change is set from a water force close to the minimum water force to a water force close to the maximum water force, the flow rate adjustment and the pulsation adjustment are performed in combination, and in other cases, In addition, the pulsation flow control is used to adjust the water force. That is, the degree of change in the water force is read from the operating states of the water force strength setting buttons SWhu, SWhd, and pulsation flow control (duty ratio control, pulsation frequency control) is performed according to the result. Specifically, if the water force is strongly set by the water force setting buttons SWhu and SWhd shown in FIG. 2, the duty ratio Dtm is increased or the pulsation frequency f
tm is reduced, or both controls are used together. The setting of the water force by the water force setting buttons SWhu and SWhd is the reverse. At this time, the wave generation device WP2-
The pulsating flow control (duty ratio control, pulsating frequency control) is performed based on the detected flow rate and the water flow change set amount by detecting the actual flow rate of the washing water that reaches 8 using a flow rate sensor (not shown). Is possible. In this case, the pressure sensor may be used as a flow rate sensor, or the flow rate may be indirectly detected by a signal from a switch or the like involved in setting the flow rate. In addition to the configuration in which the flow rate sensor is arranged upstream of the wave generation device, the flow rate sensor can be placed anywhere as long as it is at a position where the amount of washing water can be detected. Can be planned. The water pressure setting buttons SWhu and SWhd for setting the water pressure in this manner function as “water pressure setting means” according to the present invention.

The main cleaning is completed as follows by operating the stop button, and thereafter, nozzle retreat and post-nozzle cleaning are performed. That is, when the stop button is operated, the button O
In response to the N signal, the flow control switching valve WP2-2 is first switched to the functional water unit side in order to stop the ass washing water spouting from the nozzle, and then the water is stopped and the coil is excited in the flow path switching valve WN2-2. The output of the pulse signal is stopped, and the energization of the heater is reduced. This heater power reduction is maintained until the seating sensor is turned off. Therefore, the temperature of the washing water does not drop carelessly until the sensor is turned off, and is kept at the above-mentioned temperature slightly lower than the appropriate temperature. For this reason,
If local washing is repeated while sitting on the toilet seat,
This is preferable because the washing water can be quickly warmed to an appropriate temperature. Also, at the time of stoppage of the tail-washing and spouting, the flow control switching valve and the flow path switching valve are driven in this order, and the flow path switching valve can be driven in a state close to a no-load state. This is preferable because it is not applied. In addition, the above-mentioned main cleaning (assembly main cleaning) is performed when the user separates from the toilet seat and the seating sensor is turned off before the stop button is operated, or when the assembler is softened during ass cleaning.
The operation is similarly terminated when each of the bide washing buttons is operated.

When the flow path switching valve WN2-2 stops water, the nozzle drive motor NS1-4 is controlled to rotate in the reverse direction, and the washing nozzle WN2-1 is retracted and returned to the standby position. When the nozzle retracts, the solenoid valve is in the open state, and the flow control switching valve WP
In 2-2, since the water supply destination is a functional water unit, the functional water is discharged from the chamber. Therefore, the functional water can sterilize and clean the cylindrical portion of the cleaning nozzle even when the nozzle is retracted.

When the cleaning nozzle returns to the standby position, the flow switching valve WN2-2 is switched to the bottom flow path in order to start post-nozzle cleaning, and then the cleaning water supply destination is cleaned by the flow control switching valve WP2-2. At the same time as the nozzle side, the flow rate at that time is set. As a result, the adjusted flow rate of the washing water is sent to the washing nozzle at the standby position, and the tail water outlet NH2-2.
, The nozzle head is washed by the rebound water in the chamber NS1-14 (see FIGS. 8 and 10). Due to the flow of water in the post-nozzle cleaning, the functional water applied to the nozzle head when the nozzle retreats is washed away. Even in this post-nozzle washing, the flow control switching valve and the flow path switching valve can be driven in this order, and the flow path switching valve can be driven in a state close to no load. Is preferred.

When the post-nozzle cleaning is performed for a predetermined time,
To prepare for the next and subsequent local cleaning, the solenoid valve WP1-10
Is controlled to close the valve to stop supplying the cleaning water to the local cleaning device. Thereafter, the cleaning water remaining in the water supply pipe downstream of the flow control switching valve, the downstream flow switching valve 71 and the cleaning nozzle 24 is discharged. That is, upon receiving the closing of the solenoid valve 65,
Pulsation generation coil WP2-15 of wave generation device WP2-8
Is repeatedly excited with a small duty ratio Dtm to reciprocate the plunger WP2-14. In this case, the pulsation frequency ftm may be a low frequency. When the plunger is reciprocating in this manner, the washing water is not supplied to the wave generating device. A delivery is made. Therefore, the washing water remaining in the downstream water supply pipe or the like is gradually sent downstream by the washing water sent out by the plunger, and the switching flow path of the flow path switching valve (in this case, the ass flow path) Is discharged to the toilet bowl from the tail water discharge hole of the nozzle at the standby position. When the discharge of the remaining washing water is completed in this manner, a series of tail washing operations is completed by switching the flow control switching valve to the functional water unit side and stopping the water of the flow path switching valve. In the operation after the nozzle retreat, the switching destination of the flow path switching valve and the advance destination of the cleaning nozzle (the bidet cleaning position in the case of a bidet) according to the operated cleaning button.
However, the same applies to a soft cleaning button and a bidet cleaning button.

[0297] In the present embodiment, the following procedure was used to complete the discharge of the remaining washing water using the wave generator WP2-8.

When the plunger WP2-14 is moved by energizing the pulsation generating coil WP2-15 of the wave generating device WP2-8 to move the plunger WP2-14, a back electromotive force is generated in the coil with the movement of the plunger, and the energizing current is reduced. The so-called bottom phenomenon, which once decreases, occurs. Since this bottom phenomenon appears as a waveform of the current flowing through the coil, there is a correlation between the current waveform and the movement of the plunger. By the way, considering the situation where the pulsation generating coil is excited when the above-mentioned residual cleaning water is discharged, before and after the residual cleaning water is completely discharged, the plunger moves in a state where there is the cleaning water in the plunger cylinder. Then, the plunger moves under an empty condition where there is no washing water. Since the washing water in the cylinder acts as a movement resistance of the plunger, if the coil excitation is performed under the same condition (in the present embodiment, the same duty ratio Dtm), the plunger is higher than before in an empty state where there is no washing water. Moves fast. Therefore, when the plunger moves under the condition where the washing water is present in the cylinder and moves to the plunger under the condition where the washing water is empty, that is, when the remaining washing water is completely discharged, the bottom phenomenon occurs. The situation changes. Therefore, in the local cleaning device of the present embodiment, the bottom phenomenon is detected by the bottom detection circuit CT2-2 (see FIG. 65) to detect the completion of the discharge of the remaining cleaning water, and the function of the flow control switching valve as described above. After switching to the water unit side and stopping the water of the flow path switching valve, a series of butt washing operations is completed.

FIG. 86 is a circuit diagram showing an example of the bottom detection circuit CT2-2 for the pulsation generating coil WP2-15, and FIG. 87 illustrates the state of the current waveform when the pulsation generating coil WP2-15 is energized. FIG.

As shown in FIG. 86, the bottom detection circuit CT
2-2 is a comparator CT2-3 and a capacitor CT2
-4 and a resistor CT2-5, and the resistor and the capacitor constitute a delay circuit composed of a CR filter circuit. The CR filter circuit delays the input signal by a delay determined by a resistor and a capacitor and outputs the delayed signal. Therefore, the bottom detection circuit calculates an input signal (a voltage generated in the detection resistor CT2-6 reflecting the supplied current) input to the negative terminal and a delay signal obtained by delaying the input signal by a comparator. Process. As a result, a pulse signal (bottom detection signal) indicating the completion of the movement of the plunger is output from the bottom detection circuit to the electronic control unit CT2-1 as follows.

After the completion of the post-nozzle cleaning, the pulsation generating coil W
A pulse signal having a predetermined cycle (constant duty ratio Dtm) shown in the figure is output to the switching transistor CT2-7 of P2-15, and energization of the coil is started in accordance with each pulse. Focusing on a certain pulse, the current flowing through the pulsation generating coil increases with time. And
After a lapse of a predetermined time from the start of energization by the pulse, the plunger starts to move, and a back electromotive force is generated in the pulsation generating coil with the movement of the plunger. A bottom phenomenon occurs. This current waveform (original signal waveform) is input as a voltage to the negative terminal of the comparator. On the other hand, a delay signal as indicated by a dotted line in the figure is generated by a CR filter circuit and input to the positive terminal. For this reason, since these signals are calculated by the comparator in consideration of the polarity of the input terminal, a pulse signal is generated as shown in the figure. This pulse-like signal (bottom detection signal) is generated corresponding to each pulse output to the transistor, and is input to the electronic control unit at the predetermined cycle. However, as described above, when the residual washing water is completely drained, the moving speed of the plunger is high, so that the bottom detection signal at this time is input at a different cycle from before. Therefore, from the state of the signal input, the electronic control unit determines completion of the discharge of the residual water, stops the pulse output thereafter, and ends a series of butt cleaning operations. In addition to the completion of the residual water discharge based on such a bottom detection result, it is also possible to stop the pulse excitation and stop the coil excitation when a predetermined time has elapsed from the coil excitation for the residual water discharge, thereby terminating the cleaning operation. it can.

H2 / Move cleaning: In the local cleaning apparatus of this embodiment, move cleaning can be performed as follows. For example, while the cleaning nozzle is reciprocated back and forth around the center position, the pulsation frequency ftm according to the nozzle position.
Alternatively, the duty ratio Dtm is changed and controlled. At this time, the pulsation frequency ftm can be increased near the center position to increase the softness and continuity, and the pulsation frequency ftm can be reduced near the forward end and the backward end to emphasize the hard feeling.
Further, if the duty ratio Dtm is also reduced around the center position, a soft feeling can be emphasized. Conversely, in the vicinity of the center position, the pulsation frequency ftm can be lowered to increase the sense of hardness and stimulation, and in the vicinity of the forward end and the backward end, the pulsation frequency ftm can be increased to emphasize the software.

J2 / Massage cleaning: In the local cleaning device of this embodiment, massage cleaning can be performed as follows. The massage cleaning period is a repetition of the cleaning periods TA, TB, TC,.
tm = DtmL), as shown in FIG. 84 (a), the pulsation frequency ftm is regularly controlled to increase or decrease in this massage cycle. For example, the pulsation frequency ftm is changed to ftmS → ftmm →
ftmL → ftmM → ftmS (ftmS <ft
It changes regularly for every massage cycle like mM <ftmL). Also, ftmS → ftmM → ftmL →
ftmS → ftmm...
Alternatively, in addition to the regular increase / decrease control of the pulsation frequency ftm, as shown in FIG. Dtm is variably controlled regularly. For example, the duty ratio Dtm is changed from DtmL to Dtmm to Dtm.
mS → Dtmm → DtmL ... (DtmS <Dtmm
<DtmL) It changes regularly for every washing period. Also, DtmS → Dtmm → DtmL → DtmS →
Dtmm ... can also be used.

This massage cycle is such that the frequency determined by its reciprocal is outside the above-mentioned dead band frequency range (less than about 5 Hz).
It is to be. As a result, as described above, the transition of the washing feeling and the stimulating feeling accompanying the duty ratio Dtm and the pulsation frequency ftm is clearly sensed by the user. Therefore,
The washing feeling and the stimulating feeling received from the water spout can be regularly and repeatedly given to the user, and the regular repeating can also take various forms. Further, when the stimulus is increased by increasing the duty ratio Dtm, if the pulsation frequency ftm is reduced, the sense of continuity of the stimulus is reduced, so that a strong stimulus can be emphasized. Therefore, it is possible to amplify the intensity of the stimulus and promote defecation.

In the above-mentioned massage washing,
The cleaning periods TA, TB, TC,... Are different from each other. By doing so, the duty ratio Dtm in each cleaning period or the stimulus recognition time associated with the pulsation frequency ftm is changed, so that the way of receiving a stimulus diversifies,
The feeling of defecation can be more effectively promoted. In addition, by synchronizing with the five senses such as music, light, and odor (aromatherapy), a relaxing space can be provided, and further a feeling of defecation can be further promoted.

K2 / fluctuation cleaning: In the local cleaning apparatus of this embodiment, the fluctuation cleaning for giving a sense of comfort and comfort by irregularly changing the feeling of washing and irritation received from the spout is performed as follows. be able to. The fluctuation cleaning period is the repetition of the cleaning periods TA, TB, TC,... At the same time interval, and this time interval is a fluctuation period, and the duty ratio Dtm and the pulsation frequency ftm or both are irregularly increased and decreased in the fluctuation period. Control. For example, as described in the above reference example, when the duty ratio Dtm and the pulsation frequency ftm are irregularly changed, a random number generation program is loaded to generate a random number, and the obtained random number is used to generate the duty ratio Dtm and the pulsation frequency ftm. Is determined. By doing so, the duty ratio Dtm becomes DtmS → D
tmM → DtmS → DtmS → DtmL → DtmS ...
The pulsation frequency ftm is as follows: ftm → ftmS
→ ftmm → DtmL → DtmS → DtmL ..., with a constant fluctuation cycle. Alternatively, the two change independently.

[0307] In this way, with the transition of the duty ratio Dtm or the pulsation frequency ftm, the feeling of washing and irritation received from the water discharge changes irregularly. In this case, with respect to the above-mentioned fluctuation cycle in which the washing feeling and the stimulating feeling change according to the duty ratio Dtm or the pulsation frequency ftm, the frequency f determined by the reciprocal of the fluctuation cycle is the massage cycle TM.
And the same frequency (less than about 5 Hz). As a result, the duty ratio D
The change in the feeling of washing and irritation accompanying the tm and the pulsation frequency ftm is clearly sensed by the user. The changing feeling of washing and irritation is different for each fluctuation cycle, and the changing of the feeling of washing and irritation is also irregular. Will receive it. As a result, similarly to the above-described reference example, it is difficult to predict the change in the stimulus change.
The parasympathetic nervous system becomes dominant, and the internal anal sphincter is easily unconsciously relaxed, and defecation can be promoted more effectively. Also, if this fluctuation cleaning is performed for local cleaning after defecation, the duty ratio Dtm and the pulsation frequency ftm
Since it is difficult to predict the intensity of the stimulus due to the change, the monotonous feeling at the time of local washing can be further eliminated.

In the above-described fluctuation cleaning, the cleaning periods TA, TB, TC,... Are different from each other. In this case, since the stimulus recognition time associated with the duty ratio Dtm or the pulsation frequency ftm in each cleaning period is changed, it becomes more difficult to predict the stimulus sensation.
Therefore, defecation can be promoted more effectively. Also,
By synchronizing with the five senses such as music, light, and odor (aromatherapy), a relaxing space can be provided, and the defecation can be further promoted.

Further, the power spectrum of the physical quantity such as the fluctuation width or the instantaneous flow rate which determines the transition width of the duty ratio Dtm and the pulsation frequency ftm, and the transition timing thereof, is determined by the biological rhythm of the human body such as the heart rate and the natural world. Similarly to the rhythm of the above, it can be made to be proportional to the reciprocal of the frequency. This makes it possible to give the user a feeling of relaxation, so that the parasympathetic nerve becomes dominant, the internal anal sphincter is relaxed, and the effect of promoting defecation is enhanced.

[0310] According to the local cleaning apparatus of the above embodiment,
In addition to the above, there are the following advantages. First, the accumulator W provided upstream of the wave generator WP2-8
P2-7 has the following advantages. FIG. 88 is an explanatory diagram for describing an effect obtained by the accumulator WP2-7.

By driving the wave generation device WP2-8, the above-mentioned pulsating flow of washing water is discharged into the upstream water supply line WP2-8.
5 (see FIG. 60) (primary pressure) and the pressure (secondary pressure) of the downstream water supply pipeline WP2-6 on the downstream side of the wave generator. And the accumulator W
The primary pressure in a state where P2-7 was not provided upstream of the wave generation device WP2-8 was measured downstream of the flow control switching valve WP2-2. Further, the primary pressure when the accumulator WP2-7 was provided as shown in FIG. 60 was measured downstream of the flow control switching valve, that is, upstream of the accumulator. FIG. 88 shows the result.

When the accumulator is incorporated upstream of the wave generator of the present embodiment, water hammer reduction, which is the original function of the accumulator, can be exhibited in the upstream water supply line WP2-5, and the following advantages are obtained. is there. That is,
As shown in FIG. 88, when a pulsating flow is generated by the wave generation device, the pressure fluctuation of the primary pressure in the upstream water supply pipe can be effectively suppressed. Therefore, it is possible to avoid the disturbance of the temperature distribution of the washing water in the tanks TH1 to TH3 by suppressing the water hammer as described above.
It is possible to avoid disturbance of the washing water temperature distribution of the tank by suppressing the next pressure fluctuation. Therefore, since the heater can be used to warm the tank with no disturbance in the temperature distribution, the heater control can be simplified and the temperature of the washing water can be made uniform with good responsiveness. Moreover, the pulsating flow generated by the wave generating device is in a state where the primary pressure is accumulated by the accumulator and amplified on the secondary side,
It is possible to reduce the capacity and size of the wave generation device.
In addition, the pressure gain by the accumulator can be obtained,
In the wave generation device, the energy required for pressure fluctuation generation (pulsation generation) is reduced, and power saving can be achieved. Although the accumulator is arranged close to or integrated with the wave generating device WP2-8, the accumulator may be arranged close to the flow control switching valve WP2-2 or integrated with the device. it can.

Further, in the local cleaning apparatus of this embodiment, when the cleaning water is discharged by periodically changing the flow of the cleaning water, the wave generating device W utilizing the reciprocating motion of the plunger.
P2-8 was used to prevent the pulsating flow generated by this wave generation device from appearing at a zero flow rate. Therefore, a situation in which the flow of the washing water in the pipeline is not interrupted does not occur, so that no water hammer is generated. For this reason, it is not necessary to make the water path components such as the wave generating device high in water hammer resistance, and the configuration and structure can be simplified, the size can be reduced, and the resin can be used.

Further, in the wave generation device WP2-8, when the pulsation is generated by the reciprocation of the plunger, the condition of zero flow rate is not developed as described above. Do not need. For this reason, the structure and structure can be further simplified and downsized. And since such miniaturization can be achieved, the degree of freedom of the installation location of the wave generation device is increased, and attachment and integration with other members having a large mass are simplified.

Further, since the flushing water with a zero flow rate does not occur when the pulsating flushing water is spouted, the following advantages are provided. The pulsation frequency is within the dead band frequency range (about 5 Hz or more)
Even so, it can be said that the continuity of the stimulation of the user receiving the water discharge tends to fade as the pulsation frequency approaches the lower limit of the dead band frequency region. However, as described above, since the flush water discharge state with the zero flow rate does not occur, the sense of continuity of the stimulus can be hardly faded. Therefore, the wave generation device WP2
In the flush water spouting of the pulsating flow by -8, the adjustment range of the pulsating frequency can be extended to near the lower limit of the dead zone region,
By adjusting the pulsation frequency in a wide range, it is possible to diversify the washing feeling and the water force.

Further, in the local cleaning apparatus of this embodiment, when the cleaning operation is completed in the buttocks cleaning, the soft cleaning, and the bidet cleaning, the wave generating device WP2-8 is driven to reciprocate the plunger as described above. The remaining washing water was forcibly discharged. Therefore, the drainage of the pipe from the flow control switching valve WP2-2 to the nozzle head of the washing nozzle WN2-1 is completely performed. Therefore, freezing of the remaining water can be reliably avoided. After the residual water is completely discharged by the wave generating device, the flow control switching valve WP2-2 is switched to the functional water unit side to drain the water from the flow control switching valve WP2-2 to the functional water unit. It is preferable to perform the above because freezing in this pipeline can be prevented. When the wave generating device is driven for draining water, the duty ratio Dtm of the pulsation generating coil WP2-15 is reduced and the pulsation frequency ftm is set to a low frequency, so that the plunger is moved at a constant speed and with a weak force. The plunger does not collide with the cylinder end with high speed and strong force. For this reason, the sound of the plunger can be reduced. Furthermore, as described above, when the flow path switching valve is opened at the time of draining, all communication holes of each nozzle flow path can be drained from all the flow paths in the washing nozzle.

In addition, in the local cleaning device of this embodiment,
As described above, the user is provided with a feeling that he or she is receiving continuous water discharge, while reducing the amount of wash water (water discharge amount) to increase the effectiveness of water saving. Therefore, it is possible to reduce the power consumption for heating the cleaning water to the desired temperature by the heaters TH1-2. That is, the limit capacity of the outlet in the toilet room is generally 15A. However, in a local cleaning apparatus conventionally used in a toilet, the capacity of a hot water heater of an instantaneous heat exchanger is set to about 2500 watts in order to enable a sufficient temperature and a sufficient time of water discharge even in a cold season. I have. In order to reduce the heater capacity, air is forcibly mixed into the cleaning water to reduce the amount of cleaning water. However, even in this case, a heater capacity of at least 1000 watts or more is required. Was. For this reason, when a local cleaning device having such a heater capacity is plugged into an outlet in a toilet room, the limit capacity of the outlet is approached, so that there is a problem that other electric devices cannot be connected.
In addition, when the hot air drying function and the indoor heating function provided in the local cleaning device are simultaneously operated, the overall heater capacity increases. Therefore, when these functions are simultaneously operated, there is also a problem that a measure such as stopping the energization of any heater has to be taken.
In addition, although it is necessary to install a plurality of local cleaning devices in hotels and facilities, there is a problem that they cannot be installed due to an upper limit of power consumption. However, according to the local cleaning device KS2-1 of this embodiment, the wave generation device WP
A pulsation is generated by 2-8, and a pulsation frequency f of the pulsation is generated.
Through the control of tm and the duty ratio Dtm, the amount of washing water and the power consumption can be significantly reduced, and the above-described power supply problem can be solved.

In the local cleaning device of the above-described embodiment, the flow rate of the cleaning water reaching the wave generator WP2-8 is detected by a flow sensor (not shown). Therefore, as described above, the water pressure can be finely adjusted by pulsating flow control (duty ratio control, pulsating frequency control) using the flow rate detected by this sensor, and the following advantages are provided. That is, the electronic control unit CT2
-1, when an excessive flow rate occurs due to a failure of a solenoid valve or when an abnormality such as water cutoff occurs, the detection signal from the flow rate sensor is received, the drive of the wave generation device WP2-8 is stopped, and the heater TH1-2. The power supply to the cleaning nozzle WN2-1 is returned to a standby position, and the like. In this way, it is possible to avoid occurrence of a tapping sound due to the idling of the plunger, and to avoid idling of the heater.

Next, the local cleaning device KS of the above embodiment is described.
A modified example of 2-1 will be described. It is to be noted that the same members as those of the above-described reference example or its modification are denoted by the same member names and the same reference numerals as they are, and members having the same functions are denoted by the same member names.

B2-1 / Modification of Channel System Configuration; FIG.
FIG. 90 is a block diagram illustrating a water channel configuration of a local cleaning device according to another modification. FIG. 91 is a block diagram illustrating a water channel configuration of a local cleaning device according to another modification. FIG. It is a schematic block diagram which shows the schematic structure of WP2-20 with a part broken away. FIG. 92 is a block diagram illustrating a water channel configuration of a local cleaning device according to another modification. FIG. 93 is a cross-sectional view illustrating a configuration of an on-off valve WP2-27 arranged in the waterway system, and FIG. 94 is an explanatory diagram illustrating water pressure in a waterway system of a local cleaning device according to a modification having the on-off valve. . FIG. 95 is a block diagram illustrating a water channel configuration of a local cleaning device according to another modification. It is.

(1) As shown in FIG. 89, in this modification, the accumulator WP2-7 and the wave generator WP2
-8 is provided downstream of the heat exchange unit TH1-1, and a flow control switching valve WP2-20 is provided downstream of this wave generation unit. This flow control switching valve is configured separately from the washing nozzle WP2-1,
The water supply destination of the washing water is switched to one of the above-described nozzle flow paths of the cleaning nozzle (each nozzle flow path for ass cleaning, soft cleaning, and bidet cleaning) and a flow path leading to the functional water unit WP1-4. At the same time, the flow rate of the washing water flowing through each of the switched flow paths is adjusted. Therefore, with this flow control switching valve, water supply switching between the washing nozzle and the functional water unit, water supply switching for each nozzle flow channel in the cleaning nozzle, and cleaning water flow rate adjustment to each flow channel can be performed. For this reason, in the above embodiment,
Two valves were used: a flow control switching valve WP2-1 for switching water supply to the washing nozzle and the functional water unit and adjusting the flow rate, and a flow path switching valve WN2-2 for switching each nozzle flow path of the washing nozzle. However, in this modification, one flow control switching valve WP2-
20 is enough. Therefore, there are advantages in manufacturing, such as reduction in the number of assembly steps and cost due to the reduction in the number of parts.

(2) In another modification shown in FIG. 90, separate washing nozzles for the buttocks and bidet are provided, and each nozzle is connected to the flow control switching valve WP2-20 of the above modification. .
And, this flow control switching valve is used for the ass washing nozzle WN2-
22 and the bidet cleaning nozzles WN2-23, and the water supply destination of the cleaning water is switched and switched to the nozzle flow paths (bottom cleaning nozzle flow path and bidet cleaning nozzle flow path) for each of these cleaning nozzles. Adjust the flow rate of washing water flowing through each flow path. In addition, it is also possible to provide a functional water unit as described above and switch the water supply to the unit.

Wash nozzle WN2-2 for buttocks and bidets
2 and 23 are mounted on the nozzle device NS2-10. The nozzle device is configured to separately advance and retreat the respective cleaning nozzles from the standby position to the respective cleaning positions,
The drive is controlled by an electronic control unit. As described above, even in the local cleaning device having separate cleaning nozzles for the buttocks and the bidet, as described above, through control of the pulsation frequency ftm and the duty ratio Dtm, while maintaining the effectiveness of water saving, Various washing feelings and water levels can be set.

The flow control switching valve WP2-20 of these modified examples
May be, for example, a drum type flow control switching valve as shown in FIG. In this flow control switching valve, a drum WP2-22 is rotatably (forward / reverse) inside a drum casing WP2-21. Water supply grooves WP2-23 are formed on the surface of the drum for each water supply port. The degree of overlap between each water supply groove of the drum and the water supply port is adjusted to switch the water supply destination and to the switched water supply destination. Adjust the water supply flow rate. According to the drum type flow control switching valve, pulsation damping can be more effectively suppressed as compared with a switching valve utilizing the elasticity of an elastic body such as a diaphragm.

[0325] Further, in the apparatus provided with the buttocks washing nozzle WN2-22 and the bidet washing nozzle WN2-23, one of the buttocks and bidet washing nozzles is provided with a soft washing water discharge hole and a It can have a nozzle flow path. Further, a cleaning nozzle for soft cleaning may be provided separately from the above-mentioned two cleaning nozzles.

(3) In the modification shown in FIG. 92, the flow of the cleaning water is instantaneously reduced to zero by instantaneously increasing the pressure of the supplied cleaning water and interrupting the flow of the cleaning water downstream thereof. The feature is that the flow is intermittent. That is, the local cleaning device of this modified example has a heat exchange unit TH1-1 in the waterway system.
WP2-25 and the flow control switching valve WP2
-2 and an intermittent flow generation unit WP2-26, and discharges cleaning water from a cleaning nozzle WN2-1 via a flow path switching valve WN2-2.

[0327] The pressurizing device WP2-25 is provided with a pressurizing pump such as a line pump, and is provided with a heat exchange unit TH1-1.
, And pressurizes the washing water supplied from the above to supply the downstream equipment. Then, the pressurizer instrument, pump displacement to increase the primary pressure to about 0.2 MPa {about 2 kgf / cm ^2} of approximately 0.13MPa pressure regulated by the pressure regulating valve WP2-4 {1.3kgf / cm ^2} It has. In addition, the pressure regulating pressure by this pressure regulating valve (about 0.13 MPa０．１1.3 kgf / c)
m ² }) is almost the same as the conventional product.

The intermittent flow generation unit WP2-26 has an accumulator WP2-7 from the upstream side and an intermittent valve WP2-27 for interrupting the flow path. Intermittent valve WP2-27
As shown in FIG. 93, the motor WP2-28 rotates the valve body WP2-29 inside the housing WP2-30. The on-off valve connects and disconnects the internal valve body flow path WP2-31 with the valve flow path WP2-32 in synchronization with the rotation cycle of the motor. Thus, the intermittent valve supplies the cleaning water flow pressurized by the pressurizing device WP2-25 as an intermittent output (intermittent flow), and supplies the intermittent cleaning water to the cleaning nozzle. The state of generation of this intermittent flow will be described with reference to the drawings as follows.

As shown in FIG. 94, when the water supply pressure from the water supply source is Pw, the pressure of the washing water is reduced to about 0.13 MPa {1.3 kgf / cm ² } by the pressure regulating valve WP2-4. The pressure reaches the pressurizing device WP2-25, where the pressure is increased to about 0.2 MPa {about 2 kgf / cm ² }. The washing water is intermittently flown by receiving the periodic interruption of the washing water flow by the intermittent valve WP2-27, and is discharged from the washing nozzle. The intermittent period DT of the intermittent flow at this time
Is twice as long as the motor rotation cycle of the intermittent valve, and can be variably controlled through the rotation control of the motor by the electronic control unit CT2-1. In this modification, the frequency (intermittent frequency) defined by the intermittent cycle DT is in the dead band frequency range (5 Hz or more, preferably 10 to 100 Hz).
Hz). Therefore, even in this modified example in which the intermittent flow of washing water obtained through intermittent flow of the flow path is spouted from the washing nozzle, the amount of washing water is kept constant by controlling the frequency of the spouting water as in the above-described embodiment. Even
It is possible to diversify the washing feeling and adjust the water pressure. Also,
If the adjustment of the amount of washing water is used together, the flow rate of washing water can also be changed, so that it is possible to further diversify the feeling of washing and finely adjust the water level. Further, since the water pressure can be adjusted by the frequency control as described above, the water pressure desired by the user can be ensured even if the amount of the washing water is insufficient. In other words, since the user's desired feeling of washing and water force can be secured by controlling the frequency of the intermittent flow, the amount of washing water can be significantly reduced as described above.

According to this modification, there are the following advantages. As shown in FIG. 93, the intermittent valve WP2-27 has an inclined portion WP2-33 at the opening of the valve body flow path WP2-31. The inclined portion functions to gradually close the valve flow path when the valve body WP2-29 rotates the valve flow path WP2-32 to the shielding side. Therefore, at the time of driving the intermittent valve for generating the intermittent flow, it is possible to suppress the occurrence of water hammer when the flow path is cut off due to the valve driving.

(4) In another modified example shown in FIG. 95, the cleaning water is pressurized by the pressurizing device WP2-25 and the intermittent flow generation unit WP2-26 to make the intermittent flow of cleaning water. Also,
The washing nozzles WN2-22 and 23 for buttocks and bidets are advanced and retracted by the nozzle device NS2-10, and the flow control switching valve WP2 is used.
At -20, the flow path is switched to the nozzle and the flow rate is adjusted. After the flow rate is adjusted, the above-mentioned intermittent washing water is discharged from each of the ass and bidet washing nozzles. As described above, the apparatus having the separate washing nozzles WN2-22 and 23 for the buttocks and the bidet can be configured to discharge intermittently flowing washing water.

E2-1: Deformation of Cleaning Nozzle: In order to improve the soft feeling in each local cleaning, a modification may be made so that air is forcibly mixed into the cleaning water. FIG. 96
Is a modified cleaning nozzle WN2-
FIG. 97 is an explanatory diagram for explaining the configuration of No. 25, and FIG. 97 is a graph showing the relationship between the amount of air mixed in when air is forcibly mixed into the cleaning water and the cleaning area of the cleaning water discharged by the aeration. . FIG. 98 is an explanatory diagram illustrating the configuration of a cleaning nozzle WN2-25 according to another modification for forcibly mixing air.

(1) As shown in FIG. 96, the cleaning nozzle WN2-25 according to the modification is provided to the nozzle head NH2-10.
Each spout hole NH2- for ass washing, soft washing, bidet washing
The first through fourth head channels NH2-5 through 7 through 4-7
It has the third air passages NH2-11 to NH13. These air flow paths are formed by the cylindrical portion WN2- of the cleaning nozzle WN2-25.
5 in the upper compartment WN2-26.
2-27 to 29 are individually connected. The compressed air sent from the air pump WN2-30 is supplied to each of the air pipes at a flow rate adjusted by an air flow rate adjustment valve WN2-31. The air flow control valve also switches air supply to each of the air pipes WN2-27 to 29.
Therefore, the compressed air is blown into each head channel through each air channel in the nozzle head. The wash water flowing in each of the head flow paths in a pulsating flow or an intermittent flow is subjected to frictional force generated by blowing compressed air while being discharged in a water mass as described above due to water discharging in the pulsating flow or the intermittent flow. For this reason, by blowing compressed air, the cleaning water is discharged as a minute water mass as shown in the figure. Even if these minute water bodies are ejected from the water discharge holes, they are in a state in which they are hardly combined with each other again.

When air is mixed in this way, as shown in FIG. 97, it can be seen that the water mass is finely dispersed and the cleaning area increases as the flow rate of the blown air increases. Therefore, when the amount of water is reduced and the cleaning range is narrowed, the cleaning range can be expanded by increasing the air flow rate. As shown in FIG. 75, the pulsating flow or intermittent flow of cleaning water discharged from the water discharge hole is increased into a large water mass. Can be made small, so that a soft washing feeling can be obtained. In this way, by blowing air, it is possible to increase or decrease the cleaning range and adjust the cleaning intensity. In addition, the washing strength and the like can be more finely adjusted in combination with the adjustment of the water force and the washing feeling in the pulsating flow or the intermittent flow. Furthermore, the amount of washing water can be reduced by the amount of air mixing, and a soft feeling of washing can be provided while enhancing the effectiveness of water saving.

(2) As shown in FIG. 98, the cleaning nozzle according to another modification includes head passages NH2-15 for tail cleaning, soft cleaning, and bidet cleaning in the nozzle head NH2-15.
First to third air pipes NH2-16 to NH18 are inserted into the water discharge holes NH2-2 to NH4 of Nos. 5 to 7, respectively. The first to third air pipes are connected to the air pump WN2-
30. Therefore, the compressed air from the first to third air pipes is jetted directly into the cleaning water flowing through each head channel. According to this configuration, since the air is blown directly into the cleaning water flow, the action of dispersing the cleaning water flow can be further enhanced.

E2-2 / Other Modifications of Washing Nozzle: The washing nozzle may be modified to take advantage of the negative pressure of the washing water flow to achieve natural aspiration. FIG. 99 and FIG. 100 are schematic cross-sectional views of main parts of the cleaning nozzles of the respective modified examples for natural suction. FIG. 101 is a schematic diagram schematically illustrating a cleaning nozzle of another modified example for natural aspiration, and FIG. 102 is a graph illustrating air entrainment characteristics in another modified example.

(1) As shown in FIG. 99, the nozzle head NH2-20 of the cleaning nozzle of this modified example has head passages NH2-20 for butt cleaning, soft cleaning, and bidet cleaning.
An orifice NH2 for reducing the flow path area is provided in a part of 5-7.
-21 to 23. Further, downstream of each of the orifices, an outside air introduction passage NH2-24 to introduce outside air from the back of the nozzle head is provided. According to this configuration, a negative pressure is generated when the flow of the cleaning water flowing out of each orifice increases the flow path area, and air is mixed into the cleaning water from each external air introduction passage. According to this modification, there is no need to provide an air pump or the like, so that the configuration can be simplified.
In this case, each orifice corresponding to the head flow path of the tail cleaning, the soft cleaning, and the bidet cleaning may have a different orifice diameter for each of the tail cleaning, the soft cleaning, and the bidet cleaning. For example, the orifice diameter is defined so that the amount of air entrainment in soft cleaning / bide cleaning is larger than that in bottom cleaning. If you do this, you can wash your ass,
Since the degree of mixing of air is different in each bidet cleaning, the cleaning feeling can be changed for each cleaning operation.

(2) In another modification shown in FIG. 100, the nozzle head NH2-27 includes a nozzle flow path N for bidet cleaning.
An external air introduction pipe NH2-28 is arranged and provided in H2-7. Even in this case, air can be directly introduced into the washing water stream. The same applies to the nozzle flow path for ass cleaning and soft cleaning.

(3) In another modified example shown in FIG. 101, the following configuration is provided to improve the efficiency of natural aspiration. In addition, for convenience of explanation, one water discharge hole (butt water discharge hole) will be described, but the same applies to a soft water discharge hole and a bidet water discharge hole. Another modification is a nozzle head NH2-
30 is provided with an outside air entrapment chamber NH2-31. The nozzle head is provided with an orifice N in the head channel NH2-5 for cleaning the buttocks with the outside air entrapment chamber interposed therebetween.
The H2-21 and the tail water discharge hole NH2-2 are arranged to face each other, and the outside air entrainment chamber is provided with an outside air introduction passage NH2-24. With such a configuration, a so-called jet pump having the washing water discharged from the orifice as the driving fluid, the air from the outside air introduction passage as the driven fluid, and the buttocks discharge hole as a throat is configured.

In this modification, the orifice NH2-21
Is provided in the same direction as the water discharge direction of the washing water,
The damping of the water force can be suppressed. Further, the amount of air entrainment can be increased by the action of the jet pump. Therefore, the amount of washing water can be reduced by the amount of air increase, and the effectiveness of water saving can be further improved,
It can provide a softer feeling of washing.
Further, since the orifice and the flush water spouting direction are the same, there is no bending of the pipe downstream of the orifice. Therefore,
Since the collision of the washing water does not occur at the bent portion of the pipe, there is no energy loss and the flow velocity is not reduced.

In this modification, the air entrapment amount was measured by variously changing the area ratio (S2 / S1) between the orifice diameter S1 and the throat diameter S2. When this air entrapment amount was expressed as a ratio of air to water (air entrapment ratio%) and graphed, as shown in FIG.
If so, a large air entrapment amount of 40 to 80% could be obtained. In other words, when the jet pump is configured as in this modification and the area ratio is set to 1 to 4, it is about 1.2 to 2 times as large as that having the orifice and the outside air introduction passage as shown in FIG. The amount of air entrainment can be increased, which is advantageous for improving the effectiveness of water saving and for giving a soft feeling of washing. In addition, the air entrapment amount was measured as follows. That is, a microwire air flow meter of the hot wire type is connected to the air suction port to directly measure the air flow rate, calculate the air entrapment rate from this air flow rate and the flow rate of water supply to the nozzle, and use this as the air entrainment amount. 102 graphs were obtained.

E2-3 / Another Modification of Cleaning Nozzle: FIG. 103 is a schematic view showing a nozzle head NH2-33 in which the cleaning nozzle shown in FIG. FIG. 104 is a perspective view, and FIG. 104 is a graph showing air entrainment characteristics in a nozzle head NH2-33 according to another modification.

As shown in FIG. 103, the nozzle head NH2-33 of this modification is similar to the nozzle head NH2-33 described above.
Similarly to 30, the outside air entrapment chamber NH2-31, the orifice NH2-21, and the tail water outlet NH2-2 as a throat
And a jet pump configured with an outside air introduction passage NH2-24. The nozzle head has a cleaning water vortex chamber NH2-34 between the orifice and the head passage NH2-5 for cleaning the buttocks. The washing water vortex chamber has an inner peripheral wall that has a larger diameter toward the bottom and is inclined from the bottom to the orifice. Since the head flow path is eccentrically connected to the washing water swirling chamber as shown in the figure, the washing water flowing into the swirling chamber is moved along the inclined inner peripheral wall as shown by an arrow SY in the figure. Turn. Then, the washing water swirled in this manner is discharged in a state where a large amount of air is entrained when the washing water is discharged from the throat (ass water discharge hole) through the orifice and the outside air entrapment chamber.

[0344] The cleaning water discharged in this manner is affected by the swirling force of the cleaning water itself, and adopts a spiral water discharging form as schematically shown in the figure. In this modification, when the washing water flows into the washing water vortex chamber NH2-34, the washing water is supplied from the head channel NH2-5 for ass washing in the above-described pulsating flow or intermittent flow. Therefore,
The flush water discharged in this manner adopts a spiral water discharge form with air mixed therein as shown in the drawing, while maintaining the above-described water discharge property in the pulsating flow or intermittent flow. The swirling force of the washing water is determined by the inflow speed (washing water speed) of the washing water into the washing water swirl chamber, and the inflow speed defines the degree of swirling of the washing water in the washing water swirling chamber. Also, the degree of aeration is determined by the washing water speed. Therefore, by adjusting the washing water inflow speed (washing water speed) into the washing water swirl chamber, it is possible to variously adjust the degree of spiral expansion and the degree of air mixing in the spiral water discharge form. Since the extent of the spiral affects the cleaning area, in this modification, the cleaning area can also be adjusted. The washing water speed can be variously changed by frequency adjustment or duty ratio adjustment in a pulsating flow or an intermittent flow, and flow adjustment by a flow regulating valve. Therefore, it is possible to discharge water with various cleaning areas and discharge water with various air mixing amounts, and it is possible to provide a more comfortable cleaning feeling, a soft feeling, and the like. In addition, it is possible to realize water pressure adjustment at a low flow rate by a pulsating flow or an intermittent flow.

Also in this modified example, the amount of air entrainment was measured by variously changing the area ratio (S2 / S1) of the orifice diameter S1 and the throat diameter S2, and the result shown in FIG. 104 was obtained. That is, about 1.3 to 2 times as compared with the above-described nozzle head NH2-30 having no vortex chamber (see FIG. 101).
The air entrapment amount can be increased about twice as much, which is further advantageous from the viewpoint of improving the effectiveness of water saving and providing a soft feeling of washing. It is preferable to set the area ratio to about 1.2 to 3 from the viewpoint of increasing the amount of air entrainment. The air entrainment was measured by the same method as described above.

In the nozzle head NH2-33 of the modification shown in FIG. 103, the degree of spiral expansion and the degree of air entrainment in the spiral water discharge mode are determined by the flow rate of cleaning water into the cleaning water swirl chamber (the cleaning water velocity). Stipulated. Therefore, only by supplying the continuous flow of cleaning water that has been subjected to normal flow rate adjustment using a flow rate adjusting valve or the like, it is possible to discharge water in various cleaning areas and water with various amounts of air mixed in. Soft feeling and the like can be imparted. In other words, according to the above-described nozzle head NH2-33, it is not necessary to supply the cleaning water in a pulsating flow or an intermittent flow state. The existing device can be easily improved so as to give a soft feeling or the like.

In addition, this nozzle head NH2-33
Only the extent of the spiral in the spiral water discharge form is defined by the washing water inflow speed (washing water speed) into the washing water swirl chamber.
Therefore, only by supplying a continuous flow of washing water whose normal flow rate has been adjusted by a flow rate adjusting valve or the like, it is possible to discharge water in various washing areas depending on the extent of the spiral. For this reason, in the above-described nozzle head NH2-33, a comfortable cleaning feeling, a soft feeling, and the like can be imparted even if the configuration relating to the supply of the cleaning water and the entrainment of air in a pulsating flow or an intermittent flow is omitted.

The nozzle head NH2-33 has
It is also possible to forcibly mix air using an air pump or the like. In this way, the amount of air mixed in increases, so that a more soft feeling can be provided. In a case where forced air mixing is performed in this way, the above-described pulsating flow or intermittent flow of washing water is discharged while forced air mixing is performed, or the forced air mixing is stopped. It is also possible to discharge water with a pulsating flow or intermittent flow of cleaning water.

In the above-described embodiment and each of the modifications, the head flow paths for the tail cleaning, the soft cleaning, and the bidet cleaning in the nozzle head may be arranged vertically. By doing so, the width direction of the cleaning nozzle can be narrowed, various devices and units including the nozzle device can be arranged close to each other, and the size of the device can be reduced. In this case, the nozzle flow path can be formed vertically in the cleaning nozzle in addition to the upper and lower head flow paths. Further, the nozzle head may be configured such that the head cover having each of the water discharge holes is mounted on the base having each of the head flow paths, and an outside air introduction hole is provided between the base and the head cover.

In addition, the local cleaning device of the above embodiment or each modified example can be modified as follows. (1) Although the above-described wave generation device WP2-8 was used for making the pulsating flow of washing water, a pump capable of obtaining a pulsating output, such as a gear pump or a trochoid pump, can be used. In this case, the pulsation frequency can be variably controlled through the rotation speed control of these pumps to adjust the water force and the like. In addition, the wave generation device WP2-
8, the phase angle control may be performed by using the AC drive, and the water force or the like may be adjusted similarly to the duty ratio control in the above-described embodiment. (2) In addition, the intermittent valve WP2-27, which makes intermittent flushing water through intermittent flow, is opened and closed with a solenoid valve using a solenoid or a water supply poppet to open and close the water supply port. May be a poppet type valve.

(3) A pressurizing device WP2-25 having a pressurizing pump composed of a line pump and an intermittent valve WP2-27 are used for pressurizing the washing water and thereafter forming an intermittent flow. Configuration. However, the configuration is not limited to this, and the cleaning water may be configured to be pressurized and intermittent. FIG.
5 is an explanatory view illustrating a cleaning nozzle WN2-35 of still another modification, and FIG. 106 is an explanatory view illustrating a schematic configuration of a solenoid pump WN2-36 used in the cleaning nozzle of this modification.

As shown in the figure, the solenoid pump comprises a suction-side check valve WN2-37 and a discharge-side check valve WN2-
This is a normal flow type electromagnetic pump having 36. And
This solenoid pump is an electromagnetic solenoid WN2-39.
Is excited to move the plunger WN2-40 forward and backward to obtain intermittent pressurized water from the pump chamber WN2-41. Normal solenoid pumps are
An accumulator is also used in order to eliminate fluid intermittent due to plunger advancing and retreating, which is sandwiched between the discharge-side check valves, and to obtain a smooth pressure. However, the solenoid pump WN2-36 of this modification can obtain an intermittent cycle synchronized with the excitation voltage of the electromagnetic solenoid by using the intermittent pressure without using an accumulator. According to this embodiment, since the pressurizing section and the intermittent section can be realized by one solenoid pump WN2-36, the configuration can be simplified. Even in this case, the excitation cycle of the electromagnetic coil, that is, the intermittent cycle, is set so that its frequency falls within the dead band frequency range described above.

(4) In addition, the pressurizing device WP2-25 and the intermittent valve WP2-27 are used for pressurizing the washing water and for intermittent flow thereafter.
As shown in FIG. 94, the intermittent flow in which the pressure periodically fluctuates with the pressure regulating pressure of the pressure regulating valve as the maximum pressure as shown in FIG.
An intermittent flow in which the pressure fluctuates periodically may be set as the minimum pressure of the pressure regulating valve. In this way, even if the pressure of the water supply source itself such as water supply is originally low,
Water can be spouted with the intermittent flow of wash water as described above.

(5) Further, in the above-described embodiment and its modifications, by stopping the driving of the wave generator WP2-8 and the like, it is possible to discharge the washing water by the continuous flow as in the conventional case. Therefore, a button for selecting the on / off state of the pulsating flow spout is provided on the remote control device or the sleeve of the main body, etc., and in accordance with the operation of the button, that is, according to the user's preference, the form of spouting of the pulsating flow flushing water. It is also possible to select the same type of water discharge as the conventional one by using the local cleaning in the above and the continuous flow of cleaning water.

(6) The tank TH of the heat exchange unit
A buffered hot water storage tank may be provided on the tapping side of 1-3 and may be used in place of the accumulator WP2-7. The configuration of the buffered hot water storage tank includes a tank arranged so as to have a higher water level than the tank.
And the vacuum breakers TH1-4. This buffered hot water tank absorbs pressure fluctuations propagating from the downstream side to the tank in almost the same manner as the accumulator. Therefore, even with this buffered hot water storage tank, disturbance in the temperature distribution in the tank can be suppressed by fluctuation absorption, and the temperature in the tank can be made uniform, thereby stabilizing the temperature control characteristics. A mixing plate or a mixing passage for promoting mixing of hot water may be provided in the buffered hot water storage tank to further enhance the pressure fluctuation absorbing effect. Further, the buffered hot water tank may be integrated with the heat exchange unit, and a mixing plate or the like may be provided inside the unit.

(7) In order to detect the temperature of water supplied to the heat exchange unit, instead of using a water temperature sensor, for example, the derivative of the amount of power supplied to the heater is determined based on the amount of power supplied to the heater. It may be calculated based on the value.
This eliminates the need for an incoming water temperature sensor and simplifies the configuration. The same applies to the reference example described above. Moreover, the incoming water temperature sensor SS16a and the outgoing water temperature sensor SS1
13 can be provided not only in the tank but also before and after the heat exchange unit, as long as it reflects the temperature of the hot water in the tank.

(8) In the pulsating flow or intermittent flow of washing water described above, the flow rate can be variably controlled while the flow rate is kept constant. First, pulsating flush water discharge (hereinafter, referred to as pulsating water discharge) using the wave generation device WP2-8 will be described. FIG. 169 shows that in this pulsating water discharge, the flow velocity vm is decelerated while keeping the flow rate constant (vm2 → v
m3). In the drawing, t2 and t3 (> t2) represent the energization time for exciting the coil of the wave generator, T2 represents the pulsation generation period of the pulsation generated by the wave generator, and V represents the pulsation generator. A voltage applied to the switching transformer for turning ON / OFF the pulsation generating coil, that is, a coil excitation voltage. In the figure, (a) shows the state of the duty ratio of the pulse signal, (b) shows the relationship between the voltage V and time,
(C) shows the relationship between the flow velocity vm-time of the flushing water discharged,
Each is represented. With reference to FIG. 169, a description will be given of a control for increasing the flow velocity while keeping the flow rate constant in the pulsating water discharge.

When the pulsation generator comprises a pulsation generating coil and a plunger driven by this coil, the flow rate depends on the stroke length of the driven plunger, and the flow rate depends on the driving speed of the plunger, ie, the suction force of the plunger. Is defined respectively. First, assuming that deceleration is to be performed, the voltage V applied to the pulsation generating coil (that is, the current flowing to the pulsation generating coil) is reduced (V3 → V2; see (b)). As a result, the suction force of the plunger decreases and the flow velocity decreases. At this time, if the duty ratio is the same before and after the voltage change, the stroke length of the plunger is shortened by the reduction in the driving speed of the plunger, and the flow rate is reduced. Therefore, if it is sufficient to reduce the flow rate even if the flow rate is reduced,
More than simply reducing the voltage with a constant duty ratio as described above. The reverse is true for increasing the flow velocity.

On the other hand, in order to accelerate or decelerate only the flow velocity without changing the flow rate, the following control is performed. In the case of the deceleration control, the duty ratio is increased (t2 / T2 → t) in order to shorten the stroke length, that is, compensate for the insufficient flow rate.
3 / T2; (a)). When the duty ratio is increased in this way, the coil excitation period also becomes longer, so that the plunger can be driven by the regular stroke and the stroke length of the plunger can be kept constant. Therefore, only the flow velocity can be reduced while keeping the flow rate constant. This phenomenon is
In the left and right graphs (c) showing the relationship between the flow velocity and time,
This can also be explained from the fact that the areas S2 during one cycle are equal. In the case of speed-up control, the reverse is true. Of course, in addition to this, when pulsation is constantly generated at the stroke limit of the plunger, the flow rate does not change because the drive stroke length does not change, just by controlling the applied voltage or energizing current to the pulsation generating coil, Control with constant flow rate and variable flow rate becomes possible.

(9) As another example of increasing the flow rate without changing the flow rate, the following method can be used for intermittent flow of flush water using a pressurizing pump and an on-off valve. When the pressure applied to the wash water is increased by the pressure pump,
The flow rate of the washing water increases (substantially proportional to 1/2 power). At this time, by shortening the opening time of the opening / closing valve communicating with the water discharge hole (decreasing the opening time duty), it is possible to keep the washing water constant while increasing the flow velocity.
Furthermore, if the reciprocating motion of the plunger is not used as a means for adding the energy of spouting water to the washing water, but as a means for increasing and decreasing the flow path cross-sectional area similar to the opening and closing valve,
As described above, the flow rate can be increased without changing the flow rate by increasing the pressure applied to the washing water by the pressurizing pump. Further, even if the acceleration / deceleration control of the flow velocity in the constant flow rate described above and the control of the pressurizing pump are executed in combination, the flow velocity can be controlled independently of the flow rate.

Next, another embodiment will be described.
FIG. 107 is a schematic cross-sectional view of a main part of a cleaning nozzle WN3-1 included in the local cleaning device of the second embodiment. FIG. 108 is a schematic cross-sectional view of a main part of a cleaning nozzle WN4-1 of the third embodiment.
Is an exploded perspective view of a main part of the cleaning nozzle WN4-1. In the following description, the same member names and the same reference numerals will be used as described above.

As shown in FIG. 107, the cleaning nozzle WN3-1 of the second embodiment is provided with a nozzle head NH3-1 at the tip of a nozzle cylindrical body WN3-2 in a watertight manner. This nozzle head has a bottom water discharge hole NH3-2 and a bidet water discharge hole NH3-3 on its upper surface, and a first head flow path NH3-4 for guiding cleaning water to each of the water discharge holes inside the head. And a second head passage NH3-5. Further, a first inflow chamber NH3-6 and a second inflow chamber NH3-7 into which the cleaning water flows are formed at the junction of each water discharge hole and each head flow path. The first and second inflow chambers have first and second water turbines NH3
-8 and 9 are incorporated. The first and second turbines are
It is rotatably supported in each of the inflow chambers, and rotates in the direction of the arrow in the figure by the washing water flowing into the inflow chamber.

The first and second turbines NH3-8 and NH3-9 are provided with a plurality of blades at equal intervals from the center thereof, and the water discharge holes in the first and second inflow chambers NH3-6 and NH3 are provided between adjacent blades. Shielding plate NH3-1 that closes the opening (inflow chamber side opening)
Has zero. In this embodiment, three shielding plates are formed at equal intervals. It should be noted that one shielding plate may be provided over half of the blades of the water turbine.

The cleaning nozzle WN3-1 has first and second nozzle channels WN3-3, 4 communicating with the first and second head channels NH3-4, NH3 in the nozzle cylinder. The washing water heated by the heat exchange unit (not shown) has a flow rate adjusted by a flow control valve (not shown),
It flows into the second head channels NH3-4 and NH3. Then, the washing water is discharged from the tail water discharge hole NH3-2 or the bidet water discharge hole NH3-3 via the first and second head flow paths and the first and second inflow chambers NH3-6 and NH3.

As described above, the washing water is supplied to the first and second inflow chambers NH.
When passing through 3-6 and 7, the washing water collides with the blades of the turbine and exerts a rotational force on the turbine to rotate the turbine.
Therefore, since the shielding plates NH3-10 are formed at equal intervals as described above, the opening of the water discharge hole on the inflow chamber side is repeatedly shielded with the rotation of the water turbine. Then, the washing water passes through the inflow-chamber-side opening only while the inflow-chamber-side opening is not shielded by the shielding plate, and is discharged from the water discharge hole.
For this reason, the washing water is discharged from the water discharge hole in an intermittent flow state in which the flow is divided by the shielding plate at the opening of the water discharge hole on the inflow chamber side.

On the other hand, the rotational force of the water wheel is determined by the flow rate of the wash water into the inflow chamber (wash water speed), and this flow rate defines the rotational speed of the water wheel. Therefore, the shielding period of the inflow-chamber-side opening by the shielding plate, that is, the intermittent period of the washing water intermittently caused by the division of the flow, is determined by the rotation speed of the water turbine, that is, the washing water speed. Therefore, when the cleaning water is supplied to the cleaning nozzle WN3-1 of the second embodiment, the frequency determined by the above-mentioned intermittent cycle can be made to be in the above-described dead band frequency range by adjusting the cleaning water speed. For this reason, according to the cleaning nozzle WN3-1, similarly to the previous embodiment and its modification, the pulsating flow or intermittent flow of the cleaning water can be used to adjust the water level at a low flow rate. In this case, the inner diameter of the inflow chamber is defined by the first turbine NH3-8 and the second turbine NH3-9,
If the size of the shielding plate, the installation interval of the shielding plate, and the like are different, the intermittent cycle of the washing water intermittently flowed as described above is made different between the ass washing and the bidet washing. be able to. For this reason, in the ass washing and bidet washing,
Since the frequency determined by the intermittent cycle can be changed, the feeling of cleaning at the time of each cleaning can be made different. For example, if the frequency of the bidet cleaning is set to be higher, the cleaning feeling of the bidet cleaning can be made softer than that of the buttocks cleaning. From these facts, the above-mentioned water turbine and the device such as the flow regulating valve for adjusting the washing water speed function as the “water discharging means” in the present invention, and the electronic control device for controlling this device is referred to as the “water discharging control” in the present invention. Function as a "means", "control means" or "variation control executing means".

In the cleaning nozzle WN3-1 of the second embodiment, an electric drive device such as a motor is not required to obtain the effect of adjusting the water force and the cleaning feeling by the intermittent flow of the cleaning water as described above. Therefore, a high power saving effect can be achieved as a whole device, and the configuration can be simplified. In addition, since an electric wiring process up to the nozzle head is not required and an electric driving device is not required, there are advantages in manufacturing such as a reduction in the number of assembly steps and a reduction in cost.

The cleaning nozzle WN3-1 may be configured so that the orifice is provided with an outside air introduction passage in the middle of the path of each water discharge hole to perform air mixing. Further, the washing nozzle WN3-1 may be configured such that a motor for rotating the water wheel is incorporated in the nozzle head, and the rotation of the water wheel is controlled by the motor. In this case, since the above-mentioned intermittent cycle can be variably controlled irrespective of the washing water speed, it is possible to adjust the water force through the frequency control of the intermittent flow without being affected by the washing water speed.

As shown in FIG. 108, the cleaning nozzle WN4-1 of the third embodiment is provided with a nozzle head NH4-1 at the tip of a nozzle cylinder WN4-2 in a watertight manner. This nozzle head has an intermittent water discharge mechanism NH4-2 on its upper surface. In the following description, the cleaning nozzle WN4-1 will be described as for cleaning the buttocks.

The intermittent water discharge mechanism NH4-2 cleans the intermittent flow of the continuous flow of cleaning water supplied from the head passage NH4-3 by dividing the flow similarly to the above-described cleaning nozzle WN3-1. It discharges water as water. That is, the intermittent water discharge mechanism is provided with the cleaning water inflow chamber NH at the end of the head flow path.
4-4 has a bottom plate NH4-5 and a water wheel NH4-6. The bottom plate allows the wash water flowing from the head flow path into the wash water inflow chamber to flow toward the peripheral wall of the inflow chamber as indicated by the arrow in the drawing. As shown in FIGS. 108 and 109, the water wheel is incorporated into the lower peripheral wall of the water wheel support NH4-7 on the upper surface of the nozzle head, and is inserted into the shaft NH4-8 at the center of the support. When the turbine support is fixed to the upper surface of the nozzle head in this state, the turbine becomes rotatable about the shaft inside the lower peripheral wall of the turbine support. This waterwheel is
A shielding plate NH4-9 covering the blade is provided on the upper surface.

As shown in FIG. 109, the water turbine support NH4-7 has notches NH4-10 at equal intervals on the lower peripheral wall. Therefore, the washing water that has flowed to the inner peripheral wall side of the washing water inflow chamber by the bottom plate NH4-5 passes through each notch and collides with the blade of the waterwheel NH4-6 to rotate this waterwheel. The washing water collides with the shield plate NH4-9 of the turbine from below, and pushes the turbine toward the lower surface of the turbine support. For this reason, the water turbine rotates with its upper surface in contact with the lower surface of the water turbine support. The water turbine support is located at a position overlapping with the shield plate of the water turbine.
1, the water discharge hole is blocked or opened with the rotation of the water wheel. For this reason, the washing water is discharged from the water discharge port opened by the water turbine, so that attention is paid to one water discharge hole. An intermittent flow in which the flow is divided by the shielding plate in the hole is discharged from the water discharge hole. In the case where a plurality of water discharge holes are provided at equal intervals as in the present embodiment, since the water discharge holes opened by the shielding plate sequentially move by the rotation of the water turbine,
The water discharge of the washing water is sequentially switched to each water discharge hole, and each water discharge hole is in the state of the intermittent flow described above.

Even with the washing nozzle WN4-1, the inflow speed of the washing water defines the rotation speed of the water turbine.
That is, it is determined by the washing water speed. Further, the switching cycle for switching to water discharge at the adjacent water discharge hole is also determined by the rotation speed of the water turbine, that is, the washing water speed. Accordingly, the cleaning nozzle WN4-
By adjusting the washing water speed at the time of supplying the washing water to 1, the frequency determined by the above-mentioned intermittent cycle and the frequency determined by the above-mentioned switching cycle can both be in the dead band frequency range described above. For this reason, according to the cleaning nozzle WN4-1, similarly to the previous embodiment and its modification, the pulsating flow or the intermittent flow of the cleaning water can be used to adjust the water level at a low flow rate. In this case, as described in the reference example, the user can recognize that water is sequentially discharged from each of the water discharge holes, although the water discharge holes of the wash water are sequentially switched on the forming circumference of each of the water discharge holes. Instead, it feels as if water is being continuously discharged from each water discharge hole. For this reason, it is possible to change the water force at that time by adjusting the intermittent frequency while giving a feeling that water is continuously discharged over a wide area. Also in the third embodiment, the water turbine and the device such as the flow regulating valve for adjusting the washing water speed function as the "water discharging means" in the present invention, and the electronic control device for controlling this device is the present invention. Function as "water discharge control means", "control means" or "variation control execution means".

The washing nozzle WN4-1 of the third embodiment does not require an electric drive device such as a motor in order to obtain the effect of adjusting the water force and washing feeling by the intermittent flow of washing water as described above. Accordingly, the same effect as in the second embodiment can be obtained. It should be noted that even with the washing nozzle WN4-1, a configuration is possible in which the rotation of the water turbine is controlled by a motor. In this case, since the above-mentioned intermittent cycle can be variably controlled irrespective of the washing water speed, it is possible to adjust the water force through the frequency control of the intermittent flow without being affected by the washing water speed.

Next, another embodiment will be described. FIG.
10 is a schematic cross-sectional view of a main part of a cleaning nozzle NH5-1 included in the local cleaning device of the fourth embodiment. In the following description, the same member names and the same reference numerals will be used as described above. In addition, the description will be made assuming that the cleaning nozzle NH5-1 is for cleaning the buttocks.

The cleaning nozzle NH5-1 of the fourth embodiment
Is characterized in that, when air is forcibly mixed into the cleaning water and the water is spouted, the pulsating flow or intermittent flow of the cleaning water is spouted by periodically changing the air mixing amount. That is, as shown in FIG. 110, the cleaning nozzle NH5-1 has a tail water discharge hole NH5-2 at the nozzle tip, and supplies the cleaning water to the water discharge hole via the nozzle flow path NH5-3. An aeration chamber NH5-4 is formed below the water discharge hole opening. In this aeration chamber, a nozzle flow path is formed by a porous pipe NH5-5 made of resin, metal, ceramic, or the like.
It is formed with.

The air mixing chamber NH5-4 is provided with an air passage NH5.
It is connected to the pneumatic feed mixing unit NH5-7 through -6. As shown schematically in the drawing, this air pressure feeding and mixing unit sends air to the air mixing chamber while periodically varying the air flow rate or at a fixed set flow rate.
The air pressure mixing unit mixes air into the cleaning water through the porous pipe NH5-5 in the air mixing chamber. The porous pipe mixes air as fine bubbles into the cleaning water passing therethrough due to its porous nature. Therefore, in combination with the pressure feeding from the air pressure feeding / mixing unit, it is possible to mix air up to four times in volume ratio with respect to the washing water.

[0377] The above-mentioned pneumatic feeding and mixing unit may be constituted by using a variable displacement type air pump, or by using a constant displacement or variable displacement type air pump and a flow regulating valve arranged downstream thereof. it can. Alternatively, the air pump can be configured using these air pumps and an on-off valve arranged downstream of the air pump to open and close the pipeline. In order to pump air while periodically fluctuating the air flow rate in the air pressure mixing unit configured as described above, the flow rate may be periodically fluctuated by controlling the rotation speed of the air pump, or the line may be controlled by a flow regulating valve. May be changed periodically in the range of 0 to 100%, or may be changed periodically in the range of 10 to 100%.
In the case of an on-off valve, the opening and closing of the pipeline may be repeated periodically. In this case, if a positive displacement air pump is used as the air pump, the air supply / stop / repeating is repeated in accordance with the operation of the air pump. In such a configuration, when the effective area of the pipeline is set to 0 by the flow control valve, the pipeline is shut off by the on-off valve, or the operation of the positive displacement air pump is stopped, the washing water is cut off. Situation, i.e., only air comes out of the spout. Therefore, it is possible to adopt a water discharge mode in which the mixed air becomes a sandwich in a state of water, air, water, air, etc. without being finely mixed with water. This water discharge form has almost the same behavior as the above-described water discharge form of intermittent flow of wash water. Because of this, the apparent volume increases due to air mixing, the flow rate of the cleaning water is increased, and the water is sandwiched by air, so that the cleaning water becomes a water mass and is discharged.
The same effect can be expected as the washing water spouting of the wave flow.

In the cleaning nozzle NH5-1, when water is supplied to the nozzle from the cleaning water supply unit NH5-8 in a state where the air supply from the air supply mixing unit NH5-7 is stopped, the tail water discharge port NH5-2 is provided. The washing water can be spouted in a continuous flow. Also, the pneumatic feed mixing unit NH5-7
When water is supplied to the nozzle with the air pressure feeding from the nozzle set to a constant set flow rate, the washing water containing bubbles mixed at a substantially constant ratio can be in a continuous flow state. In other words, it is possible to selectively use the flushing water that has been mixed with air and the flushing water that contains only the flushing water. And water can be saved by the amount of air mixing. In addition, by adjusting the setting of the amount of mixed air and / or adjusting the flow rate of the washing water, the washing water mixed with air at various ratios can be discharged in a continuous flow state, depending on the amount of mixed air and the flow rate. A feeling of washing and water force can be obtained.

In the cleaning nozzle NH5-1, air is fed under pressure while periodically varying the flow rate of air, and is mixed into the cleaning water. The washing water is a part of which is periodically repeated. In the part where the air mixing amount is dense, the flow rate of the washing water is increased by the amount of air mixing, and in the sparse part, the flow velocity does not increase as much as the dense part. The portion where the air mixing amount is high and the flow speed is high catches up with the sparse and low flow speed portion and unites with this. This phenomenon is not different from the phenomenon described with reference to FIG.
Moreover, in the fourth embodiment, when the air is pumped while periodically varying the air flow rate, the variation frequency determined by the variation cycle is set within the dead band frequency range described above. As a result, the washing water spouting in the fourth embodiment becomes a pulsating or intermittent flushing spout according to the state of the periodic fluctuation of the air flow rate. Is equivalent to That is, the flush water spouting in the fourth embodiment is as shown in FIG. Therefore, according to the fourth embodiment, the same effect as that of the first embodiment, that is, the improvement of the water saving effect and the setting of various washing feelings and water levels can be achieved. In the fourth embodiment, diversification of the cleaning feeling can be brought about by adjusting the fluctuation width at the time of the periodic fluctuation of the air flow rate and / or the flow rate of the cleaning water. That is, even if the flow velocity is reduced due to a shortage of water, the water force can be maintained or the strength can be adjusted by adjusting the fluctuation width during the air pressure feeding. In the fourth embodiment, the air pressure feeding / mixing unit NH5-7 that causes a periodic variation of the air flow rate to make the pulsating flow or intermittent flow of the cleaning water function as the “water discharging means” according to the present invention. The electronic control device that controls the unit functions as “water discharge control means”, “control means”, or “variation control execution means” according to the present invention.

Next, another embodiment will be described.
FIG. 111 is a block diagram illustrating a water channel configuration included in the local cleaning device KS6-1 of the fifth embodiment.

The local cleaning device KS6-1 of the fifth embodiment is
The feature is that the washing water spouting by the swing rotation of the spouting hole realized in the first reference example and the washing water spouting by the pulsating flow realized in the first embodiment can be executed individually or simultaneously. That is, as shown in FIG. 111, the local cleaning apparatus of the fifth embodiment has the cleaning nozzle WN1-1 of the reference example of FIG. 4 in the water channel configuration of the first embodiment of FIG. Therefore, this local cleaning device has the following advantages.

(1) The wave generation device WP2-8 of the wave generation unit WP2-3 may be in a stopped state to supply washing water downstream thereof. In this aspect, since the washing water passes through the stopped wave generation device as described above, the washing nozzle WN1-1 is supplied with the washing water in a continuous flow. Such a water supply state is not different from the reference example of FIG. Therefore, in the local cleaning apparatus KS6-1 of the fifth embodiment, pseudo swinging of the buttocks movable body NH1-9 and the bidet movable body NH1-11 from the cleaning nozzle WN1-1 just like the reference example. The cleaning water can be spouted in a pseudo-conical shape by rotation (see FIGS. 22 and 23). In this case, the same effect as in the reference example can be obtained. As an example, when the pseudo-oscillating rotation of the movable body is caused, the duty ratio variable control and the frequency variable control or both controls are used to set the strength of the water without depending on the flow control result of the washing water by the flow control valve. In addition, it is possible to diversify the washing feeling. In the case where the washing water is spouted by the pseudo swinging rotation of the movable body, the washing nozzle WN1-1 can be supplied with a continuous flow of washing water by bypassing the wave generation unit WP2-3. Pressure loss at the time of supply of washing water can be suppressed.

(2) First, the buttocks movable member NH1-9 and the bidet movable member NH1-11 are set in a free state by deenergizing all the electromagnetic coils, or by simultaneously exciting all the electromagnetic coils. The movable body is brought into a state of being attracted to the coil. In this state, a mode can be adopted in which the pulsating flow cleaning water in the dead band frequency region generated by the wave generation device WP2-8 of the wave generation unit WP2-3 is supplied to the cleaning nozzle. Since this water supply mode is not different from the first embodiment, the pulsating flow of the flush water can be discharged from the cleaning nozzle WN1-1 in the same manner as in the first embodiment. Therefore, by the duty ratio variable control and the frequency variable control or both of the control in generating the pulsating flow, the strength of the water force can be set and the feeling of cleaning can be diversified without depending on the flow control result of the cleaning water by the flow control valve. For example, the same effects as those of the first embodiment can be obtained. In both water supply modes, it is possible to naturally improve water saving efficiency and reduce the capacity of the heater.

In this case, if the above-described pulsating flow water discharge is performed with the movable body in a free state, the following advantages can be obtained. The flange portion NH1-15 and the cylindrical portion NH1-16 supporting the movable body are
As described above, it is formed of an elastic material exhibiting a deformation restoring property. Therefore, the frequency of the pulsating flow can be controlled so that the frequency of the pulsating flow resonates with the vibration characteristics of the movable member in the free state determined by the degree of elasticity of these members, the weight of the movable member, and the like. In this case, the pressure fluctuation width of the pulsating flow can be emphasized by the resonance vibration of the movable body having the water discharge hole itself, and a sharp stimulus can be provided. Further, since the fluctuation range of the pulsating flow can be reduced, power can be saved accordingly.

(3) The pulsating flow washing water in the dead band frequency region generated by the wave generating device WP2-8 of the wave generating unit WP2-3 is supplied to the washing nozzle, and the above-mentioned quasi-oscillating rotation of the movable body is performed. The cleaning water can be spouted in a pseudo-conical spouting form. In this case, the flow rate adjustment by the flow control valve is complemented by a duty ratio variable control and a frequency variable control or a control of both of them (hereinafter, this control is referred to as a movable body control) at the time of the pseudo swing rotation of the movable body. Duty ratio variable control and frequency variable control or both of these controls (hereinafter, this control is referred to as pulsating flow control) when generating a pulsating flow can be achieved. Therefore, even under a stricter flow rate of washing water at a lower flow rate, the user can achieve a desired washing feeling and water force by supplementing the flow rate adjustment by the movable body control and the pulsating flow control. As a result, the effectiveness of further water saving can be enhanced. In addition, there are the following advantages.

At the time of massage washing for facilitating defecation using the movable body control, the movable body is supplied with pulsating flow cleaning generated by the pulsating flow control. In this way, the change in the washing sensation based on the change in the washing area (see FIG. 36) by the movable body control and the change in the cleaning sensation of the hardware and software based on the way of the pulsation by the pulsation flow control are more effective for promoting the convenience. is there. When spotting and widening the cleaning area using the movable body control (see FIG. 34), the movable body is supplied with the pulsating flow cleaning generated by the pulsating flow control. In this way, in each cleaning area changed by the movable body control,
It is possible to receive a change in the feeling of hard / soft washing based on the manner in which pulsation is generated by the pulsating flow control, and the feeling of washing is further diversified. Further, the monotonous feeling at the time of spot-wide cleaning is more effectively eliminated. When the filth OB around the local area is separated by spotting and widening the cleaning area using the movable body control (see FIG. 37), the movable body is supplied with the cleaning of the pulsating flow generated by the pulsating flow control. In this way, it is possible to give the model water discharge water column RT that changes by the control of the movable body a strong and weak change in the water force based on the manner of generation of the pulsation by the pulsation flow control. Therefore, the peeling effect of the waste OB is further enhanced. At the time of the fluctuation cleaning due to the irregular change of the cleaning area using the movable body control, the movable body is supplied with the cleaning of the pulsating flow generated by the pulsating flow control. In this way, the prediction of the cleaning area change (see FIG. 40) in which the cleaning area changes irregularly due to the control of the movable body can be more accurately determined by the change in the strength of the water and the change in the feeling of cleaning based on the manner in which pulsation is generated by the pulsation flow control. Because it is difficult, it is possible to more effectively promote consent. Further, if the fluctuation cleaning by the pulsating flow control (see FIG. 84) is performed in addition to the fluctuation cleaning by the movable body control, it becomes more difficult to predict the transition of the cleaning state, which is advantageous for promoting the bowel movements and developing the enema effect. In the move cleaning using the movable body control (see FIGS. 32 and 48), the movable body is supplied with the pulsating flow cleaning generated by the pulsating flow control. In this manner, the cleaning during the move cleaning is performed based on the change in the cleaning feeling based on the change of the cleaning area by the movable body control according to the nozzle position, and the change in the strength of the water and the change in the cleaning feeling based on the pulsation expression by the pulsating flow control. The feeling is diversified, and the monotonous feeling of local cleaning can be more effectively eliminated.

Next, a modification of the above-described local cleaning apparatus of the fifth embodiment will be described. The local cleaning device of this modification is characterized in that the cleaning water is discharged to a cleaning point desired by the user. FIG. 112 is an explanatory diagram showing a schematic configuration of a local cleaning device KS6-2 of this modification, FIG. 113 is an explanatory diagram for explaining a control method when discharging cleaning water to a cleaning point, and FIG. It is explanatory drawing explaining instruction | indication panel KS6-5 of the washing point in the modification of FIG.

As shown in FIG. 112, the local cleaning apparatus KS6-2 of the modified example has a rotary knob KS6-4 for indicating the cleaning points XA, XB, XC on the sleeve KS6-3 of the main body. The cleaning points XA, XB, XC are shown in FIG.
Correspond to the installation positions of the electromagnetic coils for exciting each movable body shown in FIG. For example, in the case of the bidet movable body NH1-11,
The cleaning point XA is connected to the electromagnetic coil NH1-33a by XB
Is the electromagnetic coil NH1-33b, XC is the electromagnetic coil NH
1-33c. Electronic control unit CT6-2
Reads the rotation operation amount of the rotary knob, and on the locus on which the schematic water spouting water column RT (see FIG. 22) can be applied by the local cleaning device, where the user wants to apply the water column Judge. For example, if the rotary knob matches the cleaning point XA, it is determined that the local skin XAN corresponding to the XA is to be cleaned. In addition,
When the rotary knob is operated in the middle of each washing point, the washing point desired by the user is determined based on the deviation from any one of the washing points.

The electronic control unit CT6-2, which has determined the washing point in this way, performs the quasi-oscillating rotation of the movable body by the movable body control and the pulsation flow generation by the pulsation flow control as follows. Hereinafter, for convenience of explanation, it is assumed that the cleaning point is XA.

That is, when the movable body is oscillated and rotated at the pulsation frequency, when the movable body is tilted by the suction of the electromagnetic coil corresponding to the washing point, the pulsating flush water is discharged from the water discharge hole of the inclined movable body. Let the water be spouted. In this manner, the pulsating flow of the washing water can be discharged to the washing point desired by the user to wash the washing point.

By the way, in a device such as the wave generating device WP2-8 which requires driving of a plunger or the like, a response delay occurs in driving the plunger. Therefore, the electronic control unit CT6-
2 is the response delay time ta as shown in FIG.
In consideration of this, the pulsation flow is generated by driving the wave generation device WP2-8 faster by this time ta. In this manner, the cleaning can be performed by accurately discharging the schematic water discharge column RT at the cleaning point desired by the user. In this case, the response delay time t
“a” may be written in the ROM of the electronic control unit, and the delay time ta may be read in the pulsating flow control. The delay time ta can be variably set by a dedicated slide switch or the like, and can be adjusted at the time of maintenance or inspection or at the time of product shipment.

Instead of the above-mentioned rotary knob KS6-4,
Cleaning point instruction panel KS6 as shown in FIG. 114
-5 can be used. The pointing panel has a so-called matrix switch on the surface of the panel, and generates pointing position data at a fingertip using the capacitance of a human body. The electronic control unit determines the cleaning point based on the designated position data. The instruction panel may be provided on the sleeve of the remote control device or the main body. Further, instead of such an instruction panel, a joystick or the like may be used to instruct a washing point.

Next, another modification of the local cleaning apparatus of the fifth embodiment will be described. This modified example is based on the washing water spouting by swinging rotation of the spouting hole realized in the reference example (hereinafter, simply referred to as swing rotating spouting), and the washing water spouting by the pulsating flow realized in the first embodiment (hereinafter, pulsation). It is characterized in that sequence control is performed by combining water discharge) in the cleaning operation. FIG. 170 is an explanatory diagram showing an example of sequence control of the pulsating water discharge and the oscillating rotary water discharge. An operation switch (not shown) for instructing automatic cleaning is provided on a remote control device, a sleeve of the main body, or the like, and when the user operates this switch, the cleaning shown in FIG. 170 is automatically performed.
For example, each operation switch (auto 1 switch, auto 2 switch) for executing the automatic cleaning 1 and the automatic cleaning 2 shown in FIG. 170 is provided as a switch for the cleaning operation independent of the other cleaning switches, and this switch is operated. The automatic cleaning may be activated when the automatic cleaning is performed.
In this case, each automatic cleaning is performed only when the above-mentioned auto switch is operated.

Here, the illustrated automatic cleaning will be described starting with automatic cleaning 1. In the following description, the cleaning operation period is divided into cleaning periods in time series, and each cleaning period is referred to as a step. Auto wash 1
Is a mode assuming local cleaning after defecation. In step 1 at the start of the cleaning operation, the flow rate is set to a small value (for example, 200 cc / min), and water is discharged with a weak swirling by oscillating rotary water discharge. This allows the user to start using the apparatus without worrying about suddenly receiving strong flush water. Subsequently, the washing proceeds to step 2, and the flow rate is increased while maintaining the form of the oscillating rotary spout (for example, 500 cc /
min), washing is performed from the local peripheral portion by oscillating rotating water spouting. At this time, as shown in FIG. 37, control may be performed so that dirt adhering to the local portion is collected at the central portion. Stimulation from the local periphery allows the stimulation to be more finely amplified for delicate local areas. Next, the process proceeds to step 3 in which the form of water discharge is changed to pulsating water discharge, and the central part is thoroughly washed by the pulsating water discharge. As for the feeling of washing, since the local part is used to the stimulation, a comfortable feeling of stimulation and feeling of washing can be obtained. Finally, the process proceeds to step 4, in which the water discharge mode is returned to the initial swing rotation water discharge, and dirt scattered on the local peripheral portion is washed out by the swing rotation water discharge. Step 4 serves as a finishing wash. Of course, the combination elements and order of each cleaning are not limited to this example, and it goes without saying that the cleaning elements may be freely set without departing from the concept of cleaning by combining the characteristics of each cleaning. In addition, the oscillating rotary water discharge in step 2 and step 4 illustrated above may be changed by changing the rotation frequency, the cleaning area, and the like.

[0395] The automatic washing 2 is a mode assuming promotion of defecation at the time of defecation. In this automatic cleaning 2, in step 3 following the above steps 1 and 2, the flow rate control for stabilizing the flow rate in the pulsating discharge as shown in FIG. 169 is performed, and the pulsating cleaning water having a faster flow rate is locally provided. Multiply. In this case, the stimulus to the central part of the local area is increased by the pulsating water discharge as the flow velocity increases. In the last step 4, since the flow velocity is further increased with the pulsating spout, the washing water enters the anus and has an enema effect. In each cleaning step of each automatic cleaning, the cleaning mode may be changed such that the illustrated rotationally oscillating water is changed to pulsating water. Further, the time spent in each step may be the same or may be longer or shorter.

Also, in order to carry out these automatic washings continuously, an automatic washing setting switch is provided, and while the automatic washing setting is turned on by this switch, each of the ass washing, the soft washing and the bidet washing is performed. The cleaning is performed in a sequence in the automatic cleaning 1 or the automatic cleaning 2 described above. Then, if the setting of the automatic cleaning is turned off, the normal butt cleaning, soft cleaning,
Each bidet wash is executed in response to a button operation.

[0397] The automatic cleaning is not limited to one type, and it is more preferable to provide a plurality of types. For example, as shown in FIG. 170, an automatic washing 1 and an automatic washing 2 are provided, each of which can be used for washing after defecation and washing before defecation. As can be seen from FIG. 170, the cleaning is suitable for each purpose (removal of dirt in the automatic cleaning 1, promotion of defecation in the automatic cleaning 2).

It is preferable to provide a plurality of automatic washings according to gender, age, personal preference, and the like. In addition, it is more preferable that the contents of the automatic cleaning be set not only by the manufacturer but also freely by the user. By providing a means for the user to individually set the contents of the automatic cleaning and a means for storing and recalling the set contents, the user can select the most preferable cleaning mode for himself / herself. Needless to say, the present invention is not limited to the posterior cleaning, and the bidet cleaning may employ an automatic cleaning in accordance with the bidet cleaning. Further, each of the above-described steps may be set as a switch so that the user can use each step for a desired time interval.

FIG. 115 is an explanatory view showing a local cleaning apparatus provided with a cleaning nozzle WN20 according to another reference example. The local cleaning device includes a cleaning water supply unit WP20-1, a heat exchanger TH20-2, a cleaning nozzle WN20, and a control unit WN.
20-6. Cleaning water supply means WP20-1
Is a water pump WP20-11 and a water stop valve W
P20-12 and a flow control valve WP20-13. The water pump WP20-11 is attached to the water pump WP20-11 when the tap water pressure for discharging is insufficient or when the tap water pressure is not used. Further, the washing nozzle WN20 is provided at the tip of the water passage in the water discharge swinging means WN20-41. The water discharge rocking means WN20-41 includes a rotation motor WN20-41a and a rotation motor WN20-41.
and a rotating disk WN20-41b driven by a, and has a water discharge hole WN20-41c at a position eccentric to the rotation axis of the rotating disk WN20-41b. The control unit WN20-6 includes a cleaning water supply unit WP
20-1 water pump WP20-11 and flow control valve W
Cleaning water supply control means WN20- for controlling P20-13
61, a heat exchanger control means WN20-62 for controlling the heat exchanger TH20-2, and a trajectory control section control means WN20-64 for controlling the water discharge rocking means WN20-41. The path of the washing water of the washing nozzle WN20 will be described. When the washing water is supplied from the washing water supply means WP20-1 to the heat exchanger TH20-2, the heat exchanger TH20-2.
Is changed into warm water, flows into the cleaning nozzle WN20, is discharged from the water discharge holes WN20-41c, and local cleaning is performed. The trajectory control unit control means WN20-64 of the control unit WN20-6 controls the water discharge swinging means WN20-41. The water discharge rocking means WN20-41 includes a rotating disc W
By rotating the N20-41b, the rotating disk W
The washing water is spirally discharged from a water discharge hole WN20-41c provided at a position eccentric to the rotation axis of N20-41b.

FIG. 116 is a configuration diagram showing a cleaning nozzle WN22 according to another reference example. FIG. 116 (a) is a top view, and FIG. 116 (b) is a cross-sectional view from the side.

The washing nozzle WN22 is connected to the heat exchanger TH22.
-51, connected to the flow control water stop valve WP22-53. The water discharge part WN22-3 is provided with a water discharge hole WN22-31.
b, water passages WN22-32b, and the like.
The water discharge holes WN22-31b are configured by arranging a plurality of holes in a row in the radial direction from the center of the disk. The water discharge section drive mechanism WN22-4 includes a motor WN22-
41d, a shaft WN22-42b and the like. Water discharge part WN22-3 and water discharge part drive mechanism WN22-4
And are integrally formed via a shaft WN22-42b. Seal part WN22-34 and seal part WN
Reference numerals 22-35 are attached so that the washing water does not leak from other than the water discharge holes WN22-31b.

[0402] The motor WN22-41d of the water discharge section drive mechanism WN22-4 is controlled by the predetermined trajectory control means CT22-2. That is, the predetermined trajectory control means CT22
-2 controls the cleaning water at a predetermined locus and at a predetermined frequency by rotating the motor WN22-41d by controlling the power supply to the motor. With the configuration in FIG. 116, the motor WN22-
When 41d rotates, the water discharging section WN22-3 also rotates, so that the cleaning water discharged from the water discharging holes WN22-31b is discharged while drawing a predetermined trajectory.

FIG. 117 is an explanatory view showing a cleaning nozzle WN24 according to another reference example. FIG. 117 (a) is a sectional view, and FIG. 117 (b) is a plan view showing the movement of the water discharge holes WN24-4b. The cleaning nozzle WN24 has a shaft WN24-6a.
Spout W that moves along a predetermined trajectory without rotating around
N24-4b.

[0404] The cleaning nozzle WN24 is provided with a drive motor WN2.
4-51a, and a rotating shaft WN24-51b protruding from the drive motor WN24-51a,
An eccentric cam WN24-51c eccentric with respect to 4-6a is fixed. Further, the eccentric cam WN24-51c is provided separately from the eccentric cam WN24-51c.
4-42. Eccentric cam receiver WN24-42
Is a water passage WN24-4a and a water discharge hole WN24-
4b. The movable water passage WN24-4a is connected to the immovable water passage WN24-3a by a telescopic joint WN24-2.
Connected through.

In the configuration of the cleaning nozzle WN24 in FIG. 117, if the drive motor WN24-51a is driven, the eccentric cam WN24-51c rotates around the axis WN24-6a of the drive motor WN24-51a.
24-4a and the immovable water passage WN24-3a are connected by an elastic joint WN24-2, and the eccentric cam receiver WN24-42 contacts the eccentric cam WN24-51c separately. For this reason, the eccentric cam receiver 42 slides with respect to the eccentric cam WN24-51c, and the shaft WN24
Rotate or substantially rotate without rotating around -6a. At this time, the joint WN24-2 is connected to the eccentric cam receiver WN2.
4-42, drive motor WN24-51a
There is no such thing as not moving.

In the cleaning nozzle WN24, if the driving motor WN24-51a is driven and the cleaning water is supplied, the eccentric cam receiver WN24-42 becomes the shaft WN24-6a.
The spout hole WN24-4b also rotates or substantially rotates without self-rotation around the axis WN24-6a without rotating around the axis, and the washing water is spouted while rotating or substantially rotating. You. As a result, the cleaning water discharged from the water discharge holes WN24-4b has a predetermined trajectory that has been rotated or substantially rotated. As described above, the cleaning nozzle WN24 in the present reference example can move the water discharged from the water discharge hole WN24-4b and the washed water after the water discharge along a predetermined trajectory without providing a seal portion around the water discharge hole WN24-4b.

Also, the cleaning nozzle WN24 in FIG.
Moving water channel WN24-4a and immovable water channel WN24-3a
Since there is no seal portion between them, there is no loss due to frictional resistance of the seal portion, and there is no need to make the drive motor WN24-51a unnecessarily large, and a compact washing nozzle can be obtained. Further, since there is no seal portion, there is no problem that durability of packing or the like of the seal portion becomes a problem.

In particular, the water discharge holes WN24-4b are made smaller,
When performing water-saving cleaning at an increased water discharge speed, the pressure of the cleaning water in the water passage is high, so that there is a problem due to the use of the seal portion, that is, a problem such as a loss due to frictional resistance and durability of the packing of the seal portion. Great effect on

FIG. 118 shows a cleaning nozzle WN26 according to another reference example. FIG. 118 (a) is a sectional view, and FIG.
(B) is an oblique perspective view. The cleaning nozzle WN26 includes a water discharging unit WN26-4. The water discharge section WN26-4 is
Water inlet WN communicated via passage WN26-4c
26-4a, water discharge hole WN26-4b, and eccentric cam receiver W
N26-4d, and packing WN26-10
, And is freely supported by the support portion WN26-52 of the cleaning nozzle WN26, and can move around the support portion WN26-52 as a fulcrum. Eccentric cam receiver WN26-4
d is in contact with the eccentric cam WN26-20b, and the eccentric cam WN26-20b is connected to the water discharge section drive motor WN26-2.
0 and is eccentrically joined to the axis of rotation shaft WN26-20a. The water supply port WN26-2a is separated from the water supply port WN26-4a via an air gap so as to face the inside of the water inlet WN26-4a. In addition, the support part WN
The packing WN26-10 at 26-52 has a
It is preferable to have an appropriate flexibility so that the N26-4 can be supported without hindering the movement. This packing WN2
6-10 also has a function of preventing water from entering the inside of the washing nozzle, but if there is no problem even if water enters the inside of the washing nozzle, the packing WN26-10 may not be particularly necessary.

In the cleaning nozzle WN26, by supplying electricity to the water discharge section drive motor WN26-20, the water discharge section WN2
6-4, with the support portion WN26-52 as a fulcrum, a water supply port WN26- corresponding to the amount of eccentricity of the eccentric cam WN26-20b.
A conical motion, which is a relative displacement operation with respect to 2a, is performed. As a result, the cleaning water discharged from the water discharging holes WN26-4b draws a conical spiral trajectory, so that a wide range of cleaning can be performed at the cleaning target portion by discharging water in an annular trajectory. The water inlet WN26-2a and the water inlet WN26-4a are
The cleaning water, which is isolated through the gap and discharged from the water supply port WN26-2a, faces the inside of the water supply port WN26-4a during the operation of the water discharge section WN26-4a.
4a, the water supply section WN2
The connection of the water channel between 6-2 and the water discharging section WN26-4 can be performed in a non-contact manner. Thus, there is no connection between the water supply section WN26-2 and the water channel of the water discharge section WN26-4, and the water discharge section WN2
By performing a wide range of cleaning with only a small operation of 6-4, the driving force required for the motor is extremely small, and noise and vibration during the water discharge cleaning operation can be reduced. Noise and vibration due to the noise can be eliminated, and a more reliable and compact washing nozzle can be realized. In addition, since a wide range of cleaning can be performed with only a slight operation of the water discharge section, even when driven at a high speed, the moving speed of the predetermined path of the cleaning water can be maintained without increasing the vibration and noise generated by the driving. Can be easily changed to a high speed, variable from a low speed to a high speed, or quickly started up to a high speed. Furthermore, since the intermittent cycle at which the cleaning water is applied locally is determined by the moving speed of the cleaning water, when used for cleaning the human body, moving the cleaning water at a high speed provides a continuous and soft cleaning feeling. On the other hand, if the washing water is moved at a low speed, a washing feeling with strong intermittent stimulation can be obtained. For this reason, the washing feeling can be changed over time without changing the flow rate of the washing water, and it is possible to easily correspond to various tastes of the washing feeling. Furthermore, since the instantaneous water discharge amount can be reduced, the temperature control of the heat exchanger that makes the cleaning water warm can not follow the increase / decrease of the instantaneous water discharge flow rate, so that even when the washing feeling is made variable, a stable hot water temperature can be obtained. Water can be discharged.

The water inlet WN26-2a and the water inlet WN
26-4a are isolated through an air gap, and the water supply port WN26
-2a has a structure in which the water inlet WN26-4a is arranged so as to face the inside of the water inlet WN26-4a during the operation of the water discharging unit WN26-4, and therefore, the cleaning water in the cleaning nozzle WN26 When there is a place communicating the space WN26-11 in which the water discharge section WN26-4 is arranged and the outside of the cleaning nozzle WN26, when the cleaning water discharged from the water supply port WN26-2a enters the water inlet WN26-4a,
Air can be entrained by the ejector effect and air bubbles can be mixed in the washing water. As a result, bubbles can be mixed into the wash water without the need to provide a bubble mixing means separately from the water discharging operation device. As a result, it is possible to realize a highly reliable cleaning nozzle having a small size and a small number of parts, and it is possible to enhance the cleaning power, particularly when used for cleaning a human body. In this case,
By forcibly sending air into the space WN26-11 using an air pump, air bubbles can be mixed in the washing water. Further, for the purpose of preventing washing water from leaking between the water supply port WN26-2a and the water inlet WN26-4a, and for the purpose of enhancing the air mixing effect, the water discharge port WN26-a is provided.
4b is greater than or equal to the cross-sectional area of water inlet WN26-2a,
The vicinity of the water inlet WN26-4a of the passage WN26-4c has a gently tapered shape, and the passage WN26-4c preferably has a straight line portion for rectifying the washing water.

[0412] Further, in the scanning operation of the water inlet WN26-4a by the relative displacement operation of the water discharging section WN26-4,
The scanning area that is always secured is at least the water inlet WN
26-4a, the area occupied by the wash water discharged from the water supply port WN26-2a is larger than the area occupied by the water supply port WN26-2a.
The cleaning water discharged from 26-2a is surely supplied to the water inlet WN2.
6-4a, the cleaning water can be discharged from the water discharge hole WN26-4b without leaking to the other, to secure a stable cleaning flow rate, and to wash all the cleaning water discharged from the water supply port for the purpose of cleaning. It can be used.

[0413] Furthermore, in the configuration of the reference example, the water discharge hole WN2
The water supply port WN26-2a and the water inlet WN26-4 by moving the predetermined path without rotating the 6-4b.
The installation direction of the water supply port WN26 is not restricted.
-2a and the discharge direction of the wash water and the water discharge hole WN26-4
Since the discharge direction of the washing water from b can be set freely, the design and the degree of freedom in design can be improved.

A plurality of water outlets WN26-4b are provided for one water inlet WN26-4a, and a plurality of water inlets WN26-4 are provided for one water outlet WN26-4.
a and the water discharge holes WN26-4b.
In the case where a plurality of water inlets WN26-4a are installed, the same number or more of the water inlets WN26-2a corresponding to each of the water inlets is provided, so that one water outlet WN is provided.
26-4 alone, it is possible to evenly discharge water over a wider range, and it is possible to simultaneously discharge a plurality of cleaning waters with different air mixing rates and water discharge diameters from respective water supply ports WN26-2a,
In particular, when used for cleaning the human body, various cleaning feelings can be realized.

FIG. 119 is a sectional view showing a cleaning nozzle WN28 according to another reference example. The cleaning nozzle WN28 is
Water discharge state changing means WN for changing the average relative distance (gap distance) between water inlet WN28-2a and water inlet WN28-4a.
28-3. Water discharge state changing means WN28-3
Means that the water discharge section WN28-4 is provided with the washing water supply passage WN28-5.
1 connected. An O-ring WN28-3b is attached to the hole WN28-3a connected to the washing water supply passage WN28-51 to prevent water leakage.
N28-2 and the water discharge section WN28-4 are connected in a sealed state. Further, the water supply section WN28-2 causes the water supply section flange WN by the urging force of the spring WN28-3c.
28-3d is in contact with the water discharge state changing cam WN28-21b. The water discharge state changing motor WN28-21, which is joined to the water discharge state change cam WN28-21b, is driven to overcome the urging force of the spring WN28-3c to discharge the water discharge portion WN.
28-4 by moving the water inlet WN28-2.
a and the average relative distance between the water inlet WN28-4a (gap distance)
To change. By changing the amount of air mixed into the wash water, the washing power can be changed regardless of the flow rate of the wash water, the moving speed of the water discharge trajectory, and the water discharge range, especially when used for human body cleaning. It is also possible to change the washing feeling regardless of the flow rate of the washing water, the water discharge trajectory, the moving speed of the water discharge trajectory, and the water discharge range, and it is also possible to obtain a massage effect by changing the average relative distance over time. it can. In addition, as a method of changing the water discharge state,
The water outlet WN is moved by moving the water discharge section WN28-4.
A method of similarly changing the average relative distance between the water inlet WN28-4a and the water inlet WN28-4a by using a motor.
There is also a method of changing the area of the water supply port WN28-2a or the water inlet WN28-4a by providing a throttle plate or the like at the 2a or the water inlet WN28-4a.

FIG. 120 shows a cleaning nozzle WN30 according to another reference example. FIG. 120 (a) is a sectional view, and FIG.
(B) is a perspective view. The cleaning nozzle WN30 has a water discharge hole whose predetermined locus is a repetition of forward / reverse inversion movement.

In FIG. 120, the cleaning nozzle WN30
Is connected to a rotating shaft WN30-51b projecting from the drive motor WN30-51a.
The crank disk WN30-51d is provided integrally with the crank disk 51b. The crank disk WN30-51d is separately connected to one end of the connecting rod WN30-51e at the connecting portion WN30-A. Another end of the connecting rod WN30-51e is separately connected to the reversing disc WN30-43 at a connecting portion WN30-B. Since the connecting portions WN30-A and B are separately connected, slippage occurs and the crank disk W
If N30-51d rotates about axis WN30-6b, it has a crank mechanism. In addition, the reversing disc W
N30-43 is a movable water passage WN30-4a and a water discharge hole W
N30-4b. In addition, mobile waterway WN
30-4a and the immovable water passage WN30-3a are connected by an elastic joint WN30-2.

The drive motor WN30-5 having the configuration shown in FIG.
1a, the crank disk WN30-51d
Can be rotated in one direction, and the crank disk W
Despite the unidirectional rotation of N30-51d, the forward / reverse reversing disk WN30-43 repeats reversing movement around the axis WN30-6a in the forward and reverse directions by the crank mechanism via the connecting rod WN30-51e. Forward / reverse reversing disk WN3
0-43 is a forward / reverse reversal movement, so the joint WN30-2
May be unnecessarily twisted, blocking the water passage and impeding water flow, or the joint WN30-2 may be replaced by the reversing disc WN30.
There is no wrapping around -43 or the drive motor WN30-51a does not move.

[0419] Therefore, when the drive motor WN30-51a is driven to discharge the washing water, the forward / reverse inversion disk WN30
-43 repeats the forward / reverse inversion movement around the axis WN30-6a, so that the water discharge hole WN30-4b also repeats the forward / reverse inversion movement around the axis WN30-6a, and the cleaning water is forward / reverse in an arc shape or a substantially arc shape. Water is spouted while being inverted. Cleaning nozzle W
The movement of the water discharge hole WN30-4b of N30 and the predetermined trajectory of the wash water after water discharge is a repetition of forward / reverse inversion. Therefore, the moving water passage WN30-4a and the immovable water passage WN30-
Without providing a seal portion between the water discharge holes WN30.
-4b and the flush water after water discharge can be moved along a predetermined trajectory.

Further, as another effect of the cleaning nozzle WN30, if the twist of the joint WN30-2 is intentionally used, the cross-sectional area of the water passage in the joint WN30-2 can be changed over time, and Not only can you perform a great variety of washing feelings,
It is also highly effective in water-saving cleaning with improved cleaning efficiency.

FIG. 121 shows a cleaning nozzle WN32 according to another reference example. FIG. 121 (a) is a sectional view, and FIG.
(B) is a perspective view. The cleaning nozzle WN32 has a shaft W
A structure having a water discharge hole WN32-4b that moves along a predetermined trajectory without rotating around N32-6a is provided.

[0422] The cleaning nozzle WN32 is connected to the moving water passage WN3.
A ferromagnetic material WN32-52b is annularly arranged integrally with the movable water passage WN32-4a outside 2-4a. In addition, a gap WN32-5 is provided outside the ferromagnetic material WN32-52b.
2c is provided, and the electromagnetic coils WN32-52a are arranged in a ring shape. Since the electromagnetic coil WN32-52a may be embedded inside the cleaning nozzle WN32 due to its characteristics, the electromagnetic coil WN32-52a does not get wet by embedding the electromagnetic coil WN32-52a in the cleaning nozzle WN32. A plurality of ferromagnetic materials WN32-52b and electromagnetic coils WN32-52a are arranged in the circumferential direction. Moving water channel WN32-4a and immovable water channel WN32-
3a is connected by an elastic joint WN32-2. In addition, the water discharge hole WN32-4b, the moving water passage WN
32-4a and the eccentric cam receiver WN32-52b have a structure movable in the radial direction with respect to the shaft WN32-6a via the joint WN32-2.

In the configuration of the cleaning nozzle WN32 shown in FIG. 121, if the power supply to the electromagnetic coil WN32-52a is controlled, the magnetic field generated by the electromagnetic coil WN32-52a causes
An attractive force or a repulsive force is generated between the moving water passage WN32-4a and the ferromagnetic material WN32-52b integrally formed. In this case, the ferromagnetic material WN32-52b integrated with the water discharge hole WN32-4b and the moving water passage WN32-4a is used.
Is movable through the joint WN32-2.
A gap WN32-52c in the radial direction with respect to N32-6a
Any movement is possible within the range.

Thus, by controlling the energization of the electromagnetic coil WN32-52a and discharging the cleaning water, the water discharging hole WN32-52a is discharged.
4b rotates or substantially rotates or swings without rotating around the axis WN32-6a, and the washing water is discharged while rotating or substantially rotating or swinging.

FIG. 122 shows a cleaning nozzle WN34 according to another reference example, FIG. 122 (a) is a perspective view from the side of the cleaning nozzle, and FIG. 122 (b) is a cross-sectional view of the cleaning nozzle WN34 from another direction. It is.

In FIG. 122, in the cleaning nozzle WN34, a water pump WN3
4-2, the flow control valve WN34-3a and the rotary water discharging means WN34-4 are arranged in the water passage WN34-1a, and the cleaning water is discharged from the water discharging hole WN34-1b. The rotary water discharge means WN34-4 includes an impeller WN34-4a, an impeller casing WN34-4b, an impeller bearing WN34-4c,
It is composed of a seal part WN34-4d. However,
The presence / absence of the seal portion WN34-4d and the sealing property may be determined according to the usage state of the cleaning nozzle WN34. Further, the impeller WN34-4a and the water discharge hole WN34-1b are integrated. Further, the outlet WN34-31a of the flow control valve WN34-3a and the impeller WN34-4a are adjacent to each other, and the washing water is supplied to the impeller WN34 without decay of the kinetic energy flowing out of the outlet WN34-31a as much as possible.
-4a. The water pump WN34-2 and the flow control valve WN34-3a are separately and independently controlled by a control unit (not shown).

A cleaning nozzle WN3 according to the structure of FIG.
In 4, the washing water is pressurized by a water pump WN34-2, and is adjusted to a predetermined instantaneous discharge water amount by a flow control valve WN34-3a.
flows into a. Then, a part of the kinetic energy of the washing water is transmitted to the impeller WN34-4a, and the impeller WN3
While rotating 4-4a, water is discharged from the water discharge hole WN34-1b. Impeller WN34-4a and water discharge hole WN34-
1b is formed integrally, so that the impeller WN34-
When 4a rotates, the water discharge hole WN34-1b also rotates, and the cleaning water is discharged while rotating or substantially rotating.

If the capacity of the water pump WN34-2 is changed by the control unit and the flow rate regulating valve WN34-3a is controlled by the control unit so as to maintain a predetermined instantaneous discharge water amount, the instantaneous discharge water amount is constant. Despite that
The outflow kinetic energy from the wash water outlet WN34-31a can be changed, and the rotation speed of the impeller WN34-4a can be changed without depending on the instantaneous discharge water amount.

Therefore, the water discharge holes W in the cleaning nozzle WN34
Since only the vicinity of N34-1b is rotated using the kinetic energy of the cleaning water, the moving part is smaller than in the case where the cleaning nozzle WN34 itself is moved along a predetermined trajectory and the cleaning water is discharged while rotating or substantially rotating the cleaning water. In addition, there is almost no electric drive noise or vibration by the actuator, and it is very excellent in quietness and non-vibration. Furthermore, since only the vicinity of the water discharge hole WN34-1b is rotated by the rotary water discharge means WN34-4, it is easy to increase the rotation speed of the washing water or substantially the rotation speed, and by the effective dispersion of the washing water. , Water saving effect.

Also, since there is no direct electric drive part for rotating or substantially rotating the washing water, a very compact washing nozzle WN34 can be provided. Further, the durability of the electrically driven portion does not matter. Furthermore, unlike the case where power is transmitted by wiring, there is no leakage from wiring due to washing water,
Even when the washing nozzle WN34 itself is used in an environment where the washing nozzle WN34 is apt to be exposed to water, leakage does not cause a problem. Furthermore, there is no need for electrical wiring work up to the nozzle tip.

Further, the number of rotations for rotating or substantially rotating the washing water and the instantaneous discharge water amount can be controlled independently of each other, and the rotation speed of the washing water rotation or substantially rotation can be controlled at a low speed regardless of the increase or decrease of the instantaneous discharge water amount. It can be variably controlled from to high speed. Thus, when used as a washing nozzle for a local washing device, a washing head for washing a human body such as a shower head for washing a human body, a faucet outlet for hand washing, and a washing nozzle for washing a human body, it is possible to make the instantaneous discharge water amount constant and change only the feeling of washing. It is possible to sufficiently cope with various user's washing preferences despite the fact that the instantaneous discharge water amount is constant. In addition, since the instantaneous water discharge amount can be reduced, the temperature control of the heat exchanger that makes the washing water warm can not follow the increase or decrease of the instantaneous water discharge flow rate. Water can be spouted.

FIG. 123 shows a cleaning nozzle WN36 according to another reference example. FIG. 123 (a) is a plan view and FIG. 123 (b) is a side view. FIG. 123 (a)
As shown in the figure, the cleaning nozzle WN36 has an outlet WN36.
The shape of the water passage WN36-1a from -31a to the inflow to the impeller WN36-4a is rapidly expanded, and the air passage WN36-1c is provided in the rapidly expanded water passage WN36-1a, or the water passage WN36- The air intake port WN36-1c is provided in a portion where the rapid expansion of 1a cannot be avoided. The air inlet WN36-1c mixes air by the ejector effect of the washing water. By performing air mixing in this manner, when saving water for washing, or when using as a washing nozzle for washing a human body such as a washing nozzle of a local washing device, a shower head for washing a human body, or a faucet spout for hand washing, It is possible to make the washing feeling soft. The water pump WN36-2 and the flow control valve WN36-
By independently controlling 3a, the kinetic energy of the washing water can be changed in spite of a constant instantaneous discharge water amount, so that the air mixing ratio by the ejector effect can be changed, and the water saving rate according to the use situation. Can be changed, and various washing feelings can be obtained. When mixing air, forced mixing may be performed using an air pump.

Also, as shown in FIG. 123 (b), instead of the air intake WN36-1c, the flush water downstream of the impeller WN36-4a in the flow direction of the flush water is rapidly expanded through the water passage WN36-1a. With such a mechanism, energy loss in the water passage WN36-1a, which rapidly expands, can be suppressed, and the efficiency of the whole water passage WN36-1a system can be increased. In particular, the effect is great in a use situation where the instantaneous discharge water amount is small.

FIG. 124 shows a cleaning nozzle WN38 according to another reference example, and FIG. 124 (a) shows a cleaning nozzle WN38.
124B is a perspective view from the side of FIG.
FIG. 8 is a cross-sectional view of FIG. 8 from another direction.

The washing nozzle WN38 has two water passages. That is, the wash water is arranged in the flow passage WN38-1h in the order of the flow direction of the wash water, in order from the upstream in the flow direction of the wash water, and the flow control valve WN38-3b and the rotation protrusion WN38-1d.
Water is discharged from the water discharge hole WN38-1b. In addition, the different system water is supplied from the water pump WN3 in order from the upstream in the flow direction of the different system water.
8-2, the flow control valve WN38-3a and the rotary water discharge means WN38-4 are disposed in the water passage WN38-1a, and are discharged from the discharge port WN38-1e to the outside of the washing nozzle WN38. The rotation projecting portion WN38-1d is a rotating water passage WN.
38-12d and a water discharge hole WN38-1b.
Further, the rotary water discharge means WN38-4 is provided with an impeller WN38-
4A, an impeller casing WN38-4b, an impeller bearing WN38-4c, and a seal portion WN38-4d. In addition, the rotation protrusion WN38-1d and the cleaning nozzle WN
38, a sealing portion WN38-1d is provided between the rotating projection portion WN38-1d and the rotating water discharging means WN38-4.
Prevent leakage of cleaning water from other than b. However, the seal portion W
The presence / absence of N38-4d and the sealing portion WN38-1f and the sealing property may be determined according to the use condition of the cleaning nozzle. In addition, the rotating protrusion WN38-1d and the impeller WN38
-4a is integrally formed via a shaft WN38-1g. The outlet WN38-31a of the flow control valve WN38-3a and the impeller WN38-4a are adjacent to each other. -4
a. The water pump WN38-2 and the flow control valve WN38-3a are provided with a control unit (not shown).
The flow control valve WN38-3b
Is also controlled by the control unit.

If the cleaning water and the separate system water are discharged in the configuration of FIG. 124, the separate system water is pressurized by the water pump WN38-2, and the movement required to rotate or substantially rotate the cleaning water. Energy is given, and is adjusted to a predetermined instantaneous discharge water amount by the flow control valve WN38-3a,
Flow into the impeller WN38-4a, a part of the kinetic energy is transmitted to the impeller WN38-4a, and the impeller WN38-4
While rotating a, it is discharged to the outside of the cleaning nozzle WN38 from the discharge port WN38-1e. Impeller WN38-4a
And the water discharge hole WN38-1b are integrally formed,
If the impeller WN38-4a rotates, the water discharge hole WN38-
1b also rotates, and the washing water is discharged while rotating or substantially rotating.

If the control unit changes the capacity of the water pump WN38-2 or the opening of the flow control valve WN38-3a, the instantaneous discharge amount of the other system water can be changed, and the kinetic energy of the other system water can be changed. Can be changed, the rotation speed of the impeller WN38-4a can be changed by changing the capacity of the water pump WN38-2 or the opening degree of the flow control valve WN38-3a.

If the capacity of the water pump WN38-2 is changed by the control unit and the flow control valve WN38-3a is controlled by the control unit so as to maintain a predetermined instantaneous discharge water amount,
Although the instantaneous discharge amount of the separate system water is constant, the kinetic energy of the outflow from the outlet WN38-31a of the wash water can be changed, and thus the rotation speed of the impeller can be changed without changing the instantaneous discharge amount. .

Therefore, the instantaneous discharge amount of the separate system water is simply determined by controlling the capacity of the water pump WN38-2 or controlling the flow control valve W
Since it can be easily changed only by controlling the opening degree of N38-3a,
In a use environment where there is no limitation on the amount of water used in the separate system water, the rotation speed of the washing water can be changed easily or substantially without changing the instantaneous discharge amount of the washing water.

Further, the discharged system water may be used separately, or may be discharged to the sanitary ware bowl when used as a local washing nozzle. The water pump WN38-2 is
Provided before distributing the wash water and the separate system water, the distribution ratio is adjusted by the flow control valve WN38-3a and the flow control valve WN38-3b, and the kinetic energy of the separate system water is supplied to the rotary spouting means W
N38-4, or depending on the object to be cleaned, the water pump WN38-2 may be used only for separate system water, or the water pump WN38- may be used for cleaning water and separate system water, respectively.
2 may be used.

In the above reference example, the number of holes of the water discharge hole is described as one. However, the number of holes of the water discharge hole does not hinder the implementation of the present invention. The number may be determined by the designer.

In the above reference example, the use of a water pump has been described. However, in the case where tap water pressure is directly used, or where a storage tank is provided and the head of the storage tank can be used, the present invention is not sufficiently performed. If a high water pressure and / or instantaneous discharge water volume can be obtained, a kinetic energy of flowing water can be adjusted by providing a pressure control valve instead of a water pump.
The kinetic energy of the flowing water can be controlled in the same manner as when the control is performed using a water pump, and the above reference example can be implemented by using a pressure control valve.

FIG. 125 is an explanatory view showing each example of a cleaning nozzle WN40 according to another reference example. Cleaning nozzle WN4
0 is the impeller WN40-2 by the water pump WN40-1.
The cleaning water is spirally discharged by rotating. The shape of the impeller WN40-2 may be any as long as it converts the kinetic energy of the running water into rotational energy for rotating or substantially rotating the cleaning water by using a mechanical mechanism. , Centrifugal impeller WN40-2b as shown in FIG. 125 (b), and axial flow impeller WN40-2c as shown in FIG. 125 (c). And FIG.
As shown in (d), various configurations such as a mixed flow impeller WN40-2d can be adopted, and a configuration other than a cross flow impeller (not shown) may be adopted.

FIG. 126 shows a cleaning nozzle WN42 according to another reference example. FIG. 126 (a) is a sectional view, and FIG.
FIG. 126 (b) is a perspective view, FIG. 126 (c) is a layout diagram of the permanent magnet and the electromagnetic coil, and FIG. 126 (d) is a schematic diagram of the movement by the permanent magnet and the electromagnetic coil. Cleaning nozzle WN42
Has a water discharge hole WN42-4b that moves on a predetermined trajectory without rotating around the axis WN42-6a.

[0445] The cleaning nozzle WN42 is
2-44 is provided. The swing protrusions WN42-44 are
The water discharge hole WN42-4b, the moving water passage WN42-4a, and the permanent magnet WN42-53b are constituted by one body. The permanent magnets WN42-53b are arranged below the moving water passage WN42-4a in the axial direction of the shaft WN42-6a.
In the axial direction of the axis WN42-6a and the permanent magnet WN4
Below the 2-53b, the electromagnetic coil WN42-53a is disposed such that the magnetic pole generated by energization faces the direction of the axis WN42-6a. The swing protrusions WN42-44 are fixed by elastic flanges WN42-53c such that a gap WN42-53d is formed between the permanent magnet WN42-53b and the electromagnetic coil WN42-53a. Flange W
N42-53c is preferably made of a resin, but may be metal as long as it has a bellows structure. Electromagnetic coil W
Since N42-53a may be embedded in the main body of the cleaning nozzle WN42 due to its characteristics, the electromagnetic coil WN42-53a
a is embedded in the main body so that the electromagnetic coil WN42
-53a is not flooded. Mobile water channel WN42-
4a and the immovable water passage WN42-3a are connected by an elastic joint WN42-2. In addition, the spout hole WN42-
4b, moving water passage WN42-4a and permanent magnet WN42-
53b is a joint WN42-2 and a flange WN42-
The structure is movable in the radial direction with respect to the axis WN42-6a via the pin 53c.

The arrangement of the permanent magnets WN42-53b is shown in FIG.
As shown in FIG. 26 (c), four or more are arranged in a square or a rectangle, and each side is A, B, C, and D, respectively. The magnetic poles are circumferentially alternated in a square or rectangular shape. The arrangement of the electromagnetic coils WN42-53a is shown in FIG.
As shown in FIG. 26 (c), four or more are arranged in a grid pattern, and the vertical and horizontal sides of the grid pattern are respectively (a1, a2,
...), (b1, b2, ...). In addition, the permanent magnet WN
The relative arrangement of the electromagnetic coil WN42-53a and the electromagnetic coil WN42-53a is such that the side A of the permanent magnet WN42-53b and the side (a1, a2,. The (b1, b2, ...) sides of the coil are determined so as to be parallel or substantially parallel.

As shown in FIG. 126 (d), the magnetic poles are controlled by energizing the electromagnetic coils WN42-53a. Is supplied so that the magnetic pole becomes. As a result, the electromagnetic coil WN42-
53a, the permanent magnet WN42-53b
Between them, an attractive force or a repulsive force is generated, and the swing protrusions WN42-44 can be moved in the direction of the energized side.
Next, by energizing the side A of the permanent magnet WN42-53b and another side, for example, by energizing so that only the side b of the electromagnetic coil WN42-53a closest to the side B becomes an alternate magnetic pole,
The swing protrusions WN42-44 can be moved in the direction of the energized side. In this way, by repeating the energization for each side, the swing protrusion WN42-44 is
It can be swung around N42-6a.

Depending on the method of controlling the energization of the electromagnetic coils WN42-53a, for example, a1 side → b5 side → a5
When power is supplied in the order of side → b1 side → a1 side, the swing protrusion W
It is also possible to rotate or substantially rotate N42-44. Further, the (a1, a2,...) Side and the (b1, b2,
...) The swing amplitude can be arbitrarily changed by selecting the side to be energized.

In the cleaning nozzle WN42 shown in FIG.
If the power supply to the electromagnetic coils WN42-53a is controlled and the cleaning water is discharged, the water discharge holes WN42-4b are moved to the shaft WN42-6.
Washing water is discharged while arbitrarily oscillating or rotating or substantially rotating without rotating around a. At this time, the spout hole WN42-4
The movement of b and the predetermined trajectory of the cleaning water after the water discharge is arbitrary swinging or rotating or substantially rotating. The cleaning nozzle WN42 according to this configuration can move the water discharging hole WN42-4b and the cleaning water after water discharging along a predetermined trajectory with a simple configuration without providing a seal portion.

Further, as an effect of the cleaning nozzle WN42, when the cleaning nozzle WN42 is used as a local cleaning nozzle or a shower head for cleaning a human body, by controlling the energization of the electromagnetic coil WN42-53a, the user's desired cleaning area can be controlled at hand. It can be changed. Also, when used as a cleaning nozzle for a local cleaning device, by changing the cleaning area, despite performing cleaning with one type of water discharge hole,
It is possible to discharge the washing water with the optimum cleaning area for the hips and bidet cleaning, and the water discharge holes for the hips and bidet cleaning are used together in a form suitable for each cleaning more than in the reference example You can also.

FIG. 127 is a sectional view showing a cleaning nozzle WN44 according to another reference example. The cleaning nozzle WN44 is
Check valve WN44-41 and flow regulating water stop valve WN44-42
And a water discharge oscillating unit WN44 that oscillates water discharge on a predetermined trajectory.
-70, and these are connected by a water supply channel WN44-44. FIG. 127 is an explanatory diagram illustrating the configuration of the flow regulating water stop valve WN44-42. Flow control water stop valve WN44-42
The rotating ceramic disks WN44-46, which are rotated by the fixed ceramic disks WN44-45 and the flow adjusting stepping motors WN44-47, change the flow path area depending on their rotation positions to adjust or stop the flow rate of the washing water. Rotating ceramic disk WN44-4
6 is always pushed against the fixed ceramic disk WN44-45 by springs WN44-48 so as not to cause leakage from the water stopping surface particularly when water is stopped. Further, the water discharge oscillating unit WN44-70 includes a water discharge unit space WN44-71 connected to the water supply passage WN44-44, a nozzle unit WN44-72 that oscillates and discharges cleaning water, and a nozzle unit WN4.
Swing cam W for swinging 4-72 along a predetermined locus
N44-73, and a swing motor WN44-74 for rotating the cam at a predetermined number of revolutions. The tip of the nozzle portion WN44-72 is swingably connected to the nozzle body, and the swing cam WN arranged on the opposite side.
44-73 is always inclined at a fixed angle by pressing the inner surface of the nozzle portion WN44-72. Also,
The nozzle portion WN44-72 has a straight line portion, and a part thereof is always connected to a hole communicating with the water discharge space WN44-71 and the water discharge hole WN44-75.

The flow of water inside the cleaning nozzle WN44 will be described in detail. When the user instructs washing, the flow regulating stepping motor WN of the flow regulating water stop valve WN44-42.
44-47 and the rotating ceramic disk WN44-46 connected thereto rotate. When the positions of the grooves provided in the rotating ceramic disks WN44-46 and the holes provided in the fixed ceramic disks WN44-45 overlap with each other, a water supply passage is formed and washing water starts flowing. FIG.
Reference numeral 8 denotes a rotating ceramic disk WN44-46 and a fixed ceramic disk WN44-
It is explanatory drawing which shows the shape of 45 grooves. As described above, since the water supply passage formed by the rotating ceramic disk WN44-46 and the fixed ceramic disk WN44-45 is formed so that the cross-sectional area changes depending on the rotational position, it is possible to control not only the water stoppage but also the flow rate. is there.

As described above, the flow regulating water stop valve WN44-42
Is installed near the water discharge holes WN44-75, and especially, is installed inside the washing nozzle WN44, so that a flexible portion connecting a movable portion and a fixed portion when the washing nozzle WN44 is advanced and retracted before and after washing. Because there is no
Responsiveness of flow rate adjustment and water stoppage / water passage is extremely fast, and it can sufficiently follow the case where water stoppage / water passage is repeated at high speed or the flow rate is changed in a short cycle. In addition, reliable control is possible with less influence of the water supply pipe.

The check valve WN44-41 mounted on the upstream side of the flow regulating water valve WN44-42 is for preventing sewage from flowing backward from the water discharge hole. Since the check valve WN44-41 is attached near the water discharge hole WN44-75, the check valve WN44-41 is less affected by the water supply pipe and can be reliably controlled.

[0455] By the operation of the flow regulating water stop valve WN44-42,
When the water supply is started, the cleaning water is supplied to the check valve WN44-4.
1. Water supply channel WN44-44, flow regulating water stop valve WN44-4
2. Water supply channel WN44-44, water discharge swinging part WN44-70
And discharged from the water discharge holes WN44-75. Here, in accordance with the selection of the cleaning mode selected by the user, the control of the flow regulating water stop valve WN44-42 and the control of the water discharge oscillating section WN44-70 can be combined to perform the cleaning as desired. That is, when the cleaning mode is selected, an electric signal is sent from the electric control device WN44-40, and the oscillating motor WN44-74 and the oscillating cam W connected thereto are transmitted.
N44-73 rotates. Swing cam WN44-73
Presses the inner surface of the concave portion of the nozzle portion WN44-72 outward, thereby giving the nozzle portion WN44-72 a tilt. However, when the swing cam WN44-73 rotates, the nozzle portion WN44-72 tilts. Changes at a predetermined angle in time. The direction of water discharge is determined by the water discharge hole WN44-
It is determined by the inclination of the linear part immediately before 75, but since the inclination of this linear part changes over time by the swing cams WN44-73, the water discharge direction changes along a predetermined locus over time. In addition, since a part of the straight line portion immediately before the water discharge holes WN44-75 communicates with the water discharge space WN44-71, it is configured such that water can flow even when the nozzle portion WN44-72 is inclined at any angle. Have been.

As described above, since the water discharge oscillating portion WN44-70 is installed immediately before the water discharge hole WN44-75, the movable portion for water discharge oscillating is made of a very small component. Therefore, the water discharge oscillating portions WN44-70 can be oscillated with a motor having a small torque, vibration and noise are small, and the reliability and reliability of the driving portion are greatly improved. In addition, high-speed swinging is possible, and the nozzle portion WN44-7 can be used.
The swing locus can be freely set by the shape of the inner surface of the second concave portion. Further, since the nozzle portions WN44-72 operate based on the electric signal, reliable and stepless control can be freely performed, and fast responsive control is also possible.

In the cleaning nozzle WN44, the oscillating motor WN44-74 is operated based on the electric signal. For example, an electric signal may be used as a trigger by using such a method.

FIG. 129 is a sectional view showing a cleaning nozzle WN46 according to another reference example. The cleaning nozzle WN46 shown in FIG. 129 has the electromagnetic coils WN46-52a arranged in a conical shape, and the moving water passage WN46-4a is connected to the shaft WN46.
-6a, it is possible to rotate or substantially rotate or swing around the axis WN46-6a without rotating around the axis WN46-6a. Further, since the angle Α can be changed by controlling the energization of the electromagnetic coils WN46-52a, it is possible to discharge the washing water while rotating or substantially rotating or swinging at an arbitrary spread angle. The spout hole WN46-4b in the cleaning nozzle WN46 is connected to the shaft WN4.
Since the direction with respect to 6-6a can be arbitrarily changed, the water discharge trajectory is rotated or substantially rotated or arbitrarily rocked. In addition, a seal portion is not particularly required around the water discharge hole WN46-4b, and the configuration can be simplified.

When the washing nozzle WN46 is used as a local washing nozzle or a shower head for washing a human body, the user can change the washing area desired by the user at hand by controlling the energization of the electromagnetic coil WN46-52a. It is also possible. In addition, when used as a cleaning nozzle for a local cleaning device, the cleaning area is changed, so that cleaning is performed with one type of water discharge hole. It is possible to discharge water, and it is also possible to use the water discharge holes for buttocks cleaning and bidet cleaning in a form more suitable for each cleaning than in the combined use in the reference example.

FIG. 130 is a sectional view showing a cleaning nozzle WN48 according to another reference example and a modified example thereof. FIG.
In the cleaning nozzle WN48 shown in FIG.
8-5a is arranged in a conical shape, and the side of the mover WN48-5b close to the water discharge hole WN48-4b has an elastic fixing tool W.
It is fixed with N48-51d. Mover WN48-5b
Moves in a predetermined locus in a conical shape, and the washing water is also discharged in a predetermined locus in a conical shape.
When the distance is much larger than the distance from the armature WN48-5a to the armature WN48-5a, the amount of energization to the armature WN48-5a is variably controlled, and the conical spread angle WN48-α of the armature WN48-5b is reduced. The spread of the cleaning water can be greatly changed by a slight change, and the cleaning area can be largely changed by a slight difference in the moving distance of the mover WN48-5b. The cleaning nozzle WN48 shown in FIG.
As shown in FIG. 1B, if the moving distance of the conical shape is small, FIG.
The elastic fixture WN48-51 shown in FIG.
Instead of d, the locus moving projection WN48-4 may be provided with a conical clearance with the flange WN48-52d so as to receive the flange WN48-52d. Further, the conical spread of the armature WN48-5a is changed to the cleaning nozzle WN48 shown in FIG.
As shown in FIG. 130C, the cleaning nozzle WN48 shown in FIG.
Inversely, the joint WN48 of the mover WN48-5b
By fixing the side close to -2 with the elastic fixture WN48-51d, it is possible to perform the same discharge of the cleaning water as in FIG.

Further, the direction of the magnetic pole generated by the armature WN48-5a is not arranged so that all the armatures WN48-5a face the center of the circumference.
5a, the magnetic poles are arranged in a direction deviating from the center of the circumference, the sizes of the ferromagnetic materials WN48-51b are different from each other, or the ferromagnetic materials WN48-51b and the armature WN4 are opposed to each other.
The gap WN48-5c between the armature WN48-5a and the ferromagnetic material WN48-5 can be made different from each other.
1b can be changed without changing the amount of current to each armature WN48-5a without changing the amount of current supplied to each armature WN48-5a. It is possible to move.

As described above, since the movement of the mover WN48-5b and the locus moving projection WN48-4 on the predetermined locus can be arbitrarily controlled, a desired place within the range to be cleaned can be mainly washed, or the desired location can be cleaned. The area can be changed as desired, and in the case of human body washing, various washing feelings in which the washing position and area change with time can be obtained.

FIG. 131 is a configuration diagram showing a cleaning nozzle WN50 according to another reference example. FIG. 131 (a) is a top view, and FIG. 131 (b) is a cross-sectional view from the side.

[0464] The washing nozzle WN50 is connected to the heat exchanger WN50.
-51, connected to the flow rate control water shutoff valve WN50-53. The water discharge part WN50-3 is provided with a water discharge hole WN50-31.
a and WN50-31b, water passage WN50-32b,
It consists of a valve box WN50-32c, a valve body WN50-32d, and the like. The distance from the water discharge hole WN50-31a to the center of the disk is configured to be larger than the water discharge hole WN50-31b. In addition, the spout hole WN50-
31a and WN50-31b are valve box WN50-32.
c, water passages WN50-32e and WN5, respectively.
They are connected at 0-32f. Also, the valve body WN50-3
2d is a stainless steel sphere, valve box WN50-32c
It can be freely moved and rotated inside. The water discharge section drive mechanism WN50-4 includes a motor WN50.
-41d, a shaft WN50-42b and the like. Water discharge part WN50-3 and water discharge part drive mechanism WN50-
4 are integrally formed via a shaft WN50-42b. Seal part WN50-34 and seal part W
The N50-35 is mounted so that the washing water does not leak from other than the water discharge holes WN50-31a and WN50-31b.

The motor WN50-41d of the water discharge section drive mechanism WN50-4 is controlled by the predetermined trajectory control means WN50-2. That is, the predetermined trajectory control means WN50
-2 controls the cleaning water at a predetermined locus and at a predetermined frequency by controlling the rotation of the motor WN50-41d by rotating the motor. With the configuration of FIG.
When −41 d rotates counterclockwise, the water discharging section WN50-3 also rotates counterclockwise, so that the valve body WN50-32d is
It moves in the direction opposite to the rotation direction in N50-32c, and closes the water passage WN50-32e. As a result, the washing water passes only through the water passage WN50-32f, and the water discharge hole WN50-32f is formed.
Water is discharged while drawing a predetermined trajectory only from 31b. When the rotation direction of the motor WN50-41d is clockwise, water is discharged only from the water discharge holes WN50-31a, contrary to the above. Therefore, since the water discharge holes WN50-31a and the water discharge holes WN50-31b have different distances from the center of rotation, the object to be driven can be changed by changing the rotation direction of the motor WN50-41d without changing the amount of power supply. Rotation radius of (water discharge hole and washing water) (moving range of predetermined locus)
Can be changed.

FIG. 132 shows a cleaning nozzle WN52 according to another reference example. FIG. 132 (a) is a sectional view, and FIG.
(B) is a perspective view of the main part. As shown in FIG. 132 (a), the ferromagnetic body WN52-51b, which is a component of the mover WN52-5b, has a locus moving protrusion WN52-4.
, A gap WN52-5c is provided below the ferromagnetic material WN52-51b, and a gap WN52-5 is further provided.
Armature WN52-5a is arranged below c. Ferromagnetic material W
The relative arrangement of N52-51b and armature WN52-5a is such that the ferromagnetic material WN52 is arranged as shown in FIG.
-51b and a plurality of armatures WN52-5a are circumferentially arranged at predetermined intervals, and each ferromagnetic material WN52-5-5
1b and armature WN52-5a are arranged so as to face each other. The direction of the magnetic pole of the armature WN52-5a generated by energization is set to face the opposite ferromagnetic material WN52-51b. The flange WN52-52b of the trajectory moving protrusion WN52-4 is instructed to have a conical clearance formed in the outer peripheral recess of the cleaning nozzle WN52. Movable element WN52-5b and locus moving protrusion WN5
2-4 is an elastic joint WN52-2 and a flange W
Through N52-52b, it is possible to move conically.

The material of the ferromagnetic material WN52-51b is a soft magnetic material (for example, Fe-Si [silicon steel], Fe-Ni [permalloy], Fe-Si-Al [Sendust], Mn-Zn ferrite, Crystalline alloy). In this case, any of the armatures WN
52-5a, the energized armature WN52
Attraction acts between −5a and the opposing ferromagnetic material WN52-51b, and the ferromagnetic material WN52-51b moves in the direction of the energized armature WN52-5a. Therefore,
Movable element WN52-5b and locus moving protrusion WN52-4
Tilts with respect to the non-energized state.

[0468] In this case, the order of energizing a plurality of armatures WN52-5a circumferentially arranged at a predetermined interval may be, for example, left or right without energizing the two armatures WN52-5a at the same time. The energized armature WN52-5 can be provided by sequentially energizing clockwise or energizing two adjacent armatures WN52-5a simultaneously and energizing counterclockwise or sequentially.
a and the attractive force acting between the ferromagnetic material WN52-51b sequentially moves left or right, so that the tilt of the mover WN52-5b also sequentially moves left or right, and the mover WN52-51b moves.
5b and the trajectory moving protrusion WN52-4 move in a conical shape without rotating left or right clockwise.

As the material of the ferromagnetic material WN52-51b, a hard magnetic material (for example, Fe-Ni-Co-Al [Alnico], Ba ferrite, rubber magnet, Sm-Co, Nd-Fe-B, etc.) may be used. it can. In this case, the ferromagnetic material WN52-51b
Armature WN52-5 with the N-pole or S-pole magnetic poles
armature WN52-
If a current is applied so that the magnetic pole generated on the side of the opposite ferromagnetic material WN52-51b by 5a is opposite to the magnetic pole of the opposite ferromagnetic material WN52-51b, the same as in the case of using a soft magnetic material, , The opposite ferromagnetic material WN52-5
1b and the armature WN52-5a generate an attractive force, so that the ferromagnetic material WN52-51b is opposed to the energized armature WN5-5a.
It moves in the direction of 2-5a (the mover WN52-5b and the locus moving protrusion WN52-4 are inclined with respect to the non-energized state).

Therefore, the order of energizing a plurality of armatures WN52-5a circumferentially arranged at predetermined intervals is determined, for example, by turning left or right without energizing the two armatures WN52-5a at the same time. To each other, or two adjacent armatures WN
By simultaneously energizing 52-5a and sequentially energizing left or clockwise, the attractive force between the energized armature WN52-5a and ferromagnetic material WN52-51b sequentially moves counterclockwise or clockwise. The tilt of the mover WN52-5b also sequentially moves to the left or clockwise, and the mover WN52-5b and the trajectory moving protrusion WN52-4 move in a conical manner without rotating left or right clockwise.

Further, of the armatures WN52-5a which are circumferentially arranged at a predetermined interval and which are energized,
5a and the armature WN52-5a on the opposite side of the circumference (hereinafter, referred to as the armature WN52-5a).
In the reference example, these two armatures WN52-5a are referred to as a pair armature WN52-5a), and a ferromagnetic material WN52-51b is used.
When a current is applied so that a repulsive force acts between the movable element WN5
The movement of the predetermined trajectory 2-5b can be performed more smoothly, which is suitable when a larger driving force is required. Further, the armature WN52-5a and the ferromagnetic material WN52
Armature WN5 without using the attractive force acting between
Even if the direction of energization to 2-5a is reversed to generate a repulsive force, and the repulsive force moves the predetermined trajectory, the same movement as that using the attractive force can be performed.

[0472] Therefore, when the cleaning water is discharged, the locus moving projection WN52-4 sequentially moves left or right in a conical shape, so that the cleaning water also moves while drawing a predetermined locus in a conical left or right direction. I do. Also, unlike the electric motor, no rotational force is generated in the circumferential direction, so that the locus moving protrusion WN52-4 does not rotate as in the case of driving the locus moving protrusion WN52-4 by the electric motor. , Joint WN
52-2 is a mover WN52-5b or a locus moving protrusion WN
There is no wrapping around 52-4 or malfunction.

Further, by changing the left or right clockwise energizing cycle, it is possible to change the moving speed of the predetermined trajectory of the mover WN52-5b, and, consequently, the trajectory moving projection WN52.
The drive speed of the drive target such as -4 and the wash water can be variably controlled. For example, when used as a washing nozzle for washing a human body, various washing feelings can be obtained according to the moving speed of the wash water.

Further, the energization order of the armature WN52-5a must be sequentially turned left or right (for example, the armature WN52-5a is moved back and forth by energization, and then is moved to another armature WN52-5a). When the pair of armatures WN52-5a are moved sequentially in another front-rear direction by energizing them and the paired armatures WN52-5a to be energized are sequentially switched, or a plurality of armatures WN52-5a are simultaneously energized.
, And there are countless patterns, such as a case where a plurality of switches that are sequentially energized are sequentially switched.), The armature WN52-5a
Arbitrarily controlled predetermined trajectory in accordance with the power supply order to
The mover WN52-5b can be moved.

Furthermore, if the armature WN52-5a is not arranged in a circumferential shape but is arranged in, for example, a U-shape or a polygonal shape, the mover WN52-5b and the driven object can be arranged in the armature WN52-5a. It can be moved along any combined locus.

Further, by changing the amount of current supplied to the armature WN52-5a, the armature WN52-5a and the ferromagnetic material WN
The strength of the attractive force or the repulsive force acting between the movable element WN52-5b and the moving distance of the movable element WN52-5b can be changed. Therefore, the mover WN52-
5b moves conically on a predetermined locus, and the washing water is also discharged on the conical predetermined locus.
When the distance from the armature WN52-5a is large compared to the distance from the armature WN52-5a, the amount of current supplied to the armature WN52-5a is variably controlled, and the conical spread angle α of the armature WN52-5b is slightly reduced. The spread of the washing water can be greatly changed only by changing the moving distance, and the washing area can be largely changed by a slight difference in the moving distance of the mover WN52-5b.

Further, some armatures WN52-5a are not arranged such that all armatures WN52-5a face the direction of the opposing ferromagnetic material WN52-51b. For -5a, the magnetic poles are arranged in a direction deviating from the direction of the opposing ferromagnetic material WN52-51b, the sizes of the ferromagnetic materials WN52-51b are different from each other, or the armature and the opposing ferromagnetic material WN52-51b are different. If the gaps WN52-5c between the armature WN52-5a and the ferromagnetic material WN are different from each other,
The strength of the attractive force or the repulsive force generated between the armature WN52-5b and the armature WN52-5b can be changed without changing the amount of current supplied to each armature WN52-5a. It is possible to move a predetermined locus.

In this manner, the movement of the mover WN52-5b and the locus moving projection WN52-4 on the predetermined locus can be controlled arbitrarily. The area can be changed as desired, and in the case of washing a human body, various washing feelings in which the washing position and area change with time can be obtained.

FIG. 133 shows a cleaning nozzle WN54 according to another reference example. FIG. 133 (a) is a sectional view of FIG.
(B) is an arrangement view of the actuator WN54-6.
The actuator WN54-6 includes a water discharging section W which is a mover.
N54-4 and armature WN54-6b. The water discharge part WN54-4 is made of a ferromagnetic material WN54-6a.
, Water inlet WN54-4a, and water outlet WN54-4b.
And a passage WN54-4c communicating the water inlet WN54-4a and the water discharge hole WN54-4b. Ferromagnetic material WN54
133a and a plurality of armatures WN54-6b are circumferentially arranged at predetermined intervals as shown in FIG. 133 (b).
6b are opposed to each other. The ferromagnetic material WN54-
An air gap is provided between 6a and the armature WN54-6b.
The water discharge part WN54-4 is provided to the support part WN54- with respect to the main body of the cleaning nozzle WN54 via the packing WN54-10.
52, and is freely supported by the support portion WN54-52.
Relative to the water supply port WN54-2a. In addition, water inlet WN54-2a
Are separated from each other via a gap so that the cleaning water to be discharged is directed into the water inlet WN54-4a. Further, the armature WN54-6b can be incorporated in the cleaning nozzle WN54 so as not to be wet. In this case, the packing WN54-10 may not be provided.

In the configuration shown in FIG. 133, the ferromagnetic material WN54-6 is used.
a is a soft magnetic material (for example, Fe—Si [silicon steel], Fe—Ni [permalloy], or Fe—Si—Al
[Sendust], Mn-Zn ferrite, amorphous alloy, or the like), if any one of the armatures WN54-6b is energized, the ferromagnetic material WN54-6a opposed to the energized armature WN54-6b Between the armature WN5 and the energized armature WN5
As the water moves in the direction of 4-6b, the water discharging section WN54-4
Tilt (deflect) with respect to the non-energized state. Therefore, a plurality of armatures WN54-6b circumferentially arranged at predetermined intervals.
The order of energizing the two armatures WN54
The current-carrying armature can be obtained by energizing the armature WN54-6b successively to the left or clockwise by simultaneously energizing the two armatures WN54-6b adjacently without energizing the motor −6b. Since the attractive force between the WN 54-6b and the ferromagnetic material WN 54-6a sequentially moves left or right, the inclination (deflection) of the water discharger WN 54-4 also sequentially turns left or right. The water discharging unit WN54-4 moves left or right without rotating.

In the structure shown in FIG. 133, the ferromagnetic material WN54-6 is used.
a is a hard magnetic material (eg, Fe-Ni-Co-
Al [Alnico], Ba ferrite, rubber magnet, Sm-
Co, Nd—Fe—B), the ferromagnetic material W
The N54 or N pole of N54-6a is arranged so that the magnetic pole of the N or S pole faces the facing armature WN54-6b.
The magnetic pole generated on the a side is the opposite ferromagnetic material WN54-6.
When the current is supplied so as to be opposite to the magnetic pole of a, the opposite ferromagnetic material WN
Attraction works between 54-6a and armature WN54-6b,
The ferromagnetic material WN54-6a is connected to the opposed energized armature W
It moves in the direction of N54-6b. Therefore, the water discharge section WN5
4-4 tilts (deflects) with respect to the non-energized state.

Therefore, the order of energizing the plurality of armatures WN54-6b circumferentially arranged at a predetermined interval is determined, for example, by turning left or right without energizing the two armatures WN54-6b at the same time. To each other, or two adjacent armatures WN
By simultaneously energizing 54-6b and sequentially energizing left or clockwise, the attractive force acting between the energized armature WN54-6b and ferromagnetic material WN54-6a sequentially moves counterclockwise or clockwise. The inclination (deflection) of the water discharging section WN54-4 also sequentially turns left or right. In addition, the water discharging section WN54-4
Moves left or right without rotating.

Further, the energized armature WN54-b of the plurality of armatures WN54-6b circumferentially arranged at a predetermined interval.
6b and the armature WN54-6b on the opposite side of the circumference (hereinafter referred to as
When the two armatures WN54-6b are referred to as a paired armature in the reference example so that a repulsive force acts between the two armatures WN54-6a and the ferromagnetic material WN54-6a, the predetermined locus of the water discharging portion WN54-4 moves. Can be performed more smoothly. Also,
Instead of utilizing the attractive force acting between the armature WN54-6b and the ferromagnetic material WN54-6a, the direction of energization to the armature WN54-6b is reversed to generate a repulsive force, and a predetermined locus is moved by the repulsive force. Even when the movement is performed, the same movement as in the case of using the attractive force can be performed.

In the structure shown in FIG. 133, if the actuator WN54-6 is driven in conjunction with the flushing of the washing water, the flushing section WN54-4 sequentially deflects clockwise or counterclockwise. Then, the washing water can be moved left or right in a predetermined locus. Moreover, only a slight deflection in the washing water spouting direction (actuator WN54-6)
A wide range of cleaning can be performed, albeit with a low driving load.

Further, by changing the left or right turning energizing cycle, the moving speed of the predetermined trajectory of the water discharging section WN54-4 can be changed, so that the moving speed of the predetermined trajectory of the washing water can be controlled.

If the amount of current supplied to the armature WN54-6b is changed, the armature WN54-6b and the ferromagnetic material WN5
4-6a, the strength of the attractive force or the repulsive force can be changed, so that the moving distance of the water discharging unit WN54-4 can be changed, and the inclination (the amount of deflection) of the water discharging unit WN54-4 can be changed. Can be variably controlled by controlling the amount of current supplied to the armature WN54-6b, and the amount of deflection of the cleaning water in the water discharge direction can be controlled, so that a wide range of cleaning and a narrow range of cleaning can be easily switched. be able to. further,
Since the cleaning area can be easily changed by only slightly changing the amount of deflection in the water discharge direction, it is only necessary to slightly change the amount of current supplied to the armature WN54-6b.

If the order of energizing the armature WN54-6b is not sequentially turned to the left or right (for example, the armature WN54-6b is moved back and forth by energizing it, then another pair of armature WN54-6b For example, when the armature WN54-6b is moved in another front-rear direction by energizing to sequentially switch the paired armatures WN54-6b to be energized, or when a plurality of armatures WN54-6b are simultaneously energized and simultaneously switched to a plurality of energized ones, The water discharger WN54-4 can be tilted (deflected) along an arbitrary controlled predetermined trajectory in accordance with the order of energizing the armature WN54-6b.
Various predetermined trajectories of the washing water can be moved. further,
If the armature WN54-6b is not arranged in a circumferential shape but arranged in, for example, a U-shape or a polygonal shape, the water discharging portion WN54-4 is inclined at an arbitrary locus corresponding to the arrangement of the armature WN54-6b (deflection). ), And the cleaning water can be moved along various predetermined trajectories.

[0488] Water inlet WN54-4a and water inlet WN54-
2a is isolated through a gap, and the water inlet WN is set so that the cleaning water discharged from the water supply port WN54-2a faces the inside of the water inlet WN54-4a during the operation of the water discharge section WN54-4.
By adopting the structure in which the water supply unit 54-4a is arranged, the water supply unit WN54-2 and the water discharge unit WN54-4 can be connected to each other in a non-contact manner.
Can draw an arbitrary movement trajectory within the movable range of, and in addition to the effect of the reference example, it is possible to draw various water trajectories of washing water as described above with only a slight deflection of only the water discharging part WN54-4. Can be easily done. Therefore, the cleaning can be efficiently performed with the cleaning area corresponding to the portion to be cleaned, and the cleaning range can be changed at a high speed. Therefore, it is easy to efficiently perform the cleaning over a wide range. In particular, when used for human body washing, a wide washing feeling in a wide range of washing and a spot-like washing feeling in a narrow washing can be easily used without increasing or decreasing the flow rate of washing water. Can be easily handled. Therefore, as in the case where the washing area is made variable by increasing or decreasing the instantaneous discharge water amount, the temperature adjustment control of the heat exchanger that makes the cleaning water warm can not follow the increase or decrease in the instantaneous discharge water amount.
Even when the washing area is changed, it is possible to perform the spouting at a stable hot water temperature.

In the cleaning nozzle WN54, the water inlet W
N54-4a and the water supply port WN54-2a are isolated via a gap, and the cleaning water discharged from the water supply port WN54-2a receives the water inlet WN5 during the operation of the water discharge section WN54-4.
By adopting a structure in which the water inlet WN54-4a is arranged so as to face the inside of 4-4a, it is possible to mix bubbles in the washing water by using an ejector effect or an air pump. Further, in the configuration of the reference example, the actuator WN54-6 includes the water discharge section WN54-4 and the water supply section WN.
It is also possible to form an integral structure with the device 54-2. For this reason, both the bubble mixing means and the actuator WN54-6 can be simultaneously and integrally configured in the water discharge section WN54-4 and the water supply section WN54-2, so that a more compact and highly reliable cleaning nozzle can be realized. Becomes This actuator WN54-6 can be applied to the cleaning nozzle shown in the reference example.

[0490] Of the pair of opposing ferromagnetic materials WN54-6a and armature WN54-6b, one or more pairs of ferromagnetic material WN54-6a and armature WN54-6b are formed into an elastic spring structure. However, the ferromagnetic material WN54-6
The cleaning water can be moved along a predetermined trajectory by using the attraction and / or repulsion acting between the armature a and the armature WN54-6b.

Also, in the scanning operation of the water inlet WN54-4a by the relative displacement operation of the water discharge section WN54-4,
The scanning area that is always secured is at least the water inlet WN
In addition to the area occupied by the cleaning water discharged from the water supply port WN 54-2a in the water supply port WN 54-4a,
The water inlet WN54-4a moves around the vicinity of the water inlet 54-4a, so that the scanning range of the water inlet WN54-4a and the shape of the opening of the water inlet are substantially the same. Therefore, water inlet WN5
The cleaning water discharged from 4-2a is surely supplied to the water inlet WN54.
-4a, the washing water does not leak to the other
N54-4b, water can be discharged from the water supply hole W. In addition to securing a stable flow rate of cleaning water and discharging water, all the cleaning water discharged from the water supply port can be used for cleaning.
The water discharge state of the cleaning water discharged from N54-4b can always be kept stable even if the water discharge unit WN54-4 moves.

Further, in the cleaning nozzle WN54, the water outlet WN54-2a and the water inlet WN5-4b move by a predetermined trajectory without rotating.
The installation direction of 4-4a is not restricted, and the water supply port W
N54-2a and the discharge direction of the wash water and the water discharge hole WN5.
The discharge direction of the cleaning water from 4-4b can be freely set.

In the cleaning nozzle WN54, one water inlet WN54-4a is connected to a plurality of water discharge holes WN54.
-4b, and a plurality of water inlets WN54-4a and water outlets WN54-4b can be provided in one water outlet WN54-4. It is also possible to have the same number or more of water supply ports WN54-2a corresponding to the water ports WN54-4a.

Also, with the configuration of the cleaning nozzle WN54, the amount of air mixed into the cleaning water can be changed.

FIG. 134 shows a cleaning nozzle WN56 according to another reference example. FIG. 134 (a) is a sectional view, and FIG.
(B) is a drive switching mechanism diagram depending on the rotation direction of the electric motor WN56-4c. The cleaning nozzle WN56 has a configuration in which the cleaning water moves along a predetermined path around the axis of the axis WN56-7.

As shown in FIG. 134 (a), the coupling WN56-A is connected to the rotating shaft WN56-41c of the electric motor WN56-4c, and the coupling WN5
The 6-A projection WN56-A1 is coupled to the coupling WN5.
6-B protrudes to the long groove WN56-B1. The coupling WN56-A has a structure that can slide in the long groove WN56-B1 using the long groove WN56-B1 as a guide. Further, the coupling WN56-B and the eccentric cam WN5
6-4d are connected, for example, as shown in FIG. 134 (b), the rotation of the electric motor WN56-4c in the left direction causes the protrusion WN56-A1 to reach the end WN56-B2 of the long groove WN56-B1. As it moves, coupling W
N56-B and the eccentric cam WN56-4d move upward in the drawing and rotate. Further, the electric motor WN56-4c
Is rotated rightward, the protrusion WN56-A1 moves to the end WN56-B3 of the long groove WN56-B1, so that the coupling WN56-B and the eccentric cam WN56-4.
d moves downward in the drawing and rotates.

[0497] The movable part WN56-4e is connected to the moving water passage WN.
56-3c, water discharge hole WN56-3d, and flange WN
56-41e and an eccentric cam receiver WN56-42e as constituent elements, and a movable water passage WN56-3c and an immovable water passage WN56-3e are provided with an elastic joint WN56-3.
f. An elastic packing WN56-3h is sandwiched between the flange WN56-41e and the flange receiver WN56-3g of the main body of the cleaning nozzle WN56. Therefore, the movable part W is moved so that the water discharge direction can be deflected three-dimensionally.
N56-4e is movable. Electric motor WN56-
4c does not receive the water pressure, so if it has a simple waterproof property, it does not have the packing WN56-3h, and the flange receiver WN56-3g and the flange WN56-41e can change the water discharge direction three-dimensionally. A predetermined clearance may be provided between them. In addition, the instantaneous discharge water volume adjustment of the wash water,
Performed by a flow control valve WN56-3b (not shown),
It is controlled by the control unit. Also, the electric motor WN56-4c
Is controlled by a control unit (not shown).

The eccentric cam WN56-4d and the eccentric cam receiver WN56-42e are in contact with each other, and the electric motor WN56-4c of the eccentric cam WN56-4d at the contact portion.
Moving part WN56-4e according to the amount of eccentricity from the rotation axis of
Deflects. As the eccentric cam WN56-4d rotates, the contact portion also sequentially moves clockwise or clockwise, so that the movable portion WN56-4e does not rotate according to the amount of eccentricity of the eccentric cam WN56-4d at the contact portion. The light is sequentially deflected three-dimensionally left or right.

In the configuration shown in FIG. 134, if the electric motor WN56-4c is driven in conjunction with
Since N56-4e sequentially deflects three-dimensionally to the left or right, the water discharge direction of the cleaning water is also three-dimensionally deflected, and the cleaning water is supplied to the cleaning nozzle WN56 with respect to the axis WN56-7 in the cleaning nozzle WN56. , Left or right in a predetermined trajectory. In addition, the three-dimensional slight deflection of the washing water spouting direction (electric motor WN56-4)
Although the driving load of c is small), a wide range of cleaning can be performed.

Also, by changing the rotation speed of the electric motor WN56-4c, the moving speed of the predetermined locus of the movable portion WN56-4e can be changed, so that the moving speed of the predetermined locus of the washing water can be controlled.

Further, by changing the direction of rotation of the electric motor WN56-4c clockwise or counterclockwise, the amount of eccentricity at the contact portion between the eccentric cam WN56-4d and the eccentric cam receiver WN56-42e can be changed. The size (deflection amount) of the three-dimensional inclination of the WN56-4e can be variably controlled by controlling the rotation direction of the electric motor WN56-4c, and thus the three-dimensional deflection amount of the washing water spouting direction can be controlled. Therefore, switching between cleaning of a wide range and cleaning of a narrow range can be performed only by changing the rotation direction of the electric motor WN56-4c. Further, since the cleaning area can be easily changed only by slightly changing the deflection amount in the water discharge direction three-dimensionally, it is not necessary to increase the size of the eccentric cam WN56-4d and the eccentric cam receiver WN56-42e.

FIG. 135 shows a cleaning nozzle WN58 according to another reference example. FIG. 135 (a) is a sectional view, and FIG.
FIG. 13B is a cross-sectional view taken along the line AA in FIG.
FIG. 5C is a top view near the elastic body WN58-4 provided near the movable portion WN58-2.

[0503] The cleaning nozzle WN58 is provided with moving means WN58.
-3 and a movable portion WN58-2. The moving means WN58-3 is attached to a rotating shaft of the electric motor WN58-3c and the electric motor WN58-3c.
Eccentric cam WN58- eccentric from the rotation shaft of N58-3c
3D, and an annular follower WN58-3e separately contacting the eccentric cam WN58-3d. Annular follower WN58-
3e is also a component of the movable part WN58-2.

The movable part WN58-2 is an elastic body WN58-
4 is supported by the main body of the cleaning nozzle WN58.
The elastic body WN58-4 has a semi-ring-shaped portion WN58-41b.
And a spring-shaped resin WN58-4 having flange portions WN58-42b at both ends of a semi-ring-shaped portion WN58-41b.
b and sheet-shaped rubber WN58-4c, and the movable portion WN58-2 is supported by the flange portion WN58-42b with respect to the main body of the cleaning nozzle WN58. Flange W
N58-42b may be integrally formed with the movable portion WN58-2 and the main body of the cleaning nozzle WN58, or may be bonded or welded. Sheet shape rubber WN58-4
c is welded to the movable part WN58-2 and the main body of the cleaning nozzle WN58 so as to spatially disconnect the inside and the outside of the cleaning nozzle. Therefore, the spring-shaped resin WN58-4b and the sheet-shaped rubber WN58-4c may be formed integrally or may be separated. In addition, the spring-shaped resin WN58-4b can further improve the durability when the fixing position of the cleaning nozzle WN58 to the main body is determined in accordance with the distribution of the load applied to the elastic body WN58-4.

[0504] By the rotation of the electric motor WN58-3c,
The eccentric cam WN58-3d is connected to the annular follower WN58-3e and the movable portion WN58-2 in contact with each other in accordance with the eccentricity ratio.
Is moved without rotating in one direction continuously,
The washing water spouted from the spout hole WN58-2b on the movable part WN58-2 can be swung. Further, since the water discharge hole WN58-2b is supported by the spring-shaped resin WN58-4b, the cleaning water is conically discharged in a movement range smaller than the movement of the annular follower WN58-3e. Further, since the cleaning water is discharged while entraining air from the ejector port WN58-2c, it is possible to improve water-saving cleaning and detergency due to the incorporation of air, and to improve the feeling of cleaning in the case of human body cleaning.

Further, the sheet-shaped rubber WN58-4c is
The sheet-shaped rubber WN58-4c can be integrated with the movable part WN58-2 and the cleaning nozzle WN58 by screwing, bonding, or insert molding. Furthermore, sheet-shaped rubber WN58-4c
Instead of rubber, the main body of the cleaning nozzle WN58 and the movable portion WN58-2 may be formed in two colors by using an elastomer instead of rubber.

Therefore, the electric motor WN58-3c as the moving means WN58-3, the eccentric cam WN58-3d, the annular follower WN58-3e, and the spring-shaped resin WN58
-4b and the sheet-shaped rubber WN58-4c can stably discharge the conical water of the cleaning water, and use the electric motor WN58-3c, so that the movable portion WN58-2 is used.
The effect similar to that described in the first reference example can be simply and easily obtained, except that the effect of performing the cleaning in a narrow range to a wide range and the effect of making the swing locus (cleaning locus) variable by a slight change in the movement of It can be implemented reliably.

Further, the spring-shaped resin WN58-4b may be made of metal. However, in this case, it is preferable to select a shape or a material (for example, stainless steel) resistant to rust or to perform a rust prevention process, as necessary, in order to prevent rust and the like due to being wet.

The movable part WN58-2 has a configuration in which water is discharged in a conical shape. However, the movable part WN58-2 is a pendulum-shaped water discharge that deflects the cleaning water in only two directions, or an oscillating water discharge that does not deflect the water discharging direction of the cleaning water. You may.

FIG. 136 is an explanatory diagram showing a cleaning nozzle WN60 according to another reference example. The cleaning nozzle WN60 is
A water supply system for supplying the cleaning water and an air system for mixing the compressed air into the cleaning water and oscillating the rotary oscillator WN60-26 are provided. The flow of the washing water is, in order from the upstream, a water pump WN60-11, a flow control valve WN60.
-12, water supply channel WN60-13, rotation swing means WN60
-14, through the water discharge passage WN60-25, the water discharge hole WN60-
Water is discharged from 15. The air flow path has two systems, and the first air flow is, in order from the upstream, the air pump AP60-16,
First air valve AP60-17a, first air flow path A
After passing through P60-18a, it enters the rotation swing means WN60-14, and transmits the kinetic energy of air to the air port AP60.
From -19, it is discharged outside the cleaning nozzle WN60. Also, the second air flow is based on the air pump AP60-16,
The second air valve AP60-17b passes through the second air flow path AP60-18b and passes through the bubble mixing means AP60-20.
And mixed into the water in the water discharge channel WN60-25 and discharged together with the washing water. The rotation swing means WN60-14 is
Air turbine AP60-21 and eccentric cam WN60-
22, a bearing WN60-23, and a flexible joint WN60
-24, the rotary oscillator WN60-26, and the water discharge channel WN6.
0-25 and a spout hole WN60-15. Air turbine AP60-21 and eccentric cam WN60
-22 are integrally formed, and this is the bearing WN60.
Supported by -23. The air is in the first air flow path A
When the air flows into the air turbine AP60-21 through P60-18a, the air turbine AP60-21 and the eccentric cam WN60-22 rotate by the kinetic energy of the air. The eccentric cam WN60-22 causes the oscillating body WN60-26 to move by drawing a predetermined trajectory in the horizontal direction by the eccentric portion. The trajectory is determined by the notch shape of the rotary oscillator WN60-26. Rotating rocker WN60-26 and water discharge channel W
N60-25 are integrally fixed, and these are fixed by a swing fixing portion WN60-29 at the tip of the water discharge passage WN60-25 so that they can swing in the horizontal direction around the rotary oscillator WN60-26. Has become. The tilt of the water discharge passage WN60-25 is changed by the swing, and the water discharge direction of the washing water is changed. Air bubble mixing means AP60-
20 is an air chamber AP60-27 and a water discharge channel WN60-25.
Is constituted by a porous body WN60-28 provided on the outer wall. When the air flows into the air chamber AP60-27 through the second air flow path AP60-18b and the pressure rises, the air passes through the porous body WN60-28 and the water discharge passage WN60-27.
The cleaning water is mixed in the cleaning water 25 and discharged together with the cleaning water.

[0511] In the cleaning nozzle WN60 of FIG.
If the flush water is directed, the flush water is supplied to the water pump WN60.
At the same time when the pressure is increased by -11, the flow control valve WN
The water amount is adjusted to a predetermined instantaneous discharge amount by 60-12, and water is discharged from a water discharge hole WN60-15 through a water supply channel WN60-13 and a water discharge channel WN60-25.

[0512] If the user instructs the rotation of the washing water, the air pump AP60-16 pressurizes the air and at the same time, the first pump.
Air valve AP60-17a is opened, and the air passes through the first air flow path AP60-18a, and the air turbine AP60
-21 and rotate it, and the eccentric cam WN60-
22, the water discharge passage WN via the rotary rocking body WN60-26.
The angle of 60-25 changes and the washing water can be rotated or rocked.

As described above, only the vicinity of the water discharge hole WN60-15 in the cleaning nozzle WN60 is rotated by using the kinetic energy of the air. As compared with the case where water is discharged, the moving part is small, and there is almost no electric drive noise or vibration by the actuator, and the sound is very excellent in quietness and non-vibration. Further, the rotation swing means WN60-
14, only the vicinity of the water discharge holes WN60-15 is rotated, so that it is easy to shorten the rotation or oscillation cycle of the washing water, and there is a water saving effect due to the effective dispersion of the washing water.

[0514] Also, since there is no direct electric drive part for rotating or rocking the cleaning water, a very compact cleaning nozzle can be provided. Further, the durability of the electrically driven portion does not matter.
Furthermore, unlike the case where power is transmitted by wiring, there is no leakage from the wiring due to the cleaning water, and the leakage does not pose a problem when used in an environment where the cleaning nozzle itself is apt to be wet. Furthermore, there is no need for electrical wiring work up to the nozzle tip.

[0515] If the user gives an instruction to introduce air bubbles, the second air valve AP60-17b is opened, and air flows into the air chamber AP60-27 through the second air flow path AP60-18b. When the pressure in the air chamber AP60-27 increases, the air passes through the porous body WN60-28 and mixes into the cleaning water as a number of fine bubbles. Since a large amount of fine air bubbles can be mixed into the washing water, the water splash is reduced, and the washing power is very excellent even with a small amount of water. .

[0516] Further, the number of rotations for rotating or oscillating the washing water, the instantaneous discharge water amount, and the amount of air bubbles mixed can be independently controlled. The number can be variably controlled from low speed to high speed, and the amount of air bubbles can be controlled in a wide range, so cleaning for human body such as cleaning nozzle of local cleaning device, shower head for human body cleaning and faucet spout for hand washing. When used as a nozzle, it is possible to vary only the feeling of cleaning with a constant instantaneous discharge water amount, and, despite the constant instantaneous discharge water amount, can sufficiently cope with various users' washing preferences. Since the washing feeling can be varied without depending on the increase or decrease of the instantaneous water discharge amount, the temperature control of the heat exchanger that makes the washing water warm can not follow the increase or decrease of the instantaneous water discharge flow rate. Even when the variable can perform a stable hot water temperature water discharge.

Also, since an air pump for rotating or oscillating the spouting direction of the washing water and an air pump for mixing air bubbles are used, a compact and inexpensive apparatus is possible, and the oscillating and oscillating operation is performed at a high speed. It is possible to reduce the problem of flying splash, which is likely to occur at the time, by mixing bubbles, and to make the washing feeling soft.
Furthermore, if both are combined, drastic water saving washing becomes possible.

FIG. 137 is an explanatory view showing a cleaning nozzle WN61 according to another reference example. The cleaning nozzle WN61 is
A configuration is used in which a part of the compressed air from the air supply means for swinging the rotation swing means WN61-14 is used for the bubble mixing means AP61-20 for mixing air into the washing water. That is, a part of the air that has exited the rotation swinging means WN61-14 is supplied to the cleaning nozzle WN from the air port AP61-19.
61, but another part of the air is guided to the bubble mixing means AP61-20 through the air passage, and
Porous body WN61-28 provided on outer wall of N61-25
And is mixed into the wash water and discharged together with the wash water. According to this configuration, it is not possible to independently control the entrainment of air and the rotation swing, but it is possible to use a common air flow path in the cleaning nozzle WN61, and simultaneously perform the entrainment of air bubbles and the rotation swing with a small amount of air. This can be realized, and the air flow rate can be controlled independently of the amount of flushing water.

FIG. 138 shows a cleaning nozzle WN62 according to another reference example, in which FIG. 138 (a) is a diagram viewed from the side and FIG. 138 (b) is an explanatory diagram viewed from above. The cleaning nozzle WN62 is provided with a rotation swinging means WN62-14 for swinging the water discharge holes WN62-15 by compressed air. The flow of the washing water is, in order from the upstream, the water pump WN62-1.
1. Flow control valve WN62-12, water supply channel WN62-
13, rotation swing means WN62-14, water discharge passage WN62-
The water is discharged from the water discharge hole WN62-15 through the nozzle 25. The air flow path is, as shown in FIG.
After passing through the passage 62-16, it is divided into two routes, passes through the air valve AP62-17 and the air passage AP62-18, respectively, enters the rotary swing means WN62-14, and transmits the kinetic energy of the air to the cleaning nozzle. It is discharged outside WN62. The rotation swing means WN62-14 is provided with an air nozzle AP6.
2-30, a flexible joint WN62-24, a rotary rocker WN62-26, a spring WN62-31, a water discharge passage WN62-25, and a water discharge hole WN62-15. The rotary rocking body WN62-26 has a water discharge passage WN.
62-25 and is integrally fixed to the water discharge passage WN62-
25 Washing nozzle WN with swing fixed part WN62-29 at the tip
62 and can swing horizontally about the swing fixing portion WN62-29.

If the user instructs the washing water to rotate or swing, the air pump AP62-16 pressurizes the air, and at the same time, the two air valves AP62-17 open and close at a predetermined cycle to rotate and swing the air. Air nozzle A of means WN62-14
Send to P62-30. The sent compressed air is 2
The rotary oscillator W discharged from the air nozzle AP62-30 and held by the spring WN62-31
N62-26 is swung alternately from two directions. By this swing, the direction of water discharge can be changed by changing the inclination of the water discharge passage WN62-25 connected to the rotary rocking body WN62-26. Here, if the switching cycle of the air valve AP62-17 is shortened, it is possible to rotate or oscillate the water at a short cycle.
Is increased, the inclination of the water discharge passage WN62-25 changes greatly, and the water discharge direction and the water discharge area can be largely changed.

According to the structure of the cleaning nozzle WN62,
Since the area (spread) of the spouted water and the cycle of rotation or oscillation can be controlled independently of the flow rate, the cleaning nozzle WN62 can support various types of cleaning modes.
In addition, the washing nozzle WN62 can rotate or swing at high speed even with a small amount of air, so that the user can obtain a feeling of washing as if water is being spouted from the entire water spouting surface, and can greatly save water. It is.

FIG. 139 shows a cleaning nozzle WN64 according to another reference example. FIG. 139 (a) is a sectional view, and FIG.
(B) is a perspective view. The cleaning nozzle WN64 has a configuration in which the water discharge holes WN64-4b move reciprocally back and forth or left and right across the axis WN64-6a.

[0523] The cleaning nozzle WN64 is provided with a drive motor WN6.
4-51a and an axis WN64- of the rotating shaft WN64-51b integral with the rotating shaft WN64-51b.
6b is provided with an eccentric cam WN64-51c which is eccentric with respect to 6b. The follower portion WN64-45 is in contact with the eccentric cam WN64-51c. Follower WN64-4
5 is a moving water passage WN64-4a and a water discharge hole WN64-4.
b, and is urged in connection with the leaf spring WN64-51f. The movable water passage WN64-4a is provided with an elastic joint WN64-2 to the immovable water passage WN64-3a.
Connected through. In addition, follower part WN64-45
When the eccentric cam WN64-51c rotates about the axis WN64-6b and is pushed in the direction B shown in FIG. 139 (a), the plate spring WN64-51f receives a reaction force in the direction A. Therefore, by driving the drive motor WN64-51a, when the thick side of the eccentric cam WN64-51c faces the follower portion WN64-45, the follower portion W
N64-45 moves in the direction B, and the eccentric cam WN64-5
When the thinner side of 1c is opposed to the follower portion WN64-45, the follower portion WN is acted on by the resistance of the leaf spring WN64-51f.
64-45 moves in the A direction. Drive motor WN64-
If the 51a is driven continuously, the follower WN64-45 becomes
The shaft WN64-6a repeatedly moves back and forth with the shaft WN64-6a interposed therebetween.
It repeatedly moves back and forth with respect to 6a.

In the cleaning nozzle WN64 shown in FIG. 139, when the drive motor WN64-51a is driven to discharge the cleaning water, the water discharge holes WN64-4b move reciprocally back and forth with the shaft WN64-6a interposed therebetween. The washing water is discharged while swinging back and forth (drawing a predetermined trajectory).

FIG. 140 shows a cleaning nozzle WN66 according to another reference example. FIG. 140 (a) is a sectional view, and FIG.
(B) is a perspective view. The cleaning nozzle WN66 has a water discharge hole WN66- in which a predetermined trajectory repeats forward / reverse inversion movement.
4b.

[0527] The cleaning nozzle WN66 is connected to the electromagnetic coil WN6.
6-54a, a ferromagnetic body WN66-54b disposed opposite to the electromagnetic coil WN66-54a with a gap WN66-54c interposed therebetween, and a moving water passage WN66-4a and a water discharge hole WN66-4b. . Electromagnetic coil WN
Since the 66-54a may be embedded in the cleaning nozzle WN66 due to its characteristics, the electromagnetic coil WN66-54a is not wet by embedding the electromagnetic coil WN66-54a in the main body. The movable water passage WN66-4a is an elastic joint WN66-a to the immovable water passage WN66-3a.
2 are connected. Electromagnetic coil WN66-54
a and a spring WN66 on the opposite side to the axis WN66-6a.
−54d is provided. One end of the spring WN66-54d is in contact with a member constituting the moving water passage WN66-4a, and the other end of the spring WN66-54d is fixed to the cleaning nozzle body. In addition, the spout hole WN66-4
b, moving water passage WN66-4a and ferromagnetic substance WN66
The member constituting -54b has a structure that is movable back and forth across the shaft WN66-6a via the joint WN66-2.

In the cleaning nozzle WN66 shown in FIG.
If the energization of the electromagnetic coil WN66-54a is controlled, the magnetic field generated by the electromagnetic coil WN66-54a causes the ferromagnetic material WN6 integrally formed with the moving water passage WN66-4a.
An attractive force or a repulsive force is generated between 6-54b. Thereby, the water discharge hole WN66-4b and the moving water passage WN66-
4a and the ferromagnetic material WN66-54b are connected to the joint WN66-2.
, It moves reciprocally back and forth across the axis WN66-6a. Further, the amplitude of the forward and backward movement can be arbitrarily controlled within the range of the gap WN66-54c.

Also, by reversing the direction of current supply to the electromagnetic coil WN66-54a, the generated magnetic pole can be reversed. If a hard magnetic material (permanent magnet) is used as the ferromagnetic material WN66-54b, the spring WN66-54d can be used. Without using the water outlet hole WN66-4b on the shaft WN66-6.
It can be moved in a reciprocating motion repeatedly back and forth with respect to a.

In the cleaning nozzle WN66, when the power supply to the electromagnetic coils WN66-54a is controlled and the cleaning water is discharged, the water discharge holes WN66-4b are moved to the axis WN66-6a.
, The washing water is spouted back and forth (while drawing a predetermined trajectory).

It is preferable to use a resin tube as the elastic joint WN66-2 in the cleaning nozzle WN66, but a metal may be used as long as it has a bellows structure.

The ferromagnetic substance W used for the cleaning nozzle WN66
As a material of N66-54b, a hard magnetic material generally used for motors (for example, Fe-Ni-Co-A
l [Alnico], Ba ferrite, rubber magnet, Sm-C
o, Nd-Fe-B, etc.) and soft magnetic materials (for example, F
e-Si [silicon steel], Fe-Ni [permalloy], F
e-Si-Al [Sendust], Mn-Zn ferrite, amorphous alloy, etc.) can be considered.
The present invention can be implemented as long as it is a ferromagnetic material that generates an attractive force or a repulsive force by the magnetic field of 6-54a.

FIG. 141 shows a cleaning nozzle WN68 according to another reference example, and FIG. 141 (a) is a sectional view of FIG.
(B) is an oblique perspective view. The cleaning nozzle WN68 is a water discharge swinging unit WN6 that discharges water while moving the cleaning water in a predetermined trajectory by two-dimensionally deflecting the water discharging direction of the cleaning water.
8-8.

As shown in FIG. 141 (a), the water discharge oscillating portion WN68-8 is composed of a mover WN68-8a and two armatures WN68-8b.
a has two ferromagnetic bodies WN68-81a, a moving water passage WN68-3c, a water discharge hole WN68-3d, and a flange WN68-82a. Two armatures WN68-
8b is a movable element WN68 sandwiching the movable element WN68-8a.
-8a, two ferromagnetic bodies WN6
8-81a is arranged so as to face each armature WN68-8b. An air gap WN68-8c is provided between the ferromagnetic material WN68-81a and the armature WN68-8b. The moving water passage WN68-3c is an immovable water passage WN68.
-3e via an elastic joint WN68-3f. An elastic packing WN68-3h is interposed between the flange WN68-82a and the flange receiver WN68-3g. Therefore, the mover WN6
8-8a is movable so that the water discharge direction can be deflected two-dimensionally. Further, the armature WN68-8b can be incorporated in the main body of the cleaning nozzle WN68 so as not to be wet. In this case, the water discharge direction can be changed two-dimensionally without using the packing WN68-3h. As described above, a predetermined clearance may be provided between the flange receiver WN68-3g and the flange WN68-82a. In addition, the instantaneous discharge water amount adjustment of the wash water is performed by the flow control valve WN68-3.
b (not shown), and is controlled by a control unit (not shown). Further, the driving of the water discharge rocking unit WN68-8 is controlled by the control unit.

In the configuration of the cleaning nozzle WN68 in FIG. 141, the material of the ferromagnetic material WN68-81a is a soft magnetic material (eg, Fe—Si [silicon steel], Fe—Ni [permalloy], Fe—Si—Al [Sendust] and Mn-
(Zn ferrite, amorphous alloy, etc.), if any one of the armatures WN68-8b is energized, the ferromagnetic material WN68-
81a and the ferromagnetic material WN68-81a
Moves in the direction of the opposing energized armature WN68-8b. Therefore, the mover WN68-8a tilts (deflects) with respect to the non-energized state.

Thus, by alternately energizing the two armatures WN68-8b in order of energization, the attractive force acting between the energized armature WN68-8b and the ferromagnetic material WN68-81a generates an attractive force acting on the armature WN68. -8a works alternately before and after or left and right, so the tilt (deflection) of the mover WN68-8a
Are also changed two-dimensionally alternately.

The ferromagnetic material WN68-81a is made of a hard magnetic material (eg, Fe—Ni—Co—Al [Alnico], Ba ferrite, rubber magnet, Sm—Co, N
d-Fe-B), the ferromagnetic material WN68-
The armature WN6 to which the N-pole or S-pole of 81a is opposed
Armature WN arranged to face 8-8b and energized
The magnetic pole generated on the side of the opposing ferromagnetic substance WN68-81a by the ferromagnetic substance WN68-81a
When the current is supplied so as to be opposite to the magnetic pole of the ferromagnetic material WN6, as in the case where the soft magnetic material is used,
Attraction works between 8-81a and armature WN68-8b,
The ferromagnetic material WN68-81a moves in the direction of the opposing energized armature WN68-8b. Therefore, the mover WN
68-8a inclines (deflects) with respect to the non-energized state.

[0537] Further, the ferromagnetic material WN68-81 is connected to the energized armature WN68-8b and another armature WN68-8b.
a, the movable element WN
The movement of the predetermined locus of 68-8a can be performed more smoothly. Also, without using the attractive force acting between the armature WN68-8b and the ferromagnetic material WN68-81a, the direction of current supply to the armature WN68-8b is reversed to generate a repulsive force. Even if the movement is performed, it is possible to perform the same movement as in the case where the attractive force is used.

[0538] If the water discharge swinging unit WN68-8 is driven in conjunction with the discharge of the cleaning water, the movable element WN68-8a is two-dimensionally deflected. Deflects the cleaning water to the cleaning nozzle WN68 with respect to the axis WN.
It can be moved in a reciprocating reciprocating motion (predetermined locus) back and forth or left and right across 68-7. In addition, a wide range of washing can be performed with only a two-dimensional slight deflection in the washing water spouting direction (even though the driving load of the spout swinging unit WN68-8 is small).

If the energization cycle is changed, the movable element W
Since the moving speed of the predetermined locus of N68-8a can be changed, the moving speed of the predetermined locus of the washing water can be controlled.

Therefore, as in the case of a cleaning nozzle that performs two-dimensional deflection in the water discharge direction using a fluid element mechanism, the moving speed (oscillation frequency) of a predetermined trajectory increases or decreases according to the increase or decrease in the instantaneous discharge water amount. It is possible to easily control the moving speed (oscillation frequency) of a predetermined trajectory independently of the increase and decrease of the instantaneous discharge water amount, and it is necessary to change the cleaning flow rate as in the case of using a fluid element mechanism. Instead, cleaning can be performed at a moving speed suitable for the surface to be cleaned.

Further, when the feeling of washing becomes a problem in the washing of the human body, only the feeling of washing can be made variable while the amount of instantaneous discharge water is constant. In addition to being able to sufficiently respond to the taste of the user, the washing feeling can be varied without depending on the increase or decrease of the instantaneous discharge water amount. The temperature control of the heat exchanger does not fail to follow the increase or decrease in the instantaneous water discharge flow rate, and the stable hot water discharge can be performed even when the washing feeling is made variable.

Furthermore, since the cleaning nozzle WN68 itself is not driven and the driving portion is smaller than in the conventional case in which the cleaning water spouting direction is two-dimensionally deflected by an actuator disposed outside the cleaning nozzle, the predetermined path of the cleaning water Providing a compact cleaning nozzle and cleaning device that can easily increase the moving speed of the cleaning, change from low speed to high speed, start up at high speed at once, and increase the responsiveness of switching the cleaning area. can do. Also, in the case of human body washing, various washing feelings can be easily obtained as compared with the conventional case in which the washing water spouting direction is two-dimensionally deflected by an actuator outside the washing nozzle.

If the amount of current to the armature WN68-8b is changed, the armature WN68-8b and the ferromagnetic material WN6
Since the strength of the attractive force or the repulsive force acting between the mover WN68-8a and the mover WN68-8a can be changed, the magnitude of the two-dimensional inclination of the mover WN68-8a can be changed. Since the (deflection amount) can be variably controlled by controlling the amount of current supplied to the armature WN68-8b, and thus the two-dimensional deflection amount in the water discharge direction of the washing water can be controlled,
Switching between cleaning in a wide range and cleaning in a narrow range can be easily performed. Further, since the cleaning area can be easily changed only by slightly changing the amount of deflection in the water discharge direction two-dimensionally, it is only necessary to slightly change the amount of current supplied to the armature WN68-8b.

Therefore, switching between cleaning in a wide range and cleaning in a narrow range can be achieved by only slightly changing the amount of deflection in the water discharge direction (only by changing the amount of power to the armature WN68-8b). Good), as in the case of the cleaning nozzle using the fluid element mechanism, there is no problem that the amplitude (cleaning area) of the predetermined trajectory increases or decreases according to the increase or decrease of the instantaneous discharge water amount.
The responsiveness of switching the cleaning range can be easily performed at a high speed regardless of the increase or decrease of the instantaneous discharge water amount, and the cleaning can be performed with the cleaning area corresponding to the surface to be cleaned regardless of the increase or decrease of the instantaneous discharge water amount.

[0545] Furthermore, when the cleaning nozzle is held by hand for cleaning the human body, the cleaning area can be changed without greatly moving the hand, and when the cleaning nozzle is fixed, the cleaning area can be reduced without moving the human body or a part of the human body. Because it can be changed, even in the case where the movement of the body is inconvenient, even for elderly people and children, it is possible to vary the cleaning of a wide range and a narrow range without inconvenience.

[0546] Further, in the case of human body washing, a wide washing feeling in a wide range of washing and a spot-like washing feeling in a narrow washing can be easily used independently of the increase or decrease of the instantaneous discharge water amount, and further various washing feelings can be obtained. It can be easily handled.

Further, in the case of washing the human body, the temperature control of the heat exchanger that makes the washing water warm can not follow the increase or decrease in the instantaneous discharge water, as in the case where the washing area is made variable by increasing or decreasing the instantaneous discharge water amount. In other words, even when the cleaning area is made variable, it is possible to discharge water at a stable hot water temperature.

The cleaning nozzle WN68 can be configured such that one of the two opposing ferromagnetic materials WN68-81a and armature WN68-8b has an elastic spring structure, and the cleaning nozzle WN68 and the armature WN68-8b have the same structure. Utilizing the attraction and / or repulsion acting between the armatures WN68-8b, the cleaning water is moved relative to the cleaning nozzle WN68 in a reciprocating reciprocating motion (predetermined locus) back and forth or right and left across the axis WN68-7. be able to.

FIG. 142 is a perspective view showing a cleaning nozzle WN70 and a cleaning nozzle WN72 according to another reference example. The cleaning nozzle WN70 shown in FIG. 142 (a) includes a nozzle rotation motor WN70-41b on the side opposite to the water discharge hole, and the nozzle rotation motor WN70-41b
A structure for swinging the water discharge hole WN70-1 is provided. The cleaning nozzle WN72 shown in FIG. 142 (b) includes two nozzle front / rear drive motors WN72-41c and nozzle left / right drive motors WN72-41d. Then, the water discharge hole WN72-1 is moved to a predetermined locus.

FIG. 143 is an explanatory view showing a cleaning nozzle WN74 according to another reference example. The cleaning nozzle WN74 is
The fluid device WN74-1 is provided. This fluid element WN
74-1 oscillates the cleaning water discharged from the water discharge hole WN74-2 according to the flow velocity.

FIG. 144 is an explanatory view showing a cleaning nozzle WN76 according to another reference example. The cleaning nozzle WN76 is
The nozzle rotation motor WN76-41b moves the nozzle itself left and right, and the fluid element WN76-1 swings the cleaning water back and forth. The fluid element WN76-1 is
The cleaning water discharged from the water discharge hole WN76-2 is swung according to the flow velocity. According to the cleaning nozzle WN76, water can be discharged three-dimensionally from the water discharge hole WN76-2.

FIG. 145 is an explanatory view showing a cleaning nozzle WN77 according to another reference example. The cleaning nozzle WN77 is
A vibration motor 41e for vibrating the water discharge hole is provided, and the vibration of the vibration motor 41e is propagated to swing the cleaning water. Such a water discharging means by the vibration motor 41e may be combined with a configuration in which the nozzle itself moves. Further, a configuration in which these trajectory control units are combined may be employed.

FIG. 146 shows a cleaning nozzle WN78 according to another reference example, and FIG. 146 (a) is a schematic configuration diagram, and FIG.
6B is an explanatory diagram illustrating a state in which the water discharge direction is deflected right and left, and FIG. 146C is an explanatory diagram illustrating a state in which the water discharge direction is deflected forward and backward. Cleaning nozzle WN78
Is provided with a configuration for deflecting the water discharge direction of washing water three-dimensionally.

The front-rear deflection motor WN78-4a is fixed to a cleaning nozzle support (not shown), and its rotating shaft WN78-41a is connected to a nozzle guide WN78-21b. In addition, the left and right deflection motor WN78-4b
Is fixed to a nozzle guide WN78-21b, and its rotating shaft WN78-41b is connected to the cleaning nozzle WN78. Further, the rotation axis direction of the front-rear deflection motor WN78-4a is different from the rotation axis direction of the left-right deflection motor WN78-4b. Also, the cleaning nozzle W
N78 is supported by the nozzle guide WN78-21b so as to rotate in the left-right direction. The cleaning nozzle WN78 is controlled by the control unit CT78-5. That is, the control unit WN78-5 controls the instantaneous discharge water amount of the cleaning water by the flow control valve WN78-3b, and controls the driving of the front-rear deflection motor WN78-4a and the left-right deflection motor WN78-4b.

[0555] Therefore, if the control section WN78-5 discharges the washing water while switching and controlling the rotation direction of the left and right deflection motor WN78-4b, the control section WN78-5 changes the discharge direction of the washing water as shown in FIG. 146 (b). It can be deflected two-dimensionally. The control unit WN78-5 includes a front-rear deflection motor WN
If the cleaning water is spouted while switching and controlling the rotation direction of 78-4a, the spouting direction of the cleaning water can be deflected two-dimensionally back and forth as shown in FIG. 146 (c).

In the cleaning nozzle WN78, by driving the front / rear deflection motor WN78-4a and the left / right deflection motor WN78-4b in conjunction with the discharge of the cleaning water, the front / rear two-dimensional deflection in the water discharge direction and the left / right two-dimensional can be achieved. By combining the deflection, the water discharge direction of the cleaning water can be deflected three-dimensionally, and the cleaning water is discharged while moving along a predetermined trajectory. In addition, by the combination of the reversal frequency and the rotation angle by the front-rear deflection motor WN78-4a and the left-right deflection motor WN78-4b, the water discharge direction is not only sequentially deflected cyclically,
Various predetermined trajectories of the washing water can be moved.

Therefore, despite the small driving load of the front-rear deflection motor WN78-4a and the left-right deflection motor WN78-4b, it is possible to discharge water over a wide area by three-dimensional slight deflection in the direction of water discharge. it can.

Even when the reversing frequency of the front / rear deflection motor WN78-4a and the left / right deflection motor WN78-4b is driven at a high frequency, the driving load is small, so that vibration and noise generated by the driving can be reduced. Further, a front-rear deflection motor WN78-4a and a left-right deflection motor WN78
-4b makes it easy to increase the moving speed of a predetermined trajectory of the washing water, change it from a low speed to a high speed, or start it up to a high speed at once, regardless of the increase or decrease of the instantaneous discharge water amount. The cleaning can be performed at a moving speed suitable for the surface to be cleaned without depending on the cleaning speed. Besides, in the case of human washing,
Moving the washing water at a high speed gives a continuous and soft feeling of washing, while moving the washing water at a low speed gives a strong washing feeling with intermittent stimulation. Can be varied, and it is possible to easily cope with various tastes of washing feeling. Also, in the case of human body washing, as in the case where the feeling of washing is made variable by increasing or decreasing the amount of instantaneous water discharge, the temperature control of the heat exchanger that makes the wash water hot can not follow the increase or decrease of the instantaneous water discharge flow rate. In addition, even when the washing feeling is made variable, it is possible to perform the spouting at a stable hot water temperature.

Further, by performing a drive for slightly changing the rotation angle of the front-rear deflection motor WN78-4a and the left-right deflection motor WN78-4b, it is possible to switch between a wide range of cleaning and a narrow range of cleaning. The switching of the range can be easily performed at a high speed regardless of the increase or decrease in the instantaneous discharge water amount, and the washing can be performed with the cleaning area corresponding to the surface to be cleaned regardless of the increase or decrease in the instantaneous discharge water amount.

Further, when the washing nozzle WN78 is held by hand for washing the human body, the washing area can be changed without greatly moving the hand, and when the washing nozzle WN78 is fixed, the washing can be performed without moving the human body or a part of the human body. Because the area can be changed, even in the case where the movement of the body is inconvenient, or even for the elderly or children, it is possible to vary the washing of a wide area and a narrow area without inconvenience.

In the case of human body washing, a wide washing feeling in a wide range of washing and a spot-like washing feeling in a narrow washing can be easily used regardless of the increase or decrease of the instantaneous discharge water amount, and further various washing feelings can be obtained. It can be easily handled.

In the case of washing the human body, as in the case where the washing area is made variable by increasing or decreasing the instantaneous discharge water amount, the temperature adjustment control of the heat exchanger that makes the wash water hot cannot follow the increase or decrease in the instantaneous discharge water amount. In other words, even when the cleaning area is made variable, it is possible to discharge water at a stable hot water temperature.

Further, when the deflection in the water discharge direction is sequentially repeated cyclically by the combination of the reversal frequency and the rotation angle by the front-rear deflection motor WN78-4a and the left-right deflection motor WN78-4b, a wide range of washing is reduced. The cleaning can be smoothly changed to the range of cleaning, and the cleaning object adhered to the surface to be cleaned can be cleaned so as to be sequentially collected at the center of the circular cleaning. Therefore, not only does the cleaning object adhering to the surface to be cleaned be unnecessarily spread, but also the cleaning efficiency can be increased by collecting the cleaning objects at one place.

FIG. 147 is an explanatory diagram for explaining a local cleaning apparatus having a cleaning nozzle WN80 according to another embodiment. The cleaning nozzle WN80 includes an intermittent discharge unit WN80-4.
It has. The washing nozzle WN80 includes a water supply means WN80-1, a heat exchanger TH80-2, and a hot water storage section TH.
Wash water is supplied via 80-5. Water supply means WN8
0-1 is a water pump WN80-13, a water stop valve WN80-
14 and a flow control valve WN80-15. Wash water from the water supply means WN80-1 is supplied to the heat exchanger T
H80-2 is supplied to the hot water storage section TH80-5. The intermittent discharge means WN80-4 includes an electromagnetic valve WN80-43. The electromagnetic valves WN80-43 turn on and off the water passage at a predetermined intermittent frequency. This electromagnetic valve WN
By turning on / off by 80-43, the discharge of the washing water becomes intermittent as shown in FIG.
As shown in (b), the pulsation occurs. Since the electromagnetic valve WN80-43 can change its on / off time from a low speed to a high speed, the intermittent frequency can be easily changed from a high value to a low value. from these things,
The above water pump WN80-13 and the flow control valve WN8
0-15, the electromagnetic valve WN80-43 functions as the "water discharge means" according to the present invention, and the electronic control device or control unit that controls these functions is the "water discharge control means" according to the present invention;
It functions as "control means" or "variation control executing means". The same applies to the following embodiments. The position where the intermittent discharge means WN80-4 is disposed is such that the lower the downstream side of the water passage, the better the followability of intermittent discharge.
Is best right before Further, since the hot water storage portion TH80-5 is provided between the heat exchanger TH80-2 and the intermittent discharge means WN80-4, it is possible to reduce the temporal fluctuation of the washing water passing through the heat exchanger TH80-2. As a result, the temperature control of the washing water in the heat exchanger TH80-2 becomes easy. In the case of intermittent discharge in which the discharge of the wash water is performed intermittently, the control of the instantaneous discharge water amount, the flow rate of the wash water, and the space volume ratio of the wash water is performed by using the water pump WN80-13 or the flow rate control valve WN80-15 in time. An electromagnetic valve WN80- for controlling a flush water discharge time in an intermittent cycle or one intermittent cycle.
43 is controlled. Water pump WN80-1
3 and the flow control valve WN80-15 are controlled by the control unit.

[0566] Even when the flow rate of the washing water is increased by the washing nozzle WN80, the instantaneous discharge water amount can be further reduced (further water saving) according to the washing water discharge time or the wash water discharge amount in one intermittent cycle. Since the washing water flow rate can be increased, the washing power can be secured, and even though the washing water flow rate has been increased, the instantaneous discharge water amount can be further reduced. A feeling of washing can be secured. Furthermore, since the local area in the local area is not continuously washed, the washing water is intermittently applied when viewed from the local area in the local area, and the feeling of cleaning is improved by the intermittent stimulation. That is,
It is possible to further save water while achieving both sufficient washing power and comfortable washing feeling.

Also, the frequency of the intermittent stimulus can be changed by changing the intermittent frequency of the washing water. Therefore, by controlling the intermittent frequency of the washing water, the washing water is intermittently viewed from a local local range. Can be controlled. For example, I do n’t like intermittent stimulation,
If you prefer a continuous feeling of cleaning, use the electromagnetic valve WN80-4.
By controlling the on / off of 3 at a high speed, the intermittent frequency of the cleaning water can be controlled at a high speed, and the user can obtain a more continuous cleaning feeling. In particular, if the cleaning water is discharged at the frequency of the intermittent stimulus that is equal to or higher than the threshold at which the local part senses the intermittent stimulus, the effect of the continuous stimulus feeling is remarkable. Conversely, when strong intermittent stimulation is desired, the user can obtain strong intermittent stimulation by controlling the on / off of the electromagnetic valves WN80-43 to be driven at a low speed. Further, by controlling the intermittent frequency of the washing water to change with time, it is possible to sufficiently cope with the user's various tastes of the washing feeling.

FIG. 148 is an explanatory view for explaining a local cleaning apparatus provided with a cleaning nozzle WN84 according to another embodiment. The cleaning nozzle WN84 has a shower discharge configuration for discharging cleaning water from a water discharge hole WN84-42 having a plurality of discharge holes. In the case of shower discharge in which washing water is discharged from the water discharge holes WN84-42 having a plurality of water discharge holes WN84-42, the control of the instantaneous discharge water amount, the flow rate of the cleaning water, the volume ratio of the cleaning water space, and the cleaning area is performed by a water pump. WN84-
13 or by controlling the flow control valve WN84-15 and the variable valve WN84-45. The water pump WN84-13 and the flow rate control valve WN84-15 are provided with the cleaning water supply control means CT84-71 of the controller CT84-7.
Is controlled by From these facts, the above water pump W
The N84-13, the flow control valve WN84-15, and the variable valve WN84-45 function as the "water discharging means" in the present invention, and the cleaning water supply control means CT84-71 of the control unit CT84-7 for controlling these functions is the present invention. Function as "water discharge control means", "control means" or "variation control execution means".

FIG. 149 is a sectional view showing a cleaning nozzle WN86 according to another embodiment. The cleaning nozzle WN86 is
Flow regulating water stop valve WN86-42 for temporally controlling water discharge amount
And an intermittent water discharge unit WN86-76 for controlling the ON-OFF time of water discharge. The intermittent water discharge unit WN86-76 is a minute valve body WN86 having a permanent magnet WN86-77a attached to the head disposed at the tip of the nozzle body.
-77, an ultra-small electromagnetic coil WN86-78 made by a semiconductor fine processing technology for sucking it, and a valve element WN8
Spring body WN86-7 for pressing 6-77 against the nozzle body
9. When the user gives an instruction for washing, the flow regulating water stop valve WN86-42 is operated to start spouting of washing water. At the same time, depending on the cleaning mode selected by the user, the electromagnetic coil WN of the intermittent water discharge unit WN86-76 is used.
When a magnetic force is generated by flowing a current through the valve 86-78, the valve body W
N86-77 is attracted and opened by magnetic force against the force of the spring body WN86-79, and the washing water flows out of the gap. By passing an alternating current through the electromagnetic coil WN86-78 in a short cycle, the direction of the magnetic force can be changed, and the opening and closing operation can be repeated by pressing or pulling the valve element WN86-77. In this manner, the valve body W immediately before the water discharge hole WN86-75 is used.
Since the N86-77 is opened and closed, there is no deterioration in responsiveness due to minute air present in the water supply pipe or expansion of the pipe, and intermittent water discharge in a short cycle or short-time water discharge is possible. . Furthermore, since the minute valve body WN86-77 operates based on an electric signal, reliable and stepless control can be freely performed, and control with high responsiveness is also possible. From these facts, the above-mentioned flow regulating water stop valve WN86-42 and the intermittent water discharge unit WN86-76 function as the "water discharge means" in the present invention, and the electronic control device that controls them functions as the "water discharge control" in the present invention. Function as a "means", "control means" or "variation control executing means".

FIG. 150 is an explanatory view showing a cleaning nozzle WN89 according to another embodiment. Cleaning nozzle WN89
In, a water pump may be used to supply cleaning water to the rotating disk WN89-42c. As the water pump, in the case of a positive displacement pump, the flushing cycle, the intermittent cycle in terms of a stroke, or the flush water discharge time in one intermittent cycle may be controlled. The rotating disk WN89-4
When an intermittent variable valve is used instead of 2c, a plunger-type on-off valve may be used. From these, the above-mentioned rotating disk WN89-42c, water pump,
The intermittent variable valve functions as “water discharging means” in the present invention, and the electronic control device that controls these functions as “water discharging control means”, “control means”, or “variation control executing means” in the present invention.

FIG. 151 is an explanatory view for explaining a local cleaning apparatus provided with a cleaning nozzle WN90 according to another reference example. In the cleaning nozzle WN90, when the cleaning water is supplied from the cleaning water supply means WP90-1, the cleaning water flows into the cleaning nozzle WN90 via the heat exchanger TH90-2 that makes the cleaning water warm, and is discharged from the water discharge holes WN90-31. Local cleaning is performed. The cleaning water supply unit WP90-11 performs the on-off of the cleaning water discharge.
And a water force changing means WP90-12 for adjusting the flow rate of the washing water and changing the water force.

The washing water discharging means WP90-11 is provided with a valve section WP90-11a comprising an open / close valve, a check valve and the like.
And a water pump WP90-11b mounted when water pressure is insufficient or when water pressure is not used. The configuration of the valve unit WP90-11a changes depending on the required quality and the supply form of cleaning water (supply using water pressure, supply from a storage tank, etc.). For example, in the case of supply using water pressure, the valve unit WP90-11a May have a pressure reducing valve.

The water force changing means WP90-12 is composed of a flow control valve WP90-12a, a water pump WP90-12b, and the like, and has an air pump (not shown) for discharging cleaning water mixed with air. Water pump WP
90-11b and a water pump WP90-12b, and a valve unit WP90-11a and a flow control valve WP90-1.
2a may be shared.

[0573] The control unit CT90-6 is provided with cleaning water discharge control means CT90-61 for controlling the discharge of cleaning water, water pressure change control means CT90-63 for controlling the water pressure of the cleaning water, and electric power to the heat exchanger TH90-2. It has a heat exchanger control means CT90-62 for controlling the supply. User operation section S
Local cleaning operation instructing means SW by operation of W90-7 or the like
90-71 are operated, and the local cleaning operation instructing means SW90 is operated.
A signal for instructing discharge of the wash water from -71 is transmitted to the wash water discharge control means CT90-61.
And the cleaning water is discharged. Further, the user operates the operation section SW90-7 or the like to operate the water pressure indicating means SW90-.
72 is operated, and a signal for instructing the water level of the washing water from the water level instructing means SW90-72 is supplied to the water level change control means CT90.
-63, the water force change control means CT90-63 controls the water force change means WP90-12 to change the water force of the washing water. The water pressure instructing means SW90-72 may indicate the water force by turning a knob from the high side setting to the low side setting, or may indicate the water force by pressing a strong button or a weak button.

When the cleaning water is intermittently discharged,
It is possible to achieve the same discharge power E as before while increasing the flow rate v of the cleaning water and reducing the instantaneous discharge water amount Q without reducing the cleaning area. Therefore, the instantaneous discharge water amount Q at the time of the strongest water force is set to 6.7 × 10 ⁻⁶ [m ³ / sec] or less, and the conventional water force has the same discharge force E as the setting of the strongest water force. While ensuring the same detergency as the setting of the strongest water force, a hard washing feeling can be enjoyed, and the instantaneous discharge water amount Q at the time of the weakest water force is 0.67 × 10 ⁻⁶ [m ³ / sec.
c] above, the conventional water force has the same discharge force E as the weakest water force setting, so that the conventional water force has the same detergency as the weakest water force setting while removing dirt and the like adhering to the local part. There is no trouble of running down, and you can enjoy a soft cleaning feeling. In this way, if the design is made to increase or decrease the discharge force E equivalent to the conventional one, it is possible to change the water force to correspond to the user's various preferences similar to the conventional one despite the fact that the instantaneous discharge water amount is reduced, It can be carried out easily and reliably without reducing the cleaning power.

Even when the water pressure is set to the weakest, if the discharge force E is designed so as to satisfy 0.03 [W] or more, the cleaning can be performed with the same cleaning power as before. In addition, since the cleaning power is reduced, there is no problem in that, for the same cleaning time as in the past, dirt remains in a local area, and the cleaning time is longer than in the past.

Also, assuming that the above reference example is for general household use (AC 100 V), the allowable current value of one power supply is about 15 A, and the lower limit value of the variation of the power supply voltage is about 85 V AC. About 1275 with power supply
Since W is an allowable value, if it is designed so that the instantaneous discharge water amount Q at the time of the strongest water pressure satisfies 6 × 10 ⁻⁶ [m ³ / sec] or less, an instantaneous heat exchanger without fear of running out of hot water. When using, it can be used simultaneously with other devices while exhibiting a sufficient temperature-raising performance of about 40 ° C even in the middle of winter. For example, the power consumption of the heater for the toilet indoor heating device can be set to 200 [W].

Further, in all of the above reference examples or embodiments, the instantaneous discharge water amount Q at the time of the strongest water force is 4.8 × 10 ^−6.
If it is designed so as to satisfy [m ³ / sec] or less, when using an instantaneous heat exchanger without fear of running out of hot water, it will exhibit a sufficient temperature rising performance of about 40 ° C. even in the middle of winter, and It can be used simultaneously with many or other devices that use a large amount of power. For example, the power consumption of the heater for the toilet room heating device can be 400 [W].

As described above, if attention is paid to the discharge force E and if the discharge force E is designed to be increased or decreased in the same manner as in the related art,
When it is desired to perform water-saving cleaning, it is possible to easily (with no trial and error) and surely carry out a water pressure change corresponding to various user preferences similar to the conventional one without reducing the cleaning power.

FIG. 152 is an explanatory view showing a cleaning nozzle WN91 according to another reference example. This cleaning nozzle WN91
Is a reference example having a rotary discharge mechanism as a discharge unit so that the cleaning water draws a predetermined trajectory. Wash water rotation motor WN
91-41a near the tip of the nozzle, and by rotating the washing water rotation motor WN91-41a, the water discharge hole W
N91-31 rotates, and the cleaning water is discharged while drawing a predetermined trajectory. The flow of the washing water in this case is annular or substantially annular. The water pump WP is controlled by the water pressure change control means CT91-63 in accordance with the instruction of the water pressure instruction means SW91-72.
By controlling the 91-12b and the flow control valve WP91-12a, the discharge force E = ρ × Q × v × v [W] can be increased or decreased, and if the design is made to increase or decrease the discharge force E equivalent to the conventional case. In addition, it is possible to easily implement a water pressure change corresponding to various preferences of the user as in the related art.

If the effective area of the water discharge holes of the water discharge holes WN91-31 is reduced, it is possible to achieve the same discharge force E as before while increasing the flow velocity v of the washing water and reducing the instantaneous discharge water amount Q. Therefore, the instantaneous discharge water amount Q at the time of the strongest water force is 6.7 × 1
0 ^-6 [m ³ / sec] or less, and the conventional water force has the same discharge force E as that of the strongest water force setting. And the instantaneous discharge amount Q at the time of the weakest water force is set to 0.67 × 10 ⁻⁶ [m ³ / sec] or more, and the discharge force E of the conventional water force is equivalent to the setting of the weakest water force. By doing so, it is possible to enjoy a soft washing feeling without the problem that the dirt and the like adhering to the local part does not flow down while the same detergency as the setting of the weakest water force is obtained with the conventional water force. In this way, if the design is made to increase or decrease the discharge force E equivalent to the conventional one, it is possible to change the water force to correspond to the user's various preferences similar to the conventional one despite the fact that the instantaneous discharge water amount is reduced, It can be carried out easily and reliably without reducing the cleaning power.

Also, since the washing water draws a predetermined trajectory, the washing area can be made equal to the conventional one, not only does not cause a problem such as a large movement of the body (buttock), but also from a local local area. It can be seen that the washing water is intermittent and does not stimulate continuously, so the intermittent stimulation further enhances the feeling of washing.

FIG. 153 is an explanatory view showing a cleaning nozzle WN92 according to another embodiment. The cleaning nozzle WN92 is
The cleaning water is discharged intermittently.
An intermittent valve portion WN92-12d is provided in N92-9,
Water passage WN92- by intermittent valve part WN92-12d
The cleaning water is intermittently discharged by opening and closing 9. The intermittent valve portion WN92-12d is connected to the water passage WN9 by an electromagnetic valve.
2-9 may be opened and closed, or as shown in FIG.
, The cleaning water may be intermittently discharged. The intermittent valve portion WN92-12d has a better intermittent response as it is closer to the nozzle tip. The intermittent valve section W
N92-12d is a heat exchanger HT92 in the water channel.
-2 to the discharge hole WN92-31,
As the position is closer to N92-31, the intermittent responsiveness is better and the intermittent is not alleviated.

In the case where the cleaning water is intermittently discharged, the water pump WP9 is used after grasping the instantaneous discharge water amount Q and the cleaning water flow rate v.
2-12b, the flow control valve WP92-12a, and the intermittent valve section WN92-12d, by changing the performance, the discharge force E and the increase or decrease of the discharge force E can be easily designed. 72 in response to the instruction of the water pressure change control means CT92-63.
By controlling the P92-12b, the flow control valve WP92-12a, and the intermittent valve part WN92-12d,
If the discharge force E can be increased or decreased, and the discharge force E is increased or decreased as in the conventional case, the water force can be easily changed to correspond to the various preferences of the user as in the conventional case. From these, the water pump WP92-12 is used.
b, flow control valve WP92-12a, intermittent valve section W
N92-12d functions as the "water discharging means" according to the present invention, and controls the water force change control means CT9
2-63 functions as "water discharge control means", "control means" or "variation control execution means" according to the present invention. The water force indicating means SW92-72 functions as "water force setting means" in the present invention.

FIG. 154 is a sectional view showing a cleaning nozzle WN94 according to another reference example. Explaining the flow of cleaning water through the cleaning nozzle WN94, the water supply connection port WN94-
The cleaning water supplied from 6b into the cleaning nozzle WN94 is as follows:
After passing through the electromagnetic valve WN94-2a, the water pump WN94
Mover WN9 which is pressurized and / or flow-adjusted at -2b and is a part of the component of the oscillating water discharge section WN94-2c.
A gap WN94 is formed in the water passage WN94-23c in the 4-22c.
-24c, water is supplied while entraining air.
In accordance with the movement of N94-22c, the cleaning nozzle WN94
The water is discharged to the outside of the cleaning nozzle WN94 while swinging around the axis WN94-4a located inside.

The swing water discharge section WN94-2c is provided with a movable element WN.
94-22c and a plurality of armatures WN94-21c, and the mover WN94-22c includes a ferromagnetic material WN94-c.
A plurality of 25c are arranged so as to be paired with the armature WN94-21c. The ferromagnetic material WN94-25c is arranged so as to enter a magnetic field generated by energizing the armature WN94-21c.
Attraction or repulsion occurs during 1c. In this case, by sequentially energizing the plurality of armatures WN94-21c, the mover WN94-22c becomes
Elastic body WN94-26c which is a support part of N94-22c
With the fulcrum as a fulcrum, the robot moves without rotating in a conical shape. The mover WN94-22c is swingably fixed to the main body of the cleaning nozzle WN94 via an elastic body WN94-26c. The elastic body WN94-26c is made of a hard material such as rubber or an elastomer, a metal having a spring characteristic, a soft plastic, or the like.
c can be swingably supported.

[0586] In the cleaning nozzle WN94, a power line WN94-3 for supplying power to the armature WN94-21c is provided.
c, a power line WN94-3a for supplying power to the electromagnetic valve WN94-2a, and a power line WN94-3b for supplying power to the water pump WN94-2b. Further, power is supplied from the outside of the cleaning nozzle WN94 to the inside of the cleaning nozzle WN94 via the terminal WN94-6a. These power lines can be prevented from being leaked without the need to apply a coating or the like, without the power lines being flooded by the flushed water. Further, since the power line is embedded inside the cleaning nozzle WN94, the design is good and the cleaning nozzle can be made compact. further,
When the cleaning nozzle WN94 is held by hand, the power line does not hinder the movement of the hand.

Further, by using the oscillating water discharge section WN94-2c, it is possible to easily discharge water while oscillating variably from low speed to high speed. (Easy, poor design, power line entanglement) does not occur, and extensive cleaning, water-saving cleaning that maintains detergency and a feeling of cleaning, soft cleaning with high-speed oscillation, and low-speed oscillation and intermittent Washing and the like that actively use the stimulus can be performed regardless of the flow rate of spouting water.

FIG. 155 is an explanatory view showing a cleaning nozzle WN96 and a cleaning nozzle WN97 according to another reference example. The cleaning nozzle WN96 shown in FIG. 155 (a) is a water discharge swinging part WN96-21d using a motor WN96-2d.
And a configuration for transmitting power by a shaft. The cleaning nozzle WN shown in FIG.
97 is a movable unit WN9 via a gear WN97-21d.
A structure for swinging the 7-22d is provided, so that it is possible to flexibly cope with a design conflict. The movable part W
A seal structure such as an O-ring or a Y-packing may be provided on the periphery of N97-22d, if necessary, so that the cleaning water does not leak outside.

FIG. 156 is an explanatory view showing a cleaning nozzle WN98 and a cleaning nozzle WN99 according to another reference example. The cleaning nozzle WN98 shown in FIG. 156 (a) has a configuration in which the nozzle head WN98-1 at the tip can be extended and contracted. The cleaning nozzle WN98 has an expansion joint WN98-
11b is provided. By pressing a cleaning start button (not shown), a pinion WN98-8b connected to a motor (not shown) is rotated, and the pinion WN98 is rotated.
When the rack WN98-8c meshing with −8b moves rightward in the drawing, the cleaning nozzle WN98 is extended, and the cleaning water is discharged toward the human body part. By pressing the washing stop button when washing is completed, the pinion WN9 is pressed.
As the rack 8-8b rotates and the rack WN98-8c meshing with the pinion WN98-8b moves leftward in the drawing, the cleaning nozzle WN98 contracts and is housed in the local cleaning device. Inside the washing nozzle WN98, the heat exchanger W
N98-2e. Heat exchanger WN98-2e
Has a heater WN98-21e and a heater WN9
By energizing 8-21e, the temperature of the cleaning water can be raised, and comfortable local cleaning can be performed according to the temperature desired by the user.

[0590] A spring-like portion WN98-7a is provided in the cleaning nozzle WN98. The spring-like portion WN98-7a functions as a power supply line for supplying electric power to the electric device in the cleaning nozzle WN98. Thus, since the spring-like portion is constituted by the spring, the cleaning nozzle expands and contracts at the same time as the cleaning nozzle expands and contracts, and does not hinder the operation.

Further, the cleaning nozzle WN9 shown in FIG.
As shown in FIG. 9, the same effect as the case where the spring-like portion WN98-7a is provided can be obtained by providing the feed line WN99-7b which can be bent instead of the spring-like portion WN98-7a. it can.

FIG. 157 is an explanatory diagram showing a cleaning nozzle WN100 according to another reference example. Cleaning nozzle WN100
Is an air pump WN100-2f and this air pump W
A mixing section WN100-21f for mixing the air from the N100-2f into the washing water, and a water discharge oscillating section WN100-2.
1d. In this cleaning nozzle WN100,
Since the air pump WN100-2f was wired near the water discharge hole, the mixing part WN10 was connected from the air pump WN100-2f.
There is no need to use a long tube or the like to connect to 0-21f. For this reason, air can be mixed with good responsiveness and stably, and there is no danger of leakage from the power line or entanglement of the power line, and there is little danger of air leakage from the tube.

FIG. 158 is an explanatory view showing a local cleaning apparatus provided with a cleaning nozzle WN102 according to another embodiment.
In FIG. 158, the nozzle body WN102-50 and the nozzle head WN102-70 are shown in a sectional view, and the water flow system and the control instruction system are shown in a block diagram. Here, the power limiting means CT102-8 includes an intermittent ejection control section CT102-8a.
And a cleaning water flow rate control unit CT102-8b. The intermittent ejection control unit CT102-8a
N102-81a, washing water flow rate control unit CT10
2-8b comprises a flow control unit CT102-35. The electromagnetic valve WN102-81a is provided with a plunger WN102.
-82a, the ferromagnetic material WN102-83a attached to the plunger WN102-82a, and the ferromagnetic material WN102-
83a by applying a magnetic field to the ferromagnetic material WN102-83
and armature WN102-84a for driving plunger WN102-82a and plunger WN102-8
2a and a spring WN102-85a attached to the opposite side. One end of the spring WN102-85a is fixed to the nozzle body WN102-50. Armature WN10
By energizing 2-84a, the armature WN102-
An attraction is generated between the ferromagnetic material 84N and the ferromagnetic material WN102-83a, and the movement of the plunger WN102-82a against the extension of the spring WN102-85a opens the water passage, thereby turning on the discharge of the washing water. Conversely, armature WN
By stopping the energization to the armatures 102-84a, the attractive force between the armature WN102-84a and the ferromagnetic material WN102-83a is released, and the armature WN102-85a is displaced by the reverse movement of the plunger WN102-82a due to the tension of the spring WN102-85a. The water channel is closed, and the discharge of the cleaning water is turned off. Further, based on the settings of the water pressure setting dial SW102-13d and the discharge temperature setting dial SW102-13e, the electromagnetic valve WN is transmitted by a signal via the hot water / nozzle control device.
102-81a and the flow control unit CT102-35 are controlled. Further, the control of the intermittent rate of the cleaning water and the control of the intermittent frequency are performed by turning on and off the power supply to the electromagnetic valves WN102-81a. In addition, the instantaneous discharge water amount used in the following description does not indicate a minute change in the instantaneous discharge water amount due to intermittent discharge, but indicates an average instantaneous discharge water amount when the intermittent ratio and the discharge flow rate are not changed. Also,
In the present invention, the intermittent rate is determined by “((OFF time of discharge of cleaning water) / (O of discharge of cleaning water)
N time + OFF time of discharge of cleaning water).

Here, for example, if the user sets the water pressure setting dial SW102-13d to “strong” water pressure, the electromagnetic valve WN102-81a and the flow control unit CT102-3 are set.
As a result of the intermittent discharge of the washing water under the control of 5, the discharge flow rate becomes 1
0 [m / sec], instantaneous discharge water amount is 430 [cc / mi]
n], and the cleaning water is discharged. Despite the instantaneous discharge water amount of 430 [cc / min], the discharge flow rate is 10 [m / sec]. Therefore, even a user who wants to obtain a strong water force should simulate and secure a sufficient water force. And the instantaneous discharge water amount is 430 [cc / mi
n], even a user who wants to wash at a high temperature (for example, 40 ° C. or more) can perform washing with a favorite hot water temperature even in the middle of winter, and thus, the washing water heating means WP102-31 while maintaining a feeling of washing. Can be limited to 1200 [W] or less. Further, by further increasing the intermittent ratio of the discharged washing water and increasing the discharge flow rate, the instantaneous discharge water amount can be reduced while maintaining the washing power and the feeling of washing, and the power consumption of the washing water heating means WP102-31 can be further reduced. Can be restricted to

[0595] Also, the user sets the water pressure setting dial SW10.
If 2-13d is set to "weak" water force, the electromagnetic valve WN
Under the control of the flow control unit 102-81a and the flow control unit CT102-35, the instantaneous discharge water amount is the same as the “strong” water force, and only the intermittent ratio of the discharged wash water can be made small or zero, and the discharge flow rate becomes 2 [ m / sec], and the instantaneous discharge water amount is adjusted to be 430 [cc / min], and the wash water is discharged. Since the discharge flow velocity is 2 [m / sec], even a user who wants to obtain a weak water force can perform mild washing without pain, and the instantaneous discharge water amount is 430 [cc / min] despite the weak water force. So
The width of the power supply control for the temperature control in the cleaning water heating means WP102-31 can be widened, the accuracy with respect to the target hot water temperature can be easily secured, and a high-quality local cleaning device can be provided, and the feeling of cleaning can be maintained. Washing water heating means WP
The power consumption in 102-31 can be limited to 1200 [W] or less.

[0596] Instead of changing the instantaneous discharge water amount, the electromagnetic valve WN102-81a and the flow control unit CT102-
By the control of 35, the control of reducing the instantaneous discharge water amount at the time of the "weak" water force is performed, so that the user is satisfactorily satisfied so that the desired water force is obtained. ] It is also possible to limit to the following.

Also, a combination of a change in water force by changing the discharge rate and the discharge flow rate without changing the instantaneous discharge water amount and a change in water force by changing the instantaneous discharge water amount simulate the user to obtain a desired water force. May be satisfied. In this case, for example, when the setting by the water pressure setting dial SW102-13d is "strong" water force to "slightly strong" water force, the instantaneous discharge water amount is set to 430 [cc / min], and the water force is changed by increasing or decreasing the discharge ratio and the discharge flow rate. , Water setting dial SW102-
When the setting by 13d is "slightly strong" to "slightly weak", the instantaneous discharge water amount is set to 380 [cc / min], the water pressure is changed by increasing / decreasing the discharge ratio and the discharge flow rate, and the water pressure setting dial SW102-13d. Is slightly weak
When the water force is "weak", the instantaneous water discharge amount is 330 [cc].
/ Min] to change the water force by increasing or decreasing the discharge rate and the discharge flow rate.

Also, in the embodiment of FIG. 158, the explanation has been made of the embodiment in which the discharge of the cleaning water is intermittently controlled by the electromagnetic valve WN102-81a. Since it can be satisfied, the disc valve having a predetermined opening is rotated using a motor, and the discharge of the cleaning water is turned on and off, for example, by turning on and off the discharge of the cleaning water.
What is necessary is just to be able to control -OFF. From these facts, the intermittent discharge control section CT102-8a and the washing water flow rate control section CT102-8b function as the "water discharge means" according to the present invention, and the water pressure change control means CT92-63 for controlling these control means are provided. It functions as "water discharge control means", "control means" or "variation control execution means" according to the present invention. In addition, the power setting dial SW102-13d
Functions as “water force setting means” in the present invention.

FIG. 159 is an explanatory view showing a local cleaning apparatus provided with a cleaning nozzle WN104 according to another reference example.
159 (a) is a sectional view of the nozzle body WN104-50 and the nozzle head WN104-70, a block diagram of a water flow system and a control instruction system, and FIG. 159 (b) is a discharge section WN104-82e and a discharge hole group disk. WN104
-81e as viewed from the discharge direction. Here, the power limiting unit CT104-8 includes a discharge hole group WN104-8e, which is an aggregate of a plurality of discharge holes, and a cleaning water flow rate control unit CT104-8b. Discharge hole group WN
104-8e are distributedly arranged in the discharge units WN104-82e. In addition, a discharge hole group WN104 from which the cleaning water is discharged.
-8e, the ejection hole group disk WN10
4-81e and a switching motor WN104-86e.
The discharge hole group disk WN104-81e has a discharge hole group unit WN having a total water discharge hole area of 7.2 × 10 ⁻⁷ [m ² ].
104-83e, total water discharge hole area is 9.6 × 10
^-7 [m ² ] discharge hole group unit WN104-84
e, having a discharge hole group unit WN104-85e having a water discharge hole total area of 3.6 × 10 ⁻⁶ [m ² ];
N104-86e and ejection hole group disk WN104-81
e is rotated by a predetermined angle (15 [deg] rotation in this reference example)
By doing so, the cleaning water is discharged from the discharge hole group unit communicating with the discharge hole group WN104-8e on the discharge part WN104-82e. Cleaning water flow rate control unit CT104-8
b comprises a flow control unit CT104-35. Also,
Based on the settings of the water pressure setting dial SW104-13d and the water discharge temperature setting dial SW104-13e, the switching motor WN104 is output by a signal via the hot water / nozzle control device.
-86e and the flow control unit CT104-35 are controlled.

Here, for example, if the user sets the water force setting dial SW104-13d to "strong" water force, the switching motor WN104-86e selects the discharge hole group unit WN104-85e as a water discharge hole, and the flow control unit C
At T104-35, the discharge flow rate is adjusted to 10 [m / sec], and the instantaneous discharge water amount is adjusted to 430 [cc / min], and the wash water is discharged. Instantaneous discharge water amount is 430 [cc
/ Min], the discharge flow rate is 10 [m
/ Sec], a user who wants to obtain a strong water force can simulate and secure a sufficient water force, and the instantaneous discharge water amount is 430 [cc / min]. [° C. or more], a user who wishes to perform cleaning can also perform cleaning at the desired hot water temperature even in the middle of winter, thereby limiting the power consumption in the cleaning water heating means TH104-31 to 1200 [W] or less while maintaining a feeling of cleaning. can do. In addition, since the ejection hole group is arranged so as to be sufficiently dispersed so as to be able to clean the same cleaning area as in the related art, there is no problem that the cleaning area is reduced. Further, if the total area of the water discharge holes of the discharge hole group unit is further reduced, the discharge flow velocity of the wash water is greatly increased, and the wash water can be sufficiently dispersed within the wash area by increasing the number of holes. The power consumption of the water heating means TH104-31 can be limited to a smaller value.

[0601] Also, the user sets the water pressure setting dial SW10.
If 4-13d is set to "weak" water force, the switching motor WN
The discharge hole group unit W is used as a water discharge hole by 104-86e.
N104-83e is selected and the flow control unit CT104
At -35, the discharge flow rate is adjusted to 2 [m / sec], and the instantaneous discharge water amount is adjusted to 430 [cc / min], and the wash water is discharged. Since the discharge flow velocity is 2 [m / sec], even a user who wants to obtain a weak water force can perform mild washing without pain, and the instantaneous discharge water amount is 430 [cc / min] despite the weak water force. So
The width of the power supply control for temperature adjustment in the washing water heating means TH104-31 can be widened, the accuracy with respect to the target hot water temperature can be easily ensured, and a high-quality local washing device can be provided, and the feeling of washing can be maintained. Washing water heating means TH
The power consumption in 104-31 can be limited to 1200 [W] or less.

In the reference example, the use of the discharge hole group units has been described separately. However, only the discharge hole group units WN104-85e are used, and at the time of "weak" water pressure, control is also performed to reduce the instantaneous discharge water amount so that the desired water force is obtained. The user may be pseudo-satisfied. In this case, precision is required for the energization control in the washing water heating means, but the switching motor WN104-86 is required.
e is not required and the number of parts can be reduced, so that not only the cost can be reduced, but also the power consumption in the washing water heating means TH104-31 can be reduced while maintaining the feeling of washing.
00 [W] or less.

[0603] The user may be satisfactorily satisfied with a desired water force by a combination of a water force change by properly using the discharge hole group unit and a water force change by changing the instantaneous discharge water amount. In this case, for example, the power setting dial SW1
When the setting by 04-13d is “strong” water force to “slightly strong” water force, the setting is performed by a combination of the discharge hole group unit WN104-85e and the increase / decrease of the instantaneous discharge water amount, and the water force setting dial SW1 is used.
The setting by 04-13d is "somewhat strong" water force ~ "somewhat weak"
At the time of the water pressure, the combination of the discharge hole group unit WN104-84e and the increase / decrease of the instantaneous discharge water amount is performed.
Setting by W104-13d is "slightly weak" water force-"weak"
In the case of a water force, the present invention can be implemented by performing the discharge hole group unit WN104-83e in combination with the increase and decrease of the instantaneous discharge water amount.

Even if both the buttocks cleaning and the bidet cleaning are performed by one discharge mechanism or performed by another nozzle, the practice of the present invention is not hampered, and the above embodiments are combined with each discharge mode. Thus, it is possible to satisfactorily satisfy the user with the water pressure set by the water pressure setting dial SW104-13d with a smaller amount of instantaneous discharge water.
The washing water heating means TH104-
The power consumption of the power supply 31 can be limited to 1200 [W] or less, and can be further reduced to a lower power consumption.

Also, in the above reference example, the buttocks cleaning setting means SW104-13a or the bidet cleaning button SW1
Although the current is controlled based on the operation of 04-13b, the instantaneous cleaning water heating means TH104-31 for heating the supplied cleaning water to the target temperature instantaneously has been described, but the supplied cleaning water is temporarily stored. Water temperature setting dial SW104
A hot water storage type washing water heating means for constantly heating and keeping the temperature at the appropriate temperature set at -13e may be used. In this case, the amount of instantaneous discharge water can be reduced by half as compared with the conventional method, so that even when washing is performed for a long time, the hot water runs out. And the capacity of the washing water heating tank can be made smaller than before, so the heat radiation in the washing water heating tank is also small, and the transportability and workability of the local cleaning device can be improved significantly, resulting in a satisfactory usability. It is possible to provide a local cleaning device which achieves both convenience and energy saving.

FIG. 160 is an explanatory view showing a cleaning nozzle WN108 according to another reference example. Cleaning nozzle WN108
Is provided with a variable valve WN108-45. The variable valve WN108-45 includes a rotating disk WN108-4.
5a, and a drive motor WN108-45c for rotating the rotating disk WN108-45a. The rotating disc WN108-45a is formed of a water discharge hole having a large number of water discharge holes WN108-45b. Further, a water discharge hole WN10 is formed on the upper surface of the tip of the cleaning nozzle WN108 so as to face the rotating disk WN108-45a.
Many 8-31s are formed. Drive motor WN108
When the rotating disk WN108-45a is rotated by −45c and the cleaning water is supplied to the cleaning nozzle WN108, water is discharged from a water discharging hole having a large number of water discharging holes WN108-45b toward the human body through the water discharging holes WN108-31. . In this case, the spout hole WN108-
Since the number of overlapping portions of the water discharge holes 45B and the water discharge holes WN108-31 is different in time with the rotation of the rotary disk WN108-45a, the water discharge holes WN108 from which the cleaning water is discharged.
−31 changes, and the volume ratio of the washing water space and the washing area can be easily controlled.

FIG. 161 is an explanatory diagram for explaining a cleaning nozzle WN112 according to another reference example. Cleaning nozzle WN1
In 12, the control of the instantaneous discharge water amount, the flow rate of the wash water, the volume ratio of the wash water and the wash area in the case of the oscillating discharge in which the wash water after the discharge oscillates is performed by the water pump WP112-13 or the flow control valve WP112-12. Swing means WN112-
This is performed by controlling 44. Water pump WP112-
13 and the flow control valve WP112-12 are controlled by the cleaning water supply control means CT112-71. Swing means W
N112-44 is provided with a vibration motor that swings the cleaning water by attaching a vibration motor to the tip of the cleaning nozzle and vibrating the water discharge hole. By controlling the swing frequency with this vibration motor, if the swing frequency is high,
The effect of acceleration in the oscillating direction is large, the cleaning area can be large, and the space volume ratio can be reduced. When the oscillating frequency is low, the effect of acceleration in the oscillating direction is small, the cleaning area is small, and The rate can be increased. In addition, by controlling the swing diameter of the swing discharge, when the swing diameter is large, the washing area can be increased and the space volume ratio can be reduced, and when the swing diameter is small, the washing area can be reduced. It can be small and the space volume ratio can be increased.

FIG. 162 is an explanatory view showing a local cleaning apparatus provided with a cleaning nozzle WN120 according to another reference example.
First, the path of the washing water will be described. When the washing water is supplied from the washing water supply means WP120-1, the washing nozzle WN12 passes through a heat exchanger TH120-2 which makes the washing water warm.
0, and is discharged from the water discharge holes WN120-31, and local cleaning is performed. The cleaning water supply means WP120-1 is
Flow control valve WP120-12 and water stop valve WP12
0-11, when the water pressure for discharging is insufficient or when the water pressure is not used, the water pump WP120-
It is necessary to add 13.

Next, a specific control method in the cleaning ability control means CT120-7 will be described for each discharge mode. The control of the instantaneous discharge amount, the flow rate of the wash water, and the volume ratio of the wash water space when the wash water is mixed with air is controlled by the water pump WP12.
This is performed by controlling 0-13 or the flow control valve WP120-12 and the air pump AP120-41.
Water pump WP120-13 and flow control valve WP120
-12 is controlled by the cleaning water supply control means CT120-71. The aeration unit AP120-41a is located downstream of the heat exchanger TH120-2 and is provided with a water discharge hole WN1 of the washing nozzle.
The interval between 20 and 31 is the best, and it is not necessary to increase the capacity of the air pump AP120-41 on the downstream side.
The air pump AP120-41 is provided with an air pump controller C.
It is controlled by T120-72. Since the air mixing rate is determined by the balance between the water pressure and the air pressure of the mixing section, the water pump WP
120-13 or flow control valve WP120-12
By controlling the capacity of the air pumps AP120-41, the air entrapment rate can be controlled, the space volume ratio ρ after the flushing water can be controlled, and the air entrapment rate can be changed independently of the instantaneous discharge water amount. By performing the control, the flow rate of the washing water can be controlled independently of the instantaneous discharge water amount.

FIG. 163 is an explanatory diagram for explaining a shower head according to another reference example. Cleaning nozzle WN124
Is built into the showerhead. That is, as shown in FIG. 163, the shower head is connected to the armature WN1.
24-3b, the movable part WN124-2, and the movable part WN1
Ferromagnetic material WN124-3a integrally formed with 24-2
And is incorporated. In this case, the water discharge hole WN124-
2b is preferably a large number. Main body water channel WN1
From the 24-1b, at the stage of supplying the cleaning water to the movable portion WN124-2 through the gap, water may be supplied to the movable portion WN124-2 in the same number as the number of water discharge holes, or a backflow may occur inside the movable portion. The structure may be divided into a large number of pieces so as not to cause the problem.

FIG. 164 is an explanatory diagram showing a cleaning nozzle WN126 according to another reference example. Cleaning nozzle WN126
Is provided with a configuration for discharging cleaning water mixed with air. Air mixing part AP126-4 is inserted into water passage WN126-9.
2a is provided, and air is mixed from the air mixing unit AP126-42a. The configuration of the air mixing section AP126-42a may be a configuration in which air is self-primed by the ejector effect, or an air pump AP126-12c may be provided to perform forced mixing. In addition, the aeration unit AP126-42a connects the water discharge hole WN from the heat exchanger TH126 in the water passage.
126-31 is better, but the closer it is to the water discharge hole WN126-31, the less likely it is that the air mixing state is affected by the water passage, and if the air pump AP126-12c is provided, the air pump AP126 There is no need to increase the capacity of -12c more than necessary.

In the case of discharging the cleaning water mixed with air, the water pump W is controlled after grasping the instantaneous discharge water amount Q and the cleaning water flow velocity v.
P126-12b and flow control valve WP126-12a
By changing the capacity of the air pump AP126-12c, it is possible to easily design the discharge force E and the increase or decrease of the discharge force E. -63 and water pump WP126-12b and flow control valve WP12
By controlling the 6-12a and the air pump AP126-12c, the discharge force E can be increased or decreased. If the discharge force E is designed to be increased or decreased in the same manner as in the related art, the user can enjoy various preferences similar to those in the related art. Can easily be changed.

FIG. 165 is a block diagram illustrating a water channel system and a control system in a human body cleaning apparatus having a cleaning nozzle WN130 according to another reference example, FIG. 166 is a detailed diagram of an operation panel, and FIG. 167 is a cleaning nozzle WN130. FIG.

[0614] The cleaning nozzle WN130 is connected to the operation panel SP.
Cleaning switch SW130-21 arranged at 130-6
On-off valve WP130-2 that is opened and closed by pressing
Is opened, the washing water is supplied from the washing water suction port WP130-1. The washing water is supplied to the constant flow valve WP130.
-3, the flow rate is controlled to be constant, and further heated by the washing water heating means TH130-7. The output of the washing water heating means TH130-7 is output from the operation panel SP130.
Water discharge temperature setting button SW130-23 arranged at -6
And the first temperature detecting means WP130-
It is set by the difference from the temperature of the cleaning water before heating detected in step 4. Further, the heated washing water is supplied to the aeration unit AP13.
When air is mixed in at 0-10, the flow rate is increased although the amount of water is small, and the water discharge hole WN130- is formed as the aerated cleaning water WN130-12 having a high cleaning strength.
Water is spouted from 11.

Here, the constant flow valve WP130-3 is used as a means for keeping the flow rate of the washing water constant, but a pressure reducing valve may be used.

Also, in the aeration unit AP130-10,
An air pump AP130-14 for sending in air is connected, and a predetermined amount of air is sucked in from an air inlet AP130-15, and is mixed with the washing water moderately in the air mixing unit AP130-10. The amount of air is determined by the selection of the cleaning intensity setting button SW130-22, and the air pump AP13
It can be adjusted by varying the input voltage of 0-14. Normally, when the weak cleaning intensity is selected, the input voltage is reduced to reduce the amount of air, and when the strong cleaning intensity is selected, conversely, the input voltage is increased to increase the amount of air. Thereby, the aerated cleaning water WN130-12 having the set cleaning intensity can be obtained.

[0617] In addition, the cylindrical filter WN130-1 is provided in the aeration section AP130-10 in the cleaning nozzle WN130.
0a is disposed, and the air sent from the air pump AP130-14 passes through the air flow path AP130-32 and the air chamber AP130-10b, and the cylindrical filter WN130-1.
0N, the cylindrical filter WN130-1
The cleaning water flowing inside 0a is mixed with air as bubbles in a moderate amount.

FIG. 168 is an explanatory view showing a local cleaning apparatus provided with a cleaning nozzle WN132 according to another reference example.
In FIG. 168, the nozzle main body WN132-50 and the nozzle head WN132-70 are cross-sectional views, and the water flow system and the control instruction system are schematically illustrated. Here, the power limiting unit CT132-8 is provided with an aeration control unit CT132-8.
d and the washing water flow rate control unit CT132-8b. The air mixing control unit CT132-8d is an air pump A
P132-81d and an air mixing section AP132-82d, and the washing water flow rate control section CT132-8b is provided with a flow control unit WP132-35 and the air pump AP132-8.
1d and the aeration section AP132-82d. Based on the settings of the water pressure setting button SW132-13d and the discharge temperature setting button SW132-13e, the air pump AP132 is operated by a signal through the hot water / nozzle control device.
-81d and the flow control unit WP132-35 are controlled.

Here, for example, when the user sets the water pressure setting button SW
If 132-13d is set to the "strong" water force, the discharge flow velocity is 13 [m / sec] and the instantaneous discharge water amount is due to the forced mixing of air into the wash water under the control of the air pump AP132-81d and the flow control unit CT132-35. Is 430 [cc /
min], and the cleaning water is discharged.
Since the instantaneous discharge water amount is 430 [cc / min] and the discharge flow velocity is 13 [m / sec] despite the air cushion effect due to air mixing, users who want to obtain a strong water force are sufficient. It is possible to simulate the water force and wash it, and the instantaneous discharge water amount is 430 [cc / mi].
n], even a user who wants to wash at a high temperature (for example, 40 ° C. or more) can perform washing at a desired hot water temperature even in the middle of winter, and thus, the washing water heating means TH132-31 while maintaining the washing feeling. Can be limited to 1200 [W] or less. Also, the air mixing unit AP13
In the case of 2-82d, if air is mixed from the fine gaps of the porous body, air can be mixed as finer bubbles, and since the bubbles are fine, the disappearance of bubbles is small and the amount of mixed air is greatly increased. As a result, the discharge flow rate can be further increased to reduce the instantaneous discharge water amount, and furthermore, the power consumption of the washing water heating means TH132-31 can be limited to a small value, and a sufficient bubble state can be obtained even when colliding with a local part. Since it is maintained, there is no problem such as pain due to the air cushion effect even though the flow velocity is greatly increased.

The user sets the water pressure setting button SW132
If -13d is set to "weak" water force, the air pump AP1
Under the control of the 32-81d and the flow control unit CT132-35, the instantaneous discharge water amount is the same as the "strong" water force, and only the ratio of forced mixing of air into the wash water can be reduced or set to zero. 3 [m / sec] and the instantaneous discharge water amount is adjusted to be 430 [cc / min], and the wash water is discharged. Since the discharge flow velocity is 3 [m / sec], even a user who wants to obtain a weak water force can perform mild washing without pain, and the instantaneous discharge water amount is 430 [cc / min] despite the weak water force. So that
The width of the power supply control for the temperature adjustment in the washing water heating means TH132-31 can be widened, the accuracy with respect to the target hot water temperature can be easily secured, and a high-quality local washing device can be provided, and the feeling of washing can be maintained. Washing water heating means TH
The power consumption in 132-31 can be limited to 1200 [W] or less.

[0621] In the reference example, the instantaneous discharge water amount is not changed. However, by controlling the air pumps AP132-81d and the flow regulating unit CT132-35, the control to reduce the instantaneous discharge water amount at the time of "weak" water force is performed. , And the power consumption in the washing water heating means TH132-31 is reduced to 1200.
[W] It can be limited to the following.

Also, the combination of the water pressure change by changing the air mixing ratio without changing the instantaneous discharge water amount and the water force change by changing the instantaneous discharge water amount quasi-satisfies the user so that the desired water force is obtained. You may. In this case, for example, when the setting by the water pressure setting button SW132-13d is “strong” to “slightly”, the instantaneous discharge water amount is set to 430 [cc].
/ Min], the water pressure is changed by increasing / decreasing the air mixing ratio, and when the setting by the water pressure setting button SW132-13d is “slightly strong” to “slightly weak”, the instantaneous discharge water amount is 38.
The water pressure is changed by changing the air mixing ratio to 0 [cc / min], and when the setting by the water pressure setting button SW132-13d is "slightly weak" to "weakly", the instantaneous discharge water amount is set to 3
The water pressure can be changed by increasing or decreasing the air mixing ratio to 30 [cc / min]. In addition, the cleaning nozzle W of this reference example
In N132, it is also possible to cause periodic fluctuations in the amount of air entrapment to cause pulsation or intermittent discharge water.

The embodiments of the present invention have been described above.
The present invention is not limited to the above-described examples and embodiments at all, and it goes without saying that the present invention can be implemented in various modes without departing from the gist of the present invention.

[Brief description of the drawings]

FIG. 1 shows a local cleaning device K of a reference example mounted on a toilet bowl.
It is a schematic perspective view showing S1-1.

FIG. 2 is a remote control device RC1 of the local cleaning device.
FIG. 3 is an explanatory diagram for explaining -1.

FIG. 3 is a schematic perspective view around a sleeve for explaining an auxiliary operation unit KS1-9 of the local cleaning device.

FIG. 4 is a block diagram showing a schematic configuration of the local cleaning device with a focus on a water channel system.

FIG. 5 is a block diagram illustrating a schematic configuration of a control system.

FIG. 6 is a schematic perspective view illustrating a nozzle device NS1-1.

FIG. 7 is an explanatory diagram for explaining how the cleaning nozzle WN1-1 moves forward and backward.

FIG. 8 is an explanatory view showing the periphery of a tip of a cleaning nozzle at a standby position in a main body of a local cleaning device.

FIG. 9 is a schematic perspective view showing a functional water unit WP1-4 partially broken away.

FIG. 10 is a schematic sectional view taken along line 10-10 of FIG. 8;

FIG. 11 is a schematic sectional view taken along line 11-11 of FIG. 8;

FIG. 12 is an enlarged schematic perspective view of a nozzle head NH1-1 at the tip of a cleaning nozzle.

FIG. 13 is a schematic sectional view taken along line 13-13 of FIG. 12;

FIG. 14 is a plan view of a nozzle head base NH1-2.

FIG. 15 is a bidet movable body NH1-11 used for bidet cleaning.
FIG.

FIG. 16 is a schematic plan view for explaining a bidet movable body and its related members.

FIG. 17 is a schematic perspective view for explaining a bidet movable body and related members.

FIG. 18 is a schematic exploded perspective view for explaining a magnetic force generator NH1-26.

FIG. 19 shows an electromagnetic coil installation substrate NH of a magnetic force generator.
It is a top view of 1-28.

FIG. 20 is an explanatory diagram illustrating a circuit configuration formed on the upper surface of the substrate.

FIG. 21 is an explanatory diagram illustrating the state of excitation of the electromagnetic coils NH1-33a to 33c when driving the bidet movable body NH1-11.

FIG. 22 is an explanatory diagram schematically illustrating a state of flush water spouting from a bidet spout hole NH1-10.

FIG. 23 is an explanatory view schematically illustrating an instantaneous state of flush water spouting.

FIG. 24 is another explanatory diagram for explaining the state of excitation of the electromagnetic coils NH1-33a to 33c.

FIG. 25 is a flowchart showing a cleaning and drying operation routine of the buttocks and bidet executed by the electronic control unit CT1-1.

FIG. 26 is a flowchart of a pre-nozzle cleaning routine showing details of a pre-nozzle cleaning process in a cleaning / drying operation routine.

FIG. 27 is an explanatory diagram schematically showing a state of flush water spouting in pre-nozzle cleaning prior to flush water spouting in local cleaning.

FIG. 28 is a flowchart of a main cleaning routine showing details of main cleaning operation processing in the cleaning / drying operation routine.

FIG. 29 is an explanatory diagram for describing the processing content of the main cleaning routine and the processing content of the operation stop routine.

FIG. 30 is a flowchart showing an operation stop routine.

FIG. 31 is a flowchart showing a move cleaning routine.

FIG. 32 is an explanatory diagram for explaining a state of move cleaning.

FIG. 33 is a flowchart showing a spot-wide cleaning routine.

FIG. 34 is an explanatory diagram for explaining a state of spot-wide cleaning.

FIG. 35 is a flowchart showing a massage cleaning routine.

FIG. 36 is an explanatory diagram for explaining a state of massage cleaning.

FIG. 37 is an explanatory diagram schematically illustrating an effect obtained by massage cleaning.

FIG. 38 is a flowchart showing a fluctuation cleaning routine.

FIG. 39 is an explanatory diagram for describing processing details of a fluctuation cleaning routine.

FIG. 40 is an explanatory diagram for explaining the state of fluctuation cleaning.

FIG. 41 is a flowchart showing a swing detection routine.

FIG. 42 is an explanatory diagram for describing processing details of a swing detection routine.

FIG. 43 is a flowchart showing an abnormality recovery routine.

FIG. 44 is a flowchart showing a nozzle cleaning routine.

FIG. 45 is a block diagram illustrating a water channel configuration according to a modification.

FIG. 46 is a schematic perspective view showing a nozzle device NS1-20 of a modified example.

FIG. 47 is a schematic sectional view taken along the line 47-47 in FIG. 46;

FIG. 48 is an explanatory diagram for explaining a state of move cleaning according to a modified example.

FIG. 49 is a plan view of an electromagnetic coil installation substrate NH1-50 included in a nozzle head of a modified example.

FIG. 50 is a plan view of an electromagnetic coil installation substrate NH1-60 included in a nozzle head of another modification.

FIG. 51 is an explanatory diagram for explaining a nozzle head of still another modified example.

FIG. 52 is an explanatory diagram for describing a cleaning operation of a modified example using the nozzle head NH1-70 of the modified example.

FIG. 53 is an explanatory diagram for schematically explaining a state of spouting of cleaning water by a cleaning operation of a modified example.

FIG. 54 is an explanatory diagram for describing a cleaning operation of another modified example using the nozzle head NH1-70 of the modified example.

FIG. 55 is an explanatory diagram for schematically explaining how cleaning water is spouted by a cleaning operation of another modification.

FIG. 56 is an explanatory diagram for schematically explaining a state of cleaning water spouting when the cleaning operation of another modified example is applied to move cleaning.

FIG. 57 is an explanatory diagram for explaining a manufacturing process of the bidet movable body NH1-11.

FIG. 58 is an explanatory diagram illustrating a manufacturing process of a bidet movable body according to a modification;

FIG. 59 is an explanatory diagram illustrating a manufacturing process of a bidet movable body according to another modification.

FIG. 60 is a block diagram illustrating a schematic configuration of a local cleaning device according to an embodiment, focusing on a waterway system;

FIG. 61 shows an accumulator WP provided in the waterway system.
It is sectional drawing which shows schematic structure of 2-7.

FIG. 62: Wave generation device WP also arranged in a waterway system
It is sectional drawing showing the structure of 2-8.

FIG. 63 is an explanatory diagram illustrating a state of a flow of cleaning water by the wave generation device WP2-8.

FIG. 64 is a schematic view schematically showing a state of installation of the wave generation device WP2-8.

FIG. 65 is a block diagram illustrating a schematic configuration of a control system.

FIG. 66 is a schematic perspective view showing a nozzle device NS2-1.

FIG. 67 is a schematic sectional view taken along line 67-67 in FIG. 66.

FIG. 68 is a main-portion schematic cross-sectional view for describing a configuration of a flow path switching valve WN2-2 included in the cleaning nozzle.

FIG. 69 is an exploded perspective view of a main part of the flow path switching valve.

FIG. 70 is a plan view showing the nozzle head NH2-1 in a plan view and a part of the vicinity of the head cut away.

FIG. 71 is a plan view showing a modified example of the nozzle head.

FIG. 72 is an explanatory diagram illustrating excitation of a pulsation generating coil WP2-15 of a wave generation device WP2-8 for generating a pulsation at the time of flush water discharge.

FIG. 73 is a timing chart showing a flow rate and a flow rate of cleaning water flowing out of the wave generation device WP2-8.

FIG. 74: Butt discharge hole NH2 of nozzle head NH2-1
It is explanatory drawing which illustrates typically the state of washing water discharge from -2.

FIG. 75 shows a case where pulsating flush water is discharged from a water discharge hole.
It is explanatory drawing explaining the process in which the discharged washing water is amplified into a pulsating flow.

FIG. 76 is an explanatory diagram illustrating a state in which the cleaning water stream collides with a wall surface.

FIG. 77: A predetermined distance L facing the buttocks discharge hole NH2-2
It is explanatory drawing explaining the state which installed the pressure sensor board Ps at a distance.

FIG. 78 is an explanatory diagram three-dimensionally expressing the position on the pressure sensor plate Ps and the peak value of the pressure.

FIG. 79 is a timing chart showing a detection signal detected from one of the detection units.

FIG. 80 is a graph showing a relationship between an average water discharge amount and a cleaning amount.

FIG. 81 is an explanatory diagram for explaining the reason why the cleaning intensity varies depending on the increase or decrease of the frequency.

FIG. 82 is a graph showing a relationship between a pulsating frequency and a washing intensity of a pulsating flow and discomfort due to stimulation of a human body part;

FIG. 83 is an explanatory diagram for explaining a control example in which the pulsation frequency in the pulsating flow of the washing water is made different between the tail cleaning and the bidet cleaning.

FIG. 84 is an explanatory diagram illustrating a control example of a pulsation frequency ftm and a duty ratio Dtm.

FIG. 85 is a time chart illustrating a cleaning operation of the local cleaning device of the example.

FIG. 86 is a circuit diagram illustrating an example of a bottom detection circuit CT2-2 for the pulsation generation coil WP2-15.

FIG. 87 is an explanatory diagram for describing a state of a current waveform at the time of energization excitation of the pulsation generating coil WP2-15.

FIG. 88 is an explanatory diagram for describing an effect obtained by the accumulator WP2-7.

FIG. 89 is a block diagram illustrating a water channel configuration included in a local cleaning device according to a modification.

FIG. 90 is a block diagram illustrating a water channel configuration of a local cleaning device according to another modification.

FIG. 91 is a schematic configuration diagram showing a schematic configuration of a flow control switching valve WP2-20 of a modified example, partially cut away;

FIG. 92 is a block diagram illustrating a water channel configuration of a local cleaning device according to another modification.

FIG. 93 shows an intermittent valve WP2-27 arranged in this waterway system
It is sectional drawing showing the structure of.

FIG. 94 is an explanatory diagram illustrating a water pressure in a water channel system of a local cleaning device according to a modified example having the intermittent valve.

FIG. 95 is a block diagram illustrating a water channel configuration of a local cleaning device according to another modification.

FIG. 96 is a cleaning nozzle W of a modified example in which air is forcibly mixed.
It is explanatory drawing explaining the structure of N2-25.

FIG. 97 is a graph showing a relationship between an air mixing amount when air is forcibly mixed into the cleaning water and a cleaning area of the cleaning water spouted with the air mixing.

FIG. 98 is an explanatory diagram illustrating a configuration of a cleaning nozzle WN2-25 of another modified example for forcibly mixing air.

FIG. 99 is a schematic cross-sectional view of a main part of a cleaning nozzle of each modified example for achieving natural suction.

FIG. 100 is also a schematic cross-sectional view of a main part of a cleaning nozzle of each modified example for natural aspiration.

FIG. 101 is a schematic view schematically showing a cleaning nozzle of another modification for achieving natural suction.

FIG. 102 is a graph showing air entrainment characteristics in another modified example.

103 is a schematic perspective view schematically showing the internal structure in a see-through manner for explaining a nozzle head NH2-33 in which the cleaning nozzle shown in FIG. 101 is further modified.

FIG. 104 shows a nozzle head NH in another modified example.
It is a graph which shows the air entrainment characteristic in 2-33.

FIG. 105 is a cleaning nozzle WN2-35 of still another modification.
FIG.

FIG. 106 is an explanatory diagram illustrating a schematic configuration of a solenoid pump WN2-36 used in the cleaning nozzle of this modified example.

FIG. 107 is a schematic cross-sectional view of a main part of a cleaning nozzle WN3-1 included in the local cleaning device of the second embodiment.

FIG. 108 is a schematic sectional view of a main part of a cleaning nozzle WN4-1 according to a third embodiment;

FIG. 109 is an exploded perspective view of a main part of the cleaning nozzle WN4-1.

FIG. 110 is a schematic cross-sectional view of a main part of a cleaning nozzle WN5-1 included in a local cleaning device of a fourth embodiment.

FIG. 111 is a block diagram illustrating a water channel configuration included in a local cleaning device KS6-1 of the reference example.

FIG. 112 is an explanatory diagram showing a schematic configuration of a local cleaning apparatus KS6-2 of a modified example.

FIG. 113 is an explanatory diagram for describing a control method when discharging cleaning water to a cleaning point.

FIG. 114 is an explanatory diagram illustrating a cleaning point instruction panel KS6-5 according to another modification.

FIG. 115 is an explanatory view showing a local cleaning apparatus provided with a cleaning nozzle WN20 according to another reference example.

116 shows a cleaning nozzle WN22 according to another reference example, FIG. 116 (a) is a top view, and FIG. 116 (b) is a cross-sectional view from the side.

117 shows a cleaning nozzle WN24 according to another reference example, FIG. 117 (a) is a cross-sectional view, and FIG. 117 (b) is a plan view showing the movement of water discharge holes WN24-4b.

FIG. 118 shows a cleaning nozzle WN26 according to another reference example, in which FIG. 118 (a) is a sectional view and FIG. 118 (b) is a perspective view.

FIG. 119 is a cross-sectional view showing a cleaning nozzle WN28 according to another reference example.

120 shows a cleaning nozzle WN30 according to another reference example, FIG. 120 (a) is a cross-sectional view, and FIG. 120 (b) is a perspective view.

121 shows a cleaning nozzle WN32 according to another reference example, FIG. 121 (a) is a cross-sectional view, and FIG. 121 (b) is a perspective view.

122 shows a cleaning nozzle WN34 according to another reference example, FIG. 122 (a) is a perspective view of the cleaning nozzle WN34 from the side, and FIG. 122 (b) is a cross-sectional view of the cleaning nozzle WN34 from another direction. is there.

FIG. 123 (a) shows a cleaning nozzle WN36 according to another reference example, and FIG.
(B) is the figure seen from the side.

124 shows a cleaning nozzle WN38 according to another reference example, FIG. 124 (a) is a perspective view of the cleaning nozzle WN38 from the side, and FIG. 124 (b) is a cross-sectional view of the cleaning nozzle WN38 from another direction. is there.

FIG. 125 is an explanatory diagram showing each example of a cleaning nozzle WN40 according to another reference example.

126 shows a cleaning nozzle WN42 according to another reference example, FIG. 126 (a) is a cross-sectional view, FIG. 126 (b) is an oblique perspective view, FIG. 126 (c) is a layout view of a permanent magnet and an electromagnetic coil, FIG. 126 (d) is a schematic view of the movement by the permanent magnet and the electromagnetic coil.

FIG. 127 is a sectional view showing a cleaning nozzle WN44 according to another reference example.

FIG. 128 is an explanatory diagram showing the operation of the cleaning nozzle WN44.

FIG. 129 is a sectional view showing a cleaning nozzle WN46 according to another reference example.

FIG. 130 is a sectional view showing a cleaning nozzle WN48 according to another reference example and a modified example thereof.

131 is a configuration diagram showing a cleaning nozzle WN50 according to another reference example, FIG. 131 (a) is a top view, and FIG.
(B) is a sectional view from the side.

132 shows a cleaning nozzle WN52 according to another reference example, FIG. 132 (a) is a cross-sectional view, and FIG. 132 (b) is a perspective view of a main part thereof.

FIG. 133 shows a cleaning nozzle WN54 according to another reference example, FIG. 133 (a) is a sectional view, and FIG. 133 (b) is an arrangement diagram of an actuator WN54-6.

FIG. 134 shows a cleaning nozzle WN56 according to another reference example, FIG. 134 (a) is a sectional view, and FIG. 134 (b) is a drive switching mechanism diagram according to the rotation direction of the electric motor WN56-4c.

135 shows a cleaning nozzle WN58 according to another reference example, FIG. 135 (a) is a sectional view, and FIG. 135 (b) is FIG.
FIG. 135 (c) is a sectional view taken along line AA of FIG. 35 (a), and FIG. 135 (c) is an elastic body WN58- provided near the movable portion WN58-2.
FIG.

FIG. 136 is an explanatory diagram showing a cleaning nozzle WN60 according to another reference example.

FIG. 137 is an explanatory diagram showing a cleaning nozzle WN61 according to another reference example.

FIG. 138 shows a cleaning nozzle WN62 according to another reference example, and FIG. 138 (a) is a side view, FIG. 138.
(B) is an explanatory view seen from above.

139 shows a cleaning nozzle WN64 according to another reference example, FIG. 139 (a) is a cross-sectional view, and FIG. 139 (b) is a perspective view.

140 shows a cleaning nozzle WN66 according to another reference example, FIG. 140 (a) is a cross-sectional view, and FIG. 140 (b) is a perspective view.

141 shows a cleaning nozzle WN68 according to another reference example, FIG. 141 (a) is a sectional view, and FIG. 141 (b) is a perspective view.

FIG. 142 is a perspective view showing a cleaning nozzle WN70 and a cleaning nozzle WN72 according to another reference example.

FIG. 143 is an explanatory diagram showing a cleaning nozzle WN74 according to another reference example.

FIG. 144 is an explanatory diagram showing a cleaning nozzle WN76 according to another reference example.

FIG. 145 is an explanatory view showing a cleaning nozzle WN77 according to another reference example.

FIG. 146 shows a cleaning nozzle WN78 according to another reference example, FIG. 146 (a) is a schematic configuration diagram, FIG. 146 (b) is an explanatory diagram showing a state in which the water discharge direction is deflected right and left, and FIG.
46 (c) is an explanatory diagram showing a state in which the water discharge direction is deflected back and forth.

FIG. 147 is an explanatory view showing a local cleaning apparatus provided with a cleaning nozzle WN80 according to another embodiment.

FIG. 148 is an explanatory view showing a local cleaning apparatus provided with a cleaning nozzle WN84 according to another embodiment.

FIG. 149 is a sectional view showing a cleaning nozzle WN86 according to another embodiment.

FIG. 150 is an explanatory diagram showing a cleaning nozzle WN89 according to another reference example.

FIG. 151 is an explanatory diagram showing a local cleaning device including a cleaning nozzle WN90 according to another reference example.

FIG. 152 is an explanatory diagram showing a cleaning nozzle WN91 according to another reference example.

FIG. 153 is an explanatory diagram showing a cleaning nozzle WN92 according to another embodiment.

FIG. 154 is a sectional view showing a cleaning nozzle WN94 according to another reference example.

FIG. 155 is an explanatory diagram showing a cleaning nozzle WN96 and a cleaning nozzle WN97 according to another reference example.

FIG. 156 is an explanatory diagram showing a cleaning nozzle WN98 and a cleaning nozzle WN99 according to another reference example.

FIG. 157 shows a cleaning nozzle WN100 according to another reference example.
FIG.

FIG. 158 shows a cleaning nozzle WN102 according to another embodiment.
FIG.

FIG. 159 is a cleaning nozzle WN104 according to another reference example.
It is explanatory drawing which shows the local washing | cleaning apparatus provided with.

FIG. 160 shows a cleaning nozzle WN108 according to another reference example.
FIG.

FIG. 161 shows a cleaning nozzle WN112 according to another reference example.
FIG.

FIG. 162 shows a cleaning nozzle WN120 according to another reference example.
It is explanatory drawing which shows the local washing | cleaning apparatus provided with.

FIG. 163 is an explanatory diagram showing a shower head according to another reference example.

FIG. 164 is a cleaning nozzle WN126 according to another reference example.
FIG.

FIG. 165 shows a cleaning nozzle WN130 according to another reference example.
It is a block diagram which shows the waterway system and control system in the human body washing apparatus provided with.

FIG. 166 is an explanatory diagram showing a detailed view of an operation panel.

FIG. 167 is a sectional view showing a main part of a cleaning nozzle WN130.

FIG. 168 shows a cleaning nozzle WN132 according to another reference example.
It is explanatory drawing which shows the local washing | cleaning apparatus provided with.

FIG. 169 is an explanatory diagram for explaining a control method of increasing the flow velocity while keeping the flow rate constant when performing pulsating flow of flush water in the first reference example and its modified example. FIG. 4 is an explanatory diagram illustrating a control state.

FIG. 170 is an explanatory diagram showing an example of sequence control in which washing water spouting by oscillating rotation of the spouting hole realized in the reference example and washing water spouting with a pulsating flow realized in the first embodiment are combined in the washing operation. is there.

[Explanation of symbols]

 CT1-1 ... Electronic control device CT2-1 ... Electronic control device CT2-2 ... Bottom detection circuit CT6-2 ... Electronic control device KS1-1 ... Local cleaning device KS1-2 ... Main body KS1-3 ... Toilet seat KS1-4 ... Toilet lid KS1-5 ... Sleeve KS1-6 ... Display KS2-1 ... Local cleaning device KS6-3 ... Sleeve KS6-4 ... Rotating knob KS6-5 ... Indication panel NH1-1 ... Nozzle head NH1-7 ... O Butt discharge hole NH1-9 ... Body movable body NH1-10 ... Bidet discharge hole NH1-11 ... Bidet movable body NH1-15 ... Flange part NH1-17 ... Water piece NH1-18 ... Magnetic driver NH1-18a- Numeral 18c: Magnetic operating part NH1-19: Water discharge guide hole NH1-2: Nozzle head base NH1-23: Magnetic driver NH1-23a to 23c: Magnetic operating part NH1-24: Water discharge guide hole NH1-27: outside air suction hole NH1-30: butt swing coil group NH1-31: bidet swing coil group NH1-32a to 33c: electromagnetic coil NH1-39: swing detection circuit NH1-42: flat cable NH1-61 ... Rotating coil group for hips NH1-62 ... Rotating coil group for bidet NH1-71 ... Rotating coil group for bidet NH1-75 ... Moving body for bidet NH2-1 ... Nozzle head NH2-21 ... Orifice NH3-10: shielding plate NH3-6: first inflow chamber NH3-7: second inflow chamber NH3-8: first waterwheel NH3-9: second waterwheel NH4-1: nozzle head NH4-2: intermittent water discharge mechanism NH4-6: Water wheel NH4-9: Shield plate NH5-1: Cleaning nozzle NH5-2: Butt water discharge hole NH5-3: Nozzle flow path NH5-4: Air mixing chamber NH5-5: Porous pipe H5-6: Air flow path NH5-7: Air pressure feeding / mixing unit NH5-8: Cleaning water supply unit NS1-1: Nozzle device NS1-12: Nozzle advance / retreat trajectory NS1-4: Nozzle drive motor NS1-7: Guide rail NS1-8: Drive pulley NS1-9: Follower pulley NS2-1: Nozzle device RC1-1: Remote control device RT: Schematic water discharge column SS10: Seated sensor SS113: Outgoing water temperature sensor SS14: Cleaning water amount sensor SS16a: Incoming water temperature sensor SS16b ... Water temperature sensor SS18 ... Float switch SWa ... Stop button SWb ... Bottom cleaning button SWc ... Soft cleaning button SWd ... Bidet cleaning button SWea ... Massage setting button SWfa, SWfv ... Move setting button SWhd ... Low power setting button SWk ... Nozzle cleaning Button SWua, S uv: Spot setting button SWva, SWvv: Wide setting button TH1-1: Heat exchange unit TH1-2: Heater TH1-3: Tank TH1-4: Vacuum breaker WN1-1: Cleaning nozzle WN2-10: Spring WN2-30 ... Air pump WN2-31 ... Air flow control valve WN2-36 ... Solenoid pump WN3-1 ... Cleaning nozzle WN4-1 ... Cleaning nozzle WN5-1 ... Cleaning nozzle WP1-14 ... Flow control pump WP1-16 ... Functional water generation tank WP1 -4 ... Functional water unit WP1-5 ... Upstream water supply line WP1-6 ... Downstream water supply line WP1-9 ... Constant flow valve WP2-14 ... Plunger WP2-15 ... Electromagnetic coil WP2-15 ... Pulse generation coil WP2 -25 ... Pressurizing equipment WP2-26 ... Intermittent flow generation unit WP2-27 ... Intermittent valve WP2-3: Wave generation unit WP2-30: Housing WP2-5: Upstream water supply line WP2-6: Downstream water supply line WP2-7: Accumulator WP2-8: Wave generation device WP2-9: Housing WN20: Cleaning Nozzle WN20-41: Water discharge swinging means WN20-41a: Rotating motor WN20-41b: Rotating disk WN20-41c: Water discharge hole WP20-1: Cleaning water supply means WP20-11: Water pump WP20-12: Water stop valve WP20 -13: Flow control valve WN20-6: Control unit WN2-61: Cleaning water supply control means WN20-62: Heat exchanger control means WN20-64: Orbit control unit control means TH20-2: Heat exchanger WN22: Cleaning nozzle WN22-3: water discharge section WN22-31b: water discharge hole WN22-32b: water passage WN2 2-34 ... seal part WN22-35 ... seal part WN22-4 ... water discharge part drive mechanism WN22-41d ... motor WN22-42b ... shaft CT22-2 ... predetermined trajectory control means TH22-51 ... heat exchanger WP22-53 ... flow rate Adjustable water stop valve WN24 ... Washing nozzle WN24-2 ... Coupling WN24-3a ... Immobilized water passage WN24-4a ... Moving water passage WN24-4b ... Water discharge hole WN24-51a ... Drive motor WN24-51b ... Rotating shaft WN24-51c ... Eccentricity Cam WN24-6a: Shaft WN26: Cleaning nozzle WN26-10: Packing WN26-11: Space WN26-2: Water supply unit WN26-20: Water discharge unit drive motor WN26-20a: Rotating shaft WN26-20b: Eccentric cam WN26-2a: Water inlet WN26-4 ... Water outlet WN26-4 ... Water inlet WN26-4b ... Water outlet WN26-4c ... Path WN26-52 ... Support WN28 ... Wash nozzle WN28-2 ... Water supply unit WN28-21 ... Water discharge state change motor WN28-21b ... Water discharge state change cam WN28-2a ... Water supply port WN28-3: Water discharge state changing means WN28-3a: Hole WN28-3c: Spring WN28-3d: Water supply section flange WN28-4: Water discharge section WN28-4a: Water inlet WN28-51: Cleaning water supply path WN30: Cleaning Nozzle WN30-2: Joint WN30-3a: Immovable water channel WN30-43: Forward / reverse reversing disk WN30-4a: Moving water channel WN30-4b: Water discharge hole WN30-51a: Drive motor WN30-51b: Rotating shaft WN30-51d: Crank disk WN30-51e ... connecting rod WN30- a ... shaft WN30-6b ... shaft WN30-A ... connecting portion WN30-B ... connecting portion WN32 ... washing nozzle WN32-2 ... joint WN32-3a ... immovable water passage WN32-4a ... moving water passage WN32-4b ... water discharge hole WN32 -52a ... Electromagnetic coil WN32-52b ... Ferromagnetic material WN32-52c ... Void WN32-6a ... Shaft WN34 ... Washing nozzle WN34-1a ... Water channel WN34-1b ... Water outlet WN34-2 ... Water pump WN34-31a ... Outlet WN34-3a: Flow control valve WN34-4: Rotary water discharge means WN34-4a: Impeller WN34-4b: Impeller casing WN34-4d: Sealing part WN36: Cleaning nozzle WN36-1a: Water passage WN36-1c: Air intake WN36-2: Water pump WN36-31a: Outlet WN36-3a: Flow Adjusting valve WN36-4: rotating water discharging means WN36-4a: impeller WN38: washing nozzle WN38-12d: rotating water passage WN38-1a: water passage WN38-1b: water discharging hole WN38-1d: rotating protrusion WN38-1e: draining Outlet WN38-1f Seal part WN38-1g Shaft WN38-1h Water passage WN38-2 Water pump WN38-31a Outlet WN38-3a Flow control valve WN38-3b Flow control valve WN38-4 Rotary spout Means WN38-4a: Impeller WN38-4b: Impeller casing WN38-4d: Seal part WN40: Cleaning nozzle WN40-1: Water pump WN40-2: Impeller WN40-2a: Impeller WN40-2b: Impeller WN40- 2c: Impeller WN40-2d: Impeller WN42: Cleaning tip WN42-2 ... Joint WN42-3a ... Immovable water passage WN42-44 ... Swing projection WN42-4a ... Moving water passage WN42-4b ... Water discharge hole WN42-53a ... Electromagnetic coil WN42-53b ... Permanent magnet WN42-53c ... Flange WN42-53d: air gap WN42-6a: shaft WN44: cleaning nozzle WN44-41: check valve WN44-42: flow regulating water valve WN44-44: water supply channel WN44-45: fixed ceramic disk WN44-46: rotating ceramic disk WN44-47: Flow control stepping motor WN44-48: Spring WN44-70: Water discharge swinging unit WN44-71: Water discharge unit space WN44-72: Nozzle unit WN44-73: Swing cam WN44-74: Swing motor WN44- 75 ... water discharge hole WN44-40 ... electric control equipment WN46: Cleaning nozzle WN46-4a: Moving water passage WN46-4b: Water discharge hole WN46-52a: Electromagnetic coil WN46-52b: Ferromagnetic material WN46-6a: Shaft WN48: Cleaning nozzle WN48-2: Joint WN48-4: Locus movement Projecting part WN48-4b ... water discharge hole WN48-51b ... ferromagnetic material WN48-51d ... fixture WN48-52d ... flange WN48-5a ... armature WN48-5b ... mover WN48-5c ... gap WN50-53 ... flow control Water valve WN50-3: water discharge section WN50-31a: water discharge hole WN50-31b: water discharge hole WN50-32b: water passage WN50-32c: valve box WN50-32d: valve body WN50-32e: water passage WN50-32f: water passage WN50-34: Seal part WN50-35: Seal part WN50-4 Water discharge part drive mechanism WN50-41d ... motor WN50-42b ... shaft WN50-2 ... predetermined trajectory control means WN50-51 ... heat exchanger WN52 ... washing nozzle WN52-2 ... joint WN52-4 ... trajectory movement protrusion WN52-4a ... Outlet WN52-51b ... Ferromagnetic material WN52-52b ... Flange WN52-5a ... Armature or pair armature WN52-5b ... Mover WN52-5c ... Air gap WN54 ... Cleaning nozzle WN54-10 ... Packing WN54-2 ... Water supply unit WN54-2a: Water supply port WN54-4: Water discharge part WN54-4a: Water inlet WN54-4b: Water discharge hole WN54-4c: Passage WN54-52: Supporting part WN54-6: Actuator WN54-6a: Ferromagnetic material WN54-6b ... Armature or pair armature WN56 ... Cleaning nozzle WN56 -3c: moving water passage WN56-3d: water discharge hole WN56-3e: immovable water passage WN56-3f: joint WN56-3h: packing WN56-41c: rotating shaft WN56-41e: flange WN56-4c: electric motor WN56-4d: Eccentric cam WN56-4e ... Movable part WN56-7 ... Shaft WN56-A ... Coupling WN56-A1 ... Protrusion WN56-B ... Coupling WN56-B1 ... Long groove WN56-B2 ... End WN56-B3 ... End WN56 -... Cleaning nozzle WN58-2: movable part WN58-2b: water discharge hole WN58-2c: ejector port WN58-3: moving means WN58-3c: electric motor WN58-3d: eccentric cam WN58-3e: annular follower WN58-4: elastic Body WN58-41b ... half ring-shaped part WN58-42b ... furan Part WN58-4b: Spring-shaped resin WN58-4c: Sheet-shaped rubber WN60: Cleaning nozzle WN60-11: Water pump WN60-12: Flow control valve WN60-13: Water supply path WN60-14: Rotational swing means WN60-15 ... Water discharge hole WN60-22: Eccentric cam WN60-24: Flexible joint WN60-25: Water discharge channel WN60-26: Rotating oscillating body WN60-28: Porous body WN60-29: Oscillating fixed part AP60-16: Air pump AP60-17a ... air valve AP60-17b ... air valve AP60-18a ... air flow path AP60-18b ... air flow path AP60-19 ... air port AP60-20 ... air bubble mixing means AP60-21 ... air turbine AP60-27 ... air chamber WN61 ... Cleaning nozzle WN61-14 ... Rotation swinging means WN61-2 5: water discharge channel WN61-28: porous body AP61-19: air port AP61-20: air bubble mixing means WN62: cleaning nozzle WN62-11: water pump WN62-12: flow control valve WN62-13: water supply channel WN62-14 ... Rotation rocking means WN62-15 ... water discharge hole WN62-24 ... flexible joint WN62-25 ... water discharge passage WN62-26 ... rotation rocking body WN62-29 ... rocking fixed part WN62-31 ... spring AP62-16 ... air pump AP62- 17 ... air valve AP62-18 ... air flow path AP62-30 ... air nozzle WN64 ... washing nozzle WN64-2 ... joint WN64-3a ... immovable water passage WN64-45 ... follower part WN64-4a ... moving water passage WN64-4b ... Water spout WN64-51a ... Drive motor WN64-51b ... Rotary shaft N64-51c: Eccentric cam WN64-51f: Leaf spring WN64-6a: Shaft WN64-6b: Shaft WN66: Washing nozzle WN66-2: Joint WN66-3a: Immovable water passage WN66-4a: Moving water passage WN66-4b: Water discharge Hole WN66-54a: Electromagnetic coil WN66-54b: Ferromagnetic material WN66-54c: Air gap WN66-54d: Spring WN66-6a: Shaft WN68: Cleaning nozzle WN68-3c: Moving water passage WN68-3d: Spout hole WN68-3e: Immovable water passage WN68-3f ... Joint WN68-3h ... Packing WN68-7 ... Shaft WN68-8 ... Water discharge swinging part WN68-81a ... Ferromagnetic material WN68-82a ... Flange WN68-8a ... Movement WN68-8b ... Armature WN68-8c: air gap WN70: cleaning nozzle WN70-1: water discharge hole WN70-41b: nozzle rotation motor WN72: cleaning nozzle WN72-1: water discharge hole WN72-41c: nozzle front / rear drive motor WN72-41db: nozzle left / right drive motor WN74: cleaning nozzle WN74-1: fluid element WN74-2: water discharge hole WN76: Cleaning nozzle WN76-1: Fluid element WN76-2: Water discharge hole WN76-41b: Nozzle rotation motor WN77: Cleaning nozzle 41e: Vibration motor WN78: Cleaning nozzle WN78-21b: Nozzle guide WN78-3b: Flow control valve WN78-41a: Rotating shaft WN78-41b: Rotating shaft WN78-4a: Front-rear deflection motor WN78-4b: Left-right deflection motor WN78-5: Control unit TH80-2: Heat exchanger TH80-5: Hot water storage unit WN80: Cleaning nozzle WN80 -1 ... Water supply means WN80-13: Water pump WN80-14: Water stop valve WN80-15: Flow control valve WN80-4: Intermittent discharge means WN80-42: Water discharge hole WN80-43: Electromagnetic valve WN84: Cleaning nozzle WN84-13: Water Pump WN84-15: Flow control valve WN84-42: Water discharge hole WN84-45: Variable valve CT84-7: Control unit CT84-71: Cleaning water supply control means WN86: Cleaning nozzle WN86-42: Flow regulating water valve WN86- 75 ... water discharge hole WN86-76 ... intermittent water discharge unit WN86-77a ... permanent magnet WN86-77 ... valve element WN86-78 ... electromagnetic coil WN86-79 ... spring body WN89 ... cleaning nozzle WN89-42b ... motor WN89-42c ... rotating disk WN89-42d: water discharge hole WN90: cleaning nozzle W 90-31 ... Water discharge hole WP90-1 ... Washing water supply means WP90-11 ... Washing water discharge means WP90-11a ... Valve section WP90-11b ... Water pump WP90-12 ... 12b: water pump CT90-6: control unit CT90-61: washing water discharge control unit CT90-62: heat exchanger control unit CT90-63: water pressure change control unit TH90-2: heat exchanger SW90-7: operation unit SW90 -71: Local cleaning operation instructing means SW90-72: Water force instructing means WN91: Cleaning nozzle WN91-31: Water discharge hole WN91-41a: Cleaning water rotating motor WP91-1: Cleaning water supply means WP91-11: Cleaning water discharge means WP91 -11a: Valve unit WP91-11b: Water pump WP91-12: Hand for changing water pressure Stage WP91-12a Flow control valve WP91-12b Water pump CT91-6 Control unit CT91-61 Cleaning water discharge control means CT91-62 Heat exchanger control means CT91-63 Water force change control means HT91-2 Heat exchanger SW91-7 ... Operation unit SW91-71 ... Local washing operation instructing means SW91-72 ... Water force instructing means WN92 ... Washing nozzle WN92-9 ... Water passage WN92-12d ... Intermittent valve unit WN92-44a ... Intermittent motor HT92- 2 heat exchanger WN92-31 water discharge hole WP92-12a flow control valve WP92-12b water pump SW92-72 water pressure indicating means CT92-63 water pressure change control means WN94 cleaning nozzle WN94-21c armature WN94 -22c: mover WN94-23c: water passage WN94-24 c: air gap WN94-25c: ferromagnetic material WN94-26c: elastic material WN94-2a: electromagnetic valve WN94-2b: water pump WN94-2c: swing water discharge section WN94-3a: power line WN94-3b: power line WN94-3c Power line WN94-4a: Shaft WN94-6a: Terminal WN94-6b: Water supply connection port WN96: Cleaning nozzle WN96-21d: Spray water swinging part WN96-2d: Motor WN97: Cleaning nozzle WN97-21d: Gear WN97-22d: Moving part WN98: Cleaning nozzle WN98-1: Nozzle head WN98-11b: Expansion joint WN98-21e: Heater WN98-2e: Heat exchanger WN98-7a: Spring portion WN98-8b: Pinion WN98-8c: Rack WN99: Cleaning nozzle WN99 -7b ... Power supply line WN1 00: cleaning nozzle WN100-21d: water discharge swinging part WN100-2f: air pump WN100-21f: mixing part WN102: cleaning nozzle WN102-50: nozzle body WN102-70: nozzle head WN102-81a: electromagnetic valve WN102-82a: Plunger WN102-83a ... Ferromagnetic material WN102-84a ... Armature WN102-85a ... Spring CT102-35 ... Flow control unit CT102-8 ... Power limiting means CT102-8a ... Intermittent discharge control unit CT102-8b ... Wash water flow rate control unit SW102-13e: discharge temperature setting dial SW102-13d: water pressure setting dial WP102-31: cleaning water heating means WN104: cleaning nozzle WN104-50: nozzle body WN104-70: nozzle head WN104-81 e: ejection hole group disk WN104-83e: ejection hole group unit WN104-84e: ejection hole group unit WN104-85e: ejection hole group unit WN104-86e: switching motor WN104-8e: ejection hole group WN110-82e: ejection section CT104 -35: Flow control unit CT104-8: Power limiting means CT104-8b: Cleaning water flow rate control unit SW104-13a: Anal cleaning setting means SW104-13b: Bidet cleaning button SW104-13e: Spout temperature setting dial SW104-13d: Water force Setting dial TH104-31: Cleaning water heating means WN108: Cleaning nozzle WN108-31: Discharge hole WN108-45a: Rotating disk WN108-45b: Water discharge hole WN108-45c: Driving motor WN112: Cleaning nozzle WP112-12 Flow control valve WP112-13 Water pump WN112-44 Swing means CT112-71 Cleaning water supply control means WN120 Cleaning nozzle WP120-1 Cleaning water supply means WP120-11 Water stop valve WP120-12 Flow rate control Valve WP120-13: Water pump WN120-31: Water discharge port AP120-41: Air pump AP120-41a: Air mixing part CT120-7: Cleaning capacity control means CT120-71: Cleaning water supply control means CT120-72: Air pump control Means TH120-2 Heat exchanger WN124 Cleaning nozzle WN124-1b Main body water passage WN124-2b Water outlet WN124-2 Moving part WN126 Cleaning nozzle WN126-9 Water passage AP126-42a Air mixing part AP126- 12c ... Air pump TH126: heat exchanger WN126-31: water discharge hole WP126-12b: water pump WP126-12a: flow control valve SW126-72: water pressure indicating means CT126-63: water pressure change control means WP130-4: first temperature detection means WN130 ... Cleaning nozzle WN130-10a: Cylindrical filter WN130-11: Water discharge port WN130-12: Cleaning water with air WP130-1: Cleaning water suction port WP130-2: Open / close valve WP130-3: Constant flow valve AP130-10: Air mixing section AP130-10b ... air chamber AP130-14 ... air pump AP130-15 ... air suction port AP130-32 ... air flow path TH130-7 ... washing water heating means SP130-6 ... operation panel SW130-21 ... washing switch SW130-22 ... Cleaning intensity setting button SW1 0-23: Water discharge temperature setting button WN132: Cleaning nozzle WN132-50: Nozzle body WN132-70: Nozzle head CT132-35: Flow control unit AP132-81d: Air pump AP132-82d: Air mixing unit CT132-8d: Air mixing control Part CT132-8: Power limiting means CT132-8b: Cleaning water flow rate control part TH132-31: Cleaning water heating means SW132-13d: Water pressure setting button SW132-13e: Discharge temperature setting button

 ──────────────────────────────────────────────────続 き Continued on the front page (31) Priority claim number Japanese Patent Application No. 10-137736 (32) Priority date April 30, 1998 (1998. 4.30) (33) Priority claim country Japan (JP) (31) Priority claim number Japanese Patent Application No. 10-156760 (32) Priority date May 20, 1998 (May 20, 1998) (33) Priority claim country Japan (JP) (31) Priority claim number Japanese Patent Application No. 10-158409 (32) Priority date May 21, 1998 (May 21, 1998) (33) Priority claiming country Japan (JP) (31) Priority claim number Japanese Patent Application No. Hei 11-373 ( 32) Priority date January 5, 1999 (1.5.1999) (33) Priority claiming country Japan (JP) (31) Priority claim number Japanese Patent Application No. 11-15336 (32) Priority date 1999 January 25 (1999.1.25) (33) Priority claiming country Japan (JP) (31) Priority claim number Japanese Patent Application No. 10-259231 (32) Priority date August 28, 1998 (1998. 8.28) (33) Excellent Claiming country Japan (JP) (31) Priority claim number Japanese Patent Application No. 10-126902 (32) Priority date April 20, 1998 (1998. 4.20) (33) Priority claiming country Japan (JP) (72) Inventor Hisato Haraga 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu City, Fukuoka Prefecture Inside Totoki Equipment Co., Ltd. (72) Inventor Minoru Sato 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu City, Fukuoka Prefecture East (72) Inventor Shinsuke Matsuo 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu-city, Fukuoka Prefecture In-house Ceramics Co., Ltd. (72) Nogawa Kawahara 2-chome Nakajima, Kokurakita-ku, Kitakyushu-shi, Fukuoka No. 1-1 Toto Kiki Co., Ltd. (72) Inventor Takahiro Ohashi 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu City, Fukuoka Prefecture Toko Kiki Co., Ltd. (72) Inventor Haruo Tsutsui Kokurakita, Kitakyushu City, Fukuoka Prefecture (72) Inventor Kozo Fujita 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu-shi, Fukuoka 2) Inventor Makoto Hatakeyama 2-1-1, Nakajima, Kokurakita-ku, Kitakyushu-shi, Fukuoka Prefecture (72) Inventor Koichi Toyoda 2-1-1, Nakajima, Kokurakita-ku, Kitakyushu-city, Fukuoka Totoki Equipment (72) Inventor Eiji Kitamoto 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu-shi, Fukuoka Touchi Kikai Co., Ltd. (72) Takashi Kinoshita 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu-shi, Fukuoka No. Totoki Equipment Co., Ltd. (72) Inventor Rinori Yanase 2-1-1 Nakajima, Kokurakita-ku, Kitakyushu-shi, Fukuoka Prefecture Totoki Equipment Co., Ltd. (72) Ryosuke Hayashi Nakajima, Kitakyushu-shi, Fukuoka Prefecture 2-1-1, Totoki Kiki Co., Ltd. (72) Inventor Yasuo Hamada 2-1-1, Nakajima, Kokurakita-ku, Kitakyushu-shi, Fukuoka Totoki Kiki Co., Ltd.

Claims (14)

[Claims] 1. A human body cleaning apparatus for cleaning a human body by discharging supplied cleaning water, comprising a water discharging hole for cleaning water, and a nozzle for discharging the cleaning water from the water discharging hole toward the human body; A water discharge means for discharging water so that a human body does not recognize a change in pressure of the wash water accompanying a change in a temporal flow rate of the wash water while temporally changing a flow rate of the wash water discharged from the water discharge hole. A human body washing device characterized by the above-mentioned. 2. A human body cleaning apparatus for cleaning a human body by discharging supplied cleaning water, comprising a water discharging hole for cleaning water, and a nozzle for discharging the cleaning water from the water discharging hole toward the human body; A water discharging means for discharging water so as to prevent a human body from recognizing a change in pressure of the washing water due to a change in the temporal flow rate of the washing water while temporally changing a flow rate of the washing water discharged from the water discharging hole. A human body washing device characterized by the above-mentioned. 3. A human body cleaning apparatus for cleaning a human body by discharging supplied cleaning water, comprising: a nozzle for discharging cleaning water; and a nozzle for discharging the cleaning water from the water discharging hole toward the human body. While varying the flow rate of the wash water discharged from the water discharge port with time, the human body recognizes the pressure change of the wash water due to the change in the temporal flow rate of the wash water and the change of the water discharge mode due to the pressure change. A human body washing apparatus comprising: a water discharging means for performing a cycle shorter than a possible temporal fluctuation cycle. 4. A human body cleaning apparatus for cleaning a human body by discharging supplied cleaning water, comprising: a nozzle for discharging cleaning water; and a nozzle for discharging the cleaning water from the water discharging hole toward the human body; The human body recognizes a change in the pressure of the washing water due to the change in the temporal flow rate of the washing water and a change in the water discharge mode due to the change in the pressure while changing the flow rate of the washing water discharged from the water discharge port with time. A human body washing apparatus comprising: a water discharging means for performing a cycle shorter than a possible temporal fluctuation cycle. 5. The water discharge means according to claim 3, wherein the water discharge means changes the water discharge in a water discharge mode generated in a cycle shorter than a temporal fluctuation cycle that can be recognized by a human body according to a time transition in a cleaning period. Human body washing device that changes. 6. The water discharge means according to claim 1, wherein the water discharge means causes a situation where the minimum flow rate is zero in the transition of the flow rate of the wash water accompanying the temporal fluctuation of the flow rate or the flow rate of the wash water. A human body cleaning device that performs intermittent water discharge. 7. The water discharging means according to claim 1, wherein the water discharge means does not cause a situation in which the minimum flow rate is zero in the transition of the flow rate of the wash water accompanying the temporal change of the flow rate or the flow rate of the wash water. Body rinsing device that performs pulsating spouting. 8. The human body cleaning apparatus according to claim 1, wherein a cycle of the cleaning water over time is 5 Hz or more. 9. The water discharging device according to claim 1, wherein the water discharging device controls the water discharging device in accordance with the water pressure set by the water setting device. A human body washing apparatus comprising: a water discharge control unit that changes an aspect. 10. The cycle setting means for setting the time-varying cycle of the flow rate or flow rate of the washing water according to any one of claims 1 to 9, and the water discharge so as to have the set cycle. A human body cleaning apparatus comprising: a periodic water discharge control means for controlling the means so as to discharge the cleaning water with a temporal variation of a set cycle. 11. The nozzle according to claim 1, wherein the nozzle is provided with a plurality of water discharge holes for discharging cleaning water to different regions to be cleaned and cleaning the regions. A human body washing apparatus for performing washing water spouting with time variation by the spouting means from at least one of the holes. 12. The nozzle according to claim 1, wherein a plurality of nozzles are provided for discharging cleaning water to different regions to be cleaned to clean the regions, and at least one of the plurality of nozzles is provided. And a human body washing apparatus for performing the spouting of the washing water with time variation by the water spouting means. 13. The setting unit according to claim 11, wherein the time-varying cycle of the flow rate or the flow rate of the cleaning water is set for each of the plurality of areas to be cleaned. A control means for controlling the water discharge means in such a manner as to discharge the wash water with a temporal variation of a set cycle for each of the plurality of cleaning target areas. 14. The water discharging means according to claim 1, wherein said water discharging means controls the water discharging means in synchronization with a cleaning start command from said command means. A human body washing apparatus having fluctuation control executing means for executing a flush water discharge with a temporal fluctuation due to the above.