JP5578295B2 - Sanitary washing device - Google Patents

Description

  The present invention relates to flow rate control of cleaning water in a sanitary cleaning device.

  2. Description of the Related Art Conventionally, various sanitary washing apparatuses equipped with a highly accurate flow sensor have been developed in order to eject washing water to a local part of a human body at an appropriate temperature and flow rate (see, for example, Patent Document 1).

  The sanitary washing device described in Patent Document 1 includes a flow sensor on the upstream side of a heat exchanger that heats washing water. The flow rate sensor includes a swirl chamber in which cleaning water flows in a substantially U shape, a rotor having swirl vanes, a photo interrupter, and the like. And the interruption | blocking of the light by the turning blade rotated by the washing water which flows into the swirl chamber of a flow sensor is detected with a photo interrupter, and the flow rate is detected. Accordingly, the flow rate of the cleaning water can be detected with high detection accuracy, and the cleaning water can be heated to an appropriate temperature by the heater of the heat exchanger.

  However, the above-described conventional configuration requires a complicated flow sensor separately, so that the sanitary washing apparatus cannot be made compact and there is a problem in cost. In addition, there is a problem that a detection error occurs due to bubbles or the like mixed with the cleaning water in the flow sensor.

Japanese Patent No. 3620215

  In order to solve the above problems, a sanitary washing device of the present invention includes a washing nozzle that discharges washing water, and a washing water passage that circulates washing water from a supply source to the washing nozzle. The cleaning water channel includes a positive displacement pump that controls the flow rate of the cleaning water discharged from the cleaning nozzle, and a tank that stores upstream of the positive displacement pump and stores a portion of the cleaning water channel to the atmosphere. And a water level sensor that detects the water level of the tank and outputs a signal, an electromagnetic valve that allows the cleaning water supplied from the supply source to flow into and out of the atmospheric air, and a positive displacement pump and an electromagnetic valve And a control unit for controlling. Further, the control unit has a configuration for correcting the control of the positive displacement pump by calculating the flow rate of the cleaning water supplied from the supply source per unit time based on the signal of the water level sensor.

  According to this configuration, by disposing the positive displacement pump downstream of the atmosphere opening portion, the rotational speed of the positive displacement pump is controlled without depending on the supply pressure of the water supply source, and the cleaning water discharged from the cleaning nozzle is discharged. To control the flow rate. Furthermore, the control of the positive displacement pump is corrected by measuring the flow rate actually passed by the water level sensor and feeding it back to the control unit. Thereby, it correct | amends with the flow volume detected with the water level sensor, and can control the flow volume of the washing water ejected from a positive displacement pump, without receiving the influence of the dispersion | variation in a component, aged deterioration, etc. As a result, without providing a flow sensor or a flow control valve, accurate and stable flow control can be performed over a long period of time, and a sanitary washing apparatus having a simple configuration and excellent in comfort can be realized.

FIG. 1 is a perspective view of a toilet apparatus to which a sanitary washing device according to Embodiment 1 of the present invention is applied. FIG. 2 is a front view of the remote control device of the sanitary washing device according to the embodiment. FIG. 3 is a schematic diagram illustrating a configuration of a main body portion of the sanitary washing device according to the embodiment. FIG. 4 is a schematic diagram illustrating an example of an air release portion of the sanitary washing device according to the embodiment. FIG. 5 is a cross-sectional view of the positive displacement pump of the sanitary washing device in the same embodiment. FIG. 6 is a time chart showing an example of the operation of the sanitary washing device according to the embodiment. FIG. 7 is a block diagram of a water level control unit of the control unit of the sanitary washing device according to the embodiment. FIG. 8 is a flowchart showing the correction operation of the water level control unit of the control unit of the sanitary washing device in the same embodiment. FIG. 9 is a schematic diagram of an air release portion of the sanitary washing device according to Embodiment 2 of the present invention.

  Hereinafter, a sanitary washing device and a toilet device according to embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the present embodiment.

(Embodiment 1)
Hereinafter, a sanitary washing device and a toilet device including the same according to Embodiment 1 of the present invention will be described with reference to FIG.

  1 is a perspective view of a toilet apparatus equipped with a sanitary washing device according to Embodiment 1 of the present invention. The toilet apparatus 1000 is installed in the toilet room.

  As shown in FIG. 1, a toilet apparatus 1000 according to the present embodiment includes at least a sanitary washing apparatus 100, a toilet bowl 700, an entrance detection sensor 600, and the like, and the sanitary washing apparatus 100 is mounted on the toilet bowl 700.

  The sanitary washing device 100 includes a main body 200, a remote operation device 300, a toilet seat 400, a lid 500, and the like. The main body 200 incorporates a seating sensor 610 provided in the upper front portion and a cleaning water supply mechanism (see FIG. 3) controlled by the control unit 4, and the toilet seat 400 and the lid 500 are attached to be freely opened and closed. The seating sensor 610 is composed of, for example, a reflective infrared sensor, and detects the presence or absence of a user on the toilet seat 400 by detecting infrared light reflected from the human body.

  One of the washing water supply mechanisms built in the main body 200 is connected to a toilet nozzle 40 provided at the lower front portion of the main body 200, and the other is connected to a water pipe. In FIG. 1, the toilet nozzle 40 is shown in a state of protruding to the inside of the toilet 700. At this time, the cleaning water supply mechanism supplies cleaning water supplied from the water pipe to the toilet nozzle 40. In the case of toilet cleaning, the supplied cleaning water is sprayed from the toilet nozzle 40 to a wide area on the inner surface of the toilet 700, and in the case of rear cleaning of the toilet, cleaning is performed from the toilet nozzle 40 to the back side of the inner surface of the toilet 700. Spout water.

  Further, the cleaning water supply mechanism built in the main body 200 is a nozzle composed of a butt nozzle 1 which is a local cleaning nozzle constituting the cleaning nozzle, a bidet nozzle 2 which is a bidet cleaning nozzle, a nozzle cleaning nozzle 3 and a toilet nozzle 40. It is connected to the unit 20 (see FIG. 3). Accordingly, the cleaning water supply mechanism supplies the cleaning water supplied from the water pipe to the nozzle unit 20. Then, the supplied cleaning water is ejected from the buttocks nozzle 1 and the bidet nozzle 2 to the user's local area. Moreover, the washing water supplied to the nozzle washing nozzle 3 of the nozzle part 20 is sprayed to the nozzle parts 20 such as the buttocks nozzle 1 and the bidet nozzle 2 to wash them.

  The operation unit such as the remote operation device 300 has a plurality of switches for selecting a cleaning mode for cleaning a plurality of cleaning nozzles, and is attached to a place where a user sitting on the toilet seat 400 can operate.

  The entrance detection sensor 600 is configured by, for example, a reflective infrared sensor, and is attached to an entrance of a toilet room. The room entry detection sensor 600 detects that the user has entered the toilet room when detecting infrared rays reflected from the human body.

  Further, the control unit 4 (see FIG. 3) of the main body unit 200 controls the operation of each unit of the sanitary washing device 100 based on signals transmitted from the remote operation device 300, the room entry detection sensor 600, and the seating sensor 610.

  Below, the structure of the remote control apparatus 300 of the sanitary washing apparatus 100 in this Embodiment is demonstrated using FIG.

  FIG. 2 is a front view of the remote control device of the sanitary washing device according to the embodiment.

  As shown in FIG. 2, the operation unit such as the remote control device 300 includes a wide cleaning switch 305, a rhythm cleaning switch 306, water setting switches 307 and 308, a move cleaning switch 309, Position setting switches 310 and 311, and a stop switch 302, a butt switch 303, and a bidet switch 304 that are provided below the controller main body 301 and instruct to stop the cleaning operation are provided.

  As shown in FIG. 1, first, when the user operates each switch of the operation unit of the remote operation device 300, a predetermined signal corresponding to each switch is transmitted from the remote operation device 300 to the main body unit 200, for example, by wireless transmission. Is done. The control part 4 (refer FIG. 3) of the main-body part 200 controls operation | movement of each structure part of the main-body part 200 and the toilet seat part 400 based on the received signal. For example, when the user presses down the buttocks switch 303 or the bidet switch 304, the control unit 4 moves the nozzle unit 20 of the main body unit 200 such as the buttocks nozzle 1 or the bidet nozzle 2 to eject the washing water, and the user Clean the local area. At this time, the user sets one of a plurality of water forces from the washing water force “weak” to the washing water force “strong” by the water force setting switches 307 and 308 at the time of washing the butt and the bidet. And according to the set water flow, the control part 4 controls the quantity of the washing water ejected from the nozzle part 20, and wash | cleans a local part.

  Below, the structure and effect | action of a water supply system and a control system in the main-body part 200 of the sanitary washing apparatus 100 of this Embodiment are demonstrated using FIG.

  FIG. 3 is a schematic diagram showing the configuration of the main body of the sanitary washing device according to the embodiment.

  As shown in FIG. 3, the main body 200 of the sanitary washing device 100 includes a control unit 4 having a water level control unit 4 s, a branch tap 5, a strainer 6, an electromagnetic valve 7, an air release unit 8, a constant flow valve 9, a heat It is comprised from the exchanger 12, the temperature sensors 13a and 13b, the positive displacement pump 14, the buffer tank 15, the switching valve 16, the nozzle part 20, and the toilet nozzle motor 40m. Moreover, the nozzle part 20 of the main-body part 200 is comprised from the buttocks nozzle 1, the bidet nozzle 2, the nozzle washing nozzle 3, the toilet nozzle 40, etc. as mentioned above, and the switching valve 16 contains the switching valve motor 16m.

  Further, as shown in FIG. 3, a branch tap 5 is inserted in a water supply pipe 201 that is a supply source of cleaning water, and is connected to a cleaning water flow path 202 that leads to a butt nozzle 1 and a bidet nozzle 2 constituting the cleaning nozzle. The In the washing water flow path 202, the constant flow valve 9, the strainer 6, the electromagnetic valve 7, the tank 8 a having the vacuum breaker 31 and the relief valve 51, the air release unit 8, the temperature sensor 13 a, the heat exchanger 12, the temperature sensor 13 b, buffer tank 15, positive displacement pump 14, and switching valve 16 are inserted in order from the branch tap 5.

  Further, the toilet nozzle 40 constituting the nozzle unit 20 is connected to the end of the toilet flushing water channel 205 branched from the flushing water channel 202 by the switching valve 16. A toilet nozzle motor 40 m is attached to the toilet nozzle 40.

  Next, the flow of cleaning water in the main body 200 of the sanitary washing device 100 and the control of each component of the main body 200 by the control unit 4 will be described with reference to FIG.

  First, as shown in FIG. 3, tap water flowing through the water pipe 201 is supplied to the strainer 6 by the branch tap 5 as cleaning water. Then, dust and impurities contained in the cleaning water are removed by the strainer 6.

  Next, the control unit 4 controls the electromagnetic valve 7 to switch the supply state of the cleaning water. At this time, the pressure of the washing water flowing through the washing water flow path 202 through the constant flow valve 9 formed of a rubber variable orifice whose orifice diameter changes due to the working water pressure is reduced.

  Next, the washing water controlled by the solenoid valve 7 passes through the atmosphere release section 8 described in detail below, and is heated by a heater having a heater provided downstream of the atmosphere release section 8 and upstream of the positive displacement pump 14. It is supplied to the exchanger 12.

  Next, the heater 12h of the heat exchanger 12 supplies the cleaning water supplied through the cleaning water channel 202 to a predetermined temperature such as 39 ° C. (a cleaning temperature setting unit (not shown) of an operation unit such as a remote control device). ) Heat to the temperature set by). At this time, the positive displacement pump 14 (hereinafter referred to as “positive displacement pump”), which is a pulsating pump connected to the heat exchanger 12, is driven and controlled by the water level control unit 4 s of the control unit 4 to operate the positive displacement pump 14. Washing water having a flow rate corresponding to the speed is discharged from the buttocks nozzle 1 or the bidet nozzle 2 which is a washing nozzle. Therefore, the heating operation by the heater 12h of the heat exchanger 12 is controlled by the control unit 4 based on the measured temperature value measured by the temperature sensors 13a and 13b and the flow rate of the cleaning water controlled by the positive displacement pump 14. .

  Next, the wash water heated by the heater 12 h of the heat exchanger 12 is pumped to the switching valve 16 through the buffer tank 15 by the positive displacement pump 14. Then, the switching valve 16 is controlled to be switched to the butt nozzle 1 or the bidet nozzle 2 or the nozzle cleaning nozzle 3 constituting the cleaning nozzle by the control unit 4. In addition, the switching valve 16 is controlled to be switched to a toilet nozzle 40 that is discharged onto the surface of the toilet bowl for toilet cleaning and rear cleaning of the toilet.

  At this time, the buffer tank 15 functions as a temperature buffer for heated washing water. That is, the occurrence of uneven temperature in the wash water pumped to the switching valve 16 is suppressed. The total capacity of the heat exchanger 12 and the buffer tank 15 is preferably 15 cc to 30 cc, and more preferably 20 cc to 25 cc. Thereby, in a general sanitary washing apparatus, the temperature fluctuation of washing water can be controlled with optimal responsiveness.

  Next, the control unit 4 controls the operation of the switching valve motor 16m, and the switching valve 16 is any one of the butt nozzle 1, the bidet nozzle 2, the nozzle cleaning nozzle 3, and the toilet nozzle 40 that constitutes the nozzle unit 20 of the cleaning nozzle. The washing water pumped from the positive displacement pump 14 is supplied. As a result, washing water is ejected from any one of the buttocks nozzle 1, the bidet nozzle 2, the nozzle washing nozzle 3, and the toilet nozzle 40.

  The buttocks nozzle 1 and the bidet nozzle 2 are used for cleaning the user's local area. The nozzle cleaning nozzle 3 is used for cleaning the portions of the buttocks nozzle 1 and the bidet nozzle 2 that protrude into the toilet bowl 700. Furthermore, the toilet nozzle 40 is used for cleaning the inside of the toilet.

  Next, the atmosphere opening part provided in the main body part of the sanitary washing device in the present embodiment will be described with reference to FIG.

  FIG. 4 is a schematic diagram illustrating an example of an air release portion of the sanitary washing device according to the embodiment.

  As shown in FIG. 4, the atmosphere opening unit 8 includes a tank 8 a having at least a water inlet 8 b, a water outlet 8 d, and an atmosphere opening hole 8 c, a water level sensor 11, a vacuum breaker 31, a relief valve 51, and the like. Yes. The water inlet 8b of the tank 8a is provided on the upstream side of the tank 8a, and cleaning water such as tap water is injected into the tank 8a through the electromagnetic valve 7 of the main body 200. The water outlet 8d of the tank 8a flows the washing water into the heat exchanger 12 provided on the downstream side of the tank 8a. The water level sensor 11 detects the water level of the cleaning water stored in the tank 8a and outputs, for example, a conduction signal. The air release hole 8c of the tank 8a is provided in the upper part of the vacuum breaker 31 provided in the tank 8a, and the inner upper part of the tank 8a is opened to the atmosphere to form an air layer 8e. In addition, although not shown in figure, the pipe | tube which guides the wash water which overflows from the tank 8a by a failure into the toilet bowl 700 is connected to the air release hole 8c of the tank 8a.

  At this time, the tank 8a constituting the atmosphere opening unit 8 temporarily stores cleaning water such as tap water supplied from a supply source whose temperature fluctuates depending on the surrounding environment, and suppresses fluctuations to about the room temperature. That is, the tank 8a functions as an incoming water temperature buffer for the washing water. Therefore, the temperature variation of the washing water entering from the supply source is buffered to some extent, and the washing water without a sudden temperature change can be supplied from the tank 8a to the heat exchanger 12. Thereby, when heating washing water with heater 12h of heat exchanger 12, burdens, such as electric power, can be reduced. In addition to the temperature buffering action of the buffer tank 15, the uneven discharge temperature of the cleaning water can be further reduced.

  Moreover, the vacuum breaker 31 is provided in the upper part of the tank 8a, and when the tank 8a falls down, the external leakage of the washing water in the tank 8a is prevented. The relief valve 51 is provided in the upper part of the tank 8a, and releases the internal pressure when the internal pressure of the tank 8a exceeds a predetermined pressure. Moreover, the water level sensor 11 is comprised by the electrode which consists of the 1st sensor 11b, the 2nd sensor 11a, and the 3rd sensor 11c from which three lengths differ, for example, and the 1st sensor 11b, the 2nd sensor 11a, and the 3rd sensor 11c. The tip position is set so as to detect the upper limit water level and the lower limit water level by contact with the cleaning water in the tank 8a. For example, the lower limit water level is a state in which the second sensor 11a having the longest water level sensor 11 is immersed in the cleaning water and the intermediate first sensor 11b is not immersed in the cleaning water, that is, conduction between the second sensor 11a and the first sensor 11b. Detected by disappearance. At this time, the tip position of the first sensor 11b is arranged at least at the same position as or higher than the upper end position 12g of the heater 12h of the heat exchanger 12 shown in FIG. On the other hand, the upper limit water level is detected when the tip positions of the three first sensors 11b, the second sensor 11a, and the third sensor 11c are all immersed in the cleaning water.

  As described above, the water level sensor 11 shown in FIG. 4 has a configuration in which the first sensor 11b, the second sensor 11a, and the third sensor 11c having different lengths are installed so as to protrude from the upper part of the tank 8a into the tank 8a. Although explained, it is not limited to this. For example, three sensors (not shown) having the same length correspond to the tip positions of the first sensor 11b, the second sensor 11a, and the third sensor 11c having different lengths shown in FIG. 4 from the side surface 8f of the tank 8a. For example, the water level sensor 11 may be configured by being arranged at an upper, middle, or lower height position. Thereby, a water level sensor can be comprised by one type of the same length and short sensor, without using three types of sensors from which length differs. As a result, the components constituting the sensor can be standardized from three types to one type, and the management cost and material cost can be reduced by using a short sensor configuration.

  The relief valve 51 may be disposed on the upstream side of the atmosphere opening portion 8 or may be integrated with the electromagnetic valve 7. Thereby, downsizing | reduction of the air release part 8, the main-body part of a sanitary washing apparatus, etc. can be achieved.

  Next, the configuration and operation of the positive displacement pump, which is a pulsating pump provided in the main body of the sanitary washing apparatus, will be described with reference to FIG.

  FIG. 5 is a cross-sectional view of the positive displacement pump of the sanitary washing device in the same embodiment.

  As shown in FIG. 5, the positive displacement pump 14 includes a pump main body 81 having at least a cylindrical space 82, a pressure feed piston 83, a motor 86, a link mechanism 89, and the like. At this time, the cylindrical space 82 of the pump body 81 is divided into a pump chamber 82a and a pump chamber 82b by the pressure feed piston 83.

  A flush water inflow portion 84 is provided on one side of the pump main body 81, and a wash water outflow portion 85 is provided on the other side. The inflow part 84 is connected to the heat exchanger 12 via the washing water flow path 202, and the outflow part 85 is connected to the switching valve 16 via the washing water flow path 202.

  Then, the gear 87 attached to the rotation shaft of the motor 86 and the gear 88 connected to the link mechanism 89 mesh with each other, so that the rotational motion of the motor 86 is converted to the reciprocating motion of the pressure feed piston 83 via the link mechanism 89. Converted. That is, when the motor 86 rotates, the pressure-feed piston 83 reciprocates through the gear 87, the gear 88, and the link mechanism 89.

  Thereby, the positive displacement pump 14 performs the following operation.

  First, when the pumping piston 83 moves downward and the volume of the pump chamber 82 a increases, the pressure in the pump chamber 82 a becomes lower than that of the inflow portion 84. Therefore, the cleaning water in the heat exchanger 12 is supplied from the inflow part 84a to the pump chamber 82a.

  On the other hand, when the pumping piston 83 moves upward to reduce the volume of the pump chamber 82a, the pressure in the pump chamber 82a becomes higher than that in the outflow portion 85. Therefore, the cleaning water supplied to the pump chamber 82a is discharged to the outflow portion 85a.

  Accordingly, when the cleaning water in the pump chamber 82a is discharged from the outflow portion 85a, the cleaning water is supplied from the inflow portion 84b into the pump chamber 82b. When the cleaning water in the pump chamber 82a is supplied from the inflow portion 84a, the cleaning water in the pump chamber 82b is discharged from the outflow portion 85b.

  That is, the pressure is alternately applied to the cleaning water in the pump chamber 82a or the pump chamber 82b by the vertical movement of the pumping piston 83. Moreover, periodic pulsation can be given to the wash water of the inflow part 84 by changing the reciprocating speed of the pressure feed piston 83 in one rotation. At this time, the pulsation pressure of the washing water is such that the minimum pressure during pulsation is substantially equal to the inflow pressure of the positive displacement pump 14. On the other hand, the maximum pulsating pressure is a pressure corresponding to the load of the positive displacement pump 14 and the rate of volume change of the positive displacement pump 14. Thereby, the wash water to which the pulsation pressure is applied is discharged from the outflow portion 85 of the positive displacement pump 14.

  At this time, as shown in FIG. 3, the upstream side of the positive displacement pump 14 is open to the atmosphere by the open air portion 8 inserted in the cleaning water flow path 202. That is, the inflow pressure of the washing water flowing into the positive displacement pump 14 becomes atmospheric pressure (corresponding to 0 MPa in terms of atmospheric pressure based gauge pressure) without being affected by the supply pressure of tap water that is a supply source.

  Therefore, for example, when the switching valve 16 is switched to the toilet nozzle 40, the toilet nozzle 40 includes a flush water having a flow rate and a pulsation pressure corresponding to the rotational speed of the motor 86 of the positive displacement pump 14 controlled by the control unit 4. Is supplied. Thereby, the jet of washing water can be discharged from the toilet nozzle 40 into the toilet in a stable state at an arbitrary pressure and an arbitrary flow rate without being affected by the supply pressure of tap water as a supply source. As a result, the jet of washing water discharged from the toilet nozzle 40 can be prevented from jumping out of the toilet bowl. The installation position of the positive displacement pump 14 in the height direction is preferably installed at a position lower than the water level of the atmosphere opening portion 8. Thereby, the head capacity of the positive displacement pump 14 can be reduced and energy loss can be reduced.

  That is, according to the sanitary washing device 100 of the present embodiment, the positive displacement pump 14 provided on the upstream side of the toilet nozzle 40 and a part of the flush water flow path 202 upstream of the positive displacement pump 14 are connected to the atmosphere. An air release unit 8 that opens and a control unit 4 that controls each unit are provided. Therefore, the flow rate of washing water ejected from the toilet nozzle 40 and the maximum pressure of pulsation are not affected by the supply pressure of tap water supplied from the water supply pipe serving as the supply source. That is, the flow rate of the wash water ejected from the toilet nozzle 40 and the maximum pressure of pulsation can be arbitrarily adjusted according to the operating speed of the positive displacement pump 14 by the control unit 4. Thereby, it is possible to prevent the jet of washing water discharged from the toilet nozzle 40 from jumping out of the toilet bowl. In addition, stool adhesion can be prevented by pre-wetting the toilet bowl surface with a jet of washing water from the toilet nozzle 40. Furthermore, the dirt already attached to the toilet bowl surface can be effectively removed by the washing water jet from the toilet nozzle 40.

  Hereinafter, the reason why the above-described effects can be obtained will be described.

  Generally, when the supply pressure of tap water as a supply source is acting on the inflow portion 84 of the positive displacement pump 14, the minimum pressure of the pulsation pressure of the positive displacement pump 14 is the supply pressure of tap water. At this time, if the maximum pressure of the pulsation pressure is constant, there is almost no change in the load, so the pulsation width becomes small.

  However, as in the present embodiment, when the atmosphere is released by the atmosphere opening portion 8 of the washing water flow path 202 on the upstream side of the positive displacement pump 14, the pressure of the inflow portion 84 of the positive displacement pump 14 becomes almost atmospheric pressure. . Therefore, the minimum pressure of the pulsating pressure of the positive displacement pump 14 is atmospheric pressure. On the other hand, the maximum pulsation pressure of the positive displacement pump 14 can be varied according to the number of rotations of the motor 86 of the positive displacement pump 14 and the pulsation width can be increased.

  In the present embodiment, the cleaning water is ejected from the toilet nozzle 40 to perform toilet cleaning. However, the present invention is not limited to this. For example, when the local part of the human body is washed with the buttocks nozzle 1 or the bidet nozzle 2 which is a washing nozzle, it may be applied to nozzle washing, and the same effects as shown below can be obtained.

  That is, as described above, the primary side wash water of the positive displacement pump 14 is open to the atmosphere. Therefore, the minimum pressure of the pulsation pressure of the wash water discharged from the positive displacement pump 14 is the atmospheric pressure, and the highest pressure is the positive displacement type. It can be made variable according to the rotational speed of the motor 86 of the pump 14. Therefore, by rotating the motor 86 of the positive displacement pump 14 at a low speed to reduce the flow rate, the pressure amplitude of the pulsation pressure is small, and the local cleaning with a gentler cleaning feeling can be realized. On the other hand, by rotating the motor 86 of the positive displacement pump 14 at a high speed to increase the supply flow rate to the nozzle unit 20, the pressure amplitude of the pulsation pressure is increased, and a solid local cleaning with a sense of stimulation can be performed. it can. That is, the greater the supply flow rate, the greater the pulsation width. As a result, a wider sense of cleaning can be provided to the user without being affected by the supply pressure of tap water as a supply source.

  Then, by controlling the rotational speed of the positive displacement pump 14, the flow rate discharged from the cleaning nozzle is controlled to be a flow rate according to the water flow set by the water flow setting switches 307 and 308 of the operation unit of the remote operation device 300. As described above, the number of rotations of the motor 86 is controlled by the control unit 4. By this control, the user's favorite flow rate can be accurately maintained and the optimum flow rate in each cleaning can be obtained. As a result, it is possible to realize a sanitary washing device with excellent usability.

  As described above, the sanitary washing device 100 according to the present embodiment particularly controls the washing water by variably controlling the rotation speed of the motor 86 of the positive displacement pump 14 without providing a flow sensor or a flow control valve. The flow rate can be controlled and pulsation can be imparted to the wash water.

  Further, as shown in FIG. 4, the sanitary washing device 100 of the present embodiment has a water level sensor 11 for detecting the water level of the tank 8a, and a tank at the upper part of the atmosphere opening portion 8 having a tank 8a for storing washing water. An air layer 8e that opens the inner upper portion of 8a to the atmosphere, a vacuum breaker 31 that prevents external leakage of the washing water in the tank 8a, a relief valve 51 that releases the internal pressure of the tank 8a, and the like are provided. For example, when the sanitary washing device 100 is removed from the toilet bowl 700 and the toilet bowl is cleaned, when the tank 8a is tilted upside down and the washing water in the tank 8a is about to flow out, the vacuum valve body 31a of the vacuum breaker 31 Closes the upper valve seat 31d. Thereby, the flow path through which the washing water leaks from the tank 8a can be closed. As a result, it is possible to prevent the washing water from the tank 8a from leaking or falling to the floor or the like.

  Normally, the vacuum valve body 31a of the vacuum breaker 31, for example, made of rubber, is brought into contact with the lower valve seat 31b by gravity to seal the inside of the tank 8a, but the lower valve seat 31b of the vacuum breaker 31 has an air escape path. A communication slit 31c is provided. Therefore, the upper part inside the tank 8a is opened to the atmosphere by the communication slit 31c, and the air layer 8e is formed.

  Moreover, the vacuum breaker 31 of this Embodiment is provided in the tank 8a. For this reason, when the water supply pipe side that is the supply source has a negative pressure, air is sucked from the vacuum breaker 31 provided in the upper part of the tank 8a. As a result, it is possible to prevent the wash water downstream from the tank 8a from flowing back to the water pipe that is the supply source of the wash water.

  Moreover, the relief valve 51 of this Embodiment is comprised from the relief valve body 51a and the relief spring 51b. The set pressure of the relief spring 51b of the relief valve 51 is set to, for example, 0.1 MPa so that the relief valve body 51a does not open with the head pressure of the washing water when the tank 8a is turned upside down. On the other hand, the relief valve 51 is set to open at a pressure lower than the pressure at which the tank 8a is damaged (for example, 0.4 MPa). Thereby, the internal pressure of the tank 8a is suppressed to a predetermined pressure or less, and the reliability is improved.

  Hereinafter, the operation of the sanitary washing device of the present embodiment will be described with reference to FIGS. 6 and 7 with reference to FIGS. 1 and 3.

  FIG. 6 is a time chart showing an example of the operation of the sanitary washing device according to the embodiment. FIG. 7 is a block diagram of a water level control unit of the control unit of the sanitary washing device according to the embodiment.

  FIG. 6 shows the flow of operations from the time t1 to the time t22 from the time when the user enters the toilet room to the time when the user leaves and leaves the room. 6, the operation of the electromagnetic valve 7, the water level of the tank 8a, the output of a signal for adjusting the flow rate from the water level control unit 4s, the operation mode of the positive displacement pump 14, the switching flow path of the switching valve 16, the heat Each item of the heater 12h of the exchanger 12 indicates an operation corresponding to a time series from time t1 to time t22.

  First, as shown in FIGS. 6 and 7, when the entrance detection sensor 600 detects that a user has entered the toilet room at time t1, the third sensor 11c of the water level sensor 11 cleans the tank 8a. Detect whether the amount of water is the upper limit water level. Normally, a sanitary washing device is used, and after the user has left the seat, water is supplied until the water level of the tank 8a becomes full (upper limit water level) (until the third sensor 11c detects the washing water). Preparing for use. However, when the water level of the tank 8a does not reach full water (upper limit water level) at the time when the user enters the room, the electromagnetic valve 7 is turned on to supply water until the third sensor 11c detects cleaning water.

  And if the wash water in the tank 8a is an upper limit water level, the positive displacement pump 14 will be driven and the switching valve 16 will be switched to the toilet flushing flow path, and toilet flushing will be started. At the same time, the heater 12h of the heat exchanger 12 is energized to perform “preheating” that warms the cleaning water in the tank 8a in advance.

  Next, when the wash water decreases to the first sensor 11b that detects the lower limit water level at time t2 during toilet flushing, the flow rate is calculated by the flow rate calculation unit 4s2 of the water level control unit 4s ("flow rate reading" in the figure). A signal corresponding to the flow rate is output, and the rotational speed of the positive displacement pump 14 is adjusted via the pump control unit 4s3. At this time, the positive displacement pump 14 is driven at a rotation speed set in advance in the toilet cleaning mode. However, there may be a difference between the flow rate actually discharged and the preset flow rate set in advance in toilet flushing due to aging deterioration and component variations. Therefore, first, the actual flow rate per unit time is calculated by the flow rate calculation unit 4s2 from the decreasing speed of the water level in the tank 8a. Based on the calculated value of the flow rate, if there is a deviation from the set flow rate for toilet flushing, the rotational speed of the positive displacement pump 14 is corrected and adjusted. Thereby, washing water can be pumped out of the tank 8a with a more accurate flow rate.

  Next, at time t3, the control unit 4 stops toilet flushing and preheating.

  Next, the human body is detected, and the user sits on the toilet seat at time t4, for example, after 6 seconds.

  Next, when the user depresses the butt switch 303 (or the bidet switch 304) of the operation unit such as the remote control device 300 at time t5 after the user has worked, first, the butt nozzle 1 (or the bidet nozzle 2). ) Is housed inside the main body of the sanitary washing device, and nozzle cleaning is performed by the nozzle cleaning nozzle 3. Then, after performing nozzle cleaning for a predetermined time, at time t6, the buttocks nozzle 1 is protruded from the main body to the cleaning position toward the toilet, and at time t7, human body cleaning is started.

  At this time, at the time of nozzle cleaning, the cleaning water in the tank 8a is used, and the positive displacement pump 14 and the switching valve 16 are driven in accordance with the cleaning mode of each cleaning nozzle. The heater 12h of the heat exchanger 12 is energized to heat the cleaning water while the cleaning water is used.

  In the following, first, the user sets the cleaning water power “weak” with the operation unit such as the remote control device 300 such as a remote controller, starts the human body cleaning from the time t7 to the time t12, and then sets the cleaning water power “ A case where the human body is washed during the period from time t12 to time t16 will be described as an example.

  First, when the water level in the tank 8a decreases to the first sensor 11b at time t8 during washing of the human body with the washing water flow “weak”, the electromagnetic valve 7 is turned on while the washing of the human body is continued, and the third sensor 11c is washed. Water is supplied until time t9 when the upper limit water level (full water) is detected.

  Then, while the butt cleaning is performed with the cleaning water power “weak”, the water level in the tank 8a is used during the time “tweak” at the time t10 when the water level in the tank 8a decreases from the third sensor 11c to the second sensor 11a. The actual flow rate per unit time is calculated by the flow rate calculation unit 4s2 of the water level control unit 4s of the control unit 4, and a signal corresponding to the flow rate is output. At this time, if there is a discrepancy between the preset flow rate in the water flow of the buttocks cleaning “weak” and the actual flow rate, the water level control unit 4 s of the control unit 4 is connected to the positive displacement pump 14 via the pump control unit 4 s 3. , And adjust by correcting the rotational speed. Thereby, the ejection amount of the wash water controlled by the positive displacement pump 14 can be accurately adjusted. At time t8, when the water level in the tank 8a drops to the first sensor 11b that detects the lower limit water level, water supply is required, but in this case, the flow rate is not adjusted. The reason for this is that when the water level in the tank 8a drops from the upper limit water level of the third sensor 11c to the lower limit water level of the first sensor 11b, the cleaning mode of the nozzle cleaning and the cleaning mode of the cleaning water force “weak” butt cleaning are straddled. Because. That is, the flow rate is not read when the flow rate control based on the rotational speed of the positive displacement pump 14 spans different cleaning modes or the passage of time such as driving for causing the nozzle to protrude between the water supply and the next water supply. That is, only when the water level in the tank 8a decreases from the upper limit water level of the third sensor 11c to the lower limit water level of the first sensor 11b in a single cleaning mode, the flow rate is read and the flow rate is corrected. Make adjustments. As a result, it is possible to accurately draw out the flow rate in each cleaning mode.

  In general, it is assumed that the standard cleaning time for one human body cleaning is about 30 seconds. Therefore, the installation position is determined so that the amount (volume) of wash water stored between the third sensor 11c and the first sensor 11b of the tank 8a is 60 cc. This is because, for example, the flow rate adjustment is always performed once even when the human body cleaning is performed for only 15 seconds at the minimum flow rate of about 300 cc / min (when the washing water flow is “weak” and the butt cleaning is performed). Because.

  Next, in the case where the washing water power “strong” is washed from time t12 to time t16, when it is detected at time t13 that the level of washing water in the tank 8a has decreased, water is supplied to the tank 8a. However, in this case, as described above, the flow rate is not adjusted because the wash water is reduced across the wash modes (wash water flow “weak” to wash water flow “strong”) with different flow rate settings.

  After that, when the cleaning water in the tank 8a decreases from the time t14 to the time t15, it is in the cleaning mode of the human body cleaning with the same cleaning water power “strong”, so the flow rate is calculated by the water level control unit 4s and the volume type The rotational speed of the pump 14 is corrected and adjusted as necessary.

  Next, when the user depresses the stop switch 302 of the operation unit such as the remote control device 300 at time t16, the control unit 4 and the water level control unit 4s drive the positive displacement pump 14 and the heater 12h of the heat exchanger 12. To stop. At this time, the water is supplied until the water level in the tank 8a reaches the upper limit water level (detected by the third sensor 11c).

  Then, from time t16 to time t17, the control unit 4 moves the cleaning nozzle from the protruding position to the storage position inside the main body. Thereafter, from time t17 to time t18, post-cleaning of the nozzle after being used at the storage position is performed, and the operation is stopped.

  Next, when the user leaves the toilet seat from time t19 to time t20, nozzle cleaning after the seating is performed.

  In order to prepare for the use of the next user during the nozzle cleaning after the seating or after the nozzle cleaning after the seating, the water level of the control unit 4 is set during the period from the time t21 to the time t22. The controller 4s opens the electromagnetic valve 7 and supplies cleaning water into the tank 8a to fill it up.

  As described above, a series of operations of the sanitary washing device of the present embodiment is performed.

  At this time, the water level control unit 4 s of the control unit 4 appropriately corrects the flow rate value actually measured by the water level sensor 11 while basically controlling the discharge flow rate by the positive displacement pump 14. The correction does not necessarily have to be performed every time in each cleaning mode, and may be performed in the case where a flow rate deviation occurs due to variations in component parts or the influence of aging deterioration during long-term use. Thereby, an appropriate flow rate can be ejected from the cleaning nozzle according to each cleaning mode over a long period of time.

  Below, the structure of the water level control part 4s of the control part 4 of the sanitary washing apparatus of this Embodiment is demonstrated in detail using FIG.

  Note that the control unit 4 of the sanitary washing apparatus of the present embodiment has a microcomputer (not shown), and stores in advance the optimum flow rate in each washing mode and the optimum flow rate at the water selected by the user. Yes. Then, based on the output of the water level sensor 11, the rotational speed of the positive displacement pump 14 is corrected and driven so that the flow rate corresponds to the cleaning mode.

  First, as shown in FIG. 7, the water level control unit 4s of the control unit 4 of the sanitary washing device includes at least a time detection unit 4s1, a flow rate calculation unit 4s2, a pump control unit 4s3, a water level detection unit 4s4, and an electromagnetic valve. And a control unit 4s5. Based on the signal from the water level sensor 11, the time detection unit 4s1 measures the time until the water level of the tank 8a reaches the lower limit water level from the upper limit water level. The flow rate calculation unit 4s2 calculates the flow rate discharged by the positive displacement pump 14 by dividing the volume between the upper limit water level and the lower limit water level of the tank 8a (corresponding to the wash water capacity) by the time measured by the time detection unit 4s1. The pump control unit 4s3 operates the rotational speed (rotation) of the positive displacement pump 14 so that the flow rate is selected by the user using the water setting switches 307 and 308 of the operation unit based on the flow rate value calculated by the flow rate calculation unit 4s2. (Such as number). The water level detection unit 4s4 detects the level of the cleaning water in the tank 8a based on the signal detected by the water level sensor 11 provided in the tank 8a. The electromagnetic valve control unit 4s5 controls the electromagnetic valve 7 so as to maintain the wash water in the tank 8a in the range from the upper limit water level to the lower limit water level, and supplies tap water into the tank 8a.

  Below, the correction | amendment operation | movement of the pump control part of the water level control part of the control part in the sanitary washing apparatus of this Embodiment is demonstrated using FIG. 7 and FIG.

  FIG. 8 is a flowchart showing the correction operation of the water level control unit of the control unit of the sanitary washing device in the same embodiment.

  In addition, FIG. 8 demonstrates the correction | amendment operation | movement of a water level control part when the flow volume reduces from the time t2 of FIG. 6 to the time t3 as an example.

  As shown in FIG. 8, the control unit 4 first protrudes (nozzle protrusion) the buttocks nozzle 1 (or the bidet nozzle 2) designated by the operation unit such as the remote operation device 300 into the toilet bowl 700. Then, the flow path leading to the posterior nozzle 1 (or the bidet nozzle 2) instructed by the switching valve 16 is opened to start cleaning (step S1).

  Next, the water level control unit 4s determines whether or not the third sensor 11c of the water level sensor 11 is immersed in the cleaning water in the water level detection unit 4s4 (step S2). In addition, the 2nd sensor 11a of the water level sensor 11 is installed in the lowest position (state always immersed in water) with a common sensor.

  When the third sensor 11c of the water level sensor 11 is immersed in the cleaning water (YES in step S2), the cleaning water level is at the upper limit water level of the tank 8a. This state is determined when the current between the second sensor 11a and the third sensor 11c of the water level sensor 11 is detected by the water level detection unit 4s4.

  Then, the electromagnetic valve control unit 4s5 of the water level control unit 4s performs control so as to maintain the electromagnetic valve 7 in a closed state (the electromagnetic valve 7 is OFF) (step S3).

  On the other hand, when the third sensor 11c of the water level sensor 11 is not immersed in the cleaning water (NO in step S2), although not shown, if the first level sensor 11b detects the lower limit water level at which the cleaning water is not detected by the water level detection unit 4s4, the electromagnetic wave is detected. A signal is output to the valve control unit 4s5, the electromagnetic valve 7 is turned on, and water is supplied to the upper limit water level (step S11).

  Next, the time detection unit 4s1 of the water level control unit 4s starts counting time from the state in which the third sensor 11c of the water level sensor 11 is immersed in the cleaning water (step S4). At this time, the level of the cleaning water in the tank 8a is gradually lowered by the discharge of the cleaning water from the buttocks nozzle 1 by the positive displacement pump 14.

  Next, the water level controller 4s determines whether or not the first sensor 11b of the water level sensor 11 is immersed in the cleaning water in the water level detector 4s4 (step S5). At this time, when the first sensor 11b of the water level sensor 11 is not immersed in the cleaning water (NO in step S5), the water level of the cleaning water is at the lower limit water level of the tank 8a. That is, the current between the first sensor 11b and the second sensor 11a is not detected by the water level detection unit 4s4. On the other hand, when the first sensor 11b of the water level sensor 11 is immersed in the cleaning water (YES in Step S5), the process waits until the first sensor 11b is not immersed in the cleaning water.

  Next, the time detection unit 4s1 of the water level control unit 4s ends the time counting when the first sensor 11b of the water level sensor 11 is not immersed in the cleaning water (step S6). Thereby, the time t during which the cleaning water in the tank 8a decreases from the upper limit water level detected by the third sensor 11c to the lower limit water level detected by the first sensor 11b is measured.

  Next, the flow rate calculation unit 4s2 of the water level control unit 4s has a capacity Q of the washing water in the tank 8a from the upper limit water level detected by the third sensor 11c to the lower limit water level detected by the first sensor 11b at the time t. Is divided to calculate the flow rate V.

  Next, for example, the set flow rate Vi ejected from the positive displacement pump 14 in advance in the cleaning mode is compared with the flow rate V calculated by the actual measurement (step S8). At this time, if the set water amount Vi is equal to the calculated flow rate V (YES in step S8), the pump control unit 4s3 of the water level control unit 4s maintains the rotational speed of the positive displacement pump 14 (step S9), and step Returning to S2, the same processing after step S2 is performed.

  On the other hand, when the set water amount Vi and the calculated flow rate V are different (NO in step S8), the pump control unit 4s3 of the water level control unit 4s rotates the positive displacement pump 14 so that the set water amount Vi and the calculated flow rate V are equal. The number is corrected and adjusted (step S10), and the process returns to step S2 to perform the same processing after step S2.

  As described above, the water level control unit 4s of the sanitary washing device according to the present embodiment includes the water level control unit 4s including at least the time detection unit 4s1, the flow rate calculation unit 4s2, and the pump control unit 4s3. Accordingly, the operating speed (the rotation speed, etc.) of the positive displacement pump 14 is automatically adjusted so as to maintain the desired flow rate set by the user with the water flow setting switches 307, 308, etc. without providing a separate flow rate sensor. Further, when the flow rate per unit time can be calculated based on the flow rate actually measured by the water level sensor 11, the rotational speed of the positive displacement pump 14 can be corrected and controlled using the calculated value. As a result, it is possible to realize a sanitary washing device that is compact, compact, inexpensive, and has an excellent feeling of use with no deviation from the set flow rate.

  In the sanitary washing device of the present embodiment, the relief valve 51 is provided facing the air layer 8e in the upper part of the tank 8a, not in the lower part or the bottom part of the tank 8a. For this reason, the relief valve 51 is not exposed to cleaning water since the valve seat contact surface 51c of the relief valve body 51a is in the air during normal use. If the relief valve 51 is provided at the bottom or bottom of the tank 8a, the valve seat contact surface 51c of the relief valve body 51a is exposed to the washing water and becomes inoperable due to adhesion due to water scale. There is a possibility that problems such as the occurrence of dust biting on the surface 51c cause the washing water in the tank 8a and the heat exchanger 12 to escape and the heat exchanger 12 to be scooped. Therefore, by providing the relief valve 51 so as not to face the bottom or bottom of the tank 8a but to the air layer 8e at the top of the tank 8a, the risk of air blowing in the heat exchanger 12 can be further reduced.

  Further, the control unit 4 of the present embodiment is configured such that when the lower limit water level of the wash water in the tank 8a is detected by the water level sensor 11 and the water level detection unit 4s4 of the water level control unit 4s, and when the user uses the toilet seat 400 When a predetermined time has elapsed after the seating, the water is supplied until the water level of the cleaning water in the tank 8a reaches the upper limit water level (corresponding to the position of the third sensor 11c), and then the electromagnetic valve control unit 4s5 operates the electromagnetic valve 7 and the like. To stop. Thereby, the water level of the washing water in the tank 8a can be made higher than the upper end position 12g of the heater 12h of the heat exchanger 12 shown in FIG. As a result, since the heater 12h of the heat exchanger 12 is not exposed from the cleaning water, it is possible to prevent empty baking (heating of the heat exchanger 12) by the heater 12h.

  Moreover, the control part 4 of this Embodiment is the microcomputer of the control part 4, and since the electromagnetic valve 7 is opened (the electromagnetic valve 7 is turned on), the water level of the washing water in the tank 8a normally reaches the upper limit water level sufficiently. A predetermined time is measured. If the solenoid valve 7 is not closed (the solenoid valve 7 is turned off) even after the predetermined time has elapsed, the solenoid valve 7 is forcibly closed via the solenoid valve control unit 4s5 of the water level control unit 4s. At the same time, energization to the heater 12h and the like is stopped. Thereby, the control part 4 can stop operation | movement of the main-body part 200 of a sanitary washing apparatus safely even when the water level sensor 11 fails. For example, when the water level sensor 11 does not operate and the tank 8a is full, the vacuum valve body 31a of the vacuum breaker 31 closes the upper valve seat 31d and is sealed. When the pressure inside the tank 8a becomes equal to or higher than the relief pressure, the pressure in the tank is released from the relief valve 51, and water is allowed to escape into the toilet.

  Further, the control unit 4 of the present embodiment opens the electromagnetic valve 7 when the water level of the tank 8a reaches the lower limit water level, and closes the electromagnetic valve 7 when the water level reaches the upper limit water level, so that the water level and the air layer 8e in the tank 8a are within a predetermined range. It has a water level control unit 4s to be maintained inside. And it can be set as the simple structure which does not require a pressure-reduction valve because the water level control part 4s controls opening and closing of the solenoid valve 7 with the signal from the water level sensor 11. FIG. Thereby, the water level of the tank 8a can be maintained between the upper limit water level and the lower limit water level, and can be stably supplied to the positive displacement pump 14 with the water pressure released to the atmosphere. As a result, a compact and compact sanitary washing device can be realized.

(Embodiment 2)
Hereinafter, a sanitary washing device and a toilet device including the same according to Embodiment 2 of the present invention will be described with reference to FIG.

  FIG. 9 is a schematic diagram of an air release portion of the sanitary washing device according to Embodiment 2 of the present invention.

  That is, the sanitary washing device of the present embodiment is an embodiment in which the atmosphere opening portion 8 and the heat exchanger 12 are integrally configured, and the atmosphere opening portion 8 and the heat exchanger 12 are configured as separate parts. Different from 1. Other configurations are the same as those of the sanitary washing apparatus according to the first embodiment, and thus description thereof is omitted.

  That is, as shown in FIG. 9, the sanitary washing device of the present embodiment is configured by integrating the heater 12 h of the heat exchanger 12 in the tank 8 a of the air release unit 8.

  Thereby, the components of a sanitary washing device can be reduced. As a result, a more compact and inexpensive sanitary washing apparatus can be realized.

  Also, as shown in FIG. 9, the cleaning water is supplied so as to trace the surface of the heater 12h of the heat exchanger 12 from the water inlet 8b of the tank 8a. Thereby, the heat exchange on the surface of the heater 12h can be promoted, and the efficiency of heat exchange with the washing water can be increased. As a result, the warm water of the cleaning water stored in the tank 8a is stirred, and the temperature unevenness of the cleaning water can be reduced. In addition, since another effect is the same as the sanitary washing apparatus of Embodiment 1, description is abbreviate | omitted.

  In addition, in Embodiment 1, although the structure which provides the position of the water inlet 8b facing the air layer 8e in the upper part of the tank 8a was demonstrated to the example, it is not restricted to this. For example, similarly to the configuration of the second embodiment, the water inlet 8b may be provided at a position where the cleaning water exists at least from the lower part of the side surface of the tank 8a, and the cleaning water may be supplied into the tank 8a. Thereby, generation | occurrence | production of the water supply sound at the time of supplying water from the air layer 8e from the upper part of the tank 8a, and mixing of the bubble to the wash water in the tank 8a can be prevented. Further, by suppressing the mixing of bubbles into the cleaning water, the reliability of the water level detection by the water level sensor 11 of the cleaning water in the tank 8a can be further increased, and the flow rate measurement accuracy can be improved.

  Further, in the second embodiment, the example in which the position of the water inlet 8b is provided in the lower part of the side surface of the tank 8a is described, but the present invention is not limited to this. For example, if there is no problem with the generation of water supply sound or the mixing of bubbles into the wash water in the tank 8a, the position of the water inlet 8b may be provided facing the air layer 8e above the tank 8a. Thereby, a user can be made to recognize supply of cleaning water by a water supply sound.

  Moreover, in each said embodiment, although the sanitary washing apparatus of the structure provided with the toilet nozzle was demonstrated to the example, it is not restricted to this, The sanitary washing apparatus of a structure without a toilet nozzle may be sufficient. Thereby, a low-cost sanitary washing apparatus can be realized with a simple configuration.

  As described above, the sanitary washing device of the present invention includes the washing nozzle that discharges the washing water, and the washing water flow path that circulates the washing water from the supply source to the washing nozzle. The cleaning water channel includes a positive displacement pump that controls the flow rate of the cleaning water discharged from the cleaning nozzle, and a tank that stores upstream of the positive displacement pump and stores a portion of the cleaning water channel to the atmosphere. A water level sensor that detects the water level of the tank and outputs a signal, a solenoid valve that allows the cleaning water supplied from the supply source to flow into and out of the atmosphere, and a positive displacement pump and a solenoid And a control unit for controlling the valve. Further, the control unit has a configuration for correcting the control of the positive displacement pump by calculating the flow rate of the cleaning water supplied from the supply source per unit time based on the signal of the water level sensor.

  According to this configuration, by disposing the positive displacement pump downstream of the atmosphere opening portion, the rotational speed of the positive displacement pump is controlled without depending on the feed water pressure of the feed water source, and the cleaning discharged from the washing nozzle is performed. Control water flow. Furthermore, the control of the positive displacement pump is corrected by measuring the flow rate actually passed by the water level sensor and feeding it back to the control unit. Thus, the positive displacement pump can be controlled without being affected by variations in component parts, aging deterioration, etc., by correcting the flow rate detected by the water level sensor. As a result, without providing a flow sensor or a flow control valve, accurate and stable flow control can be performed over a long period of time, and a sanitary washing device with a simple configuration and excellent usability can be realized.

  Further, the sanitary washing device of the present invention includes a heat exchanger having a heater for heating the washing water downstream of the air release unit and upstream of the positive displacement pump, and the control unit controls the heater. Good.

  According to this configuration, since the heat exchanger can be made to enter the heat exchanger by operating the positive displacement pump from the atmosphere opening portion, the water entry control to the heat exchanger can be stabilized without being affected by the supply water pressure of the supply source. You can do it. Furthermore, the influence of the drawing flow rate due to environmental factors of the supply source can be reduced by the positive displacement pump. Thereby, the precision of the heating temperature of the washing water by the temperature control of the heating by the heater of the heat exchanger is improved by the accurate flow rate control, and a stable jet can be discharged.

  Moreover, the sanitary washing apparatus of this invention is good also considering the tank of an air release part as an incoming water temperature buffer part.

  According to this structure, the temperature variation can be buffered to some extent by temporarily storing the temperature variation of the cleaning water entering from the supply source in the tank. For this reason, the buffered washing water can supply the washing water without a sudden temperature change from the tank to the heat exchanger. As a result, when heating the cleaning water with the heater of the heat exchanger, it is possible to reduce a burden such as electric power and to prevent uneven discharge temperature of the cleaning water.

  In the sanitary washing device of the present invention, the washing nozzle has a nozzle part including at least a local washing nozzle that performs local washing and a bidet washing nozzle, and includes an operation unit that selects a washing mode by the nozzle part. The control unit controls the ejection flow rate of the cleaning water according to the cleaning mode of the nozzle unit selected by the operation unit, and the volume based on the flow rate detected by the water level sensor at the time of cleaning in the cleaning mode selected by the operation unit. The flow control of the mold pump may be corrected.

  According to this configuration, the flow rate discharged from the positive displacement pump is corrected and controlled and adjusted based on the flow rate detected by the water level sensor according to the cleaning mode selected by the operation unit. Thereby, the flow volume according to washing | cleaning mode can be controlled more correctly with a positive displacement pump.

  In the sanitary washing device of the present invention, the water level sensor detects the upper limit water level and the lower limit water level of the tank, and the control unit includes a water level control unit that calculates the flow rate per unit time when the upper limit water level changes to the lower limit water level. And the amount of water stored from the lower limit water level to the upper limit water level may be smaller than the total flow rate used in one standard cleaning time in a plurality of cleaning modes.

  According to this configuration, in the case of standard use, the water level in the tank changes from the upper limit water level to the lower limit water level at least once in one cleaning. Therefore, the flow rate per unit time is calculated, and the flow rate of the cleaning water ejected by controlling the positive displacement pump is corrected. Therefore, the amount of water stored in the tank can be minimized. Thereby, while being able to make a main body small, the correction | amendment of the flow volume without a malfunction can be performed suitably.

  Moreover, the sanitary washing apparatus of this invention may provide the heater of the heat exchanger which heats at least the wash water stored in the tank of an air release part. Thereby, the components of a sanitary washing device can be reduced. As a result, a more compact and inexpensive sanitary washing apparatus can be realized.

  Since the present invention can stably supply an arbitrary pulsating jet from the washing nozzle, it is not limited to a hot water washing toilet seat, a sanitary washing device such as a face, head, hand, or foot, or an animal such as a pet, or a creature other than a living thing This is useful for cleaning devices such as cleaning.

1 Cleaning nozzle (wet nozzle)
2 Cleaning nozzle (bidet nozzle)
DESCRIPTION OF SYMBOLS 3 Nozzle washing nozzle 4 Control part 4s Water level control part 4s1 Time detection part 4s2 Flow rate calculation part 4s3 Pump control part 4s4 Water level detection part 4s5 Solenoid valve control part 5 Branch faucet 6 Strainer 7 Electromagnetic valve 8 Atmospheric release part 8a Tank 8b Inlet 8c Air opening hole 8d Water outlet 8e Air layer 8f Side surface 9 Constant flow valve 11 Water level sensor 11a Second sensor 11b First sensor 11c Third sensor 12 Heat exchanger 12h Heater 12g Upper end position 13a, 13b Temperature sensor 14 Pulsating pump (volume) Type pump)
DESCRIPTION OF SYMBOLS 15 Buffer tank 16 Switching valve 20 Nozzle part 31 Vacuum breaker 31a Vacuum valve body 31b Lower valve seat 31c Communication slit 31d Upper valve seat 40 Toilet nozzle 51 Relief valve 51a Relief valve body 51b Relief spring 51c Valve seat contact surface 81 Pump body part 82 yen Column space 82a, 82b Pump chamber 83 Pumping piston 84, 84a, 84b Inflow part 85, 85a, 85b Outflow part 86 Motor 87, 88 Gear 89 Link mechanism 100 Sanitary washing device 200 Main part 201 Water supply pipe 202 Washing water flow path 205 Toilet washing Water flow path 300 Remote control device 301 Controller main body 302 Stop switch 303 Wet switch 304 Bidet switch 305 Wide washing switch 306 Rhythm washing switch 307 Water setting switch 309 m Bed washing switch 310 cleaning position setting switch 400 toilet seat 500 lid 600 entrance detecting sensor 610 seating sensor 700 urinal 1000 toilet apparatus

Claims (6)

A human body cleaning nozzle that discharges cleaning water;
A washing water flow path for circulating the washing water from a supply source to the washing nozzle;
A control unit,
The washing water channel is
A positive displacement pump that controls the flow rate of the cleaning water discharged from the cleaning nozzle;
An air release unit that is upstream of the positive displacement pump and opens a part of the washing water flow path to the atmosphere, and has a tank for storing the washing water and a water level sensor that detects the water level of the tank and outputs a signal. When,
A solenoid valve for passing and blocking the wash water supplied from the supply source to the atmosphere opening part,
The controller is
A sanitary washing device that corrects control of the positive displacement pump by calculating a flow rate of the wash water supplied from the supply source per unit time based on a signal of the water level sensor. A heat exchanger having a heater for heating the washing water downstream of the atmosphere opening portion and upstream of the positive displacement pump;
The sanitary washing device according to claim 1, wherein the control unit controls the heater. The sanitary washing device according to claim 2, wherein the tank of the atmosphere opening portion is a water inlet temperature buffering portion. The cleaning nozzle has at least a local cleaning nozzle that performs local cleaning, and a nozzle portion that includes a bidet cleaning nozzle,
An operation unit for selecting a cleaning mode by the nozzle unit;
The controller is
The cleaning water jet flow rate is controlled in accordance with the cleaning mode of the nozzle selected by the operation unit, and the flow rate detected by the water level sensor during cleaning in the cleaning mode selected by the operation unit. The sanitary washing device according to claim 1, wherein the flow rate control of the positive displacement pump is corrected. The water level sensor detects an upper limit water level and a lower limit water level of the tank,
The control unit has a water level control unit that calculates a flow rate per unit time when changing from the upper limit water level to the lower limit water level,
The sanitary washing device according to claim 4, wherein the amount of water stored from the lower limit water level to the upper limit water level is set to be less than the total flow rate used in one standard washing time in the plurality of washing modes. The sanitary washing apparatus according to claim 2 , wherein a heater of the heat exchanger that heats at least the stored washing water is provided in the tank of the atmosphere opening portion.

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