JP2003251229A - Water spouting apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water spouting apparatus the stimulative feeling controlling range of which is widened and which is made compact by incorporating a passage area-variable means, an inflow direction-variable means and the like in the apparatus and changing the rotational speed of a water spouting body. <P>SOLUTION: The water spouting apparatus for spouting the supplied washing water from a spout is provided with an inflow chamber in which the washing water is made to flow, a water spouting part which is assembled in the inflow chamber and provided with the spout, an indoor part which is connected to the water spouting part and positioned in the inflow chamber for receiving the flowing-in washing water, the water spouting body having a pipeline for introducing the washing water in the inflow chamber into the spout, a water supplying mechanism for introducing the washing water into the inflow chamber so that a whirling stream is generated in the washing water flowing in the inflow chamber around the indoor part along the inner peripheral wall surface of the inflow chamber and the passage area-variable means for varying the washing water passage area of the water supplying mechanism. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water spouting device for spouting supplied wash water from a nozzle.

[0002]

2. Description of the Related Art Conventionally, Japanese Patent Application Laid-Open No. HEI 5-1993 discloses that different stimulating sensations are provided by switching between different water discharge forms.
115813 and JP-A-8-117309. The former can discharge water by switching the water outlet for shower and the water outlet for massage. On the other hand, in the latter, water can be discharged by switching the water outlet for the normal shower and the water outlet for the mist. In addition, by combining these, there are three shower outlets, a massage outlet, and a mist outlet.
There are also those that switch seeds, and it is possible to change the feeling of stimulation from strong stimulation to weak stimulation.

[0003]

However, JP-A-5-1 is used.
In the case as disclosed in 15813 or Japanese Patent Laid-Open No. 8-117309, there is a problem that the control range of the sensation of stimulation is narrow. Different spouts can be given different stimulus sensations, but the stimulus sensations are limited, and only digital selection is possible. That is, in the case of having three types of spouts, the sensation of stimulation is only three. In other words, it is impossible to give various stimuli. In addition, since different water discharge forms with different stimulating sensations use different water discharge ports, the number of water discharge ports is required to be the same as the number of water discharge forms, which causes a problem that the water discharge device becomes large.

The present invention has been made to solve the above problems, and an object of the present invention is to change the number of revolutions of a water discharge body by including a flow passage area varying means, an inflow direction varying means, and the like. It is to provide a compact water spouting device with a wide control range of stimulating feeling.

In the present invention, the kinetic energy of the swirling flow in the inflow chamber causes a drag force and a lift force to rotate in the indoor portion of the water discharge body. Of the forces received by a fluid (water) on an object (indoor part of the water discharge body), the component acting in the direction parallel to the flow is called drag, and the component acting in the direction perpendicular to the flow is called lift. In the present invention, the drag contributes most to the rotation speed. This is because it basically rotates in the direction parallel to the flow, that is, along the swirling flow. In the present invention, the drag force D is defined as follows. D = C _D × (ρ / 2) × V × V × A [N] where drag coefficient C _D [−], water density ρ [kg / m ³ ],
Flow velocity V [m / sec] of water acting on the object, cross-sectional area A [m ² ] in a plane perpendicular to the flow. As can be seen from the above equation, the parameter that most contributes to the rotation speed can be said to be the flow velocity V of water that acts on the object (the indoor portion of the water discharge body). Therefore, when the swirl component of the flow velocity in the inflow chamber that acts on the indoor portion of the water discharge body changes, the drag force on the indoor portion of the water discharge body changes, which in turn changes the rotational speed.

[0006]

In order to achieve the above object, in the first aspect of the present invention, there is provided a device for discharging supplied cleaning water from a water outlet, which is an inflow chamber into which the cleaning water flows. And a wash water in the inflow chamber, which has a water discharge part incorporated in the inflow chamber and provided with the water discharge port, and an indoor part which is continuous with the water discharge part and is located in the inflow chamber to receive the inflowing wash water. And a water discharger having a conduit for guiding the water to the water discharge port, and cleaning the inflow chamber so that the cleaning water flowing into the inflow chamber causes a swirling flow around the indoor portion along the inner peripheral wall surface of the inflow chamber. Since the water supply mechanism for guiding water and the flow passage area varying means for varying the wash water flow passage area of the water supply mechanism are provided, the inflow speed of the wash water flowing into the inflow chamber can be changed. As a result, the swirl component of the flow velocity in the inflow chamber changes, and the drag of the water discharger toward the indoor portion changes, so that the rotational speed of the water discharger induced by the swirl flow can be changed.

Here, the difference in the sense of stimulation due to the difference in the number of revolutions of the water discharge body, that is, the number of revolutions of the water discharge in the human sensory characteristics will be described. When the number of revolutions of spouting water is low, humans can perceive the change, so when they see it at a local site, they feel periodic stimuli, and they have a sense of rhythm and liveliness.
It has the property of feeling as a stronger massage stimulus. That is, the stimulus is strongly felt. On the contrary, when the rotation speed of the spouted water is high, the human cannot recognize the change and feels that the stimulus does not change so much. Then, because it feels like it is hitting multiple parts at the same time, the stimulus is also dispersed. Therefore, the stimulation is felt weaker. Further, at the high rotational speed in the present invention, it is taken into consideration that the water is sheared by the movement of the water discharge body to reduce the particle size, and that the swirling component of the flow velocity in the inflow chamber is large, and thus the water discharge velocity vector toward the human becomes small. The stimulating feeling becomes even weaker. Therefore, by changing the flow passage area, the rotation speed of the water discharge can be changed, and as a result, the feeling of stimulation can be controlled.
Therefore, it is possible to realize the conventional strong stimulation to weak stimulation, that is, massage water discharge / normal shower / mist water discharge. Moreover, comparing with each conventional water discharge form,
The feeling of cleaning is improved even if the instantaneous flow rate does not change. In spouting water similar to the conventional massage spouting water, by rotating at a relatively low rotation speed, it is possible to increase the difference between spouting water and non-spouting water, and to make the massage feeling stronger. Also, in the case of water discharge similar to conventional normal shower or mist water discharge, water will be periodically discharged when viewed at a local site, but since the rotation speed is relatively high, the stimulus change cannot be recognized, and as in the past, it is continuous. I feel it hits. Therefore, when compared with the same instantaneous flow rate, the instantaneous flow rate for discharging water can be increased for each local site, and as a result, the flow rate feeling (cleansing feeling) is improved. In addition, since the stimulating sensation varies according to the degree of change in the flow passage area, the stimulating sensation can be changed in an analog manner. That is, it is possible to widen the control range of the stimulating sensation instead of the limited type of stimulating sensation. Therefore, it is possible to provide various stimulating sensations, and it is possible to match the stimulating sensations of a larger number of people. In addition, since it is possible to realize a strong stimulus feeling to a weak stimulus with the same water outlet (the water outlet may be configured by a plurality of water outlets), it is not necessary to have a water outlet for each water discharge form, and the water discharge device itself is compact. There is also an advantage that

In order to achieve the above object, in Claim 2, the flow passage area varying means changes the area of the inflow port which is an inlet to the inflow chamber, so that the flow passage area is slightly changed. Only by doing so, the inflow rate of the wash water flowing into the inflow chamber can be greatly changed. This is because changing the area of the inflow port changes just before the inflow into the inflow chamber, so that there is an effect that the flow rate of cleaning water changes depending on the flow path area changing means and the flow path between the inflow ports. Because there is no. That is, it can be said that even a slight change in the flow passage area has a large contribution to the inflow velocity. As a result, the swirl component of the flow velocity in the inflow chamber can be greatly changed,
The drag force acting on the indoor part of the water discharge body also changes greatly, and the rotation speed of the water discharge body induced by the swirling flow can also change greatly. Then, the sensation of stimulation can be controlled in a wider range.

In order to achieve the above object, the third aspect of the present invention is characterized by having the inflow position changing means for changing the inflow position into the inflow chamber. Therefore, the distribution state of the flow velocity in the inflow chamber is changed, and as a result, The swirl component of the flow velocity in the inflow chamber that acts on the indoor portion of the water discharge body can be changed. Then, the drag force acting on the indoor part of the water discharge body also changes, and the rotation speed of the water discharge body induced by the swirling flow also changes,
It is possible to control the feeling of stimulation in a wide range.

In order to achieve the above-mentioned object, the invention according to claim 4 is characterized by having an inflow direction changing means for changing the inflow direction into the inflow chamber, so that the distribution state of the flow velocity in the inflow chamber is changed, and as a result, The swirl component of the flow velocity in the inflow chamber that acts on the indoor portion of the water discharge body can be changed. Then, the drag force acting on the indoor part of the water discharge body also changes, and the rotation speed of the water discharge body induced by the swirling flow also changes,
It is possible to control the feeling of stimulation in a wide range.

In order to achieve the above object, in claim 5, the water supply mechanism is provided with a water pressure varying means for varying the wash water pressure. Therefore, the inflow speed of the wash water flowing into the inflow chamber is changed. be able to. As a result, since the swirl component of the flow velocity in the inflow chamber changes, the drag force acting on the indoor portion of the water discharge body also changes, and the rotational speed of the water discharge body induced by the swirling flow can be changed. For example, when the wash water pressure is increased, the inflow speed is increased and the swirl component of the flow velocity in the inflow chamber that acts on the indoor portion of the water discharge body is increased, so that the rotation speed of the water discharge body is increased. On the contrary, when the pressure of the wash water is reduced, the rotation speed of the water discharge body becomes low. Also,
In the case of an intermittent or pulsating change in which the wash water pressure fluctuates repeatedly, the number of revolutions also fluctuates repeatedly, and the instantaneous flow rate also fluctuates, so that a wider variety of stimulation feelings can be given. Therefore, it is particularly suitable for giving a massage feeling. As described above, by having the water pressure varying means, it is possible to change the rotation speed of the water discharge body, and it is possible to control the difference in stimulation feeling due to the difference in rotation speed. In addition,
Specific examples of the water pressure change changing means include a centrifugal pump and an axial flow pump. Further, an electromagnetic pump is suitable as a device that repeatedly changes with time.

In order to achieve the above-mentioned object, in the sixth aspect of the present invention, there is provided an air mixing amount changing means for changing the amount of air mixed into the cleaning water of the water supply mechanism, so that the cleaning water flowing into the inflow chamber is provided. The inflow rate of can be changed. Then, since the swirl component of the flow velocity in the inflow chamber changes,
The drag force acting on the indoor part of the water discharge body also changes, and the rotation speed of the water discharge body induced by the swirling flow can be changed. For example, when the amount of air mixed in is large, the inflow velocity of the wash water is high, and the swirl component of the flow velocity in the inflow chamber is large, so that the rotation speed of the water discharge body is increased. On the contrary, when the amount of air mixed is small, the rotation speed of the water discharge body is low. As described above, by including the air mixing amount varying means, the rotation speed of the water discharge body can be changed, and the difference in stimulation feeling due to the difference in rotation speed can be controlled. Specific examples of the air mixing amount varying means include a forced mixing method using an air pump and a natural mixing method using an ejector effect. The forced mixing method has an advantage of easy control because the amount of mixed air changes only by changing the electric input of the air pump. Examples of the natural mixing method include a method of changing the flow rate of washing water by using a water pump and the like to change the amount of air mixing, and a method of changing the area of the air hole with a valve.

In order to solve the above-mentioned problems, the present invention is characterized in that a constant flow valve for controlling the flow rate to a predetermined value is provided in the vicinity of the water supply port from the water supply source, so that the instantaneous flow rate can be kept constant. it can. That is, the feeling of flow rate stimulation due to the instantaneous flow rate is constant. In that state, it is possible to independently change only the feeling of stimulation due to the number of rotations, so there is no problem such as excessive or insufficient feeling of flow rate stimulation, from strong feeling to weak feeling, and various It can give a stimulating feeling.

In order to achieve the above-mentioned object, in claim 8, a single inflow chamber is provided with a plurality of inflow ports which are inlets to the inflow chamber. The rotational speed range of can be widened. This is because the swirling component of the flow velocity in the inflow chamber gradually attenuates as it progresses from the inflow port, and the water supply condition that has stopped for a moment is rotated (started) by causing swirl flow at multiple locations. This is because On the other hand, with respect to the high rotation speed side rotation speed range, there is almost no change since the start-up is not a problem. Further, there may be an inflow port having no inflow port flow passage area varying means, inflow position varying means, or inflow direction varying means. However, if these influencing means are provided for each inflow port, the inflow chamber is further increased. Since the conditions for inflow to the engine can be diversified, more precise rotation speed control is possible. As described above, by having a plurality of inlets,
Since the rotation speed range is expanded and precise rotation speed control is possible, the control range of the sensation of stimulation can be further widened.

[0015]

BEST MODE FOR CARRYING OUT THE INVENTION Preferred embodiments of the present invention will be described below in order to further clarify the constitution and operation of the present invention described above. First, a water discharge device that is a first embodiment of the present invention will be described. 1 is a perspective view of the water discharger 1 from above, and FIG. 2 is a perspective sectional view of the water discharger 1 from the side.
When the opening adjustment valve 2 is opened, the cleaning water supplied from the water supply source (not shown) is supplied to the water discharger 1, and then the water supply mechanism 3 provided inside the water discharger 1 and the inflow chamber 8 in that order. It
The water supply mechanism 3 includes a water supply port 4, a water passage 5, a flow path area varying unit 6, and an inflow port 7. The flow passage area varying means 6 is composed of a flow passage opening / closing portion 6a and a handle portion 6b. Further, the water passage 5 is configured to be supplied with washing water tangentially to the inner peripheral wall surface of the inflow chamber 8.

A water discharge body 10 is provided inside the inflow chamber 8, and the water discharge body 10 is composed of a water discharge portion 11 and an indoor portion 12. The water discharge part 11 is composed of a water discharge body water supply port 11a to which wash water is supplied, a water discharge port 11c which discharges water toward a cleaning surface, and a conduit 11b which communicates with the water discharge body water supply port 11a and guides the wash water to the water discharge port 11c. Has been done.

Further, the water discharger 10 is inserted into a seal portion 13 provided in an opening above the inflow chamber 8 so as to be inscribed therein. The seal portion 13 is made of an elastic body,
Since the water discharge body 10 is provided so as to be tiltable with respect to the central axis of the inflow chamber 8, the water discharge body 10 rotates about the water discharge body 10 itself inside the inflow chamber 8, or the water discharge body 10 seals. It is possible to freely revolve around 13 at the apex for conical rotation. At this time, the water discharger 10 is configured such that the maximum inclination angle is regulated by the taper guide portion 14 provided on the upper part of the inflow chamber 8. Alternatively, the seal portion 13 may be omitted and the casing 15 and a part of the water discharge body 10 may be brought into direct contact with each other and slid.

As shown in FIG. 2, the water spouting body 10 includes a water spouting body water supply port 11a for supplying wash water, and a water spouting port 11c for communicating wash water to the water spouting body water supply port 11a. It is provided in a state of being inclined with respect to the central axis (rotational axis) of 10. That is, the discharge direction of the wash water is the water discharge body 1.
It is configured to be inclined with respect to the central axis of 0.
Further, the water discharge body may be as shown in FIG. The water discharge body 20 communicates with the water discharge body water supply port 21a to which the cleaning water is supplied and the water discharge body water supply port 21a, and the water discharge port 2 for discharging the cleaning water.
1c is provided in a state of being eccentric with respect to the central axis of the water discharge body 20. Of course, the arrangement of the water discharge body water supply port and the water discharge port may be parallel through the central axis (rotation axis) of the water discharge body instead of in such an inclined state or eccentric state, but in that case, due to rotation The water discharge trajectory does not change, only the water discharge trajectory changes due to the revolution.

The case where the flush water is discharged in the configuration of FIGS. 1 and 2 will be described focusing on the flow of the flush water. The flush water supplied to the water discharger 1 flows into the inflow chamber 8 through the water passage 5. To do. At that time, the user moves the handle portion 6b of the cleaning area varying means 6 provided in the middle of the water passage 5 in the vertical direction (arrow in FIG. 1) of FIG. The area of the flow path can be changed by changing the area to be closed. By changing the flow passage area, the flow rate of the washing water can be changed, and as a result, the inflow speed into the inflow chamber 8 can be changed. And water passage 5
Is configured so that the cleaning water flows in tangentially to the inner peripheral wall surface of the inflow chamber 8, so that the cleaning water that has flowed into the inflow chamber 8 at a variable inflow velocity will flow to the inside of the inflow chamber 8. A swirling flow is generated along the inner peripheral wall surface and around the indoor part 12. At that time, the indoor part 12 receives a force (drag, lift) generated by the kinetic energy due to the swirling flow in the inflow chamber 8, so that the water discharge body 10 rotates about the water discharge body 10 itself and the center of the inflow chamber 8 rotates. Revolves with an inclination to the axis.
Then, the water discharge body water supply port 11a provided in the water discharge body 10
Water is discharged through the conduit 11b and the water outlet 11c. At this time, the water spouting body 10 rotates (rotates and revolves), so that the wash water spouted from the spouting port 11c provided in the water spouting body 10 is spouted while rotating in accordance with the rotation of the water spouting body 10. In addition, the cleaning water is supplied to the casing 1 by the seal portion 13.
There is a seal between 5 and the water discharge body 10.

In the following description, both the rotation and the revolution of the water discharge body will be collectively referred to as "rotation". Since the rotation speed and the revolution speed are in proportion to the swirl component of the flow velocity in the inflow chamber, there is no problem in the following description of the change in the rotation speed.

Here, the difference in the feeling of stimulation due to the difference in the rotation speed of the water discharge body 10, that is, the rotation speed of the water discharge in the human sensory characteristics will be described. If the spout speed is low,
Since human beings can recognize the change, when they see it at a local site, they feel a periodic stimulus, and it has a characteristic that it feels like a rhythmic, vibrant and stronger massage stimulus.
That is, the stimulus is strongly felt. On the contrary, when the rotation speed of the spouted water is high, the human cannot recognize the change and feels that the stimulus does not change so much. Then, because it feels like it is hitting multiple parts at the same time, the stimulus is also dispersed.
Therefore, the stimulation is felt weaker. Further, at a high rotation speed in the present invention, the water is sheared by the movement of the water discharge body 10 to reduce the particle size, and the swirl component of the flow velocity in the inflow chamber 8 is large, so the discharge flow velocity vector toward the human is also reduced. The stimulating sensation becomes even weaker as a result of being added.

A change in the number of revolutions when the flow passage area of the water passage 5 is changed by the cleaning area changing means 6 will be described. For example, when the flow passage area of the water passage 5 is reduced by the cleaning area varying means 6, the inflow speed into the inflow chamber 8 increases. As a result, the swirl component of the flow velocity in the inflow chamber 8 increases, and the drag of the water discharge body 10 to the indoor portion 12 increases, so that the rotational speed of the water discharge body 10 attracted by the swirling flow increases.
Therefore, the feeling of stimulation due to the number of rotations becomes weak. At that time, since the instantaneous flow rate is slightly reduced due to the pressure loss of the cleaning area varying means 6, the flow rate stimulation feeling is slightly weakened. Therefore,
The overall feeling of stimulation, which is a combination of the feeling of stimulation caused by the number of revolutions and the feeling of stimulation caused by the instantaneous flow rate, becomes weaker. On the contrary, when the flow passage area of the water passage 5 is increased by the cleaning area varying means 6, the rotation speed of the water discharge body 10 attracted by the swirling flow decreases, and the stimulus feeling due to the rotation speed increases. Therefore, the feeling of flow rate stimulation becomes slightly stronger as the instantaneous flow rate increases slightly, and the feeling of stimulation as a whole becomes stronger.

As described above, by changing the flow passage area of the water passage 5 by the flow passage area changing means 6, the rotation speed of the water discharge can be changed, and as a result, the feeling of stimulation can be controlled. . Therefore, it is possible to realize the conventional strong stimulation to weak stimulation, that is, massage water discharge / normal shower / mist water discharge. Moreover, compared to the conventional water discharge forms, the feeling of cleaning is improved even if the instantaneous flow rate does not change. First, a washing feeling of water discharge similar to conventional massage water discharge will be described. In the conventional massage water discharge, the difference between the time of water discharge and the time of non-water discharge cannot be increased, and the feeling of massage is weak. This is because, in order to increase the difference between the time when water is discharged and the time when water is not discharged, it is necessary to make the member that blocks the flow path large and to sufficiently seal in the non-water discharge state in terms of the structure.
This is because there was a problem that it was necessary to increase the water supply energy. Therefore, the shield member must be reduced in size to make the seal insufficient, so that the difference between the time when water is discharged and the time when water is not discharged is reduced, and the feeling of massage is weakened. On the other hand, in the present invention, by rotating at a relatively low rotational speed, it is possible to increase the difference between when water is being discharged and when water is not being discharged, when viewed at a local site. Therefore, it is possible to increase the difference in the strength of the massage spouted water, and to strengthen the feeling of massage. Next, the cleaning feeling of water discharge similar to the conventional normal shower water discharge or mist water discharge will be described. In the conventional water discharge, a continuous flow is discharged to each local site. On the other hand, in the present invention, water is periodically discharged when viewed at a local site, but since the rotation speed is relatively high, the stimulus change cannot be recognized, and it is felt that the stimulus is continuously hit. Therefore, when compared with the same instantaneous flow rate, the instantaneous flow rate for discharging water can be increased for each local site, resulting in a feeling of flow rate (cleansing feeling).
Will be up. In other words, it can be said that the instantaneous flow rate can be reduced while maintaining the conventional washing feeling.

In addition, since the stimulating sensation varies according to the degree of change of the flow path area varying means 6, the stimulating sensation can be changed in an analog manner. That is, it is possible to widen the control range of the stimulating sensation instead of the limited type of stimulating sensation. Therefore, it is possible to provide various stimulating sensations, and it is possible to match the stimulating sensations of a larger number of people. Further, since a strong stimulus feeling to a weak stimulus feeling can be realized by the same water outlet 11c (the water outlet may be constituted by a plurality of water outlets),
There is also an advantage that it is not necessary to have a spout for each spouting form, and the spouting device 1 itself becomes compact.

Next, a water discharger which is another example of the first embodiment will be described. 4 is a perspective view of the water discharger 31 from above,
FIG. 5 is a perspective cross-sectional view from the side of the water discharger 31. Compared to FIGS. 1 and 2, FIGS. 4 and 5 are the same except for the position of the flow path area varying means 36.

The flow path area varying means 36 is provided in the inlet opening / closing section 3
6a and handle portion 36b. The inlet opening / closing portion 36a is provided near the inlet 37 which is an inlet to the inlet chamber 38, and the user moves the handle portion 36b in the circumferential direction of the inlet chamber 38 (arrow in FIG. 4).
The area for closing the inlet 37 can be changed to change the flow passage area of the inlet 37. At this time, since the flow path area varying means 36 is configured to open and close the side close to the center of the inflow chamber 38, the water passage 35 is always flush with the inner wall surface of the inflow chamber 38 from the tangential direction. Are configured to be supplied. In addition, regarding the portion where the flow path area varying means 36 opens and closes the inflow port 37, the inflow chamber 38
It is not limited to the side close to the center of the above, and it may be any part up, down, left, or right toward the inflow port 37. However, if the center of the inflow velocity component is brought too close to the center of the inflow chamber 38,
The swirl component of the flow velocity in the inflow chamber 38 does not act on the indoor portion 42 of the water discharge body 40, or the swirl flow in the inflow chamber 38 is biased with respect to the center of the inflow chamber 38.
There is a possibility that 0 will not rotate, so care must be taken as a design condition.

Next, the cleaning area varying means 36 is used to introduce the inflow port 37.
The change in the number of revolutions when the flow passage area is changed will be described. For example, if the flow passage area of the inflow port 37 is reduced by the cleaning area changing means 36, the inflow velocity into the inflow chamber 38 is increased. At that time, the inflow velocity into the inflow chamber 38 is significantly increased by only slightly changing the flow passage area of the inflow port 37. This is a change immediately before the inflow into the inflow chamber 38, and there is no flow path between the flow path area varying means 36 and the inflow chamber 38, so that the flow velocity of the wash water is reduced to the inflow port 37. This is because there is no such thing. Therefore,
The swirl component of the flow velocity in the inflow chamber 38 is significantly increased. As a result, the swirl component of the flow velocity in the inflow chamber 38 is significantly increased, and the drag of the water discharge body 40 to the indoor portion 42 is greatly increased, so that the rotational speed of the water discharge body 40 attracted by the swirl flow is greatly increased. Get higher Therefore, the feeling of stimulation due to the number of rotations becomes weaker. At that time, since the instantaneous flow rate is slightly reduced due to the pressure loss of the cleaning area varying means 36, the feeling of flow rate stimulation is slightly weakened, and the feeling of stimulation as a whole becomes very weak. On the contrary, when the flow passage area of the inflow port 37 is increased by the cleaning area varying means 36, the rotation speed of the water discharge body 40 attracted by the swirling flow is significantly reduced, and the sensation of stimulation caused by the rotation speed is further increased. . Therefore, the feeling of flow rate stimulation becomes slightly stronger as the instantaneous flow rate increases slightly, and the feeling of stimulation as a whole becomes very strong.
As described above, the number of rotations of the water discharge body that is attracted by the swirling flow can be significantly changed, so that even a small flow passage area varying means can control the stimulation feeling in a wider range.

Next, the control range of the feeling of stimulation including the opening adjustment valve 32 will be described. FIG. 6 is a diagram imagining a control range of stimulation feeling in the conventional water discharge device, and FIG. 7 is a diagram imagining a control range of stimulation feeling in the water discharge device 31. The horizontal axis represents the instantaneous flow rate, and the vertical axis represents the overall stimulation feeling, which is the sum of the stimulation feeling due to the instantaneous flow rate and the stimulation feeling due to the rotation speed. In a conventional water discharge device, a plurality of different stimulating sensations are provided by switching a plurality of water discharge ports. FIG. 6 shows a case having three types of water discharge ports. In the state where the opening of the opening adjustment valve is constant, only digital selection is possible, as indicated by ◯ in FIG. Further, the stimulating feeling can be changed by changing the instantaneous flow rate by changing the opening degree of the opening adjusting valve, but the stimulating feeling obtained at a certain instantaneous flow rate is limited. On the other hand, in the water discharger 31 of the present invention, in the same manner as in the past, in addition to changing the instantaneous flow rate by changing the opening degree of the opening degree adjusting valve 32 to change the feeling of stimulation, the flow path area changing means 36 changes the flow path area. By making it variable, the sensation of stimulation obtained at a certain instantaneous flow rate becomes diverse. In other words, the feeling of stimulation can be controlled independently of the feeling of flow rate. At that time, when only the flow path area varying means 36 is changed in a state where the opening degree of the opening degree adjusting valve 32 is constant, the instantaneous flow rate slightly changes due to the pressure loss of the flow path area varying means 36. The control range is slightly parallel to the right rather than parallel.

According to an experiment conducted by the applicant, water spouting similar to the conventional one was obtained under the following conditions, and it was possible to change between the water spouting states in an analog manner.

[0030]

[Table 1]

When the flow passage area of the inlet does not change, the longer the flow passage between the flow passage area varying means and the flow inlet, or the larger the flow passage area between the flow passage area varying means and the flow inlet. The flow velocity of washing water varied by the flow passage area varying means is strongly influenced by the flow passage between the flow passage area varying means and the inlet. In other words, the flow path area varying means has a large contribution as a pressure loss, and the inflow velocity into the inflow chamber is dominated by the flow path condition between the flow path area varying means and the inflow port. In such a case, the change in the number of revolutions when the flow passage area changing means changes the flow passage area is opposite to the change in the flow passage area changing means 6 and the flow passage area changing means 36. That is, when the flow passage area is reduced by the cleaning area changing means, the pressure loss of the flow passage area changing means increases,
As a result of the decrease in the instantaneous flow rate, the inflow velocity into the inflow chamber is determined by "instantaneous flow rate / flow passage area of the inflow port", and therefore decreases. Therefore, the rotation speed of the water discharge body becomes low. On the other hand, if the flow passage area is increased by the cleaning area changing means, the number of rotations increases. The control as described above is suitable when it is desired to give a more sense of flow rate to a weak stimulus.

Next, referring to FIG. 8, a water discharge device 51 will be described in which a constant flow valve 68 for adjusting the instantaneous flow rate to a predetermined value is further provided near the water supply port 54. In this case, since the instantaneous flow rate is constant, the feeling of flow rate stimulation due to the instantaneous flow rate is constant. In that state, it is possible to independently control only the stimulus sensation caused by the number of revolutions, so there is no problem such as excessive or insufficient flow stimulus sensation from strong stimulus to weak stimulus It can give a stimulating feeling.

FIG. 9 shows an image of the control range of this stimulus sensation. As can be seen from FIG. 9, the opening adjustment valve 52
When only the flow path area varying means 56 is changed in a constant state, the flow rate stimulation feeling due to the instantaneous flow rate is not changed,
It is possible to control the overall feeling of stimulation. This has an advantage that only one of the strong stimulus sensation and the weak stimulus sensation can prevent the flow sensation from becoming excessive or insufficient.

Next, a water discharger which is a second embodiment of the present invention will be described. 10 is a perspective view of the water discharger 71 from above, and FIG. 11 is a perspective cross-sectional view of the water discharger 71 from the side. When the opening adjustment valve 72 is opened, the cleaning water supplied from the water supply source (not shown) is supplied to the water discharge device 71, and then the water supply mechanism 73 provided inside the water discharge device 71 and the inflow chamber 78 in this order. It The water supply mechanism 73 includes a water supply port 74 and a water passage 7.
5, the inflow position changing means 76. The inflow position changing means 76 includes an inflow water passage 76a and a handle portion 76b.
It is composed of. Then, the user operates the handle portion 76b.
By moving in the vertical direction in FIG. 10 (arrow in FIG. 10),
By utilizing the elasticity of the elastic member 76c, the inflow water passage 76a can be translated and the inflow position of the inflow water passage 76a with respect to the inflow chamber 78 can be varied.

Next, the inflow chamber 78 is moved by the inflow position changing means 76.
The change in the number of revolutions when the inflow position of the inflow water passage 76a is changed will be described. In this embodiment, as shown in FIG. 11, the water discharge body 80 is inclined by the taper guide 84 to the vicinity of the inner wall of the inflow chamber 78. At this time, if the wash water is supplied from the inflow passage 76a in the tangential direction to the inner peripheral wall surface of the inflow chamber 78, that is, from the position away from the center of the inflow chamber 78, the indoor portion 82 of the water discharge body 80 will be In response to the swirl component having a large flow velocity in the inflow chamber 78, the rotation speed of the water discharge body 80 increases. Therefore, the feeling of stimulation becomes weaker. On the contrary, when the wash water is supplied from the position near the center of the inflow chamber 78 to the inflow water passage 76a, the indoor portion 82 of the water discharge body 80 becomes the inflow chamber 78.
Since it is inclined to the vicinity of the inner wall, it receives a swirling component having a relatively small flow velocity in the inflow chamber 78.
The number of rotations of 0 becomes low. Therefore, the feeling of stimulation becomes stronger.

As described above, when the inflow position with respect to the inflow chamber 78 is changed, the distribution state of the flow velocity in the inflow chamber 78 changes, and the swirl component of the flow velocity in the inflow chamber 78 acting on the indoor portion 82 of the water discharge body 80 also changes. To do. Due to the change of the swirl component of the flow velocity in the inflow chamber 78, the drag force acting on the indoor portion 82 of the water discharge body 80 also changes, the rotation speed of the water discharge body 80 attracted by the swirl flow also changes, and by extension, the feeling of stimulation is controlled in a wide range. can do. In this embodiment, the water discharge body 80 is
Although the taper guide 84 is inclined to the vicinity of the inner wall of the inflow chamber 78, if the maximum inclination angle is restricted to be smaller by the angle of the taper guide 84, the change in the rotational speed with respect to the inflow position also differs. Further, if the inflow position of the inflow water passage 76a is brought too close to the center of the inflow chamber 78, not only does it not act on the indoor portion 82 of the water discharge body 80, but also the swirling flow in the inflow chamber 78 with respect to the center of the inflow chamber 78. Since the water discharger 80 may not rotate, it is necessary to pay attention as a design condition.

Next, a water discharger which is a third embodiment of the present invention will be described. FIG. 12 is a perspective view from the upper part of the water discharger 91, and FIG. 13 is a perspective cross-sectional view from the side of the water discharger 91. When the opening adjustment valve 92 is opened, the cleaning water supplied from the water supply source (not shown) is supplied to the water discharge device 91, and then the water supply mechanism 93 provided inside the water discharge device 91 and the inflow chamber 98 in this order. It The water supply mechanism 93 includes a water supply port 94 and a water passage 9.
5, the inflow direction changing means 96. The inflow direction varying means 96 includes an inflow water passage 96a and a handle portion 96.
b, the inflow water channel drive unit 96c. In addition,
The inflow water passage 96a is bendable and can be moved by the inflow water passage drive unit 96c. Then, the user moves the handle portion 96c in the vertical direction in FIG.
2), the angle of the inflow water passage 96a can be changed to change the inflow direction of the inflow water passage 96a with respect to the inflow chamber 98.

Next, the inflow chamber 98 is moved by the inflow direction changing means 96.
The change in the number of revolutions when the inflow direction of the inflow water passage 96a is changed will be described. When the wash water is supplied tangentially to the inner peripheral wall surface of the inflow chamber 98 through the inflow water passage 96a, the indoor portion 102 of the water discharge body 100 receives a swirl component having a large flow velocity in the inflow chamber 98, Water spout 10
The number of rotations of 0 becomes high. Therefore, the feeling of stimulation becomes weaker. On the contrary, in the case where the inflow water passage 96a is supplied in a direction away from the tangential direction with respect to the inner peripheral wall surface of the inflow chamber 98, that is, when the cleaning water is supplied to the inside (center side) or the outside,
Since the indoor part 102 of the water discharge body 100 receives a swirl component having a relatively small flow velocity in the inflow chamber 98, the rotation speed of the water discharge body 100 becomes low. Therefore, as a feeling of stimulation,
Get stronger.

In this way, when the inflow direction to the inflow chamber 98 is changed, the distribution state of the flow velocity in the inflow chamber 98 changes, and the inflow chamber 9 acting on the indoor portion 102 of the water discharge body 100.
The swirl component of the flow velocity within 8 also changes. Due to the change in the swirl component of the flow velocity in the inflow chamber 98, the drag force acting on the indoor portion 102 of the water discharge body 100 also changes, and the rotation speed of the water discharge body 100 attracted by the swirl flow also changes, and as a result, the stimulation feeling is controlled in a wide range. can do. Further, if the inflow direction of the inflow water passage 96a is set too inward (center side) or outward of the inflow chamber 98, not only does it not act on the indoor portion 102 of the water discharge body 100, but swirling flow in the inflow chamber 98 also occurs. Inflow chamber 9
Since the water discharger 100 may not rotate because it is biased with respect to the center of 8, it is necessary to be careful as a design condition.

Next explained is a water discharger which is a fourth embodiment of the invention. FIG. 14 is a perspective view of the water discharger 111 from above. When the opening adjustment valve 112 is opened, the cleaning water supplied from the water supply source (not shown) is supplied to the water discharge device 111, and the water supply mechanism 113 provided inside the water discharge device 111,
It is supplied in the order of the inflow chamber 118. The water supply mechanism 113 includes a water supply port 114, a water passage 115, and a water pressure changing means 116. The water pressure changing means 116 is a water pump that changes the wash water pressure of the water supply mechanism 113.

Next, the water supply mechanism 11 is operated by the water pressure varying means 116.
A change in the number of revolutions when the washing water pressure of No. 3 is changed will be described. For example, when the output of the water pressure varying means 116 is increased, the instantaneous flow rate and flow velocity of the wash water are increased, and the inflow chamber 1
The inflow speed to 18 increases. As a result, the inflow chamber 11
Since the swirling component of the flow velocity in 8 increases and the drag of the water discharge body 120 to the indoor portion 122 increases, the rotation speed of the water discharge body 120 attracted by the swirling flow increases. Therefore,
The sensation of stimulation due to the number of rotations becomes weaker. At that time, as the instantaneous flow rate increases, the feeling of flow rate stimulation becomes slightly stronger, but the feeling of stimulation as a whole becomes weaker. This is suitable for giving a generous amount of flow and warming the body with a sufficient amount of warm water while giving a weak and soft stimulus. Particularly, it is very preferable to combine with the first embodiment. This is because when it is desired to make the flow passage area smaller by the flow passage area varying means 36 to give a weaker and softer feeling of stimulation, the required water pressure becomes higher. Therefore, if the wash water pressure is increased by the water pressure varying means 116, a softer feeling of stimulation can be realized with the feeling of flow rate increased. Further, even in a low water pressure home, a wider range of stimulating feeling can be given.

Further, instead of the water pressure varying means 116,
It is also possible to use an air mixing amount varying means. By using the air mixing amount varying means, air can be mixed into the cleaning water. Increasing the air mixing amount by the air mixing amount changing means increases the flow rate of the washing water and the inflow speed into the inflow chamber. As a result, the swirl component of the flow velocity in the inflow chamber increases, and the drag force of the water discharger toward the indoor portion increases, so that the rotational speed of the water discharger induced by the swirl flow increases. On the other hand, when the amount of air mixed in is large, air has a smaller impact force than water, so that humans feel that it is a soft and weak stimulus. Therefore, the higher the number of rotations, the lower the stimulation feeling, and the weaker stimulation feeling. On the other hand, if the amount of mixed air is reduced by the variable amount of mixed air, the feeling of stimulation will be stronger.

Finally, a water discharger which is a fifth embodiment of the present invention will be described. FIG. 15 is a perspective view of the water discharger 131 from above. When the opening degree adjustment valve 132 is opened, the cleaning water supplied from the water supply source (not shown) is supplied to the water discharger 131, and the water supply mechanism 13 provided inside the water discharger 131.
3 and the inflow chamber 138 are supplied in this order. Water supply mechanism 133
Is a water supply port 134, a water passage 135, a water passage A135a,
Water passage B135b, flow passage area varying means A136a, flow passage area varying means B136b, inlet A137a, inlet B
137b. The water passage 135 is the water passage A.
135a and water passage B135b, respectively, from the inlet A137a, the inlet B137b, the inflow chamber 138
The cleaning water is supplied tangentially to the inner peripheral wall surface of the.

When water is discharged by the above structure,
It is possible to widen the rotation speed range of the water discharger 140 on the low rotation speed side. This is because the swirl component of the flow velocity in the inflow chamber gradually attenuates as it progresses from the inlet, and the water supply condition that was stopped even if it was rotating for a moment is rotated by causing a swirl flow at the other inlet ( It will be started). And the inlet A137a and the inlet B
If the flow passage areas of 137b are made different, the inlet A
The inflow speed from 137a and the inflow speed from the inflow port B137b are different. Therefore, while the water discharge body 140 revolves once, the indoor part 142 receives different forces, and the rotation speed itself is not constant. That is, it is possible to give a variety of stimulation sensations that are not monotonous.

Further, as shown in FIG. 16, the water passage A155
The flow passage areas of a and the water passage B155b may be different. At that time, a flow passage switching valve 159 is provided at a branch point between the water passage A155a and the water passage B155b so that the water passage A155
a and water passage B155b, water passage A155a, water passage B
It is even better if 155b and 3 patterns are switched. In FIG. 16, the flow passage area of the water passage A155a is smaller than the flow passage area of the water passage B155b. Therefore, at the same water pressure, water passage A155a and water passage B1
In the case of branching into 55b, the inflow chamber 1 from the inlet A157a
The velocity of flowing into 58 is higher than the velocity of flowing into the inlet chamber 158 from the inlet B157b. That is, when the water passage A155a is selected, the rotation speed of the water discharge body 160 is higher than when the water passage B155b is selected. Further, one of the water passage A155a and the water passage B155b may be variably blocked.

In the fifth embodiment, the case where a plurality of flow passage area varying means is provided has been described. However, instead of the flow passage area varying means, the inflow position varying means, the inflow direction varying means, and the plurality of flow inlet areas are provided. Water pressure varying means and air mixing amount varying means may be used. Further, by combining these different variable means, it is possible to further diversify the inflow conditions into the inflow chamber, so that more precise rotation speed control is possible.

As described above, by having a plurality of inflow ports, the rotational speed range can be widened and precise rotational speed control can be performed, so that the control range of the sensation of stimulation can be further widened.

In the first, second, and third embodiments, the structure in which the user manually moves the handle portion has been described.
The handle portion may be electrically driven by the user controlling the controller. In that case,
It enables more precise control of stimulation.

Further, in all the embodiments, the single water discharge hole constituting the water discharge port has been described, but the water discharge port may be constituted by a plurality of water discharge holes as long as water is discharged from substantially the same location. Therefore, although the component forming the water discharge port may be an integral component or a separate component, it is necessary that the water discharge holes be in the immediate vicinity.

[Brief description of drawings]

FIG. 1 is a top view of a water discharger according to a first embodiment of the present invention.

FIG. 2 is a side view of the water discharger according to the first embodiment of the present invention.

FIG. 3 is a diagram showing another example of the water discharge body according to the first embodiment.

FIG. 4 is a top view of a water discharger which is another example according to the first embodiment.

FIG. 5 is a side view of a water discharger which is another example of the first embodiment.

FIG. 6 is a diagram showing a feeling of stimulation with respect to an instantaneous flow rate of a conventional water discharge device.

FIG. 7 is a diagram showing a feeling of stimulation with respect to an instantaneous flow rate of the water discharger according to the first embodiment.

FIG. 8 is a top view of a water discharger having a constant flow valve according to the first embodiment.

FIG. 9 is a diagram showing a feeling of stimulation with respect to an instantaneous flow rate of the water discharger having the constant flow valve according to the first embodiment.

FIG. 10 is a top view of the water discharger according to the second embodiment of the present invention.

FIG. 11 is a side view of the water discharger according to the second embodiment of the present invention.

FIG. 12 is a top view of the water discharger according to the third embodiment of the present invention.

FIG. 13 is a side view of the water discharger according to the third embodiment of the present invention.

FIG. 14 is a top view of the water discharger according to the fourth embodiment of the present invention.

FIG. 15 is a top view of the water discharger according to the fifth embodiment of the present invention.

FIG. 16 is a top view of a water discharger which is another example of the fifth embodiment.

[Explanation of symbols]

21 ... Water discharge area 21b ... pipe 22 ... Indoor part 33 ... Water supply mechanism 34 ... Water supply port 41 ... Water discharge part 53 ... Water supply mechanism 55 ... Waterway 57 ... Inlet 58 ... Inflow chamber 60 ... Water spout 61 ... Water discharge part 62 ... Indoor part 81 ... Water discharge part 101 ... Water discharge part 121 ... Water discharge part 141 ... Water discharge part 151 ... Water discharge device 152 ... Opening adjustment valve 154 ... Water supply port 155 ... Waterway 156a ... Flow path area varying means A 156b ... Flow path area varying means B 161 ... Water discharge part 162 ... Indoor part

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Yasuo Hamada             2-1-1 Nakajima, Kokurakita-ku, Kitakyushu City, Fukuoka Prefecture             No. Totoki Equipment Co., Ltd. F-term (reference) 2D032 FA04                 4F033 AA04 BA04 DA01 EA01 GA11                       KA03 NA01 PA01 PB02 PC02                       PD01 PD06

Claims (8)

[Claims] 1. An apparatus for spouting supplied wash water from a spout, an inflow chamber into which the wash water flows, a water spout portion incorporated in the inflow chamber and provided with the spout, and the water spout portion. And an indoor portion that is located in the inflow chamber and receives the inflowing cleaning water, and has a water discharge body that has a conduit for guiding the cleaning water in the inflow chamber to the water discharge port, and the cleaning that has flowed into the inflow chamber. A water supply mechanism that guides the wash water into the inflow chamber so that the water causes a swirling flow around the indoor portion along the inner peripheral wall surface of the inflow chamber, and a flow passage area that varies the wash water flow passage area of the water supply mechanism. A water spouting device having a variable means. 2. The water discharger according to claim 1, wherein the flow passage area varying means varies the area of the inflow port which is an inlet to the inflow chamber. 3. A device for spouting supplied wash water from a spout, an inflow chamber into which the wash water flows, a water spout part incorporated in the inflow chamber and having the spout, and the water spout part. And an indoor portion that is located in the inflow chamber and receives the inflowing cleaning water, and has a water discharge body that has a conduit for guiding the cleaning water in the inflow chamber to the water discharge port, and the cleaning that has flowed into the inflow chamber. A water supply mechanism that guides the wash water to the inflow chamber so that the water causes a swirling flow around the indoor portion along the inner peripheral wall surface of the inflow chamber, and an inflow position changing means that changes the inflow position into the inflow chamber. And a water spouting device. 4. An apparatus for discharging supplied wash water from a spout, an inflow chamber into which the wash water flows, a water spout portion incorporated in the inflow chamber, the spout having the spout, and the water spout. And an indoor portion that is located in the inflow chamber and receives the inflowing cleaning water, and has a water discharge body that has a conduit for guiding the cleaning water in the inflow chamber to the water discharge port, and the cleaning that has flowed into the inflow chamber. A water supply mechanism that guides the wash water into the inflow chamber so that the water causes a swirling flow around the indoor portion along the inner peripheral wall surface of the inflow chamber, and an inflow direction changing means that changes the inflow direction into the inflow chamber. And a water spouting device. 5. An apparatus for spouting supplied wash water from a spout, the inflow chamber into which the wash water flows, a water spouting part that is incorporated in the inflow chamber and has the spouting port, and the water spouting part. And an indoor portion that is located in the inflow chamber and receives the inflowing cleaning water, and has a water discharge body that has a conduit for guiding the cleaning water in the inflow chamber to the water discharge port, and the cleaning that has flowed into the inflow chamber. A water supply mechanism that guides the wash water into the inflow chamber so that the water causes a swirling flow around the indoor portion along the inner peripheral wall surface of the inflow chamber; and a water pressure varying means that changes the wash water pressure of the water supply mechanism. A water spouting device comprising: 6. An apparatus for discharging the supplied wash water from a water outlet, the inflow chamber into which the wash water flows, a water discharge portion provided in the inflow chamber and having the water outlet, and the water discharge portion. And an indoor portion that is located in the inflow chamber and receives the inflowing cleaning water, and has a water discharge body that has a conduit for guiding the cleaning water in the inflow chamber to the water discharge port, and the cleaning that has flowed into the inflow chamber. A water supply mechanism that guides the wash water into the inflow chamber and an amount of air mixed into the wash water of the water supply mechanism are varied so that the water swirls around the indoor portion along the inner wall surface of the inflow chamber. A water discharge device comprising: an air mixing amount varying means. 7. A constant flow valve for adjusting an instantaneous flow rate to a predetermined value is provided near a water supply port from a water supply source.
7. The water discharge device according to any one of 6 to 6. 8. The water spouting device according to claim 2, wherein a plurality of inflow ports that are inlets to the inflow chamber are provided for a single inflow chamber.