JP2003225622A - Water spout apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a water spout apparatus in which massage or water saving is carried out and cleaning property is improved by inducing the change of spouted water stream with a simple structure without necessitating a large amount or the high pressure of water. <P>SOLUTION: The water spout apparatus is provided with a swirl chamber and a rocking body in a nozzle and the rocking body causes oscillating revolution by the swirl flow produced in the swirl chamber. A shield part is provided in the swirl part and a plurality of water spout ports are provided on the downstream side wall surface opposed to the shield part in the swirl chamber. Because the spout ports are arranged radially, water is spouted from the spout ports successively shielded by the shield part with the revolution of the rocking body. Then washing water spouted from the apparatus is discharged while periodically changing the flow rate spouted from the spout ports in the circumferential direction. <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, which causes a change in spouting water and spouts water over a wide area, thereby performing massaging and enhancing the cleaning power. The present invention relates to a water discharge device for the purpose of saving water and saving water.

[0002]

2. Description of the Related Art Conventionally, as disclosed in Japanese Patent Laid-Open No. 5-115813, a water wheel is rotated to rotate a plurality of water discharge holes with a shielding plate provided on the water wheel to sequentially shield a plurality of water discharge holes. It is known that water is spouted sequentially from a water spout hole to cause a periodic change in the amount of water spouted.

[0003]

However, in such a structure, since the water wheel and the shield plate need to be rotated while being pressed by the wall surface of the device due to the water pressure, the water wheel and the shield plate and the device wall surface are rotated. It was necessary to rotate the water turbine and the shield plate with a force larger than the frictional force generated between them, which required a large flow rate and pressure. Also, because the frictional force between the water wheel and the shield plate and the device wall surface is large, the rotation speed of the water wheel becomes low, and when washing or massaged against the human body, the change speed of the water discharge is small and it feels uncomfortable. There was a problem that it would end up. Further, the contact sliding surfaces of the water wheel and the shield plate are large, and there are problems such as abrasion and sticking.

The water discharger of the present invention has been made in order to solve such a problem, and an object of the present invention is not to require a large flow rate or pressure, and to have a simple structure to discharge water. It proposes a water spouting device that can change massage, perform massage and water saving, and enhance the cleanability.

[0005]

In order to achieve the above object, a first aspect of the present invention is an apparatus comprising a nozzle for discharging supplied wash water from the nozzle, wherein the nozzle is a washing device. An inflow chamber into which water flows, a water discharge port that opens on the downstream side wall surface of the inflow chamber and discharges cleaning water, and a tapered shield that is built in the inflow chamber and that faces the water discharge port. A columnar oscillating body having a portion and an interior portion located in the inflow chamber that is continuous with the shielding portion, and wash water that has flowed into the inflow chamber causes a swirl flow in the inflow chamber.
A water supply mechanism that guides the wash water to the inflow chamber, the water supply mechanism causes a flow velocity difference in the swirl flow around the indoor portion, and exerts a force generated based on the flow velocity difference on the indoor portion, It is characterized in that the swinging body is swung to revolve in a posture in which the indoor portion is inclined in the inflow chamber.

In the water discharger of the present invention having the above-mentioned structure, the wash water supplied from the water supply source is caused to flow by the water supply mechanism as a swirling flow along the inner wall surface of the inflow chamber. Since this swirling flow causes a flow velocity difference around the indoor part, a force is generated in the inflow chamber based on the flow velocity difference. This force is of the same quality as the lift force that acts on the object when the object moves in the fluid, based on the difference in velocity of the fluid sandwiching the object. Therefore, in the following description, the force based on the flow velocity difference will be referred to as lift force for the sake of simplicity of description.

[0007] Thus, the indoor site enters the inlet chamber, lift F _L when the swirling flow around the interior portion is awake at the time of its occurrence, the speed of the indoor part is zero, the relative Is affected by the flow velocity V [m / sec] of the swirling flow. The lift _FL is the maximum projected area S [m ² ] of the indoor part that receives the lift, and the wash water density is ρ [kg.
/ M ³ ], it is represented by the following equation. C _L in the equation is a lift coefficient. ^{_{F L = (ρ · V 2}} · C L · S) / 2 [N] Note that, in this way the lift _{F L} acts on chamber parts, drag force ^{_{F D (= (ρ · V}} 2 · The room site as a result C _D
・ S) / 2 [N]) also works. This C _D is the drag coefficient. Considering the situation where a swirling flow around the indoor part occurs in the inflow chamber, the lift acts on the indoor part as described above. This lift acts outward from the central side in the swirling flow on the side where the flow velocity of the swirling flow around the indoor part is large.

On the other hand, the indoor part is
Since it is possible to swing in a tilted posture, it tilts by receiving this lift force, tilts toward the inflow chamber inner wall side, and moves in the resultant direction of this lift force and drag force. This resultant force moves in the direction in which the indoor part is moved along the flow direction of the swirl flow because the drag force is along the flow direction of the swirl flow. Therefore, when the force receiving portion receives the lift force, the force receiving portion tilts toward the inner wall of the inflow chamber and moves in the resultant direction of the lift force and the drag force. Further, this resultant force acts in the direction of moving the indoor part along the flow direction of the swirl flow because the drag force is along the flow direction of the swirl flow. In such a case, the situation of the flow velocity difference of the swirling flow around the indoor part also changes, and the lift / drag force in this new situation causes the indoor part to move in the swirling flow direction in an inclined posture. Therefore, the oscillating body swings around and revolves in the inflow chamber. Hereinafter, this revolution is referred to as a swing revolution.

Further, the columnar oscillating body has
A tapered shield provided to face the water outlet,
The columnar side surface has an indoor part. Therefore, the above-mentioned various forces are exerted around the indoor part, and the rocking body is
By revolving in an inclined manner, the tapered shielding portion moves while sequentially shielding a part of the water discharge port opened on the downstream side wall surface of the inflow chamber. Further, since the shielding portion is tapered, the gap between the water outlet and the shielding portion is maximum on the opposite side where the rocking body is inclined, and is the minimum on the inclined side. Further, since the shield portion is tapered, the gap gradually changes between the maximum side and the minimum side. Therefore, the wash water guided to the inflow chamber is discharged in a state in which the discharge flow rate is changed on the side shielded by the shield and the other side. or,
The shielding part changes the shielding position of a part of the spout according to the revolution of the oscillating body. Therefore, the cleaning water spouted from the spout also changes according to the position change of the shielding part, and the cycle is changed. The amount of water discharged is changed.

Further, the following effects can be obtained by forming the shielding portion in a tapered shape. By forming the shielding portion into a tapered shape that matches the inclination of the oscillator, the shielding portion can reliably shield the water outlet in the inclination direction of the oscillator. It is also possible to set the apex of the taper shape as the apex of revolution and set the axis passing through this apex as the center of rotation of the oscillator, eliminating the swing of the rotary shaft when the oscillator rotates.
A stable revolution can be performed. As a result, it is possible to reliably change the position of the shielding portion of the water discharge port, that is, the position of the water discharge amount change state.

Further, when the indoor portion is lifted and inclined toward the inflow chamber inner wall side as described above, this indoor portion is directly pushed by the swirling flow of the inflow chamber. Therefore, the indoor portion receives the kinetic energy directly from the swirling flow and moves in the swirling flow direction in an inclined posture, and the swinging orbiting of the rocking body is promoted. The kinetic energy A referred to here is one that can be defined by the following equation, and is energy that is governed by the flow of water (swirl flow). A = (ρ · V ² · Q) / 2 [W] where ρ is the density of water and Q is the instantaneous flow rate [m ³ / sec]
And V represents the velocity of the swirling flow. The centrifugal force is defined by the following equation. F = MV ² / R [N] where M is the mass of the oscillator, V is the revolution speed, and R is the revolution radius. This centrifugal force is a force generated when the indoor part revolves due to the rotation or swirling of water, and is a force that the rocking body tends to incline in the radial direction of the revolution or swirling. The moving body is further inclined, and the shielding portion can reliably shield the water outlet.

Further, as in the conventional case, the water stream is struck by a water stream,
When water is rotated by generating a drag force and the water is discharged by sequentially changing the water discharge holes with the shield plate provided in this water turbine, only the kinetic energy of the water flow is used as the means for rotating the water turbine. It was being appreciated. Therefore, in order to rotate the water turbine, it is necessary to increase kinetic energy, and a large flow rate and pressure are required. In addition, since the shield plate is pressed against the device wall surface by water pressure and rotates by sliding on the device wall surface, a large frictional force is generated, and in order to overcome this frictional force and rotate the shield plate, Larger flow rates and pressures were needed.

However, according to the water discharge device of the present invention, the shielding of the water discharge port is performed by the revolution of the oscillating body described above. Further, as described above, the revolution of the oscillating body uses the lift, the drag, and the centrifugal force generated by the water flow, so that a larger force is required as compared with the case of rotating the water turbine using only the drag. With this force, the swinging body can be revolved by this force, and the water outlet can be sequentially and reliably shielded.

Furthermore, since the orbiting motion of the rocking body rotating in a conical shape is used to shield the water outlet, the contacting portion between the rocking body and the inflow chamber is in a direction in which the rocking body is inclined. Only a slight contact between the part and the wall of the inflow chamber is enough. Therefore, the frictional force at the contact portion between the oscillating body and the inflow chamber is small, and the water discharge port can be easily shielded together with the large force obtained from the above-described flow.

Regarding the shielding of such a water outlet, the opening gap between the water outlet and the shielding portion is minimum (zero) on the side where the rocking body is inclined and maximum on the opposite side. Further, the opening gap changes gently between the minimum and maximum opening gaps. Therefore, it is possible to greatly change the opening of the water discharge port, even if the contact between the shielding portion and the wall surface of the inflow chamber is very slight.

Moreover, in order to discharge water with such a periodical change in the amount of discharged water, a swirl flow is caused by injecting wash water into the inflow chamber, and this swirl flow causes the oscillator to swing around the inflow chamber. It's enough if you wake it up. Therefore, it is sufficient to cause the above-mentioned oscillating body to be incorporated in the inflow chamber and to generate the swirling flow by introducing the wash water into the inflow chamber, so that the configuration can be simplified and the cost can be reduced. The device can be made compact by simplifying the configuration.

Further, the generation status of the flow velocity difference around the indoor part can be adjusted by the state of introduction of the washing water into the inflow chamber, the shape of the inflow chamber, and the like. Therefore, it is possible to adjust the swinging orbit of the rocking body,
This makes it possible to diversify the water discharge mode. For example, by increasing the lift force, drag force, and centrifugal force described above, the swinging body can be swung orbitally at high speed to periodically change the water discharge amount, and by stabilizing the swinging orbiting state of the swinging body, The trajectory of swing revolution can be easily made stable, and the amount of water discharged can be changed stably.

Further, when such a periodical change in water discharge is used to apply water to the human body for massage, the amount of water landed on the human body changes in accordance with the change in the amount of water discharge. Therefore, the blood vessels are expanded and contracted as compared with the case where continuous water discharge is simultaneously performed, and as a result, blood circulation is promoted.

Further, as described above, if the water discharge amount is periodically changed at a high speed, the human body cannot recognize the high-speed water discharge swimwear water transition even if the water landing point is changed. , The illusion that the spouted water is continuously landing does not require continuous spouting such that the cleaning water is landed at the same time in the entire water landing range. Therefore, water can be saved accordingly. In addition, when the average water discharge amount is the same, as compared with the case where water is discharged from the water discharge hole at the same time, the water discharge flow rate is partially changed by periodically changing the position and discharging water while maintaining the water discharge amount change. The position can be changed in the increased state. Therefore, it is possible to exert a high cleaning power.

In order to achieve the above object, the water supply mechanism is characterized in that the water supply mechanism has a nozzle conduit which is eccentrically communicated with the inflow chamber in the peripheral wall of the inflow chamber. Thus, when the wash water flows into the inflow chamber, the inflowing wash water swirls around the indoor part along the inflow chamber inner wall immediately after the wash water first flows into the inflow chamber. It surely causes the flow with a difference in flow velocity. As a result, it is possible to bring about swinging orbiting of the oscillating body as well as stabilization of periodic changes in the water discharge amount.

In order to solve the above problems, the third aspect of the present invention is
The water discharge port is characterized by being formed of a plurality of holes. With this configuration, for example, the water discharge ports can be arranged discretely, and the water discharge holes for discharging water can be changed discretely. Therefore, the change in the amount of water discharged is not continuous but discrete, and the change in the stimulation of water discharge based on this is also discrete, so that the feeling of massage and the water saving effect can be increased. Further, it is possible to arrange the water discharge port over a wide range without changing the total area, and it is possible to discharge water over a wider range. In addition, it is possible to combine water outlets of various sizes and shapes, and variations of water discharge are possible.

In order to solve the above problems, the fourth aspect of the present invention is
The water discharge port formed of the plurality of holes is arranged in a circle with the central axis of the inflow chamber being coaxial. In this way, when the rocking body shields the water discharge port while revolving, the orbit of the revolution, that is, the shielding portion is sequentially
The water outlet can be arranged on the orbit that contacts the downstream side wall surface, and the water outlet can be reliably shielded. Therefore, it is possible to stably change the amount of water discharged from the water discharge port.

In order to solve the above-mentioned problems, the fifth aspect of the invention is
The water discharge port is characterized in that the opening shape on the inflow chamber side is a long hole shape elongated in the radial direction of the inflow chamber. This has the following advantages. The oscillating body is inclined and inscribes in the downstream side wall surface of the inflow chamber. Therefore, the contact between the tapered shielding portion and the downstream side wall surface is performed by the linear portion in the inclined direction. Therefore, if the shape of the opening of the water discharge port is a long hole that is long in the radial direction of the inflow chamber, that is, the direction of inclination, it is possible to effectively shield the shielding portion and the linear contact portion of the downstream side wall surface. Therefore, since the water outlet can be shielded more reliably by the shield portion, the change in the water discharge flow amount becomes more significant, and the massage effect and the water saving effect described above can be enhanced.

In order to solve the above-mentioned problems, claim 6
It is characterized in that it has a guide portion for regulating the inclination angle of the rocking body. Therefore, the inclination angle of the oscillating body can be surely regulated by the guide portion, and the water discharge port can be reliably shielded by the inclination of the oscillating body. As a result, it is possible to reliably cause a change in the water discharge amount.

In order to solve the above-mentioned problems, claim 7
The oscillating body of the nozzle is characterized in that the indoor portion is inclined with respect to the inflow chamber when the cleaning water does not flow into the inflow chamber and is not inflowing.
For example, assume that the water discharge direction of the nozzle is inclined or parallel to the horizontal plane, and that the oscillating body tilts the indoor part with respect to the inflow chamber when water is not discharged due to gravity acting on itself. it can. With this configuration, the space between the indoor portion of the oscillator and the inflow chamber inner wall can be narrowed before the flush water flows into the inflow chamber. Therefore, from the beginning of the inflow of the wash water into the inflow chamber, the flow velocity can be increased while the wash water passes through the narrowed portion, and the flow velocity difference of the swirling flow can be reliably generated. Therefore, from the beginning of inflow of wash water,
Since the lift force described above can be reliably generated, it is possible to easily achieve the swing orbit of the oscillating body and the stabilization of the periodic change in the water discharge amount.

When inclining the oscillating body in this way,
You can also do the following: That is, an inclined guide portion is provided at the center of the bottom surface of the inflow chamber, and the indoor portion of the rocking body can be inclined with respect to the inflow chamber when water is not discharged by this inclined guide portion. Even in this case, the lift force can be surely generated from the beginning of inflow of the wash water, and the swinging revolution of the rocking body and the periodical change of the water discharge amount can be easily caused. It is also possible to provide such an inclined guide portion at the lower end of the indoor portion of the rocking body.

In order to solve the above-mentioned problems, claim 8 is
At least a part of the oscillator is made of metal. By forming at least a part of the oscillator with a metal having a large specific gravity in this way, it becomes possible to increase the centrifugal force when the oscillator revolves, as shown in the above-mentioned equation. Thus, the rocking body can be surely tilted to shield the water outlet.
Therefore, it becomes possible to reliably cause a change in the water discharge amount, and the massage and water saving described above can be performed. Also, by making at least a part of the oscillator a metal and making the mass heavy, it is possible to increase the inertial force of the oscillator itself, and to receive the drag force obtained from the water flow, The rotation speed can be reduced. In this case, the sense of stimulation of water discharge can be increased by shortening the cycle of changing the position of the water discharge amount change.

In order to solve the above problems, the ninth aspect of the present invention is
The oscillating body is characterized by causing the oscillating body to rotate about its own axis while rotating around the axis of the indoor part. In this way, the oscillating body is affected by the flow in the inflow chamber, and the oscillating body itself or the shield portion is affected by the frictional force generated by contacting the inner wall of the inflow chamber when revolving in the inflow chamber. It is possible to rotate freely. Therefore, it becomes possible for the oscillating body to revolve more easily by rotating without rotating against the flow or the frictional force. Further, since it does not oppose the frictional force, it is possible not only to reduce the amount of water and the pressure required for revolving the rocking body, but also to prevent abrasion, so that even if it is used for a long time, water is discharged. Stabilize.

Further, in order to solve the above-mentioned problems, a tenth aspect is provided.
Is characterized in that a protrusion is provided near the water discharge port. Therefore, for example, by forming the protrusion with a brush, the massage effect due to the periodic change in the water discharge amount and the massage with the brush can be used together. In this case, since the massage with the brush is performed by the human hand, it is a massage with a frequency of about several Hz, while the frequency of the change in the stimulation of the water flow due to the change of the water discharge position using the revolution of the oscillating body is about several tens Hz. Hundreds of Hz.
Further, the stimulus by the brush is a mechanical strong partial stimulus, whereas the stimulus by the water discharge is soft and the whole stimulus. Therefore, it is possible to simultaneously apply stimuli having different frequencies and sensations, and it is possible to enhance the feeling of massage and the cleansing power. Further, since the brush itself can be vibrated at a frequency of a few hundred Hz by the above-mentioned change of water discharge of a few hundred Hz, a high cleaning power can be exerted even by this high-speed vibration. Such a water discharge device is effectively used for washing teeth, washing the human body, washing dishes, washing bathtubs, and the like.

Further, in order to solve the above-mentioned problems, the present invention is defined in claim 11.
Is a human body local part cleaning device that spouts the supplied cleaning water toward a human body part, characterized in that it has the water discharge device and spouts the cleaning water from the nozzle toward the human body part. . In this case, since the high water-saving property and the massage effect provided by the present water discharge device can be exhibited, it is less likely that the hot water in the tank will run out during use. Also, even when boiling water using an instantaneous heat exchanger, the amount of water used can be small, so it is possible to reduce the power consumption of the heater and to bring the low-temperature washing water to the required temperature. It is possible to raise the temperature. Further, since a large-scale device is not required, it is possible to reduce the size and noise of the human body local region cleaning device itself. In addition, when changing the position of the water discharge, a particularly large flow rate or water pressure is not required. Further, the massage effect can be expected to stimulate blood vessels around the anus to improve blood circulation and promote defecation.

In order to solve the above-mentioned problems, a twelfth aspect is provided.
Is a shower device that discharges the supplied cleaning water toward a human body, and is a shower device that has the water discharging device and discharges the cleaning water toward the human body from the nozzle. . Also in this case, since it is possible to exert high water-saving and massage effects brought by this water discharge device,
As a shower device, water saving and massage can be achieved. Further, as described above, since no special device or power supply is required, it is suitable as an environment where there is a lot of moisture and rust or leakage easily occurs, for example, as a shower device in a bathroom.

Further, in order to solve the above-mentioned problems, the invention according to claim 13
Is a massage bathtub device that spouts the supplied wash water into the bathtub and spouts it toward the human body while bathing, and has the water spouting device, and spouts the wash water toward the human body from the nozzle. It is characterized by being a massage bathtub. In this case, a high massage effect provided by the water discharge device can be exhibited. In addition, even when water is discharged into the water in this way, no special device or power supply is required, so there is no risk of rust or electric leakage, which is preferable.

Further, in order to solve the above-mentioned problems, the invention according to claim 14
Is a cleaning device for discharging the supplied cleaning water toward the object to be cleaned, the cleaning device having the water discharging device and discharging water from the nozzle toward the object to be cleaned. There is. In this case, a high cleaning effect brought about by the water discharge device can be exhibited. In this case, when the average water discharge amount is the same, the water discharge flow rate can be partially increased by discharging water while changing the water discharge position, as compared with the case where water is simultaneously discharged from the water discharge hole. Therefore, since it is possible to exert a high cleaning power, it is effective to use it in a dishwasher, a bath washer or the like.

[0034]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Next, embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a top view of the water discharger of the present invention. FIG. 2 is a vertical cross-sectional view of the water discharger of the present invention. FIG. 3 is a cross-sectional view of the water discharger of the present invention taken along the line AA in FIG. FIG. 4 is a detailed view of an oscillator used in the water discharger of the present invention.

As shown in FIG. 2, the nozzle 1 is provided with a swirl chamber 15 formed in a cylindrical shape as an inflow chamber into which wash water flows, and in this swirl chamber 15, a water passage 12 and a swirl chamber inflow passage 11 are provided.
It is configured to supply cleaning water via the. The swirl chamber inflow passage 11 is a nozzle conduit, has a water passage cross-sectional area smaller than that of the water passage 12, and is eccentrically connected to the center of the swirl chamber 15 and connected to the swirl chamber 15. Therefore, the wash water from the swirl chamber inflow passage 11 flows into the swirl chamber 15 from the tangential direction thereof, and generates a swirl flow swirling along the inner wall of the swirl chamber 15 as shown in FIG. In this case, since the water passage cross-sectional area of the swirl chamber inflow passage 11 is smaller than that of the water passage 12, the flow rate of the wash water flowing into the swirl chamber 15 can be increased.

Further, the nozzle 1 is provided with the oscillating body 20 incorporated in the swirl chamber 15. As shown in FIG. 4, the oscillating body 20 has a columnar shape as a whole, and a shield portion 2 having a tapered upper surface.
5 and a hemispherical fulcrum portion 26 at the apex of the tapered shape. Further, the oscillating body has a cylindrical force receiving portion 21 with the lower side surface as an indoor portion. The force receiving portion 21 is located in the swirl chamber 15 and receives various forces described below from the swirling flow and participates in the swing revolution drive of the rocking body 20 described later. Further, a downstream side wall surface 17 is provided on the downstream side of the swirl chamber 15, and the downstream side wall surface 17 is provided in a tapered shape with an angle larger than the taper angle of the rocking body 20, and
A support portion 16 having a hemispherical recess is provided at the apex of the taper. Further, the downstream side wall surface 17 is provided with a water discharge port 5 having a plurality of openings.

Further, in the rocking body 20, the force receiving portion 21 is arranged in the swirl chamber 15, and the fulcrum portion 26 and the supporting portion 1 are provided.
6. The nozzle 1 is provided with the shielding portion 25 and the downstream side wall surface 17 facing each other. Further, the oscillating body 20 can freely revolve around the supporting portion 16 in a conical shape with the fulcrum portion 26 supported by the supporting portion 16. Furthermore, since the supporting portion 16 and the fulcrum portion 26 are not fixed to each other, the oscillating body 20 can freely rotate about the central axis of the oscillating body 20 itself. these,
The revolution and the rotation are caused by the force receiving portion 21 and the swirling flow, and details thereof will be described later.

In the upper part of the swirl chamber 15, the swirl chamber 1 is provided.
A guide portion 14 having a diameter smaller than 5 is provided. The guide portion 14 regulates the maximum inclination angle of the force receiving portion 21, and thus the rocking body 20.

Here, the state of spouting flush water and the behavior thereof in the nozzle 1 having the above-mentioned configuration will be described. FIG. 5 is an explanatory diagram for explaining the behavior of the force receiving portion 21 after the wash water has flowed into the swirl chamber 15 and the state of the force applied to the force receiving portion 21 over time. As shown in FIG. 5, the wash water is now flowed into the swirl chamber 15 from the swirl chamber inflow passage 11 (time t0). In this case, the wash water flows from the water passage 12 having a large passage cross-sectional area to the swirl chamber inflow passage 11 having a small water passage cross-sectional area, and thus flows into the swirl chamber 15 at a high flow velocity. Therefore, the kinetic energy that can be provided by the collision of the wash water is increased.

When the wash water flows into the swirl chamber 15 in this manner, the wash water flows along the inner wall of the swirl chamber 15 into the force receiving portion 21.
It creates a swirling flow that swirls around. Regarding the flow velocity in this swirling flow, the flow velocity Uin is highest in the communication portion of the swirling chamber inflow passage 11. A location where the inflowing cleaning water first swirls, that is, the peripheral wall portion 15a on the extension line of the opening of the swirling chamber inflow passage 11.
And a peripheral wall portion 15b facing the portion, a difference occurs between the flow velocity Ua and the flow velocity Ub, and the relationship between them is U
a> Ub. That is, while the wash water is spread (swirled) from the peripheral wall portion 15a to the peripheral wall portion 15b, the influence of the flow dispersion in the swirl chamber 15, the contact of the wash water with the inner wall surface of the swirl chamber 15, the wash water viscosity, the surface friction, and the like. In response, the wash water slows down.

Therefore, a flow velocity difference of the wash water occurs around the force receiving portion 21. In this case, what moves is fluid (wash water)
However, the relative relationship between the cleaning water and the force receiving portion 21 does not change from the situation in which an object moves in the fluid. Therefore, when the object moves in the fluid, the lift force acts on the object based on the speed difference between the fluids sandwiching the object.
1 and the force having the same quality as the lift acts on the force receiving portion 21. Note that, for convenience, this force is referred to as the lift force, as described above. However, if another phenomenon is used as an example, the fact that the lift force is generated due to the difference in the fluid velocity is as follows. It is similar to the generation of lift force due to the speed difference, that is, the pressure difference.

As shown in FIG. 3, the force receiving portion 21 enters the swirl chamber 15, and at time t0 in FIG. Since the swirling flow of the force receiving portion 21 around which is stopped occurs in this time t0, the lift F _L is the peripheral wall portion 15
It is affected by the flow velocity Ua [m / sec] of the swirling flow of a. Then, the lift F _L is, S [m ^2] a maximum projection area of the force-receiving portion 21 for receiving the lift, the density of the wash water ρ [kg / m ^3]
Then, it is expressed by the following equation. C _L in the equation is a lift coefficient. ^{_{F L = (ρ · V 2}} · C L · S) / 2 [N] thus lift _{F L} is to act on the force receiving portion 21, as a result the force receiving portion 21 drag _F D (= _(ρ · V ²・ C
_D / S) / 2 [N]) also works. This C _D is the drag coefficient. The maximum projected area S in the above equation is the force receiving portion 21.
Therefore, if the length L of the force receiving portion 21 is increased, the lift / drag can be increased.

As shown at time t0 in FIG.
When a swirl flow around the force receiving portion 21 occurs at, the lift force acts on the force receiving portion 21 as described above. The lift force is applied to the peripheral wall portion 15a where the flow velocity of the swirling flow around the force receiving portion 21 is large.
It works outward from the central side in the swirling flow on the side of. Meanwhile, the force receiving portion 21, the whirling chamber 15, since an inclined posture is swingably inclined in the direction indicated by the lift F _L receiving and in the arrow F _L. Thus, the force receiving portion 21
There tilts the inner wall of the swirl chamber 15, at time t1, the lift F _L and drag F _D are both acts move in the force direction. This resultant force acts in the direction of moving the force receiving portion 21 along the flow direction of the swirl flow, because the drag force is along the flow direction of the swirl flow.

In this case, the passing interval of the swirling flow becomes narrow on the side where the force receiving portion 21 is inclined, and the swirling flow velocity increases due to this narrowing. Since this situation occurs such that the narrow gap portion moves around the force receiving portion 21, the portion having the largest flow velocity of the swirling flow also moves along the inner peripheral wall of the swirling chamber 15. Therefore,
Since the direction of the lift force _{FL and} the direction of the drag force F _D also change with the movement of the portion having the largest flow velocity, the times t2, t
As it goes to 3 and t4, the force receiving portion 21 moves in the flow direction of the swirling flow while keeping the inclined posture. When the oscillating body starts to revolve under the influence of the lift force and the drag force in this way, a centrifugal force acts on the oscillating body in the radial direction of the swirling chamber, and the swinging orbiting of the oscillating body 20 is further promoted.

For this reason, the oscillating body 20 swings around the fulcrum 16 with the supporting portion 26 inwardly about the fulcrum 16 and revolves in the swirl chamber 15 (pivot orbit). . Then, the oscillating body 20 revolves around the tapered shield portion 25 inscribed in the downstream side wall surface 17 while the inclination angle is regulated by the guide portion 14. Further, as shown in FIG. 1, since the downstream side wall surface 17 is provided with a plurality of water discharge ports 5 which are opened radially around the support portion 16, the shielding portion 25 is accompanied by the revolution. Is the side where the rocking body 20 is inclined,
A part of the water discharge port 5 provided on the downstream side wall surface 17 is shielded.

In this case, in the shielding state, the gap area between the water outlet 5 and the shielding portion 25 has a minimum value on the side where the rocking body 20 is inclined, and the gap area has a maximum value on the opposite side. Further, the gap area changes gently between the minimum value and the maximum value. Therefore, by inclining the oscillating body 20, the gap area between the plurality of radially provided water discharge ports 5 and the shielding portion 25 can be changed from the minimum value to the maximum value to the minimum value in the circumferential direction. . The state of change in the gap area can be changed depending on the taper state of the shielding portion 25 and the downstream side wall surface 17 and the shape and area of the water outlet 5.
Further, the wash water supplied from the swirl chamber 15 to the water discharge port 5 and discharged is supplied through the gap between the water discharge port 5 and the shielding portion 25 described above, and thus is discharged from the water discharge port 5. The amount of wash water is determined by this clearance area.

The oscillating body 20 revolves with the fulcrum portion 26, the shield portion 25, and a small portion of the force receiving portion 21 in contact with the nozzle 1. Further, the oscillating body 20 is provided so as to rotate about the central axis of the oscillating body 20 itself, so that the oscillating body 20 rolls by receiving the frictional force generated at the contact portion with the nozzle 1 described above. While revolving in the same manner, orbit.

Here, the state of water discharge when such a water discharge device is used will be described with reference to the drawings. FIG. 6 shows the nozzle 1
It is a figure explaining the state of the water discharge using. As shown in FIG. 6, when the oscillating body 20 causes the swing orbit as described above,
The area of the gap between the plurality of radially provided water discharge ports 5 and the shielding portion 25 varies from the minimum to the maximum to the minimum in the circumferential direction. As a result, the flow rate of the wash water discharged from the water discharge port 5 also changes from the minimum to the maximum to the minimum in the circumferential direction. As shown, the rocker 2
On the side where 0 is inclined, the discharge flow rate is the minimum, and on the opposite side,
The discharge flow rate is the maximum. Further, since the rocking body 20 revolves in response to the above-described flow, the magnitude of the water discharge amount changes sequentially according to the revolution of the rocking body 20. Therefore, the wash water discharged from the nozzle 1 has a large or small change in the flow rate in the circumferential direction according to the inclination of the oscillating body 20, and further, the position of the large or small flow rate is changed in accordance with the revolution of the oscillating body 20. Water is discharged while changing periodically.

The nozzle 1 has the following advantages. If the human body is exposed to the water discharge that changes the amount of water discharged as described above, the following advantages are obtained. At the landing point of the discharged wash water, the flow rate changes periodically, so that the blood vessel repeats contraction and expansion at the water landing point as the flow rate changes. Therefore, due to the contracting and expanding actions of the blood vessels, blood circulation is promoted, and a suitable massage effect is obtained.

The water spouting device of the present invention changes the spouted water flow rate and the position of the flow rate change as described above. When performing such water spouting, the oscillating body 2 described above is used.
The revolution of 0 is used. Further, since the orbit of the oscillating body 20 utilizes the lift force, the drag force, and the centrifugal force generated by the water flow, a larger force can be obtained as compared with the case of rotating the water turbine using only the drag force. By this force,
Since the oscillating body 20 is revolved and the water discharge ports are sequentially and reliably shielded, the above-mentioned change can be surely brought about in the water discharge with a small flow rate and pressure.

Furthermore, when the water discharge port 5 is shielded, the orbiting motion of the oscillating body 20 rotating in a conical shape is utilized.
The contact portion between the oscillating body 20 and the inflow chamber 15 may be a shield portion in the direction in which the oscillating body is inclined, and a very small contact portion only on the wall surface of the inflow chamber, and at the contact portion between the oscillating body 20 and the inflow chamber 15. However, since the oscillating body 20 itself rotates by receiving the frictional force, sliding resistance and wear do not occur. In addition, there is little sliding resistance, combined with the large force obtained from the flow described above,
The spout 5 can be easily shielded.

Regarding the shielding of the water discharge port 5 as described above,
The opening gap between the water discharge port 5 and the shielding portion 25 is minimum (zero) on the side where the rocking body is inclined, and is maximum on the opposite side. or,
The opening gap changes gently between the minimum and maximum opening gaps. Therefore, it is possible to largely change the opening of the water discharge port 5 and greatly change the water discharge amount, even if the contact between the shielding portion and the wall surface of the inflow chamber is very slight. Further, by causing such a change in water discharge, it is possible to save water as compared with the case where water is simultaneously discharged from the entire water discharge port. In this case, if the average water discharge amount is the same and compared, the instantaneous flow rate at the maximum opening can be increased, and the cleaning power and the feeling of massage can be significantly improved. Further, when comparing the same amount of water discharge at the maximum opening, the water discharge at the maximum opening contributes to the cleaning power, so that the cleaning power is not reduced. On the other hand, the amount of water discharged from the maximum opening to the minimum opening can be greatly reduced. Therefore, it is possible to significantly save water without lowering the cleaning power.

Moreover, when the change of the water discharge amount and the position of the change of the water discharge amount are changed, a swirl flow is caused to inject the wash water into the inflow chamber, and this swirl flow causes the swinging body to move into the neck of the inflow chamber. It is enough to make a swing revolution. Therefore, the above-mentioned rocking member is incorporated into the inflow chamber and swirling flow is generated by introducing the cleaning water into the inflow chamber, so that the configuration can be simplified and the cost can be reduced. In addition, through simplification of the configuration,
The device can be made compact. Further, since there is no electric drive part such as an actuator, the durability of the electric drive part does not become a problem, and no electrical wiring to the tip of the nozzle is required. Therefore, it is possible to simplify the assembling work and the maintenance work, and the structure without the need for consideration of electric leakage.

In the present embodiment, the flow velocity of the wash water flowing into the swirl chamber 15 is increased on the assumption that the swirl chamber inflow passage 11 for allowing the wash water to flow into the swirl chamber 15 has a small water passage cross-sectional area. As described above, the flow velocity of the wash water flowing into the swirl chamber 15 is the lift _FL.
Stipulate. Thus, providing a swirling chamber inflow passage 11 cross-sectional flow area is a variety of, the use of these selectively, other lift F _L acting on the force receiving portion 21, the drag-centrifugal force can be adjusted . These forces also determine the frequency of the swing revolution of the oscillator 20. Therefore, by adjusting the water flow cross-sectional area of the swirl chamber inflow passage 11 or selecting the swirl chamber inflow passage 11, the frequency of the swing revolution of the oscillating body 20 can also be adjusted.

In the oscillating body 20 of this embodiment, the portion directly receiving the kinetic energy of the swirling flow has a cylindrical shape, but the shape is not limited to the cylindrical shape, and a triangular prism, a quadrangular prism,
It can also be a polygonal prism such as a hexagonal prism. On the other hand, as the material of the oscillating body 20, a synthetic resin such as PP, POM, ABS, or the like can be adopted, or metal such as stainless steel or only the force receiving portion 21 can be made of metal. In this case, by making the force receiving portion 21 that orbits the heavier, it is possible to increase the centrifugal force generated along with the orbital motion, and increase the inclination of the oscillating body 20 or the oscillating body 20 itself becomes heavy and the inertial force is increased. By increasing, the frequency of revolution can be reduced.

Next, a modified example will be described. This modification is characterized in that the oscillating body 20 is forcibly tilted when water is not discharged. FIG. 7 shows a modified nozzle 3
It is a figure for demonstrating 1. Hereinafter, description will be given with reference to FIG. 7. Like the nozzle 1 of FIG. 2, the nozzle 31 includes a cylindrical swirl chamber 15 into which wash water flows, and the swirl chamber 15 is supplied with wash water through a water passage 12 and a swirl chamber inflow passage 11. It is configured to do. The swirl chamber inflow path 11 is
The cross-sectional area of the water passage is smaller than that of the water passage 12, and is connected to the swirl chamber 15 in an eccentric manner with respect to the center of the swirl chamber 15.

Further, the nozzle 31 is provided with the oscillating body 20 incorporated in the swirl chamber 15. Here, the oscillating body 20 is the same as that shown in FIGS. Also, the swirl chamber 1
A downstream side wall surface 17 is provided on the downstream side of 5, and is provided in a tapered shape with an angle larger than the taper angle of the rocking body 20, and a hemispherically recessed support portion 16 is provided at the apex of the taper. There is. Further, the downstream side wall surface 17 is provided with a water discharge port 5 having a plurality of openings.

Further, in the rocking body 20, the force receiving portion 21 is arranged in the swirl chamber 15, and the fulcrum portion 26 and the supporting portion 1 are provided.
6. The nozzle 31 is provided with the shielding portion 25 and the downstream side wall surface 17 facing each other. Further, the oscillating body 20 can freely revolve around the supporting portion 16 in a conical shape with the fulcrum portion 26 supported by the supporting portion 16. Furthermore, since the supporting portion 16 and the fulcrum portion 26 are not fixed to each other, the oscillating body 20 can freely rotate about the central axis of the oscillating body 20 itself. These revolutions and rotations are caused by the force receiving portion 21 and the swirling flow, and the details thereof are the same as those in the above-described embodiment.

Further, a sloping tilt guide portion 32 is provided at the center of the bottom surface of the swirl chamber 15 so that the oscillating body 20 is forcibly maintained in a tilted posture. Further, a guide portion 14 having a smaller diameter than the swirl chamber 15 is provided above the swirl chamber 15. The guide portion 14 regulates the maximum tilt angle of the rocking body 20.

A case will be described in which cleaning water is discharged from the nozzle 31 having the above-described configuration. The swirl chamber 15 is passed through the wash water passage 12 and the swirl chamber inflow passage 11.
It is the same as that of the above-mentioned embodiment about the introduction into the above and generating the swirling flow along the wall surface of the swirling chamber 15. Further, in this embodiment, the rocking body 20 is tilted in advance by the tilt guide portion 32 when the cleaning water is not discharged. Therefore, a narrow portion is previously formed between the force receiving portion 21 and the inner wall of the swirl chamber 15. Therefore, swirl chamber 1
It is possible to increase the flow velocity of the wash water while the wash water passes through the narrowed portion from the beginning of inflow of the wash water to the nozzle 5, and to reliably cause the flow velocity difference of the swirling flow. For this reason,
Furthermore, when the flow rate and pressure are low, or from the beginning of inflow of wash water,
It is possible to reliably generate the lift force described above, and the rocking body 2
It is possible to easily stabilize the swinging revolution of 0 and the periodic change state of the discharged water flow rate.

Next, application examples of the present invention will be described.
In this application example, the spout is provided at the tip of the brush-like protrusion,
The feature is that water is discharged by contacting the human body or the object to be cleaned. FIG. 8 is a diagram for explaining the nozzle 41 of the application example. Similar to the above-described embodiment, the nozzle 41 includes the oscillating body 20 inside the swirl chamber 15 and has the same structure as the nozzle 1 shown in FIG. 2 up to the water discharge port. Further, the nozzle 41 has a brush-shaped protrusion 42, and is provided with a water discharge port 45 that opens at the tip of the protrusion 42 and communicates with the downstream side wall surface 17. Therefore, like the nozzle 1, when the cleaning water is supplied to the nozzle 41, a swirling flow is generated along the inner wall of the swirling chamber 15. The swirling flow causes the swinging body 20 to revolve, and the shielding portion 25 provided on the swinging body 20 sequentially shields part of the water discharge port 45. In addition, this shielding brings about a circumferential change in the amount of wash water spouted from the plurality of spouts 45 arranged radially. Further, since the nozzle 41 has the protrusion 42, it is possible to perform cleaning and massage in contact with the human body or the object to be cleaned together with the water discharge described above.

By doing so, cleaning and massage can be performed while exhibiting the water saving effect as described above. In this case, since the massage with the brush is done by the human hand, it is a massage with a frequency of about several Hz.
On the other hand, the frequency of the stimulation change of the water flow due to the change of the water discharge position using the revolution of the oscillator is about several tens Hz to a few hundreds Hz. Further, the stimulus by the brush is a mechanical strong partial stimulus, whereas the stimulus by the water discharge is soft and the whole stimulus. Therefore, it is possible to simultaneously apply stimuli having different frequencies and sensations, and it is possible to enhance the feeling of massage and the cleansing power. In addition, the hundreds H mentioned above
Since the brush itself can be vibrated at hundreds of Hz by the change in the water discharge of z, a high cleaning power can be exerted even by this high-speed vibration. Such a water discharge device is effectively used for washing teeth, washing the human body, washing dishes, washing bathtubs, and the like.

Next, another embodiment of the present invention will be described. This embodiment is characterized in that the upstream side of the water discharge port 5 is provided as an elongated slit. FIG. 9 is a diagram illustrating the nozzle 51 as viewed from above. FIG. 10 is a diagram illustrating the nozzle 51 in a vertical cross-sectional view. As shown in FIGS. 9 and 10, the nozzle 51 has the same structure as the nozzle 1 shown in FIGS. 1 and 2 up to the water discharge port 5.
Further, the nozzle 51 has an elongated slit on the upstream side of the water discharge port 5, that is, on the swirl chamber 15 side. or,
The slits 6 connect the water outlets in the same radial direction among the water outlets 5 which are provided in a circumferential shape and in a radial shape coaxial with the central axis of the swirl chamber 15. Further, the slit 6 is characterized by having a width smaller than the diameter of the water discharge port.

Discharging the wash water from the nozzle 51 having the above characteristics has the following advantages. Similar to the nozzle 1 described above, when cleaning water is supplied to the nozzle 51, the oscillating body 20 tilts and inscribes in the downstream side wall surface 17 of the swirl chamber 15 and revolves. Further, the contact between the tapered shield portion 25 and the downstream side wall surface 17 is made by the linear portion in the inclined direction. The opening area of the shielding portion 25 and the downstream side wall surface, that is, the water discharge port 5 is gradually increased with the linear portion in the inclined direction being a minimum or zero and the opposite side being the maximum. . Therefore, by making the opening shape of the water discharge port 5 a slit that is long in the radial direction of the swirl chamber 15, that is, the inclination direction, and has a width that is narrower than the diameter of the water discharge port, the shielding portion 25 and the downstream side wall surface 17 have a linear shape. The slit can be reliably shielded by the contact portion. Therefore, since the water outlet can be shielded more reliably by the shield portion, the change in the water discharge flow amount becomes more significant, and the massage effect and the water saving effect described above can be enhanced.

Here, in the above embodiment, the oscillator 2
Although 0 and the nozzle are provided by bringing the fulcrum portion 26 and the support portion 16 into contact with each other, they may be provided, for example, through a member having flexibility. In this case, movement of the oscillating body 20 is restricted when the oscillating body 20 rotates about the central axis of the oscillating body 20 itself. However, with respect to the above-described revolution, the flexible member makes the oscillating body 20 flexible. 20 can be easily tilted. Therefore, due to the tilting of the rocking body 20,
The effect of changing the water flow and the effect of reducing the frictional force at the contact part due to contact with only a part of the slope,
It can be expected as in the above-described embodiment. In addition, as for the rotation of the oscillating body 20 being restricted, the oscillating body 2
Since 0 will not be able to roll due to the frictional force at the contact portion, resistance will increase, but when water pressure and flow rate can be sufficiently secured, it can be sufficiently used.

Here, an application example of the nozzle described above will be described. FIG. 11: is a figure explaining the state which used the nozzle 1 of this invention for the hand shower. As shown in FIG. 11, the hand shower 71 includes the nozzle 1 as described above inside and the water discharge port 5 having a plurality of openings.
By using such a hand shower 71, it is possible to obtain the high water-saving effect, massage effect and high reliability as described above.

FIG. 12 is a view for explaining a state in which the nozzle 1 of the present invention is used in the massage bath 73. As shown in FIG. 12, the massage bathtub 73 is fixed to the bathtub 72, which stores bathtub water, in which the nozzle 1 as described above is provided and the water discharge port 5 is directed into the bathtub. Further, the nozzle 1 is provided with a circulation pump which sucks the bath water in the bath 72 from the water supply port and circulates the water to the nozzle 1. The circulating pump is operated by the control device receiving a signal from the operation unit. By using the massage bathtub 73 having such a configuration, it is obvious that the above-mentioned high massage effect and high reliability can be obtained even when water is discharged into water.

FIG. 13 is a view for explaining a state in which the nozzle 1 of the present invention is used in the dishwasher 76. As shown in FIG. 13, the dishwasher 76 has a storage basket 7 for storing dishes.
8 and a storage portion 77 for storing the storage basket 78. In addition, the nozzle 1 is provided with a spout 5 for spouting wash water toward the stored tableware inside the storage section.
Is equipped with. This is preferable because the above-mentioned high water-saving property and detergency can be obtained.

The nozzle 1 of the present invention is housed inside a slender cylindrical nozzle as shown in FIGS.
The nozzle can be provided at the rear of the toilet bowl to advance toward the body part of the human body, and wash water can be discharged toward the body part of the human body for local cleaning, which can be used as a human body part cleaning device. In this case, as described above, it is possible to exert high effects such as a high water saving effect, a tank size reduction due to water saving, and a massage effect to promote defecation.

[Brief description of drawings]

FIG. 1 is a top view of a nozzle 1. FIG.

FIG. 2 is a diagram illustrating a nozzle 1 in a vertical cross-sectional view.

FIG. 3 is an explanatory view taken along the line AA in FIG.

FIG. 4 is a diagram illustrating the details of the oscillating body 20.

FIG. 5 is an explanatory diagram for explaining the behavior of the force receiving portion 21 after the wash water has flowed into the swirl chamber 15 and the state of the force applied to the force receiving portion 21 over time.

FIG. 6 is an explanatory diagram illustrating a state of flush water spouting obtained by the force receiving portion 21 having such a behavior.

FIG. 7 is a diagram illustrating a nozzle 31 in a vertical cross-sectional view.

FIG. 8 is a diagram illustrating a nozzle 41 in a vertical cross-sectional view.

FIG. 9 is a diagram illustrating a nozzle 51, which is provided with an elongated slit upstream of the water discharge port, as viewed from above.

FIG. 10 is a diagram illustrating a longitudinal cross-section of a nozzle 51 having an elongated slit provided upstream of a water discharge port.

FIG. 11 is an explanatory diagram when the nozzle 1 of the present invention is used in a hand shower.

FIG. 12 is an explanatory diagram when the nozzle 1 of the present invention is used in a massage bath.

FIG. 13 is an explanatory diagram when the nozzle 1 of the present invention is used in a dishwasher.

[Explanation of symbols] 1 ... Nozzle 5: spout 6 ... slit 11 ... Swirl chamber inflow path 12 ... Waterway 14 ... Guide section 15 ... Swirl chamber 16 ... Supporting part 17 ... Downstream side wall surface 20 ... Oscillator 21 ... Force receiving part 25 ... Shield 26 ... Support point 31 ... Nozzle 32 ... Inclination guide part 41 ... Nozzle 42 ... Projection 45 ... spout 51 ... Nozzle 71 ... Hand shower 72 ... Bathtub 73 ... Massage bathtub 76 ... Dishwasher 77 ... Storage section 78 ... Storage basket

Front page continuation (51) Int.Cl. ⁷ Identification code FI theme code (reference) A61H 9/00 A61H 35/00 Q 4C100 35/00 B05B 1/18 4F033 B05B 1/18 3/04 Z 3/04 E03D 9/08 D E03D 9/08 A47K 3/22 F term (reference) 2D032 FA04 2D038 JA09 JF00 JH12 3B082 BL01 BL03 3B201 AA33 AB51 BB34 4C094 AA08 AA09 BC12 DD14 EE20 GG05 4C100 AC03 AC09 BB05 BC3 A04 BA03 4 NA01 PA01 PB25 PC02

Claims (14)

[Claims] 1. An apparatus comprising a nozzle for discharging the supplied cleaning water from the nozzle, wherein the nozzle is provided with an inflow chamber into which the cleaning water flows and a downstream side wall surface of the inflow chamber for cleaning. A columnar shape having a water discharge port for discharging water, a taper-shaped shield portion built in the inflow chamber and provided to face the water discharge port, and an indoor portion that is continuous with the shield portion and is located in the inflow chamber An oscillating body, and a water supply mechanism that guides the wash water to the inflow chamber so that the wash water that has flowed into the inflow chamber causes a swirl flow in the inflow chamber. A flow velocity difference is generated around the indoor portion, a force generated based on the flow velocity difference is applied to the indoor portion, and the oscillating body is swung to revolve in a posture in which the indoor portion is inclined in the inflow chamber. Water discharge device. 2. The water discharger according to claim 1, wherein the water supply mechanism has a nozzle conduit that is eccentrically communicated with the inflow chamber on the peripheral wall of the inflow chamber. 3. The water spouting device according to claim 1, wherein the water spouting port is formed of a plurality of holes. 4. The water discharge device according to claim 3, wherein the water discharge port formed of the plurality of holes is arranged in a circumferential shape with the central axis of the inflow chamber being coaxial. Water discharge device. 5. The water discharge device according to claim 4, wherein the water discharge port has an opening shape on the inflow chamber side that is an elongated hole elongated in a radial direction of the inflow chamber. 6. The water discharger according to claim 1, further comprising a guide portion that regulates an inclination angle of the rocking body. 7. The water spouting device according to claim 1, wherein the oscillating body of the nozzle is configured such that when the wash water does not flow into the inflow chamber and the inflow chamber is not inflowing, the indoor portion is located relative to the inflow chamber. The water discharge device is characterized by being inclined. 8. The water discharger according to claim 1, wherein at least a part of the oscillator is made of metal. 9. The water discharger according to claim 1, wherein the oscillating body causes the revolving body and causes the oscillating body itself to rotate about an axis of the indoor part. , Water discharge device. 10. The water discharge device according to claim 1, wherein:
A protrusion is provided in the vicinity of the water discharge port,
Water discharge device. 11. A human body local area cleaning device for spouting supplied wash water toward a human body local area, comprising the water spouting device according to any one of claims 1 to 9, and from the nozzle to the human body local area. A human body local cleaning device that discharges cleaning water toward the user. 12. A shower device for discharging supplied wash water toward a human body, comprising:
A shower device having the water discharge device according to any one of 0 to discharge cleaning water toward the human body from the nozzle. 13. A massage bathtub device which spouts supplied wash water into a bathtub and spouts water toward a human body taking a bath, comprising the water spouting device according to claim 1. A massage bath device for discharging cleaning water from the nozzle toward the human body. 14. A cleaning device for discharging the supplied cleaning water toward an object to be cleaned, which comprises:
A cleaning device having the water discharge device according to any one of 0 to discharge water from the nozzle toward the object to be cleaned.