JP4061571B2 - Water discharge device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention is a water discharging device that discharges supplied cleaning water from a nozzle, and performs a massage, enhances cleaning power, and saves water by causing a change in the discharged water to be discharged over a wide area. The present invention relates to a water discharge device for the purpose.
[0002]
[Prior art]
Conventionally, as disclosed in Japanese Patent Laid-Open No. 5-115183, a water wheel is rotated using a water flow, and a plurality of water discharge holes are sequentially shielded by a shielding plate provided on the water wheel, and water is sequentially discharged from the plurality of water discharge holes. What is known to cause a periodic change in the amount of water discharged is known.
[0003]
[Problems to be solved by the invention]
However, in such a configuration, since it is necessary to rotate the water wheel or the shielding plate while being pressed against the device wall surface by receiving the water pressure, the friction force generated between the water wheel or the shielding plate and the device wall surface is larger. It was necessary to rotate the water wheel and the shielding plate with force, and a large flow rate and pressure were required.
In addition, because the frictional force between the water wheel or shielding plate and the wall of the device is large, the rotation speed of the water wheel is low, and when washing or massaging it against the human body, the rate of change of water discharge is small and it feels uncomfortable. There was a problem such as.
In addition, there is a problem that the contact sliding surface of the water wheel or the shielding plate is large, causing wear or sticking.
[0004]
The water discharge device of the present invention has been made to solve such problems, and the object of the present invention is not to require a large flow rate or pressure, and has a simple structure and changes the water flow to be discharged. The present invention proposes a water discharger that can be used to perform massage and water saving, and to improve cleanability.
[0005]
[Means for solving the problems and actions / effects]
In order to achieve the above object, claim 1 is an apparatus that includes a nozzle and discharges supplied cleaning water from the nozzle, the nozzle including an inflow chamber into which the cleaning water flows and a downstream of the inflow chamber. A water outlet that opens on the side wall surface and discharges cleaning water, a tapered shielding portion that is built in the inflow chamber and is provided facing the water outlet, and is continuous with the shielding portion and is located in the inflow chamber. A columnar rocking body having an indoor part to be moved, and the washing water flowing into the inflow chamber causes a swirling flow in the inflow chamber, Along the inner wall of the inflow chamber A water supply mechanism that guides wash water to the inflow chamber, and the water supply mechanism causes a flow velocity difference around the indoor portion in the swirling flow, and exerts a force generated based on the flow velocity difference on the indoor portion, The swinging body is swung and revolved with the indoor part tilted in the inflow chamber.
[0006]
In the water discharge device of the present invention having the above-described configuration, the washing water supplied from the water supply source generates a flow as a swirling flow along the inner wall surface of the inflow chamber by the water supply mechanism.
Since this swirling flow causes a flow velocity difference around the indoor portion, a force is generated in the inflow chamber based on this flow velocity difference. This force is of the same quality as the lift acting on the object based on the speed difference of the fluid sandwiching the object when the object moves in the fluid. Therefore, in the following description, the force based on the flow velocity difference is referred to as lift for the sake of simplicity of description.
[0007]
Thus, the lift F in the case where the indoor part enters the inflow chamber and a swirling flow around the indoor part occurs. _L At the time of occurrence, the velocity of the indoor part is zero, and is relatively affected by the flow velocity V [m / sec] of the swirling flow. And this lift F _L Is the maximum projected area of the indoor part subject to lift S [m ² ], The density of the washing water is ρ [kg / m ^Three ] Is represented by the following formula. C in the formula _L Is the lift coefficient.
F _L = (Ρ · V ² ・ C _L ・ S) / 2 [N]
In this way, lift F _L Will act on the indoor part, resulting in a drag F _D (= (Ρ · V ² ・ C _D S) / 2 [N]) also acts. This C _D Is the drag coefficient.
Considering the situation where a swirling flow around the indoor part occurs in the inflow chamber, lift force acts on the indoor part as described above. This lift acts outward from the center side in the swirling flow toward the side where the flow velocity of the swirling flow around the indoor portion is large.
[0008]
On the other hand, the indoor part can be swung in an inclined posture in the inflow chamber, so that it receives this lift and tilts, tilts toward the inflow chamber wall side, and moves in the resultant force direction of the lift and drag. This resultant force moves in the direction of moving the indoor portion along the flow direction of the swirl flow because the drag is along the flow direction of the swirl flow.
Therefore, when the force receiving portion receives the lift force, the force receiving portion is inclined toward the inflow chamber wall side and moves in the resultant force 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 is along the flow direction of the swirl flow.
When this happens, the situation of the difference in the flow velocity of the swirling flow around the indoor part also changes, and the indoor part moves in the direction of the swirling flow in an inclined posture by the lift and drag force under this new situation. For this reason, the rocking body swings and revolves in the inflow chamber. Hereinafter, this revolution is referred to as a swing revolution.
[0009]
The columnar rocking body has a tapered shielding portion provided on the columnar upper surface so as to face the water discharge port, and an indoor portion of the columnar side surface.
Accordingly, the spout is opened on the downstream side wall surface of the inflow chamber because the rocking body tilts and revolves around the indoor portion by the various forces described above. It changes while shielding a part of it sequentially.
Further, since the shielding portion is tapered, the gap between the water outlet and the shielding portion is maximized on the opposite side where the oscillator is inclined, and is minimized on the inclined side. Moreover, since the shielding part 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 with the discharged water flow rate changed on the side shielded by the shielding portion and the other side.
Further, since the shielding part changes the shielding position of a part of the water discharge port with the revolution of the rocking body, the washing water discharged from the water discharge port also changes in accordance with the position change of the shielding part. The water discharge amount is periodically changed.
[0010]
Moreover, 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 oscillating body, the shielding portion can reliably shield the water outlet in the inclination direction of the oscillating body.
It is also possible to use the apex of the taper shape as the apex of revolution, and the axis passing through this apex can be used as the center of rotation of the rocking body, eliminating the swing of the rotating shaft when the rocking body rotates, and performing stable revolutions. I can do it. Thereby, the position change of the shielding part of the water discharge port, that is, the position change of the water discharge amount change state is also ensured.
[0011]
Further, as described above, when the indoor part is lifted and inclined toward the inflow indoor wall, the indoor part is directly pushed by the swirling flow of the inflow chamber. Therefore, the indoor part receives kinetic energy directly from the swirling flow and moves in the swirling flow direction while maintaining the inclined posture, and the swinging revolution of the oscillator 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 ^Three / Sec], and V represents the speed of the swirling flow.
Centrifugal force is defined by the following equation.
F = MV ² / R [N]
Here, M represents the mass of the oscillator, V represents the revolution speed, and R represents the revolution radius.
This centrifugal force is a force generated when the indoor part revolves due to the rotation or turning of water, and is a force that the rocking body tends to incline in the rotational radius direction of the revolving or turning. The moving body is further inclined, and the shielding portion can reliably shield the water outlet.
[0012]
In addition, in the case where the water turbine is rotated by hitting the water flow and generating drag, as in the conventional case, the water turbine is rotated by the shielding plate provided on the water turbine and the water discharge holes are sequentially changed. Only the kinetic kinetic energy of the water flow was used as a means of rotating the.
Therefore, in order to rotate the water wheel, it is necessary to increase kinetic energy, and a large flow rate and pressure are required. Further, since the shielding plate is rotated against the device wall surface while being pressed against the device wall surface by water pressure, a large frictional force is generated, and in order to overcome this frictional force and rotate the shielding plate, Larger flow rates and pressures were required.
[0013]
However, according to the water discharging device of the present invention, the shielding of the water outlet is performed by the revolution of the oscillator described above. In addition, as described above, the revolution of the oscillator uses the lift, drag, and centrifugal force generated by the water flow, so that a greater force can be obtained than when the turbine is rotated using only the drag. In addition, by this force, the swinging body can be revolved and the water outlet can be shielded sequentially and reliably.
[0014]
Further, since the swinging body uses a revolving motion in which the swinging body rotates in a conical shape when shielding the water outlet, the contact portion between the swinging body and the inflow chamber has a shielding part in the direction in which the swinging body is inclined, Only a slight contact portion on the wall of the inflow chamber is sufficient. For this reason, the frictional force at the contact portion between the rocking body and the inflow chamber is small, and the spout can be easily shielded together with the large force obtained from the flow described above.
[0015]
In addition, with respect to shielding the 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. In addition, the opening gap gradually changes between the minimum and maximum opening gaps.
Therefore, it is possible to greatly change the opening of the water discharge port even though the contact between the shielding portion and the inflow chamber wall surface is very slight.
[0016]
Moreover, in order to discharge water with such a periodic change in the amount of discharged water, it is sufficient to cause a swirling flow by injecting the washing water into the inflow chamber, and the swirling flow causes the swinging body to swing and revolve in the inflow chamber. . Therefore, since the above-described swinging body is incorporated into the inflow chamber and the swirl flow is generated by introducing the washing water into the inflow chamber, the configuration can be simplified and the cost can be reduced. Note that the apparatus can be made compact through simplification of the configuration.
[0017]
In addition, the state of occurrence of the flow velocity difference around the indoor part can be adjusted by the state of introduction of washing water into the inflow chamber, the shape of the inflow chamber, and the like. Therefore, the swinging and revolving state of the swinging body can be adjusted, and thereby the water discharge mode can be diversified. For example, by increasing the lift, drag, and centrifugal force as described above, the swinging body can swing and revolve at high speed to periodically change the water discharge amount, and the swinging and revolving state of the swinging body can be stabilized to stabilize this swinging The trajectory of swinging and revolving can be easily stabilized, and the change in water discharge amount can be performed stably.
[0018]
In addition, when using this periodic water discharge change and applying water discharge to the human body for massage, the water intake amount at the water landing part on the human body changes as the water discharge changes. Compared with the case of receiving continuous water discharge, the blood vessels are expanded and contracted, and as a result, blood circulation is promoted.
[0019]
In addition, as described above, if the periodic water discharge rate change is performed at high speed, the human body cannot recognize the high-speed water discharge transition even if the water landing transition occurs at the water landing point. Therefore, it is not necessary to continuously discharge water so that the washing water reaches the entire landing area at the same time. Therefore, water can be saved accordingly.
In addition, when the average water discharge amount is the same, the water discharge flow rate is partially changed by periodically changing the position and discharging water while maintaining the change in the water discharge amount as compared with the case of simultaneously discharging water from the water discharge hole. The position of the increased state can be changed.
Therefore, it is possible to exhibit a high cleaning power.
[0020]
In order to achieve the above object, claim 2 is characterized in that the water supply mechanism has a nozzle conduit that is eccentrically communicated with the inflow chamber on a peripheral wall of the inflow chamber.
In this way, when the washing water flows into the inflow chamber, the washing water that has just flowed into the inflow chamber is swirled around the indoor portion along the inflow chamber wall. Make sure the flow has a difference in flow velocity. Thereby, the swinging revolution of the rocking body and the stabilization of the periodic water discharge change can be brought about.
[0021]
Moreover, in order to solve the said subject, Claim 3 is characterized by the said water discharge port being comprised by several holes.
If it carries out like this, it will become possible to arrange | position a water discharge port discretely and it will become possible to change the water discharge hole which discharges water discretely. Therefore, the change in the water discharge amount is not a continuous change but discrete, and the stimulation change of the water discharge based on the change is also discrete, which can increase the massage feeling and increase the water saving effect.
In addition, it is possible to arrange the water discharge port over a wide range without changing the total area of the water discharge port, and water discharge over a wider range is also possible.
In addition, it becomes possible to combine water outlets of various sizes and shapes, and variations in water discharge are also possible.
[0022]
In order to solve the above-mentioned problem, a fourth aspect of the present invention is characterized in that the water discharge port constituted by the plurality of holes is arranged in a circumferential shape 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 water discharge port can be arranged on the revolving track, that is, on the track where the shielding portion sequentially contacts the downstream side wall surface. This makes it possible to reliably shield the water outlet. Accordingly, it is possible to stably change the amount of water discharged from the water outlet.
[0023]
In order to solve the above-mentioned problem, claim 5 is characterized in that the water outlet has an elongated hole shape in the radial direction of the inflow chamber.
This has the following advantages.
The rocking body is inclined and inscribed 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 with a linear portion in an inclined direction.
Therefore, if the opening shape of the water discharge port is a long hole shape that is long in the radial direction of the inflow chamber, that is, the inclined direction, it is possible to effectively shield with the linear contact portion between the shielding portion and the downstream side wall surface.
Therefore, since the water outlet can be more reliably shielded by the shielding portion, the change in the water discharge flow rate becomes clearer in magnitude, and the above-described massage effect and water saving effect can be enhanced.
[0024]
In order to solve the above-mentioned problem, claim 6 is characterized in that it has a guide portion for regulating the inclination angle of the rocking body.
Therefore, the inclination angle of the rocking body can be reliably regulated by the guide portion, and the water outlet can be reliably shielded by the inclination of the rocking body. Thereby, the amount of water discharge can be changed reliably.
[0025]
In order to solve the above-mentioned problem, according to a seventh aspect of the present invention, the rocking body of the nozzle is configured to incline the indoor portion with respect to the inflow chamber when the cleaning water does not flow into the inflow chamber. It is characterized by having.
For example, it is assumed that the water discharge direction of the nozzle is inclined or parallel to the horizontal plane, and this rocking body is inclined with respect to the inflow chamber at the time of non-water discharge by gravity acting on itself. it can. If it carries out like this, between the indoor site | part of an rocking | swiveling body and an inflow chamber wall can be narrowed before the inflow chamber inflow of washing water. Therefore, from the beginning of the inflow chamber into the wash water, the flow velocity during the passage of the wash water through the narrowing can be increased, and the difference in the flow velocity of the swirling flow can be surely caused.
For this reason, since the above-described lift can be reliably generated from the beginning of the washing water inflow, the swinging revolution of the swinging body and the stabilization of the periodic water discharge amount can be easily achieved.
[0026]
In this way, the tilting body can be tilted as follows. That is, an inclined guide portion is provided at the center of the bottom surface of the inflow chamber, and the inclined guide portion can incline the indoor portion of the oscillating body with respect to the inflow chamber when water is not discharged. Even if it does in this way, lift can be generated reliably from the beginning of the washing water inflow, and the swinging revolution of the rocking body and the periodic change in the water discharge amount can be easily caused. Such an inclined guide portion may be provided at the lower end of the indoor part of the rocking body.
[0027]
In order to solve the above problems, claim 8 is characterized in that at least a part of the oscillator is made of metal.
By configuring at least a part of the rocking body with a metal having a large specific gravity in this way, when the rocking body revolves, it becomes possible to increase the centrifugal force as shown in the above-described formula. Thus, the rocking body can be reliably tilted and the water outlet can be shielded.
Therefore, it becomes possible to cause a water discharge amount change reliably, and massage and water saving as described above can be performed.
In addition, by using at least a part of the rocking body as a metal and increasing the mass, it is possible to increase the inertial force of the rocking body itself. The number of rotations can be reduced.
In this case, the sense of stimulation of water discharge can be increased by reducing the position change cycle of the water discharge amount change.
[0028]
Further, in order to solve the above-mentioned problem, claim 9 is characterized in that the swinging body causes rotation while the swinging body itself rotates about the axis of the indoor portion while causing the revolution.
In this way, the rocking body is affected by the flow in the inflow chamber and the frictional force generated by the rocking body itself or the shielding portion contacting the inner wall of the inflow chamber when revolving in the inflow chamber, It is possible to rotate freely.
Therefore, the rocking body can revolve more easily by rotating without countering the flow or the frictional force.
In addition, since it does not oppose the frictional force, it is possible not only to further reduce the amount of water and pressure required to revolve the rocking body, but also to prevent wear, so that even when used for a long time, water discharge will not occur. Stabilize.
[0029]
Moreover, in order to solve the said subject, Claim 10 has provided the projection part in the said water outlet vicinity.
Therefore, for example, by configuring the protrusion with a brush, it is possible to use both a massage effect due to a periodic change in the amount of discharged water and a massage with a brush.
In this case, since the massage with the brush is performed by a 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 rocking body is about several tens of Hz. Hundreds of Hz.
In addition, the stimulation by the brush is a strong mechanical partial stimulation, and the stimulation by the water discharge is softer and the overall stimulation.
Accordingly, it is possible to simultaneously apply stimuli having different frequencies and feelings of stimulation in this way, and it is possible to enhance the feeling of massage and the cleaning power.
Further, the brush itself can be vibrated at hundreds of Hz by the above-described change in water discharge of hundreds of Hz, so that a high cleaning power can be exhibited even by this high-speed vibration.
Such a water discharge device is effective when used for washing teeth, washing human bodies, washing dishes, washing bathtubs, and the like.
[0030]
Further, in order to solve the above-mentioned problem, claim 11 is a human body local cleaning device that discharges the supplied wash water toward the human body local part, the human body local cleaning apparatus including the water discharging apparatus, and from the nozzle toward the human body local part. It is characterized by discharging the washing water.
In this case, since the high water-saving and the massage effect which this water discharging apparatus brings can be exhibited, it is less likely that the hot water in the tank is lost during use. In addition, even when boiling water using an instantaneous heat exchanger, the amount of water used can be reduced, so the power consumption of the heater can be reduced, and low-temperature washing water can be brought to the required temperature. It is possible to raise the temperature. In addition, since a large-scale device is not required, it is possible to reduce the size and noise of the human body local cleaning device itself.
In addition, when changing the position of water discharge, a particularly large flow rate or water pressure is not required.
Furthermore, effects such as stimulating blood vessels around the anus by massage effect to improve blood circulation and promoting constipation can be expected.
[0031]
In order to solve the above-mentioned problem, claim 12 is a shower device that discharges the supplied cleaning water toward the human body, and has the water discharging device, and discharges the cleaning water from the nozzle toward the human body. It is characterized by being a shower device.
Also in this case, since the high water saving and the massage effect which this water discharging apparatus brings can be exhibited, water saving and a massage can be achieved as a shower apparatus.
Further, as described above, since no special device or power source is required, it is also suitable as an environment where there is a lot of moisture and rust or leakage is likely to occur, for example, a shower device in a bathroom.
[0032]
Moreover, in order to solve the said subject, Claim 13 is a massage bathtub apparatus which discharges the supplied wash water in the bathtub, and discharges it toward the human body in bathing, Comprising: The said water discharge apparatus, It is a massage bathtub measure that discharges washing water from the nozzle toward the human body.
In this case, the high massage effect which this water discharging apparatus brings can be exhibited.
Also, even when water is discharged into the water in this way, no special equipment or power supply is required, so there is no risk of rust or leakage, which is preferable.
[0033]
In order to solve the above-mentioned problem, claim 14 is a cleaning device that discharges the supplied cleaning water toward the object to be cleaned, which has the water discharging device and is directed from the nozzle toward the object to be cleaned. It is a cleaning device that discharges water.
In this case, the high cleaning effect which this water discharging apparatus brings 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, compared to the case of simultaneously discharging water from the water discharge holes.
Therefore, since a high detergency can be exhibited, it is effective when used for a dishwasher or a bathtub washer.
[0034]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a top view of the water discharge device of the present invention.
FIG. 2 is a longitudinal sectional view of the water discharging device of the present invention.
FIG. 3 is a cross-sectional view of the water discharge device of the present invention taken along the line AA of FIG.
FIG. 4 is a detailed view of an oscillating body used in the water discharging device of the present invention.
[0035]
As shown in FIG. 2, the nozzle 1 includes a swirl chamber 15 formed in a cylindrical shape as an inflow chamber into which the wash water flows, and the swirl chamber 15 passes through the water passage 12 and the swirl chamber inflow passage 11 into the wash water. It is configured to supply water.
The swirl chamber inflow passage 11 is a nozzle pipe, has a smaller water passage cross-sectional area than 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, 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 flow cross-sectional area of the swirl chamber inflow passage 11 is smaller than the water flow passage 12, the flow rate of the washing water flowing into the swirl chamber 15 can be increased.
[0036]
In addition, the nozzle 1 includes a swinging body 20 incorporated in the swirl chamber 15. As shown in FIG. 4, the oscillating body 20 has a cylindrical shape as a whole, and has a tapered shielding portion 25 on the upper surface and a hemispherical fulcrum portion 26 on the apex of the tapered shape.
Further, the rocking body includes 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 later from the swirl flow, and is involved in the swing revolving drive described later of the oscillator 20.
Further, a downstream side wall surface 17 is provided on the downstream side of the swirl chamber 15 and is provided in a taper shape having an angle larger than the taper angle of the rocking body 20. A support portion 16 is provided.
Further, the downstream side wall surface 17 is provided with a plurality of water outlets 5 opened.
[0037]
In addition, the rocking body 20 is configured such that the force receiving portion 21 is disposed in the swirl chamber 15, and the fulcrum portion 26 and the support portion 16, the shielding portion 25 and the downstream side wall surface 17 face each other. 1 is provided.
Further, the rocking body 20 can be freely revolved so as to rotate in a conical shape with the support portion 16 as a vertex while the support portion 16 supports the fulcrum portion 26.
Further, since the support body 16 and the fulcrum part 26 are not fixed to the rocking body 20, the rocking body 20 itself can freely rotate and rotate about the central axis.
These revolutions and rotations are caused by the force receiving portion 21 and the swirling flow, and details thereof will be described later.
[0038]
A guide portion 14 having a smaller diameter than that of the swirl chamber 15 is provided on the swirl chamber 15. The guide portion 14 regulates the maximum inclination angle of the force receiving portion 21 and thus the rocking body 20.
[0039]
Here, the state of the washing water discharge in the nozzle 1 of the said structure and its behavior are demonstrated.
FIG. 5 is an explanatory diagram for explaining the behavior of the force receiving portion 21 after the washing water flows 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 cleaning water is caused to flow from the swirl chamber inflow passage 11 into the swirl chamber 15 (time t0). In this case, the washing water flows from the water passage 12 having a large passage cross-sectional area through the swirl chamber inflow passage 11 having a small water cross-sectional area, and therefore flows into the swirl chamber 15 at a large flow velocity.
Therefore, the kinetic energy that can be provided by the washing water causing a collision increases.
[0040]
When the cleaning water flows into the swirl chamber 15 in this way, the cleaning water causes a swirling flow swirling around the force receiving portion 21 along the inner wall of the swirl chamber 15. The flow velocity in this swirl flow is the highest at the communication portion of the swirl chamber inflow passage 11.
There is a difference between the flow velocity Ua and the flow velocity Ub at the place where the inflow cleaning water first starts swirling, that is, the peripheral wall portion 15a on the extension line of the opening of the swirl chamber inflow passage 11 and the peripheral wall portion 15b facing the portion. The relationship between the two is Ua> Ub. That is, while the cleaning water spreads (turns) from the peripheral wall portion 15a to the peripheral wall portion 15b, the influence of flow dispersion in the swirl chamber 15, contact with the wash water with the inner wall surface of the swirl chamber 15, wash water viscosity, surface friction, and the like. The wash water decelerates.
[0041]
Therefore, a flow rate difference of the washing water occurs around the force receiving portion 21. In this case, although the moving object is a fluid (washing water), the relative relationship between the washing water and the force receiving portion 21 is not different from the situation in which an object moves in the fluid.
Therefore, when an object moves in the fluid, a situation in which lift acts on the object based on the speed difference of the fluid sandwiching the object occurs between the cleaning water and the force receiving portion 21 in the swirl chamber 15. A force of the same quality as the lift acts on the force receiving portion 21. For convenience, this force is referred to as lift, as described above. However, if exemplified by other phenomena, the occurrence of lift due to the difference in fluid velocity in this way is caused by This is similar to generating lift by a speed difference, that is, a pressure difference.
[0042]
As shown in FIG. 3, the force receiving portion 21 enters the swirl chamber 15, and at time t0 in FIG. Since a swirl flow around the force receiving portion 21 stopped at this time t0 occurs, the lift force F _L Is affected by the flow velocity Ua [m / sec] of the swirling flow in the peripheral wall portion 15a. And this lift F _L Is the maximum projected area of the force receiving portion 21 that receives the lift force S [m ² ], The density of the washing water is ρ [kg / m ^Three ] Is represented by the following formula. C in the formula _L Is the lift coefficient.
F _L = (Ρ · V ² ・ C _L ・ S) / 2 [N]
Thus lift F _L Acts on the force receiving portion 21, and as a result, the force receiving portion 21 has a drag F _D (= (Ρ · V ² ・ C _D S) / 2 [N]) also acts. This C _D Is the drag coefficient.
Since the maximum projected area S in the above formula depends on the length L [m] of the force receiving portion 21, if the length L of the force receiving portion 21 is increased, the lift force / drag can be increased.
[0043]
As shown at time t <b> 0 in FIG. 5, when a swirl flow around the force receiving portion 21 occurs in the swirl chamber 15, lift is applied to the force receiving portion 21 as described above. This lift acts outward from the center side in the swirling flow toward the peripheral wall portion 15a where the flow velocity of the swirling flow around the force receiving portion 21 is large. On the other hand, since the force receiving portion 21 can swing in an inclined posture in the swirl chamber 15, this lift force F _L In response to the arrow F in the figure _L Inclined in the direction indicated by. Thus, when the force receiving portion 21 is tilted toward the inner wall side of the swirl chamber 15, the lift force F at time t1. _L And drag F _D Act together and move in the direction of the resultant force. 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 is along the flow direction of the swirl flow.
[0044]
In this case, the swirl flow passage interval becomes narrower on the side where the force receiving portion 21 is inclined, and the swirl flow velocity increases with this narrowness. Since this situation occurs so that the narrow interval portion moves around the force receiving portion 21, the portion having the highest flow velocity of the swirling flow also moves along the inner peripheral wall of the swirling chamber 15. Therefore, with the movement of the place with the highest flow velocity, lift F _L Direction and drag F _D Since the direction of is also changed, the force receiving portion 21 moves in the direction of the swirling flow while keeping the inclined posture as time t2, t3, and t4 progress. When the oscillating body starts to revolve under the influence of lift and drag in this way, centrifugal force acts on the oscillating body in the swirling chamber radial direction, and the swinging revolution of the oscillating body 20 is further promoted.
[0045]
Therefore, the oscillating body 20 revolves (swings and revolves) in the swirl chamber 15 by swinging around the fulcrum portion 16 in the state where the fulcrum portion 16 is inscribed in the support portion 26.
Then, the rocking body 20 revolves while the inclination angle is restricted by the guide portion 14 in a state where the tapered shielding portion 25 is inscribed in the downstream side wall surface 17.
Further, as shown in FIG. 1, the downstream side wall surface 17 is provided with a plurality of open spouts 5 radially about the support portion 16. However, on the side where the rocking body 20 is inclined, a part of the water discharge port 5 provided in the downstream side wall surface 17 is shielded.
[0046]
In this case, the shielding state is the side where the rocking body 20 is inclined, and the gap area between the water outlet 5 and the shielding part 25 is the minimum value, and the gap area is the maximum value on the opposite side. Further, the gap area gradually changes between the minimum value and the maximum value.
Therefore, when the rocking body 20 is inclined, the gap area between the plurality of water discharge ports 5 and the shielding portion 25 provided in the radial direction can be changed from the minimum value to the maximum value to the minimum value in the circumferential direction. .
The state of change of 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 discharge port 5.
Further, the cleaning water supplied from the swirl chamber 15 to the water outlet 5 and discharged is supplied through the gap between the water outlet 5 and the shielding portion 25 described above, so that water is discharged from the water outlet 5. The amount of washing water is determined by this gap area.
[0047]
Further, the oscillating body 20 revolves with the fulcrum portion 26, the shielding portion 25, and a small portion of the force receiving portion 21 in contact with the nozzle 1.
Further, since the oscillating body 20 is provided so as to be capable of rotating around the central axis of the oscillating body 20 itself, the oscillating body 20 rolls in response to the frictional force generated at the contact portion with the nozzle 1 described above. Revolve while rotating in the same way.
[0048]
Here, the state of water discharge when such a water discharge device is used will be described with reference to the drawings.
FIG. 6 is a view for explaining the state of water discharge using the nozzle 1.
As shown in FIG. 6, when the swinging body 20 swings and revolves as described above, the gap area between the plurality of radially provided water discharge ports 5 and the shielding portion 25 is minimum to maximum to minimum in the circumferential direction. Change.
Thereby, the flow volume 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 in the figure, the water discharge flow rate is minimized on the side where the rocking body 20 is inclined, and the water discharge flow rate is maximized on the opposite side.
Further, since the rocking body 20 undergoes the revolution in response to the flow described above, the magnitude of the water discharge amount sequentially changes in accordance with the revolution of the rocking body 20.
Therefore, the wash water discharged from the nozzle 1 has a flow rate change in the circumferential direction in accordance with the inclination of the rocking body 20, and further, the position of the flow rate is adjusted in accordance with the revolution of the rocking body 20. Water is discharged while changing periodically.
[0049]
Such a nozzle 1 has the following advantages.
If the water discharge that causes the change in the water discharge amount as described above is applied to the human body, there are the following advantages.
Since the flow rate periodically changes at the landing point of the discharged wash water, the blood vessel repeatedly contracts and expands along with the flow rate change at the landing point. Therefore, blood circulation is promoted by such a blood vessel contraction and expansion action, and a suitable massage effect can be obtained.
[0050]
Further, the water discharge device of the present invention changes the water discharge flow rate as described above and changes the position of the flow rate change, and uses the above-described revolution of the rocking body 20 to perform such water discharge.
Moreover, since the revolution of the rocking body 20 uses lift force, drag force, and centrifugal force generated by the water flow, a larger force can be obtained as compared with the case where the turbine is rotated using only the drag force. In addition, this force causes the rocking body 20 to revolve and the water outlet is sequentially shielded reliably, so that the above change can be reliably made to the water discharge with a small flow rate and pressure.
[0051]
Further, since the swinging body 20 utilizes a revolving motion in which the swinging body 20 rotates in a conical shape when the spout 5 is shielded, the contact portion between the swinging body 20 and the inflow chamber 15 is in a direction in which the swinging body is inclined. Since the shielding portion and the contact portion of the inflow chamber wall only need to be very small, the oscillating body 20 itself rotates due to the frictional force at the contact portion between the oscillating body 20 and the inflow chamber 15. No wear occurs. Furthermore, there is little sliding resistance, and the spout 5 can be easily shielded together with the large force obtained from the flow described above.
[0052]
Further, regarding such shielding of the water outlet 5, the opening gap between the water outlet 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. In addition, the opening gap gradually changes between the minimum and maximum opening gaps.
Therefore, although the contact between the shielding portion and the wall surface of the inflow chamber is very slight contact, it is possible to greatly change the water discharge amount by greatly changing the opening of the water discharge port 5.
Further, by causing such a change in water discharge, it is possible to save water compared to the case where water is discharged simultaneously from the entire water discharge port.
In this case, if the average water discharge is made the same, the instantaneous flow rate at the maximum opening can be increased, and the cleaning power and massage feeling can be greatly improved.
Further, when the water discharge flow rate at the maximum opening is made the same, 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, water can be saved significantly without reducing the cleaning power.
[0053]
In addition, in changing the amount of discharged water and the position of the changed amount of discharged water, a swirling flow is generated by injecting washing water into the inflow chamber, and the swirling flow causes the swinging body to swing and revolve in the inflow chamber. Waking up is enough.
Therefore, since the above-described oscillator is incorporated into the inflow chamber and the swirl flow is generated by introducing the washing water into the inflow chamber, the configuration can be simplified and the cost can be reduced. Note that the apparatus can be made compact through simplification of the configuration.
In addition, since there is no electrical drive unit such as an actuator, the durability of the electrical drive unit does not become a problem, and electrical wiring to the nozzle tip is not required. Therefore, it is possible to simplify the assembling work and the maintenance work and the structure without considering the leakage current.
[0054]
In this embodiment, the flow rate of the washing water flowing into the swirl chamber 15 is increased by assuming that the cross-sectional area of the swirl chamber inflow passage 11 that allows the washing water to flow into the swirl chamber 15 is small. The flow rate of the washing water flowing into the swirl chamber 15 is the lift F as described above. _L Is specified. Therefore, if the swirl chamber inflow passage 11 having various water cross-sectional areas is prepared and selectively used, the lift F acting on the force receiving portion 21 is obtained. _L In addition, drag and centrifugal force can be adjusted. These forces also determine the frequency of the swinging revolution of the rocking body 20. Therefore, the frequency of the swing revolution of the oscillating body 20 can also be adjusted by adjusting the water flow cross-sectional area of the swirl chamber inflow passage 11 or selecting the swirl chamber inflow passage 11.
[0055]
In the oscillating body 20 of the present embodiment, the portion that directly receives the kinetic energy of the swirl flow is a cylindrical shape, but the shape is not limited to the cylindrical shape, and is a polygonal column such as a triangular column, a quadrangular column, or a hexagonal column. You can also.
On the other hand, as the material of the oscillating body 20, a synthetic resin such as PP, POM, and ABS can be adopted, or a metal such as stainless steel can be used, or only the force receiving portion 21 can be made of metal. In this case, it is possible to increase the centrifugal force generated by the revolving motion by increasing the force receiving portion 21 that performs the revolution, and to increase the inclination of the oscillating body 20 or to increase the inertia of the oscillating body 20 itself. By increasing, the revolution frequency can be reduced.
[0056]
Next, a modified example will be described.
This modification is characterized in that the rocking body 20 is forcibly inclined when water is not discharged.
FIG. 7 is a view for explaining a modified nozzle 31.
Hereinafter, a description will be given with reference to FIG. The nozzle 31 includes a swirl chamber 15 formed in a cylindrical shape into which the wash water flows, like the nozzle 1 in FIG. 2, and supplies the wash water to the swirl chamber 15 through the water passage 12 and the swirl chamber inflow passage 11. It is configured to do.
The swirl chamber inflow passage 11 is configured to have a smaller water flow cross-sectional area than the water flow passage 12, and is eccentric to the center of the swirl chamber 15 and connected to the swirl chamber 15.
[0057]
In addition, the nozzle 31 is provided with the swing body 20 incorporated in the swirl chamber 15. Here, the oscillating body 20 is the same as that shown in FIGS.
Further, a downstream side wall surface 17 is provided on the downstream side of the swirl chamber 15 and is provided in a taper shape having an angle larger than the taper angle of the rocking body 20. A support portion 16 is provided.
Further, the downstream side wall surface 17 is provided with a plurality of water outlets 5 opened.
[0058]
In addition, the rocking body 20 is configured such that the force receiving portion 21 is disposed in the swirl chamber 15, and the fulcrum portion 26 and the support portion 16, the shielding portion 25 and the downstream side wall surface 17 face each other. 31 is provided.
Further, the rocking body 20 can be freely revolved so as to rotate in a conical shape with the support portion 16 as a vertex while the support portion 16 supports the fulcrum portion 26.
Further, since the support body 16 and the fulcrum part 26 are not fixed to the rocking body 20, the rocking body 20 itself can freely rotate and rotate about the central axis.
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 of the above-described embodiment.
[0059]
Further, a raised inclined guide portion 32 is provided at the center of the bottom surface of the swirl chamber 15 so that the swinging body 20 is forced to maintain an inclined posture.
A guide portion 14 having a smaller diameter than that of the swirl chamber 15 is provided on the swirl chamber 15. The guide portion 14 regulates the maximum inclination angle of the rocking body 20.
[0060]
The case where cleaning water is discharged from the nozzle 31 shown in the above configuration will be described.
The washing water is introduced into the swirl chamber 15 through the water passage 12 and the swirl chamber inflow passage 11 and the swirl flow along the wall surface of the swirl chamber 15 is generated as in the above-described embodiment.
Further, in the present embodiment, the rocking body 20 is inclined in advance by the inclined guide portion 32 when the cleaning water is not discharged.
Therefore, a narrow portion is formed in advance between the force receiving portion 21 and the inner wall of the swirl chamber 15. Therefore, from the beginning of the inflow of the wash water into the swirl chamber 15, the flow velocity during the wash water passing through the narrowed portion can be increased, and the difference in the flow velocity of the swirl flow can be surely caused.
For this reason, when the flow rate or pressure is lower or when the washing water flows in, the above-described lift force can be reliably generated, and the swinging revolution of the oscillator 20 and the periodic change of the discharged water flow rate can be stabilized. It can be easily achieved.
[0061]
Next, application examples of the present invention will be described.
This application example is characterized in that a water discharge port is provided at the tip of a brush-like protrusion, and water is discharged by contacting with a human body or an object to be cleaned.
FIG. 8 is a diagram for explaining the nozzle 41 of the application example.
The nozzle 41 includes the oscillating body 20 in the swirl chamber 15 as in the above-described embodiment, and the configuration up to the water outlet is the same as the nozzle 1 shown in FIG.
The nozzle 41 has a brush-like protrusion 42, and has a water discharge port 45 that opens at the tip of the protrusion 42 and communicates with the downstream side wall surface 17. Therefore, similarly to the nozzle 1, when cleaning water is supplied to the nozzle 41, a swirl flow along the inner wall of the swirl chamber 15 is generated. Further, the swinging body 20 is revolved by the swirl flow, and a part of the water discharge port 45 is sequentially shielded by the shielding portion 25 provided on the rocking body 20. In addition, the shielding causes a circumferential change in the amount of cleaning water discharged from the plurality of water discharge ports 45 arranged radially. Furthermore, since the nozzle 41 has the protrusion 42, it can be washed and massaged in contact with the human body and the object to be cleaned together with the water discharge described above.
[0062]
By carrying out like this, washing | cleaning and a massage can be performed, exhibiting the water saving effect as mentioned above. In this case, since the massage with the brush is performed by a 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 rocking body is about several tens of Hz. Hundreds of Hz.
In addition, the stimulation by the brush is a strong mechanical partial stimulation, and the stimulation by the water discharge is softer and the overall stimulation.
Accordingly, it is possible to simultaneously apply stimuli having different frequencies and feelings of stimulation in this way, and it is possible to enhance the feeling of massage and the cleaning power.
Further, the brush itself can be vibrated at hundreds of Hz by the above-described change in water discharge of hundreds of Hz, so that a high cleaning power can be exhibited even by this high-speed vibration.
Such a water discharge device is effective when used for washing teeth, washing human bodies, washing dishes, washing bathtubs, and the like.
[0063]
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 as viewed in a vertical cross section.
As shown in FIGS. 9 and 10, the nozzle 51 has the same configuration up to the water discharge port 5 as the nozzle 1 shown in FIGS. 1 and 2.
Further, the nozzle 51 has an elongated slit at the upstream side of the water discharge port 5, that is, the opening on the swirl chamber 15 side.
In addition, the slit 6 communicates the water outlets of the same radial direction among the water outlets 5 that are provided in a circumferential shape and a radial shape coaxial with the central axis of the swirl chamber 15.
Furthermore, this slit 6 is characterized by having a width smaller than the diameter of the water outlet.
[0064]
When washing water is discharged from the nozzle 51 characterized as described above, there are the following advantages.
Similarly to the nozzle 1 described above, when the cleaning water is supplied to the nozzle 51, the rocking body 20 is inclined, inscribed in the downstream side wall surface 17 of the swirl chamber 15, and revolves.
Further, the contact between the tapered shielding portion 25 and the downstream side wall surface 17 is performed with a linear portion in an inclined direction.
Further, the opening area of the shielding portion 25 and the downstream side wall surface, that is, the outlet 5 is gradually increased with the linear portion in the inclined direction being minimized or zero and the opposite side of the inclination being maximized. .
Accordingly, the opening shape of the water discharge port 5 is long in the radial direction of the swirl chamber 15, that is, in the inclined direction, and is a slit having a width narrower than the diameter of the water discharge port. The slit can be reliably shielded by the contact portion.
Therefore, since the water outlet can be more reliably shielded by the shielding portion, the change in the water discharge flow rate becomes clearer in magnitude, and the above-described massage effect and water saving effect can be enhanced.
[0065]
Here, in the above embodiment, the oscillating body 20 and the nozzle are provided by bringing the fulcrum portion 26 and the support portion 16 into contact with each other, but may be provided via a flexible member, for example. In this case, the movement of the oscillating body 20 rotating around the center axis of the oscillating body 20 is restricted, but the movement of the oscillating body 20 is restricted by the flexible member. 20 can be easily inclined. Therefore, the effect of causing the water flow change due to the tilting of the rocking body 20 and the effect of reducing the frictional force at the contact portion due to the contact with only a part of the tilting is expected in the same manner as in the above-described embodiment. I can do it. As for the rotation of the oscillating body 20 being restricted, the oscillating body 20 can no longer roll due to the frictional force at the contact portion, so that the resistance increases, but sufficient water pressure and flow rate can be secured. Can be used sufficiently.
[0066]
Here, an application example of the nozzle described above will be described.
FIG. 11 is a diagram illustrating a state in which the nozzle 1 of the present invention is used for a hand shower.
As shown in FIG. 11, the hand shower 71 includes the nozzle 1 as described above, and includes a plurality of water discharge ports 5 that are opened. If such a hand shower 71 is used, the high water-saving effect, the massage effect, and high reliability as mentioned above can be acquired.
[0067]
FIG. 12 is a diagram illustrating a state where the nozzle 1 of the present invention is used for the massage bathtub 73. As shown in FIG. 12, the massage bathtub 73 includes the nozzle 1 as described above in the bathtub 72 that stores the bathtub water, and is fixed in a state where the water discharge port 5 is directed into the bathtub.
Further, the nozzle 1 is provided with a circulation pump that sucks the bathtub water in the bathtub 72 from the water supply port and circulates it to the nozzle 1.
The circulating pump is operated by a control device receiving a signal from the operation unit.
If the massage bathtub 73 having such a configuration is used, it is obvious that the high massage effect and high reliability as described above can be obtained even when the water is discharged into the water.
[0068]
FIG. 13 is a diagram 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 includes a storage basket 78 for storing tableware and a storage portion 77 for storing the storage basket 78. Moreover, the nozzle 1 is provided in the state which opened the spout 5 which discharges wash water toward this stored tableware in the said accommodating part inside.
This is preferable because high water saving and detergency as described above can be obtained.
[0069]
Further, the nozzle 1 of the present invention is housed in an elongated cylindrical nozzle as shown in FIGS. 1 and 2, so that the nozzle is provided at the rear of the toilet and is advanced toward the local body part. The cleaning water can be discharged toward the local area to perform local cleaning, and can be used as a human body local cleaning apparatus.
In this case, as described above, high effects such as a high water-saving effect, tank miniaturization by water-saving, and promotion of convenience by massage effect can be exhibited.
[Brief description of the drawings]
FIG. 1 is a top view of a nozzle 1;
FIG. 2 is a diagram illustrating a nozzle 1 as viewed in a longitudinal section.
FIG. 3 is a diagram illustrating the AA cross section in FIG.
FIG. 4 is a diagram illustrating details of a rocking body 20;
FIG. 5 is an explanatory diagram for explaining the behavior of the force receiving portion 21 after washing water flows 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 for explaining the state of washing water spouting obtained by the force receiving portion 21 taking 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 as viewed in a vertical cross section.
FIG. 9 is a diagram illustrating the nozzle 51 provided with an elongated slit upstream of the water discharge port as viewed from above.
FIG. 10 is a view illustrating the nozzle 51 provided with a long and narrow slit upstream of the water discharge port, as viewed in a longitudinal section.
FIG. 11 is an explanatory diagram when the nozzle 1 of the present invention is used for a hand shower.
FIG. 12 is an explanatory diagram when the nozzle 1 of the present invention is used in a massage bathtub.
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 ... Water outlet
6 ... Slit
11 ... Swirl chamber inlet
12 ... Waterway
14 ... Guide part
15 ... Swirl room
16 ... support part
17 ... Downstream side wall surface
20 ... Oscillator
21 ... Power receiving part
25 ... Shielding part
26 ... fulcrum
31 ... Nozzle
32 ... Inclined guide part
41 ... Nozzle
42. Projection
45 ... Water outlet
51 ... Nozzle
71 ... hand shower
72 ... Bathtub
73 ... Massage bathtub
76 ... Dishwasher
77 ... Storage section
78 ... Storage basket

Claims (14)

An apparatus comprising a nozzle for discharging supplied cleaning water from the nozzle, wherein the nozzle opens to an inflow chamber into which the cleaning water flows and a downstream side wall surface of the inflow chamber to discharge the cleaning water. A columnar oscillating body having a water port, a tapered shielding portion built in the inflow chamber and provided facing the water discharge port, and an indoor portion located in the inflow chamber continuous with the shielding portion; A water supply mechanism that guides the cleaning water to the inflow chamber along the inner wall of the inflow chamber so that the cleaning water flowing into the inflow chamber causes a swirl flow in the inflow chamber. In addition, a flow velocity difference is caused around the indoor portion, a force generated based on the flow velocity difference is applied to the indoor portion, and the swinging body swings and revolves with the indoor portion inclined in the inflow chamber. A water discharger characterized by the above. 2. The water discharge device according to claim 1, wherein the water supply mechanism includes a nozzle pipe line that is eccentrically connected to the inflow chamber on a peripheral wall of the inflow chamber. It is a water discharging apparatus of Claim 1, Comprising: The said water discharging opening is comprised by the some hole, The water discharging apparatus characterized by the above-mentioned. 4. The water discharge device according to claim 3, wherein the water discharge port configured by the plurality of holes is arranged in a circumferential shape with a central axis of the inflow chamber being coaxial. 5. The water discharge device according to claim 4, wherein the water discharge port has an opening shape on the inflow chamber side which is a long hole extending in a radial direction of the inflow chamber. It is a water discharging apparatus of Claim 1, Comprising: It has a guide part which regulates the inclination-angle of the said rocking | swiveling body, The water discharging apparatus characterized by the above-mentioned. 2. The water discharge device according to claim 1, wherein the oscillating body of the nozzle is configured to incline the indoor portion with respect to the inflow chamber when no washing water flows into the inflow chamber. A water discharge device characterized by the above. The water discharging apparatus according to claim 1, wherein at least a part of the oscillating body is made of metal. 2. The water discharge device according to claim 1, wherein the rocking body causes the rotation to rotate around the axis of the indoor portion while causing the revolution. 3. The water discharging device according to claim 1, wherein a protrusion is provided in the vicinity of the water discharging port. A human body local cleaning device for discharging the supplied cleaning water toward the human body local part,
A human body local cleaning device comprising the water discharging device according to claim 1, wherein the cleaning water is discharged from the nozzle toward the human body local portion. A shower device for discharging the supplied wash water toward the human body,
The shower apparatus which has the said water discharging apparatus in any one of Claim 1 thru | or 10, and discharges washing water toward the human body from the said nozzle. A massage bathtub device that discharges the supplied cleaning water into the bathtub and discharges it toward the human body during bathing,
A massage bathtub device that has the water discharging device according to any one of claims 1 to 9, and discharges cleaning water from the nozzle toward a human body. A cleaning device for discharging the supplied cleaning water toward an object to be cleaned,
A cleaning device comprising the water discharging device according to claim 1 and discharging water from the nozzle toward the object to be cleaned.

Images