JP2018167164A - Water discharge device - Google Patents

Abstract

To provide a water discharge device which has a simple structure to reduce the size, and can obtain water discharge excellent in use feeling.SOLUTION: A water discharge device (1) includes a water discharge device body (2) and a vibration generating element (4) discharging hot water while reciprocally vibrating the hot water, where the vibration generating element has a water supply passage (10a), a hot water collision part (14) which is arranged on the downstream side end of the water supply passage, and alternately generates a swirl on the downstream side in an opposite direction by collision of the hot water introduced by the water supply passage, a vortex row passage (10b) which guides the swirl formed by the hot water collision part while growing the swirl, a first rectification part (10c) which is a passage for preventing disturbance in a direction parallel to a vibration plane and disturbance in a direction perpendicular to the vibration plane of a flow of the hot water passing through the vortex row, and a second rectification part (10d) which is provided on the downstream side of the first rectification part, and prevents disturbance in a direction perpendicular to the vibration plane of a flow of the hot water passing through the first rectification part.SELECTED DRAWING: Figure 4A

Description

  The present invention relates to a water discharge device, and more particularly to a water discharge device that discharges hot water (hot water or water) from a water discharge port while reciprocally vibrating.

  There is known a shower head in which the direction of hot water discharged from a water discharge port changes in a vibrational manner. In a water discharge device such as this shower head, the nozzle is driven oscillating by the supply pressure of hot water supplied to change the direction of hot water discharged from the discharge port. In such a type of water discharge device, since hot water can be discharged from a single water discharge port to a wide range, it is expected that a water discharge device capable of discharging water over a wide range can be configured compactly.

  On the other hand, Japanese Patent Application Laid-Open No. 2000-120141 (Patent Document 1) describes a warm water cleaning toilet seat device. In this warm water cleaning toilet seat device, self-excited oscillation is induced by using a fluid element nozzle, and the ejection direction of the cleaning water is changed in an oscillating manner. Specifically, in this warm water washing toilet seat device, as shown in FIG. 23, feedback flow paths 104 are provided on both sides of the injection nozzle 102. Each feedback flow path 104 is a loop-shaped flow path communicating with the injection nozzle 102, and is configured such that a part of the cleaning water flowing through the injection nozzle 102 flows in and circulates. Moreover, the injection nozzle 102 is comprised in the shape which spreads in the taper shape toward the injection port 102a of an elliptical cross section.

  When the cleaning water is supplied, the cleaning water sprayed from the spray nozzle 102 is attracted to the wall surface on either side of the spray port 102a having an elliptical cross section by the Coanda effect, so as to follow this. (State a in FIG. 23). When the cleaning water is jetted along one wall surface, the cleaning water also flows into the feedback channel 104 on the side where the cleaning water is jetted, and the pressure in the feedback channel 104 increases. Due to this pressure increase, the sprayed cleaning water is pushed, and the cleaning water is attracted to the opposite wall surface and sprayed along the opposite wall surface (state a → b → c in FIG. 23). . Further, when the cleaning water is discharged along the opposite wall surface, the pressure in the feedback channel 104 on the opposite side increases and the jet cleaning water is pushed back (state c → b → a in FIG. 23). . By repeating this action, the direction of the jetted washing water changes oscillating between states a and c in FIG.

  Japanese Unexamined Patent Application Publication No. 2004-275985 (Patent Document 2) describes a pure fluid element. In this pure fluid element, a connecting duct is provided so as to cross the fluid ejection nozzle, and the pressure on the upper side or the lower side in the fluid ejection nozzle alternately rises due to the action of this coupling duct. The jet pushed by this pressure increase becomes a jet along the upper plate of the fluid jet nozzle or a jet along the lower plate due to the Coanda effect, and these states are repeated at a constant cycle, and the jet direction is oscillated. It becomes a changing flow.

  Further, Japanese Patent Publication No. 58-49300 (Patent Document 3) describes a vibration spray device. This vibration spray device has the configuration shown in FIG. 24 and uses the Karman vortex generated in the front chamber 110 to change the direction of the jet flow ejected from the outlet 112 in a vibrational manner. First, the fluid flowing into the front chamber 110 from the inlet hole 114 collides with an obstacle 116 having a triangular cross section provided in an island shape in the front chamber 110. When the fluid collides, Karman vortices are alternately generated on the upper and lower sides of the obstacle 116 on the downstream side of the obstacle 116 to form a vortex street.

  The Karman vortex street reaches the outlet 112 while growing. In the vicinity of the outlet 112, the flow velocity on the side where the vortex of the vortex row exists is fast, and the flow velocity on the opposite side is slow. In the example shown in FIG. 24, Karman vortices are alternately generated on the upper side and the lower side of the obstacle 116, and the vortex streets sequentially reach the outlet 112. The state where the lower flow velocity is fast appears alternately. In a state where the upper flow velocity is high, the fluid having a high flow velocity collides with the wall surface 110a on the upper side of the outlet 112 and changes its direction, and the fluid ejected from the outlet 112 becomes a jet flow directed obliquely downward as a whole. On the other hand, in a state where the lower flow velocity is high, the fluid having a high flow velocity collides with the wall surface 110b below the outlet 112, and a jet directed obliquely upward is ejected from the outlet 112. By repeating such a state alternately, the jet flow from the outlet 112 is jetted while reciprocating.

  As described above, it is conceivable that the fluid elements described in Patent Documents 1 to 3 are applied to a water discharge device such as a shower head to discharge hot water while reciprocally vibrating.

JP 2000-120141 A JP 2004-275985 A Japanese Patent Publication No.58-49300

  First, a water discharge device that changes the direction of hot water discharged by oscillating the water spray nozzle needs to drive the nozzle, so the structure around the nozzle becomes complicated, and a plurality of nozzles are compactly discharged. There is a problem that it is difficult to store. Further, in this type of water discharge device, since the nozzle physically moves, the movable part is likely to be worn, and in order to avoid wear, there is a problem that the selection of the material of the member constituting the movable part is restricted. There is. Furthermore, since it is necessary to form the movable part of a complicated structure with the material which is hard to wear, there exists a problem that cost becomes high.

On the other hand, the ejection devices of the types described in Patent Documents 1 to 3 utilize an oscillation phenomenon caused by a fluid element, and can change the fluid ejection direction without providing a movable member. Thus, there is an advantage that the nozzle portion can be configured in a compact manner.
However, when the fluid elements described in Patent Documents 1 and 2 are applied to a water discharge device such as a shower head, the present inventors have found a problem that the comfort of spraying hot water is not good. Here, the good bathing comfort targeted by the inventor means a state where large droplets of hot and cold water are uniformly discharged over a wide area. That is, when the droplets of hot water discharged from the shower head are excessively small, the hot water becomes mist-like, and even if the same amount of hot water is taken, it is impossible to obtain the feeling of taking a shower. Moreover, if the hot water discharged is uneven within the water discharge range, the user's intentional showering portion cannot be washed out uniformly, resulting in poor usability.

  Here, since the fluid element described in Patent Documents 1 and 2 uses a phenomenon in which the ejected fluid flows along the wall surface due to the Coanda effect, the fluid ejected into the discharge range is uneven. Can be done. That is, in the hot water toilet seat device shown in FIG. 23, the wash water to be jetted transitions between the states a, b, and c, but in reality, the state a and the state where the jet is attracted to the wall surface. The period of c is long, and the period between them (near state b) is negligible. For this reason, when the fluid element described in Patent Documents 1 and 2 is applied to a water discharge device such as a shower head, the water discharge amount in the peripheral portion of the water discharge range is large, and the water discharge amount in the vicinity of the center is small. It will be in a state and will become uncomfortable.

  On the other hand, since the fluid element described in Patent Document 3 applies Karman vortex, the phenomenon that the jet flows while being attracted to the wall surface hardly occurs. For this reason, a substantially uniform water discharge amount can be obtained within a water discharge range formed by vibrationally changing the water discharge direction. In addition, when the fluidic element shown in FIG. 24 is applied to a water discharge device such as a shower head, when the flow rate of the hot water sprayed from the outlet 112 is increased, the hot water collides with the wall surface 110a (or 110b) at a high speed to increase the direction of flow. Converted. For this reason, when the flow rate is large, the hot water sprayed from the outlet 112 spreads over a wide range and the water discharge range becomes wide. However, if the flow rate of hot water is extremely high, the injected hot water is decomposed into fine droplets, and water discharge spreads in a direction perpendicular to the vibration plane in which the hot water reciprocates. If the hot water is decomposed into fine droplets in this way, even if the flow rate is increased, the user who has bathed in the hot water cannot be given a pleasant irritation and the feeling of use will be poor.

  Accordingly, an object of the present invention is to provide a water discharger that can be configured compactly with a simple structure and that can obtain water discharge excellent in usability.

  In order to solve the above-described problems, the present invention provides a water discharge device that discharges hot water from a water discharge port while reciprocatingly vibrating the water supply device main body and the water supply device provided in the water discharge device main body. A vibration generating element that discharges while reciprocating in a vibration plane, and the vibration generating element includes a water supply passage through which hot water supplied from a water discharge device body flows, and a part of a flow path section of the water supply passage. A hot water collision portion that is arranged at the downstream end of the water supply passage so as to be blocked and that collides with hot water guided by the water supply passage and alternately generates a vortex in the opposite direction on the downstream side, and the water supply passage A vortex street passage that is provided on the downstream side and guides the vortex formed by the hot water collision part while growing, and is provided on the downstream side of this vortex street passage, parallel to the vibration plane of the hot water flow that has passed through the vortex street passage. Turbulence and vibration in various directions A first rectification unit that is a passage that suppresses disturbance in a direction orthogonal to the surface, and a flow of hot water that is provided downstream of the first rectification unit and that passes through the first rectification unit in a direction orthogonal to the vibration plane. And a second rectifying unit that suppresses disturbance and does not suppress disturbance in a direction parallel to the vibration plane.

  According to the present invention configured as described above, since the hot water discharged from the water discharging device can be reciprocally vibrated by the vibration generating element, the hot water is distributed over a wide range from one water outlet with a compact and simple structure. It can be discharged. In addition, since the direction of water discharge can be changed without moving the nozzle to be discharged, there is no problem such as wear of movable parts, and a highly durable water discharge device can be configured at low cost.

  The inventor of the present invention has succeeded in reciprocating vibrations of discharged hot water with the above-described configuration. However, in order to obtain a comfortable feeling of stimulation by bathing the discharged hot water, the present inventor has a relatively high flow rate discharged from the water outlet, and the discharged hot water is relatively close to the water outlet. I faced a new technical challenge of breaking down into fine droplets. Even if the flow rate of discharged hot water is increased in order to obtain a pleasant irritation, if the injected hot water breaks down into fine droplets, the user who has bathed in the water will be given sufficient irritation. I can't. Due to the decomposition of the hot water into droplets, the discharged hot water spreads not only in the vibration plane in which the hot water reciprocally vibrates, but also in the direction perpendicular to the vibration plane, and is decomposed into fine droplets.

  In order to solve this new technical problem, it is conceivable to make the rectifying passage long in order to improve the rectification property to the hot water passing through the vortex passage. However, if the rectifying passage is configured to be long, the rectifying passage obstructs the reciprocating vibration of the hot water. Even if the rectifying passage does not hinder the reciprocating vibration of the hot water, the hot water peeled off at the peeling portion is likely to be reattached to the wall surface of the rectifying passage expanding, thereby causing the Coanda effect. As described above, when the Coanda effect occurs, the flow of hot water that oscillates back and forth is biased toward the periphery of the water discharge range, and the discharged hot water becomes uncomfortable. In order to avoid the occurrence of the Coanda effect, if the expansion angle of the rectifying passage is made extremely large, the design of the tip of the vibration generating element becomes unreasonable, and the wall surface for forming the peeling portion etc. becomes extremely thin, etc. It turned out to be a difficult form to commercialize.

  As a result of intensive research and development while repeating the trial and error as described above, the present inventor has reached the above-described structure of the present invention. In other words, according to the present invention, the hot water that has passed through the vortex street passage is first guided to the first rectification unit and then to the second rectification unit. In the first rectifying unit, the disturbance of the flowing hot water in the direction parallel to the vibration plane and the disturbance in the direction orthogonal to the vibration plane are suppressed. Thereby, it becomes possible to discharge the flowing hot water evenly in a predetermined water discharge range. However, if the flow rate of the discharged hot water is made very high only by passing through the first rectifying unit, the flow spreads in a direction orthogonal to the vibration plane in which the hot water reciprocates, and the hot water is a fine droplet. It will be broken down. Therefore, the present inventor has solved the above problem by providing a second rectification unit that suppresses disturbance in a direction orthogonal to the vibration plane on the downstream side of the first rectification unit. Since this second rectification unit does not suppress disturbance in the direction parallel to the vibration plane, the vibration plane of the hot water discharged without reducing the water discharge range or causing the Coanda effect by providing the second rectification unit. It is possible to suppress the spread in the direction orthogonal to the. As described above, according to the present invention, by providing the first rectification unit and the second rectification unit in two stages, the liquid droplets can be distributed almost uniformly within the water discharge range, and the flow rate of the discharged hot water is Can be made very high to obtain a pleasant stimulation.

  In the present invention, preferably, the width of the second rectification unit is wider than the width at the downstream end of the first rectification unit.

  According to the present invention configured as described above, since the width of the second rectification unit is configured to be wider than the width of the downstream end of the first rectification unit, hot water discharged while spreading from the first rectification unit due to reciprocating vibration. The second rectification unit can also suppress the disturbance in the direction orthogonal to the vibration plane with respect to the flow of. As a result, the spread of the hot water in the direction orthogonal to the vibration plane can be suppressed over a wider range, and a more comfortable stimulation can be obtained.

In the present invention, it is preferable that the second rectification unit is composed of two plane parts arranged in parallel to the vibration plane.
According to the present invention configured as described above, since the second rectification unit is configured by two plane parts parallel to the vibration plane, even when the flow from the first rectification part spreads in the vibration plane, A flow does not collide with the wall surface which comprises a 2nd rectification | straightening part. For this reason, in the 2nd rectification | straightening part, only the spreading of the hot water of the direction orthogonal to a vibration plane can be suppressed reliably, and the reciprocating vibration in a vibration plane is not inhibited.

In the present invention, preferably, the width of the vortex passage is configured to be constant, and the width of the first rectifying unit is narrower than the width of the vortex passage.
According to the present invention configured as described above, the width of the vortex street passage is configured to be constant, and the vortex street passage is connected to the first rectifying section having a narrow width. It is deflected abruptly at the downstream end of the water, so that the hot and cold water can be reciprocated with a larger amplitude, and a wide water discharge range can be obtained.

  In the present invention, preferably, the water discharge device main body includes a discharge opening for inserting the second rectification unit of the vibration generating element, and the vibration generation element is arranged such that the second rectification unit contacts the edge of the discharge opening. It is attached to the water discharge device main body.

  According to the present invention configured as described above, since the second rectification portion of the vibration generating element is in contact with the edge of the discharge opening of the water discharge device main body, the reaction force acting on the vibration generating element that reciprocally vibrates the hot water. However, the vibration generating element itself can be vibrated to suppress generation of abnormal noise or the like. As a result, it is possible to provide a high-quality water discharge device that does not generate abnormal noise.

  According to the water discharging apparatus of the present invention, it is possible to configure the water discharge device with a simple structure and a compact structure, and to obtain water discharge excellent in usability.

It is a perspective view which shows the external appearance of the shower head by 1st Embodiment of this invention. It is a whole sectional view of the shower head by a 1st embodiment of the present invention. It is a perspective view which shows the external appearance of the vibration generating element with which the shower head by 1st Embodiment of this invention is equipped. It is a plane sectional view of a vibration generating element in a 1st embodiment of the present invention. It is a vertical sectional view of the vibration generating element in the first embodiment of the present invention. It is a figure which shows the result of the fluid simulation which analyzed the flow of the hot water in the vibration generating element with which the shower head by embodiment of this invention is equipped. It is an example of the flash photography which shows the flow of the hot water discharged from the single vibration generating element with which the shower head by 1st Embodiment of this invention is equipped. It is a photograph which shows the state of the hot water discharged from the vibration generating element with which the shower head by 1st Embodiment of this invention is equipped. It is a photograph which shows the state of the hot water discharged from the vibration generating element which is not provided with the 2nd rectification | straightening part as a comparative example. It is a perspective view which shows the external appearance of the vibration generating element with which the shower head by 2nd Embodiment of this invention is equipped. It is a plane sectional view of a vibration generating element in a 2nd embodiment of the present invention. It is a vertical sectional view of a vibration generating element in a second embodiment of the present invention. It is a plane sectional view of the modification of the vibration generating element in a 2nd embodiment of the present invention. It is sectional drawing which shows the state which attached the vibration generating element in 2nd Embodiment of this invention inside the shower head. It is a perspective view which shows the external appearance of the vibration generating element with which the shower head by 3rd Embodiment of this invention is equipped. It is a plane sectional view of a vibration generating element in a 3rd embodiment of the present invention. It is a vertical sectional view of a vibration generating element in a third embodiment of the present invention. It is a figure which shows the result of the fluid simulation which analyzed the flow of the hot water in the vibration generating element with which the shower head by 3rd Embodiment of this invention is equipped. It is an example of the flash photography which shows the flow of the hot water discharged from the single vibration generation element with which the shower head by 3rd Embodiment of this invention is equipped. It is a photograph which shows the state of the hot water discharged from the vibration generating element with which the shower head by 3rd Embodiment of this invention is equipped. It is a photograph which shows the state of the hot water discharged from the vibration generating element which is not provided with the 2nd rectification | straightening part as a comparative example. It is a perspective view which shows the external appearance of the vibration generating element with which the shower head by 4th Embodiment of this invention is equipped. It is a plane sectional view of a vibration generating element in a 4th embodiment of the present invention. It is a vertical sectional view of a vibration generating element in a fourth embodiment of the present invention. It is a perspective view which shows the external appearance of the vibration generating element with which the shower head by 5th Embodiment of this invention is equipped. It is a plane sectional view of a vibration generating element in a 5th embodiment of the present invention. It is a vertical sectional view of a vibration generating element in a fifth embodiment of the present invention. It is a figure which shows the effect | action of the fluid element described in patent document 1. FIG. It is a figure which shows the structure of the fluid element described in patent document 3. FIG.

Next, a shower head which is a water discharge device according to a preferred embodiment of the present invention will be described with reference to the accompanying drawings.
First, a shower head according to a first embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a perspective view showing an appearance of a shower head according to a first embodiment of the present invention. FIG. 2 is a full sectional view of the shower head according to the first embodiment of the present invention. FIG. 3 is a perspective view showing the appearance of the vibration generating element provided in the shower head according to the first embodiment of the present invention. 4A is a plan sectional view of the vibration generating element in the present embodiment, and FIG. 4B is a vertical sectional view of the vibration generating element.

As shown in FIG. 1, the shower head 1 of the present embodiment includes a generally cylindrical shower head main body 2 and seven vibration generating elements 4 embedded in the shower head main body 2 so as to be aligned in a straight line in the axial direction. Have.
In the shower head 1 of the present embodiment, when hot water is supplied from a shower hose (not shown) connected to the base end portion of the shower head body 2, the hot water reciprocates from the water outlet 4 a of each vibration generating element 4. While being discharged. In the present embodiment, hot water is discharged from each water outlet 4a so as to form a sector having a predetermined central angle in a vibration plane that is substantially orthogonal to the central axis of the shower head body 2.

Next, the internal structure of the shower head 1 will be described with reference to FIG.
As shown in FIG. 2, in the shower head main body 2, a water passage forming member 6 that forms a water passage and a vibration generating element holding member 8 that holds each vibration generating element 4 are incorporated. In this embodiment, the shower head main body 2, the water flow path forming member 6, and the vibration generating element holding member 8 constitute a water discharger main body.
The water flow path forming member 6 is a substantially cylindrical member, and is configured to form a flow path of hot water supplied to the inside of the shower head main body 2. A shower hose connecting member 6 a is connected to the base end portion of the water passage forming member 6 in a watertight manner. Moreover, the front-end | tip part of the water flow path formation member 6 is notched by semicircular cross-sectional shape, and the vibration generation element holding member 8 is arrange | positioned at this notch part.

  The vibration generating element holding member 8 is a substantially semi-cylindrical member, and is arranged in a notch portion of the water passage forming member 6 so that a cylindrical shape is formed. Further, a packing 6b is disposed between the water flow path forming member 6 and the vibration generating element holding member 8, and water tightness between them is ensured. Furthermore, seven element insertion holes 8a for inserting and holding each vibration generating element 4 are formed in the vibration generating element holding member 8 so as to be aligned in a straight line in the axial direction at substantially equal intervals. Thereby, the hot water flowing into the water passage forming member 6 flows into the back side of each vibration generating element 4 held by the vibration generating element holding member 8, and is discharged from the water discharge port 4a provided on the front surface. . Further, each element insertion hole 8a is provided so as to be slightly inclined with respect to a plane orthogonal to the central axis of the shower head main body 2, and the hot water sprayed from each vibration generating element 4 is entirely taken as a shower head. It is discharged so as to spread slightly in the axial direction of the main body 2.

Next, the configuration of the vibration generating element 4 built in the shower head of this embodiment will be described with reference to FIGS. 3 and 4.
As shown in FIG. 3, the vibration generating element 4 is a substantially thin rectangular parallelepiped member. A rectangular water discharge port 4 a is provided at the front end of the vibration generating element 4, and a collar portion 4 b is formed at the end on the back side. ing. Further, a groove 4 c is provided in parallel with the flange 4 b so as to make a round around the vibration generating element 4. An O-ring (not shown) is fitted in the groove 4c, and watertightness between the vibration generating element holding member 8 and the element insertion hole 8a is ensured. Further, the vibration generating element 4 is positioned with respect to the vibration generating element holding member 8 by the flange portion 4b, and is prevented from dropping from the vibration generating element holding member 8 due to water pressure.

4A is a cross-sectional view taken along line AA in FIG. 3, and FIG. 4B is a cross-sectional view taken along line BB in FIG.
As shown in FIG. 4A, a passage having a rectangular cross section is formed inside the vibration generating element 4 so as to penetrate in the longitudinal direction. This passage is formed in order from the upstream side as a water supply passage 10a, a vortex street passage 10b, a first rectification unit 10c, and a second rectification unit 10d. Each long side of the rectangular cross-section passages is directed in a direction parallel to the vibration plane in which the discharged hot water vibrates (the direction of the paper surface in FIG. 4A).

The water supply passage 10a is a straight passage having a rectangular cross section with a constant cross-sectional area extending from the inlet 4d on the back side of the vibration generating element 4.
The vortex street passage 10b is a passage having a rectangular cross section provided on the downstream side of the water supply passage 10a so as to be continuous with the water supply passage 10a (without a step). That is, the downstream end of the water supply passage 10a and the upstream end of the vortex passage 10b have the same size and shape. A pair of opposing wall surfaces (both side wall surfaces) of the vortex street passage 10b are configured to taper so that the flow passage cross-sectional area decreases toward the downstream side over the entire vortex street passage 10b. In other words, the vortex street passage 10b is configured as a tapered portion whose entirety is narrowed toward the downstream side and gradually becomes narrower. In the present specification, the “width” means a length in a direction parallel to the vibration plane that crosses the central axis A of each passage formed inside the vibration generating element 4.

  The first rectifying unit 10c is a short passage having a rectangular cross section provided on the downstream side so as to communicate with the vortex street passage 10b, and is formed in a straight line with a constant cross-sectional area. The first rectification unit 10c rectifies the hot water containing the vortex train guided by the vortex train passage 10b and flows out to the second rectification unit 10d. The flow passage cross-sectional area of the first rectifying portion 10c is configured to be smaller than the flow passage cross-sectional area at the downstream end of the vortex street passage 10b, and there is a step between the vortex street passage 10b and the first rectification portion 10c. Part 12 is formed. The wall surface of the stepped portion, which is the surface of the stepped portion 12, is directed in a direction orthogonal to the central axis A of the vortex street passage 10b. Accordingly, the angle formed between the tapered wall surface (tapered wall surface) and the stepped wall surface of the vortex street passage 10b is greater than 90 ° (90 ° + α °). Further, the length of the stepped wall surface is configured to be shorter than the length of the tapered portion wall surface.

  The second rectification unit 10d is provided on the downstream side of the first rectification unit 10c so as to be continuous with the first rectification unit 10c. In addition, the second rectifying unit 10d is composed of two plane portions 13 that are formed in the same width as the flow path of the first rectifying unit 10c and are arranged in parallel to each other. That is, the hot water discharged from the flow passage having the rectangular cross section of the first rectifying unit 10c flows between the two parallel flat portions 13 having the same width as the first rectifying unit 10c and constituting the second rectifying unit 10d. To do. As shown in FIG. 3, these flat portions 13 are provided so as to protrude from the front end surface 4 e of the vibration generating element 4 formed in a substantially rectangular parallelepiped shape. In other words, each flat surface portion 13 of the second rectifying unit 10d is continuous with the floor surface and the ceiling surface (the wall surface parallel to the paper surface of FIG. 4A) of the flow path of the first rectifying unit 10c, The side wall surface (wall surface perpendicular to the paper surface of FIG. 4A) does not exist in the 2 rectifying unit 10d.

  That is, the side wall surface of the first rectifying unit 10c is continuous with the distal end surface 4e of the vibration generating element 4 at a bending angle β of 270 ° over the second rectifying unit 10d. In other words, the hot water flow path is connected from the first rectification unit 10c having parallel side wall surfaces (expansion angle = 0 °) to the second rectification unit 10d expanding in the vibration plane at an expansion angle θ = 180 °. The In this way, the flow path that continues from the first rectifying unit 10c to the second rectifying unit 10d is continuous at the same height in the vertical direction (the direction perpendicular to the paper surface of FIG. 4A), while in the vibration plane. It widens suddenly in a staircase shape. For this reason, there is no wall surface that restricts the flow of hot water flowing out from the first rectifying unit 10c in the width direction (vertical direction in FIG. 4A) in the second rectifying unit 10d, and the hot water flowing out from the first rectifying unit 10c is In the 2 rectification | straightening part 10d, it can spread without limitation in the width direction.

Next, as shown in FIG. 4B, the wall surfaces (ceiling surface and floor surface) facing in the height direction of the water supply passage 10a, the vortex street passage 10b, the first rectification unit 10c, and the second rectification unit 10d are all the same. It is provided on a plane. That is, the heights of the water supply passage 10a, the vortex street passage 10b, the first rectification unit 10c, and the second rectification unit 10d are all the same and constant.
In the present embodiment, the length of the second rectifying unit 10d (the length of the vibration generating element 4 in the direction of the central axis A) is the length of the passage of the first rectifying unit 10c (the central axis of the vibration generating element 4). About 1.5 times as long as the length in the A direction). Preferably, the length of the second rectification unit 10d is formed to be about 0.25 to about 10 times the length of the passage of the first rectification unit 10c.

  On the other hand, as shown in FIG. 4A, a hot water collision portion 14 is formed at the downstream end of the water supply passage 10a (near the connection portion between the water supply passage 10a and the vortex passage 10b). It is provided so as to block a part of the flow path cross section of the passage 10a. The hot water collision portion 14 is a triangular prism-shaped portion extending so as to connect the wall surfaces (ceiling surface and floor surface) facing the height direction of the water supply passage 10a, and has an island shape at the center in the width direction of the water supply passage 10a. Is arranged. The cross section of the hot water collision part 14 is formed in a right-angled isosceles triangle shape, and the hypotenuse is arranged so as to be orthogonal to the central axis A of the water supply passage 10a. It is arranged to face. By providing this hot / cold water collision part 14, a Karman vortex is generated on the downstream side thereof, and hot water discharged from the water discharge port 4a is reciprocated. Moreover, in this embodiment, the hot water collision part 14 is arrange | positioned so that the oblique side part (upstream end of the hot water collision part 14) of a right-angled isosceles triangle may be located on the boundary line of the water supply path 10a and the vortex street path 10b. Has been.

  In the present embodiment, the angle formed by the side wall surface of the vortex street passage 10b and the central axis A (angle α in FIG. 4A) is about 7 °. Preferably, the angle between the side wall surface and the central axis A is set to about 3 ° to about 25 °. By setting the angle in this way, it is possible to suppress the occurrence of the Coanda effect while suppressing the change in the water discharge range accompanying the change in the discharge flow rate.

Next, the action of the shower head 1 according to the embodiment of the present invention will be described with reference to FIGS.
FIG. 5 is a diagram showing a fluid simulation result obtained by analyzing the flow of hot water in the vibration generating element 4 provided in the shower head 1 according to the embodiment of the present invention. FIG. 6 is an example of a stroboscopic photograph showing the flow of hot water discharged from a single vibration generating element 4 provided in the shower head 1 according to the embodiment of the present invention.

  First, hot water supplied from a shower hose (not shown) flows into the water passage forming member 6 (FIG. 2) in the shower head body 2 and further generates each vibration held by the vibration generating element holding member 8. It flows into the inlet 4d (FIG. 4) of the element 4. The hot water flowing into the water supply passage 10a from the inlet 4d of each vibration generating element 4 collides with the hot water collision portion 14 provided so as to block a part of the flow path. As a result, a vortex row of Karman vortices that are alternately opposite to each other is formed on the downstream side of the hot water / impact portion 14. Karman vortices formed by the hot water / water impinging portion 14 grow while being guided by the vortex street 10b having a tapered shape and reach the first rectifying portion 10c.

  The results of analyzing the flow of hot water in the vortex passage 10b by fluid simulation are the columns (a) to (c) in FIG. As shown in the fluid simulation, a vortex is generated on the downstream side of the hot water / impact portion 14 and the flow velocity is high at that portion. The high flow velocity portions (the dark portions in FIG. 5) appear alternately on both sides of the hot water collision portion 14, and the vortex train advances toward the water discharge port 4a along the wall surface of the vortex train passage 10b. The hot water flowing into the first rectification unit 10c downstream of the vortex street passage 10b is disturbed in a direction parallel to the vibration plane (a plane parallel to the paper surface of FIG. 5) and in a direction perpendicular to the vibration plane. Suppressed and rectified. The hot water that has passed through the first rectification unit 10c is rectified in the second rectification unit 10d while only disturbance in the direction orthogonal to the vibration plane is suppressed.

  Hot water discharged from the spout 4a through the second rectifying unit 10d is bent based on the flow velocity distribution at the spout 4a, and the discharge direction changes as the portion with the higher flow velocity moves up and down in FIG. That is, in a state where the high flow rate portion is located at the upper end of the spout 4a in FIG. 5, the hot water is jetted downward, and in a state where the high flow rate portion is located at the lower end of the spout 4a, Injected upward. In this way, by generating Karman vortices alternately on the downstream side of the hot water collision portion 14, a flow velocity distribution is generated at the spout 4a, and the jet is deflected. Further, since the position of the portion having a high flow velocity reciprocates due to the progress of the vortex street, the injected hot water also oscillates reciprocally within the vibration plane (a plane parallel to the paper surface of FIG. 5). At this time, the second rectifying unit 10d is configured by only two plane parts 13 arranged in parallel with the vibration plane (no side wall surface is provided as shown in FIG. 3), and thus is orthogonal to the vibration plane. Only the turbulence in the direction is suppressed, and there is almost no effect on the reciprocating vibration of the hot water in the vibration plane.

  Further, since the step portion 12 is provided between the vortex street passage 10b and the first rectifying portion 10c, the flow along the tapered wall surface (tapered portion wall surface) of the vortex street passage 10b is peeled off at this time. 1 flows into the rectifying unit 10c. When the flow is separated from the wall surface by the stepped portion 12, the Coanda effect generated on the side wall surface of the first rectifying unit 10c is suppressed. Further, since the second rectification unit 10d on the downstream side of the first rectification unit 10c is not provided with a side wall surface and spreads rapidly (expansion angle θ = 180 °), the second rectification unit 10d includes a Coanda. There is no effect. For this reason, the hot water discharged from the water discharge port 4a is reciprocated smoothly without being substantially affected by the Coanda effect. Therefore, the step part 12 acts as a peeling part that peels the flow along the wall surface of the vortex street passage 10b and suppresses the Coanda effect. Further, the stepped wall surface that is the surface of the stepped portion 12 functions as a peeling portion wall surface.

  Next, in the stroboscopic photograph showing the flow of hot water discharged from the vibration generating element 4 in the present embodiment shown in FIG. 6, since the water discharge direction is reciprocating smoothly, a neat sine wave flow is obtained. ing. As described above, according to the vibration generating element 4 in the present embodiment, it is possible to obtain shower water that is comfortable to be discharged, in which large droplets are discharged uniformly over a wide range.

Next, the effect of the second rectifying unit 10d provided in the vibration generating element 4 will be described with reference to FIGS.
FIG. 7 is a photograph showing the state of hot water discharged from the vibration generating element 4 provided in the shower head 1 of the present embodiment. FIG. 8 is a photograph showing a state of hot water discharged from a vibration generating element not provided with the second rectifying unit 10d as a comparative example. The vibration generating element in FIG. 7 and the vibration generating element in FIG. 8 have the same configuration except for the presence or absence of the second rectifying unit 10d. 7 and 8, the two photographs on the left side show the state of hot water discharged from the vibration generating element at a flow rate of 4 m / sec, and the two photographs on the right side are discharged from the vibration generating element at a flow rate of 8 m / sec. It shows the state of hot and cold water. Further, in FIGS. 7 and 8, the upper photograph is taken from the direction perpendicular to the vibration plane, and the lower photograph is taken from the direction parallel to the vibration plane. It is.

  First, as shown in FIG. 7, the hot water discharged from the vibration generating element at a flow velocity of 4 m / sec is vibrated in a clean sine wave shape in the vibration plane (upper left of FIG. 7) and in a direction orthogonal to the vibration plane. Is discharged in a straight line with almost no spread (lower left in FIG. 7). On the other hand, when the flow rate of the hot water discharged from the vibration generating element is very high and 8 m / sec, disturbances occur in the vibration of the sinusoidal hot water in the vibration plane (upper right in FIG. 7), but the vibration plane The spread of the hot water in the direction orthogonal to is suppressed (lower right in FIG. 7). For this reason, a comfortable irritation can be given to a user who has bathed in hot water discharged at a flow rate of 8 m / sec.

  Next, as shown in FIG. 8, as a comparative example, the hot water discharged from the vibration generating element that does not include the second rectifying unit 10d is the second rectifying unit of the present embodiment when the flow rate is 4 m / sec. The flow is a sinusoidal flow substantially the same as the hot water discharged from the vibration generating element having 10d (upper left and lower left in FIG. 8). On the other hand, when the flow velocity is 8 m / sec, the hot water discharged from the vibration generating element does not remain in the form of a sine wave (upper right in FIG. 8), and the direction is orthogonal to the vibration plane. It can be seen that the flow has spread greatly (lower right in FIG. 8). This is because the hot water discharged from the vibration generating element is decomposed into fine droplets relatively near the water outlet. Thus, if the flow of discharged hot water is decomposed into fine droplets, even if the flow rate is increased to 8 m / sec, a user who has bathed in hot water cannot be given a pleasant irritation. . Since the vibration generating element (FIG. 7) of the present embodiment includes the second rectifying unit 10d, the flow of hot water spreads in a direction perpendicular to the vibration plane even when the flow rate of discharged hot water is very high. Can be suppressed (lower right in FIG. 7), and a pleasant stimulation can be given to the user.

  According to the shower head 1 of the first embodiment of the present invention, the vibration generating element 4 is provided with the first rectifying unit 10c and the second rectifying unit 10d in two stages (FIG. 4A), so that it is substantially constant within the water discharge range. In addition, the droplets can be distributed on the surface, and the flow rate of the hot and cold water discharged can be made extremely high, so that a pleasant stimulation can be obtained.

  Moreover, according to the shower head 1 of this embodiment, since the 2nd rectification | straightening part 10d is comprised from the two plane parts 13 parallel to a vibration plane (plane parallel to the paper surface of FIG. 4A), the 1st rectification | straightening part Even when the flow from 10c spreads in the vibration plane, the flow does not collide with the wall surface constituting the second rectification unit 10d. For this reason, in the 2nd rectification | straightening part, only the spreading of the hot water of the direction orthogonal to a vibration plane can be suppressed reliably, and the reciprocating vibration in a vibration plane is not inhibited.

Next, with reference to FIG.9 and FIG.10, the shower head by 2nd Embodiment of this invention is demonstrated.
The shower head of this embodiment differs from the first embodiment described above only in the configuration of the built-in vibration generating element. Accordingly, here, only the points of the present embodiment that are different from the first embodiment will be described, and descriptions of similar configurations, operations, and effects will be omitted.

FIG. 9 is a perspective view of a vibration generating element according to the second embodiment of the present invention. 10A is a plan sectional view of the vibration generating element in the present embodiment, and FIG. 10B is a vertical sectional view of the vibration generating element.
As shown in FIGS. 9 and 10, the vibration generating element 30 in the present embodiment is different from the first embodiment in the configuration of the vortex street path and the configuration of the second rectification unit. That is, in the present embodiment, the upstream side of the vortex street passage is configured by a passage having a constant cross-sectional area, and the width of the second rectification portion is configured wider than that of the first rectification portion.

As shown in FIG. 9, the vibration generating element 30 is a substantially thin rectangular parallelepiped member. A rectangular water discharge port 30 a is provided at the front end of the vibration generating element 30, and a flange 30 b is formed at the end on the back side. ing. Further, a groove 30 c is provided in parallel with the flange portion 30 b so as to make a round around the vibration generating element 30.
As shown in FIG. 10A, similarly to the first embodiment, a passage having a rectangular cross section is formed inside the vibration generating element 30 so as to penetrate in the longitudinal direction. This passage is formed in order from the upstream side as a water supply passage 32a, a vortex street passage 32b, a first rectification unit 32c, and a second rectification unit 32d.

The water supply passage 32a is a straight passage having a rectangular cross section with a constant cross-sectional area extending from the inlet 30d on the back side of the vibration generating element 30.
The vortex street passage 32b is a rectangular cross-section passage provided downstream of the water supply passage 32a so as to be continuous with the water supply passage 32a. That is, the downstream end of the water supply passage 32a and the upstream end of the vortex street passage 32b have the same size and shape. A pair of opposing wall surfaces (both side surfaces) of the vortex street passage 32b are formed in parallel on the upstream side and tapered on the downstream side so that the cross-sectional area of the flow path decreases toward the downstream end. A tapered portion 32e is provided. That is, the vortex street passage 32b is configured to extend from the upstream end with a constant cross-sectional area and then gradually narrow toward the downstream side.

  The first rectifying unit 32c is a rectangular cross-sectional passage provided on the downstream side so as to communicate with the vortex street passage 32b (tapered portion 32e), and is formed in a straight line with a constant cross-sectional area. The first rectification unit 32c rectifies the hot water containing the vortex street guided by the vortex street passage 32b and flows out to the second rectification unit 32d. The flow passage cross-sectional area of the first rectifying unit 32c is configured to be smaller than the flow passage cross-sectional area at the downstream end of the vortex street passage 32b (tapered portion 32e), and the vortex street passage 32b and the first rectification portion 32c. A stepped portion 36 that is a peeling portion is formed between them. The wall surface of the step portion, which is the surface of the step portion 36, is directed in a direction orthogonal to the central axis A of the vortex street passage 32b. Accordingly, the angle formed between the tapered wall surface (tapered wall surface) and the stepped wall surface of the vortex street passage 32b is greater than 90 ° (90 ° + α °). Moreover, the length of the stepped wall surface is configured to be shorter than the length of the tapered portion wall surface.

  The second rectification unit 32d is provided on the downstream side of the first rectification unit 32c so as to be continuous with the first rectification unit 32c. The second rectifying unit 32d is composed of two flat portions 33 having a width wider than the width of the flow path of the first rectifying unit 32c and arranged in parallel to each other. That is, the hot water discharged from the flow passage having the rectangular cross section of the first rectifying unit 32c flows between the two parallel flat surface parts 33 constituting the second rectifying unit 32d and wider than the first rectifying unit 31c. To do. As shown in FIG. 9, these flat portions 33 are provided so as to protrude from the front end surface 30 e of the vibration generating element 30 formed in a substantially rectangular parallelepiped shape. In other words, each flat surface portion 33 of the second rectifying unit 32d is continuous with the floor surface and the ceiling surface (wall surface parallel to the paper surface of FIG. 10A) of the flow path of the first rectifying unit 32c, The side wall surface (wall surface perpendicular to the paper surface of FIG. 10A) does not exist in the two rectifying units 32d.

  That is, the side wall surface of the first rectifying unit 32c is continuous with the distal end surface 30e of the vibration generating element 30 at a bending angle β of 270 ° from the second rectifying unit 32d. In other words, the flow path of hot water is connected from the first rectification unit 32c having parallel side wall surfaces (expansion angle = 0 °) to the second rectification unit 32d expanding in the vibration plane at an expansion angle θ = 180 °. The As described above, the flow path that continues from the first rectifying unit 32c to the second rectifying unit 32d is continuous at the same height in the vertical direction (the direction perpendicular to the paper surface of FIG. 10A), while in the vibration plane. It widens suddenly in a staircase shape. For this reason, there is no wall surface that regulates the flow of hot water flowing out from the first rectifying unit 32c in the width direction (vertical direction in FIG. 10A) in the second rectifying unit 32d, and the hot water flowing out from the first rectifying unit 32c is In the 2 rectification | straightening part 32d, it can spread without limitation in the width direction.

As shown in FIG. 10B, in this embodiment as well, in the same manner as in the first embodiment, the water supply passage 32a, the vortex street passage 32b, the first rectification unit 32c, and the second rectification unit 32d are opposed to each other in the height direction. The wall surfaces (ceiling surface and floor surface) are all provided on the same plane. That is, the heights of the water supply passage 32a, the vortex street passage 32b, the first rectification unit 32c, and the second rectification unit 32d are all the same and constant.
In the present embodiment, the length of the second rectifying unit 32d (the length in the direction of the central axis A of the vibration generating element 30) is the length of the passage of the first rectifying unit 32c (the central axis of the vibration generating element 30). About 1.5 times as long as the length in the A direction). Preferably, the length of the second rectification unit 32d is formed to be about 0.25 to about 10 times the length of the passage of the first rectification unit 32c. In the present embodiment, the width of the second rectification unit 32d is formed to be about twice the width of the passage of the first rectification unit 32c. Preferably, the width of the second rectification unit 32d is formed to be about 1 to about 3 times the width of the passage of the first rectification unit 32c.

  On the other hand, as shown in FIG. 10A, at the downstream end of the water supply passage 32a (near the connection portion between the water supply passage 32a and the vortex passage 32b), a part of the flow passage cross section of the water supply passage 32a is closed. A hot water collision part 34 is provided. Since the configuration of the hot water collision unit 34 is the same as that of the first embodiment, the description thereof is omitted.

  Further, by forming the length in the axial direction of the tapered portion 32e of the vortex passage 32b longer than the length in the axial direction of the first rectifying unit 32c, the change in the discharge range due to the flow rate of the discharged hot water is changed. It has been confirmed that it can be sufficiently suppressed. Preferably, the length of the taper portion 32e in the direction of the central axis A is four times or longer than the length of the first rectifying unit 32c in the direction of the central axis A. Further, the angle (angle α in FIG. 10A) formed by the side wall surface of the tapered portion 32e of the vortex street passage 32b and the central axis A is about 7 °. Preferably, the angle between the side wall surface and the central axis A is set to about 3 ° to about 25 °. By setting the angle in this way, it is possible to suppress the occurrence of the Coanda effect while suppressing the change in the water discharge range accompanying the change in the discharge flow rate. Furthermore, the flow passage cross-sectional area (the area obtained by subtracting the projected area of the hot water collision portion 34 from the flow passage cross-sectional area of the water supply passage 32a) at the downstream end of the water supply passage 32a partially blocked by the hot water collision portion 34 is The flow passage cross-sectional area of the first rectifying unit 32c is larger.

  Further, the hot water flowing into the first rectifying unit 32c on the downstream side of the vortex street passage 32b is disturbed in a direction parallel to the vibration plane (a plane parallel to the paper surface of FIG. 10A) and in a direction orthogonal to the vibration plane. Turbulence is suppressed and rectified. The hot water that has passed through the first rectification unit 32c is rectified in the second rectification unit 32d while only disturbance in the direction orthogonal to the vibration plane is suppressed.

  The hot water discharged from the water outlet 30a through the second rectifying unit 32d is bent based on the flow velocity distribution at the water outlet 30a, and the discharge direction changes according to the movement of the portion having a high flow velocity. At this time, since the second rectification unit 32d is configured by only two plane portions 33 arranged in parallel with the vibration plane (no side wall surface is provided as shown in FIG. 9), the second rectification portion 32d is orthogonal to the vibration plane. Only the turbulence in the direction is suppressed, and there is almost no effect on the reciprocating vibration of the hot water in the vibration plane. In addition, the width of the second rectification unit 32d (the width of the flat surface portion 33) is formed wider than the width of the flow path cross section of the first rectification unit 32c. For this reason, since the hot water discharged from the first rectifying unit 32c while reciprocally vibrating and discharged outward from the first rectifying unit 32c in the width direction also passes between the two flat portions 33, such hot water In contrast, the second rectification unit 32d can suppress the disturbance in the direction orthogonal to the vibration plane. Thereby, the spread of the direction orthogonal to the vibration plane of the discharged hot water can be suppressed more effectively.

  Note that the vibration generating element 30 according to the second embodiment of the present invention is different from the first embodiment described above in the configuration of the vortex street passage 32b and the second rectification unit 32d, but the vortex street passage 32b or the second rectification passage 32d. Any one of the configurations of the rectifying unit 32d can be applied to the vibration generating element in the first embodiment.

  According to the shower head of the second embodiment of the present invention, the width in the direction parallel to the vibration plane of the second rectification unit 32d (the plane parallel to the paper surface of FIG. 10A) is larger than the width of the downstream end of the first rectification unit 32c. Also, the second rectification unit 32d can suppress the disturbance in the direction orthogonal to the vibration plane even with respect to the flow of hot water discharged while spreading from the first rectification unit 32c due to the reciprocating vibration. As a result, the spread of the hot water in the direction orthogonal to the vibration plane can be suppressed over a wider range, and a more comfortable stimulation can be obtained.

Next, a modification of the vibration generating element in the second embodiment of the present invention will be described with reference to FIG.
FIG. 11 is a cross-sectional plan view of a vibration generating element according to this modification.
The vibration generating element 38 according to the present modification is different from the second embodiment described above only in the configuration of the second rectifying unit 39.

  In the second embodiment described above, the second rectification unit 32d is configured by the two flat surfaces 33 (FIG. 9), and the second rectification unit 32d is not provided with a side wall surface. On the other hand, in this modification, the 2nd rectification | straightening part 39 is comprised from the channel | path of the wide rectangular cross section, and the side wall surface 39a is provided. That is, as shown in FIG. 11, the second rectification unit 39 is a rectangular cross-sectional path provided on the downstream side of the first rectification unit 32 c, and the height thereof is the same as the height of the first rectification unit 32 c. The width is wider than the width of the first rectifying unit 32c. That is, the flow path of the hot water suddenly widens in a stepwise manner with a spread angle θ = 180 ° in the vibration plane from the first rectification unit 32c to the second rectification unit 39, and then has a constant width (expansion angle = 0 °). ). Thus, in this modification, although the side wall surface 39a is provided in the 2nd rectification | straightening part 39, since the width | variety is fully wider than the width | variety of the 1st rectification | straightening part 32c, it reciprocates from the 1st rectification | straightening part 32c. The hot water discharged while vibrating and the side wall surface 39a do not interfere with each other, and the discharged hot water does not directly hit the side wall surface 39a.

  Therefore, also in this modification, the 2nd rectification | straightening part 39 suppresses only the disorder of the direction orthogonal to a vibration plane, and has little influence on the reciprocating vibration of the hot water in a vibration plane. In the present modification, the width of the second rectification unit 39 (the distance between the side wall surfaces 39a on both sides) is formed to be twice the width of the first rectification unit 32c. For this reason, the vibration generating element 38 according to the present modification exhibits substantially the same operations and effects as the vibration generating element in the second embodiment.

In the present modification, the base end wall surface 39 b that forms the base end of the second rectifying unit 39 is oriented in a direction orthogonal to the central axis A of the vibration generating element 38. That is, the inner wall surface constituting the passage of the first rectifying unit 32c and the proximal end wall surface 39b of the second rectifying unit 39 are bent at 90 °. In other words, the side wall surface of the first rectifying unit 32c extends to the second rectifying unit 39 at a fold angle β of 270 °. The fold angle β is determined by the discharged hot water and the base wall surface 39b. Any change can be made as long as there is no interference or the generation of the Coanda effect. For example, by forming the bending angle β smaller than 270 °, the thickness of the portion constituting the first rectifying portion 32c of the vibration generating element 38 can be increased and the strength can be increased. Further, the side wall surface 39a of the second rectifying unit 39 can also be directed to an arbitrary angle as long as it does not interfere with the discharged hot water.
Similarly, the bending angle β in the first and second embodiments can also be changed.

Furthermore, in the modification shown in FIG. 11, the second rectification unit 39 itself includes the side wall surface 39 a, but the configuration substantially including the side wall surface is also provided by the configuration of the shower head body 2 to which the vibration generating element is attached. Become.
FIG. 12 is a cross-sectional view showing a state in which the vibration generating element 30 according to the second embodiment of the present invention is attached to the inside of the shower head.

  As described with reference to FIG. 2, the vibration generating element is fixed in the shower head body 2 by being inserted into the element insertion hole 8 a provided in the vibration generating element holding member 8, and the tip portion thereof is It is exposed from an opening provided in the shower head body 2. That is, as shown in an enlarged view in FIG. 12, the planar portion 33 of the vibration generating element 30 inserted into the element insertion hole 8 a of the vibration generating element holding member 8 is formed in the discharge opening 2 a formed in the shower head body 2. Inserted. Thereby, the edge of the discharge opening 2a of the shower head main body 2 is located on the side of the two flat portions 33 constituting the second rectification unit 32d, and substantially functions as a side wall surface of the second rectification unit 32d. . Further, as shown in FIG. 12, by attaching the vibration generating element 30 so that the tip end thereof is in contact with the edge of the discharge opening 2a of the shower head body 2, the vibration generating element when discharging hot and cold water that vibrates reciprocally is provided. The vibration of 30 itself can be suppressed and generation | occurrence | production of abnormal noise etc. can be suppressed.

  As described above, even when the second rectification unit 32d of the vibration generating element 30 in the second embodiment is inserted into the discharge opening 2a of the shower head body 2, the width of the flat portion 33 constituting the second rectification unit 32d is as follows. Since it is sufficiently wide, hot water discharged while reciprocating vibrations does not interfere with the edge of the discharge opening 2a.

  On the other hand, in the vibration generating element 4 in the first embodiment, the width of the second rectification unit 10d is the same as the width of the first rectification unit 10c, and therefore the side surface of the second rectification unit 10d is in contact with the edge of the discharge opening 2a. When the vibration generating element 4 is arranged in this way, the hot water discharged from the first rectifying unit 10c is likely to interfere with the edge of the discharge opening 2a. For this reason, preferably, the width of the discharge opening 2a is configured to be sufficiently wider than the width of the second rectifying unit 10d, or the second rectifying unit 10d is vibrated so as to protrude from the outer surface of the shower head body 2. The generating element 4 is arranged.

Next, a shower head according to a third embodiment of the present invention will be described with reference to FIGS.
The shower head of this embodiment differs from the first embodiment described above only in the configuration of the built-in vibration generating element. Accordingly, here, only the points of the present embodiment that are different from the first embodiment will be described, and descriptions of similar configurations, operations, and effects will be omitted.

FIG. 13 is a perspective view of a vibration generating element according to the third embodiment of the present invention. FIG. 14A is a plan sectional view of the vibration generating element in the present embodiment, and FIG. 14B is a vertical sectional view of the vibration generating element.
As shown in FIGS. 13 and 14, the vibration generating element 40 in the present embodiment is different from the first embodiment in the configuration of the vortex passage. In other words, in the present embodiment, the entire vortex street passage is constituted by a passage having a constant cross-sectional area.

As shown in FIG. 13, the vibration generating element 40 is a substantially thin rectangular parallelepiped member. A rectangular water discharge port 40a is provided at the front end of the vibration generating element 40, and a flange 40b is formed at the end on the back side. ing. Further, a groove 40c is provided in parallel with the flange portion 40b so as to make a round around the vibration generating element 40.
As shown in FIG. 14A, similarly to the first embodiment, a passage having a rectangular cross section is formed inside the vibration generating element 40 so as to penetrate in the longitudinal direction. This passage is formed in order from the upstream side as a water supply passage 42a, a vortex street passage 42b, a first rectifier 42c, and a second rectifier 42d.

The water supply passage 42 a is a straight passage having a rectangular cross section with a constant cross-sectional area extending from the inlet 40 d on the back side of the vibration generating element 40.
The vortex street passage 42b is a passage having a rectangular cross section formed in a straight line with a constant cross-sectional area provided downstream of the water supply passage 42a so as to be continuous with the water supply passage 42a. That is, the water supply passage 42a and the vortex street passage 42b have the same cross-sectional shape. Accordingly, the pair of opposing wall surfaces (both side surfaces) of the vortex street passage 42b are formed in parallel.

  The first rectification unit 42c is a rectangular cross-section passage provided on the downstream side so as to communicate with the vortex street passage 42b, and is formed in a straight line with a constant cross-sectional area. The first rectification unit 42c rectifies the hot water containing the vortex train guided by the vortex train passage 42b and flows out to the second rectification unit 42d. The flow passage cross-sectional area of the first rectifying portion 42c is configured to be smaller than the flow passage cross-sectional area of the vortex street passage 42b, and a step portion that is a separation portion is provided between the vortex street passage 42b and the first rectification portion 42c. 46 is formed. The step portion wall surface which is the surface of the step portion 46 is directed in a direction orthogonal to the central axis A of the vortex street passage 42b. Accordingly, the angle formed between the wall surface of the vortex street passage 42b and the wall surface of the step portion is 90 °.

  The second rectification unit 42d is provided on the downstream side of the first rectification unit 42c so as to be continuous with the first rectification unit 42c. The second rectification unit 42d is composed of two flat portions 43 formed in the same width as the flow path of the first rectification unit 42c and arranged in parallel to each other. That is, the second rectification unit 42 d is provided so as to protrude from the tip surface 40 e of the vibration generating element 40. The side wall surface of the first rectifying unit 42c extends from the first rectifying unit 42c having a divergence angle = 0 ° from the first rectifying unit 42c to the second rectifying unit 42d and is connected to the tip surface 40e at a bending angle β of 270 °. It is connected to the second rectifying section 42d that spreads at a spread angle θ = 180 °. The configurations of the first rectification unit 42c and the second rectification unit 42d are the same as those in the first embodiment described above, and thus the description thereof is omitted.

  Next, a hot water collision portion 44 is provided at the downstream end of the water supply passage 42a (near the connection portion between the water supply passage 42a and the vortex passage 42b) so as to block a part of the cross section of the water supply passage 42a. It has been. Since the configuration of the hot water collision portion 44 is the same as that of the first embodiment, the description thereof is omitted.

  Further, the hot water flowing into the first rectifying unit 42c on the downstream side of the vortex street passage 42b is disturbed in a direction parallel to the vibration plane (a plane parallel to the paper surface of FIG. 14A) and in a direction orthogonal to the vibration plane. Turbulence is suppressed and rectified. The hot water that has passed through the first rectifying unit 42c is rectified in the second rectifying unit 42d while only disturbance in the direction orthogonal to the vibration plane is suppressed.

Next, the operation of the shower head according to the third embodiment of the present invention will be described with reference to FIGS.
FIG. 15 is a diagram illustrating a fluid simulation result obtained by analyzing the flow of hot water in the vibration generating element 40 provided in the shower head according to the third embodiment of the present invention. FIG. 16 is an example of a stroboscopic photograph showing the flow of hot water discharged from a single vibration generating element 40 provided in the shower head according to the embodiment of the present invention.

  The results of analyzing the flow of hot water in the vortex street passage 42b of the vibration generating element 40 in the present embodiment by fluid simulation are the columns (a) to (c) in FIG. As shown in the fluid simulation, a vortex is generated on the downstream side of the hot water / impact portion 44, and the flow velocity is high at that portion. This high flow velocity portion (the dark portion in FIG. 15) appears alternately on both sides of the hot water collision portion 44 and proceeds toward the water discharge port 4a. The hot and cold water containing the vortex that has reached the downstream end of the vortex street passage 42b strikes the stepped portion 46 and is largely deflected and flows into the first rectifying portion 42c. The hot water flowing into the first rectification unit 42c is rectified by suppressing disturbance in a direction parallel to the vibration plane (a plane parallel to the paper surface of FIG. 15) and disturbance in a direction perpendicular to the vibration plane. The hot water that has passed through the first rectifying unit 42c is rectified in the second rectifying unit 42d while only disturbance in the direction orthogonal to the vibration plane is suppressed.

  The hot water discharged from the water outlet 40a through the second rectifying unit 42d is strongly bent based on the flow velocity distribution at the water outlet 40a, and the discharge direction changes as the portion with the higher flow velocity moves in the vertical direction in FIG. . As a result, the hot and cold water to be ejected reciprocates within the vibration plane (a plane parallel to the paper surface of FIG. 15). At this time, since the second rectification unit 42d is composed of only two plane parts 43 arranged in parallel with the vibration plane (the side wall surface is not provided as shown in FIG. 13), it is orthogonal to the vibration plane. Only the turbulence in the direction is suppressed, and there is almost no effect on the reciprocating vibration of the hot water in the vibration plane.

  Further, since the step portion 46 is provided between the vortex street passage 42b and the first rectifying portion 42c, the flow along the tapered wall surface (tapered portion wall surface) of the vortex street passage 42b is peeled off here. 1 flows into the rectifying unit 42c. Since the flow is separated from the wall surface by the step portion 46 and strongly deflected, the Coanda effect is not substantially generated on the side wall surface of the first rectifying portion 42c. Further, since the second rectification unit 42d on the downstream side of the first rectification unit 42c is not provided with a side wall surface, the Coanda effect does not occur in the second rectification unit 42d. Therefore, the step part 46 acts as a peeling part that peels off the flow along the wall surface of the vortex street passage 42b. Further, the stepped wall surface which is the surface of the stepped portion 46 functions as a peeling portion wall surface.

  Next, in the stroboscopic photograph showing the flow of hot water discharged from the vibration generating element 40 in the present embodiment shown in FIG. 16, a flow that vibrates in a substantially sine wave shape is obtained by the reciprocating movement in the water discharge direction. As described above, according to the vibration generating element 40 in the present embodiment, when the flow rate of the hot water discharged from the water discharge port 40a is increased, the hot water can collide with the step portion 46 at a high speed and can be largely changed in direction. The water flow can be strongly deflected, and shower water discharged in a wider range than the vibration generating element 4 in the first embodiment can be obtained.

Next, the effect of the second rectification unit 42d provided in the vibration generating element 40 will be described with reference to FIGS.
FIG. 17 is a photograph showing the state of hot water discharged from the vibration generating element 4 provided in the shower head 1 of the present embodiment. FIG. 18 is a photograph showing the state of hot water discharged from a vibration generating element that does not include the second rectifying unit 42d as a comparative example. The vibration generating element in FIG. 17 and the vibration generating element in FIG. 18 have the same configuration except for the presence or absence of the second rectifying unit 42d. 17 and 18, the two photos on the left side show the state of hot water discharged from the vibration generating element at a flow rate of 4 m / sec, and the two photos on the right side are discharged from the vibration generating element at a flow rate of 8 m / sec. It shows the state of hot and cold water. Further, in FIGS. 17 and 18, the upper photograph is taken of the hot water discharged from the vibration generating element from the direction perpendicular to the vibration plane, and the lower photograph is taken of the hot water from a direction parallel to the vibration plane. It is.

  First, as shown in FIG. 17, hot water discharged from the vibration generating element at a flow velocity of 4 m / sec is vibrated in a wide angular range in the vibration plane (upper left in FIG. 17), and in a direction orthogonal to the vibration plane. The ink is discharged in a straight line without much spreading (lower left in FIG. 17). On the other hand, when the flow rate of hot water discharged from the vibration generating element is very high and 8 m / sec, the vibration in the vibration plane is disturbed, but vibrates in a wider angle range (upper right in FIG. 17). The spread of hot water in the direction orthogonal to the vibration plane is also suppressed to some extent (lower right in FIG. 17).

  Next, as shown in FIG. 18, as a comparative example, hot water discharged from a vibration generating element that does not include the second rectifying unit 42d is greatly disturbed even at a flow rate of 4 m / sec, and is perpendicular to the vibration plane. (Upper left and lower left in FIG. 18). Further, when the flow velocity is set to 8 m / sec, the hot water discharged from the vibration generating element is decomposed into fine liquid droplets immediately after the discharge, and the flow greatly spreads in the direction perpendicular to the vibration plane. It can be seen (upper right and lower right in FIG. 18). Thus, if the flow of discharged hot water is decomposed into fine droplets, even if the flow rate is increased to 8 m / sec, a user who has bathed in hot water cannot be given a pleasant irritation. . Since the vibration generating element (FIG. 17) of the present embodiment includes the second rectifying unit 42d, the flow of the hot water spreads in a direction perpendicular to the vibration plane even when the flow rate of the discharged hot water is very high. Is suppressed (lower right in FIG. 17), and a pleasant stimulation can be given to the user.

Next, with reference to FIG.19 and FIG.20, the shower head by 4th Embodiment of this invention is demonstrated.
The shower head of this embodiment differs from the third embodiment described above only in the configuration of the built-in vibration generating element. Accordingly, only the points of the present embodiment that are different from the third embodiment will be described here, and descriptions of similar configurations, operations, and effects will be omitted.

FIG. 19 is a perspective view of a vibration generating element according to the fourth embodiment of the present invention. 20A is a plan sectional view of the vibration generating element in the present embodiment, and FIG. 20B is a vertical sectional view of the vibration generating element.
As shown in FIGS. 19 and 20, the vibration generating element 50 in the present embodiment is different from the third embodiment in the configuration of the second rectification unit.

  As shown in FIG. 19, the vibration generating element 50 is a substantially thin rectangular parallelepiped member. A rectangular water discharge port 50a is provided at the front end of the vibration generating element 50, and a flange 50b is formed at the end on the back side. ing. Further, a groove 50c is provided in parallel with the flange 50b so as to make a round around the vibration generating element 50.

As shown in FIG. 20A, similarly to the third embodiment, a passage having a rectangular cross section is formed inside the vibration generating element 50 so as to penetrate in the longitudinal direction. This passage is formed in order from the upstream side as a water supply passage 52a, a vortex street passage 52b, a first rectification unit 52c, and a second rectification unit 52d.
Among these, since the structure of the water supply path 52a, the vortex street path 52b, and the 1st rectification | straightening part 52c is the same as that of 3rd Embodiment mentioned above, description is abbreviate | omitted. Further, a step portion 56 that is a separation portion is formed between the vortex street passage 52b and the first rectifying portion 52c. Since the configuration of the step portion 56 is the same as that of the third embodiment described above, the description thereof is omitted.

  The second rectification unit 52d is provided on the downstream side of the first rectification unit 52c so as to be continuous with the first rectification unit 52c. In addition, the second rectifying unit 52d is composed of two planar portions 53 that are wider than the flow path of the first rectifying unit 52c and are arranged in parallel to each other. That is, the second rectification unit 52 d is provided so as to protrude from the tip surface 50 e of the vibration generating element 50. The side wall surface of the first rectification unit 52c extends from the first rectification unit 52c having a divergence angle = 0 ° from the first rectification unit 52c to the second rectification unit 52d and is connected to the tip surface 50e at a bending angle β of 270 °. It is connected to the second rectification unit 52d that spreads at a spread angle θ = 180 °. Since the configurations of the first rectification unit 52c and the second rectification unit 52d are the same as those of the second embodiment described above, the description thereof is omitted.

  In the present embodiment, the length of the second rectifying unit 52d (the length of the vibration generating element 50 in the direction of the central axis A) is the length of the passage of the first rectifying unit 52c (the central axis of the vibration generating element 50). About 1.5 times as long as the length in the A direction). Preferably, the length of the second rectification unit 52d is formed to be about 0.25 to about 10 times the length of the passage of the first rectification unit 52c. In the present embodiment, the width of the second rectifying unit 52d is formed to be about twice the width of the passage of the first rectifying unit 52c. Preferably, the width of the second rectification unit 52d is formed to be about 1 to about 3 times the width of the passage of the first rectification unit 52c.

  In addition, a hot water collision portion 54 is provided at the downstream end of the water supply passage 52a (near the connection portion between the water supply passage 52a and the vortex passage 52b) so as to block a part of the flow path cross section of the water supply passage 52a. ing. Since the configuration of the hot water collision portion 54 is the same as that of the first embodiment, the description thereof is omitted.

  In the vibration generating element 50, the hot water flowing into the first rectifying unit 52c on the downstream side of the vortex passage 52b is turbulent in a direction parallel to the vibration plane (a plane parallel to the paper surface of FIG. 20A) and the vibration plane. The disturbance in the orthogonal direction is suppressed and rectified. The hot water that has passed through the second rectification unit 52c is rectified in the second rectification unit 52d while only disturbance in the direction orthogonal to the vibration plane is suppressed. Further, the width of the second rectification unit 52d (the width of the flat surface part 53) is formed wider than the width of the flow path cross section of the first rectification unit 52c. For this reason, since the hot water discharged while reciprocatingly vibrating from the first rectifying unit 52c and discharged toward the outside of the first rectifying unit 52c in the width direction passes between the two flat portions 53, such hot water In contrast, the second rectifying unit 52d can suppress the disturbance in the direction orthogonal to the vibration plane. Thereby, the spread of the direction orthogonal to the vibration plane of the discharged hot water can be suppressed more effectively.

  Also, the vibration generating element 50 in the present embodiment can be modified in the same way as the modification example shown in FIGS. That is, also for the vibration generating element 50 in the present embodiment, a side wall surface (not shown) is provided in the second rectifying unit 52d, or the flat part 53 is in contact with the edge of the discharge opening 2a of the shower head body 2. The vibration generating element 50 can be disposed on the surface. That is, since the width of the second rectification unit 52d is sufficiently wide, the hot water discharged from the first rectification unit 52c while vibrating back and forth and the side wall surface (not shown) do not interfere with each other, and the discharged hot water does not enter the side wall surface. There is no direct hit.

Next, with reference to FIG.21 and FIG.22, the shower head by 5th Embodiment of this invention is demonstrated.
The shower head of this embodiment differs from the first embodiment described above only in the configuration of the built-in vibration generating element. Accordingly, here, only the points of the present embodiment that are different from the first embodiment will be described, and descriptions of similar configurations, operations, and effects will be omitted.

FIG. 21 is a perspective view of a vibration generating element according to the fifth embodiment of the present invention. 22A is a plan sectional view of the vibration generating element in the present embodiment, and FIG. 22B is a vertical sectional view of the vibration generating element.
As shown in FIGS. 21 and 22, the vibration generating element 60 in the present embodiment is different from the first embodiment in the configuration of the first rectification unit and the second rectification unit.

  As shown in FIG. 21, the vibration generating element 60 is a substantially thin rectangular parallelepiped member, a rectangular water discharge port 60a is provided at the front end of the vibration generating element 60, and a collar portion 60b is formed at the end on the back side. ing. Further, a groove 60c is provided in parallel with the flange portion 60b so as to make a round around the vibration generating element 60.

As shown in FIG. 22A, similarly to the first embodiment, a passage having a rectangular cross section is formed inside the vibration generating element 60 so as to penetrate in the longitudinal direction. This passage is formed in order from the upstream side as a water supply passage 62a, a vortex street passage 62b, a first rectification unit 62c, and a second rectification unit 62d.
Among these, since the structure of the water supply channel | path 62a and the vortex street channel | path 62b is the same as that of 1st Embodiment mentioned above, description is abbreviate | omitted. In addition, a step portion 66 that is a separation portion is formed between the vortex street passage 62b and the first rectifying portion 62c. Since the configuration of the step portion 66 is the same as that of the third embodiment described above, the description thereof is omitted.

  The first rectification unit 62c is a rectangular cross-section passage provided downstream of the vortex street passage 62b so as to be continuous with the vortex street passage 62b. In addition, a pair of opposing wall surfaces (both side wall surfaces) of the first rectifying unit 62c are configured to taper so that the flow path cross-sectional area increases toward the downstream side. That is, the width of the first rectification unit 62c is configured to increase toward the downstream side. As described above, the first rectifying portion 62c tapered so as to increase the cross-sectional area of the flow path is provided on the downstream side of the step portion 66 that separates the flow along the side wall surface of the vortex street passage 62b. The hot water flowing in the rectifying unit 62c is easy to peel off from the side wall surface. However, the first rectification unit 62c formed in this way also has an effect of suppressing the spread of the hot water flow in the vibration plane to be less than the spread of the first rectification unit 62c. Accordingly, the first rectification unit 62c in the present embodiment also suppresses the disturbance in the direction parallel to the vibration plane and the disturbance in the direction orthogonal to the vibration plane of the flow of hot water that has passed through the vortex street passage 62b. Function as. Moreover, since the taper angle of the 1st rectification | straightening part 62c is comparatively small, the thickness of the member which comprises the 1st rectification | straightening part 62c does not become extremely thin.

  The second rectification unit 62d is provided on the downstream side of the first rectification unit 62c so as to be continuous with the first rectification unit 62c. In addition, the second rectifying unit 62d is composed of two flat portions 63 that are wider than the downstream end of the flow path of the first rectifying unit 62c and are arranged in parallel to each other. That is, the second rectifying unit 62d is provided so as to protrude from the tip surface 60e of the vibration generating element 60. The side wall surface of the first rectifying unit 62c extends from the first rectifying unit 62c having a divergence angle = 40 ° from the first rectifying unit 62c to the second rectifying unit 62d and is connected to the tip surface 60e at a bending angle β of about 250 °. It is connected to the second rectifying unit 62d that spreads at a spread angle θ = 180 ° in the plane. Since the configuration of the second rectifying unit 62d is the same as that of the first embodiment described above, the description thereof is omitted.

  In the present embodiment, the length of the second rectifying unit 62d (the length of the vibration generating element 60 in the direction of the central axis A) is the length of the passage of the first rectifying unit 62c (the central axis of the vibration generating element 60). About 1.5 times as long as the length in the A direction). Preferably, the length of the second rectification unit 62d is formed to be about 0.25 to about 10 times the length of the passage of the first rectification unit 62c. In the present embodiment, the width of the second rectification unit 62d is formed to be approximately twice the width of the passage at the upstream end of the first rectification unit 62c. Preferably, the width of the second rectification unit 62d is formed to be about 1 to about 3 times the width of the passage of the first rectification unit 62c.

  Further, a hot water collision portion 64 is provided at the downstream end of the water supply passage 62a (near the connection portion between the water supply passage 62a and the vortex passage 62b) so as to close a part of the cross section of the water supply passage 62a. ing. The configuration of the hot / cold water collision unit 64 is the same as that of the first embodiment, and thus the description thereof is omitted.

  In the vibration generating element 60, the hot water flowing into the first rectifying unit 62c on the downstream side of the vortex street passage 62b is turbulent in a direction parallel to the vibration plane (a plane parallel to the paper surface of FIG. 22A) and the vibration plane. The disturbance in the orthogonal direction is suppressed and rectified. The hot water that has passed through the second rectification unit 62c is rectified in the second rectification unit 62d while only disturbance in the direction orthogonal to the vibration plane is suppressed. In addition, the width of the second rectifying unit 62d (the width of the flat surface portion 63) is formed wider than the width of the flow path cross section at the downstream end of the first rectifying unit 62c. For this reason, since the hot water discharged from the first rectifying unit 62c while reciprocally vibrating and discharged outward from the first rectifying unit 62c in the width direction also passes between the two flat portions 63, such hot water In contrast, the second rectifying unit 62d can suppress the disturbance in the direction orthogonal to the vibration plane. Thereby, the spread of the direction orthogonal to the vibration plane of the discharged hot water can be suppressed more effectively.

  Further, the vibration generating element 60 in the present embodiment can be modified in the same manner as the modified example shown in FIGS. That is, also for the vibration generating element 60 in the present embodiment, a side wall surface (not shown) is provided in the second rectifying unit 62d, or the flat part 63 is in contact with the edge of the discharge opening 2a of the shower head body 2. The vibration generating element 60 can be disposed on the surface. That is, since the width of the second rectification unit 62d is sufficiently wide, the hot water discharged from the first rectification unit 62c while vibrating back and forth and the side wall surface (not shown) do not interfere with each other, and the discharged hot water does not enter the side wall surface. There is no direct hit.

  As mentioned above, although preferable embodiment of this invention was described, a various change can be added to embodiment mentioned above. In particular, in the above-described embodiment, the present invention is applied to a shower head. However, an arbitrary water discharge device such as a faucet device used in a kitchen sink, a wash basin or the like, a hot water washing device provided in a toilet seat, etc. The present invention can be applied to. Further, in the above-described embodiment, the shower head is provided with a plurality of vibration generating elements, but the water discharge device can be provided with an arbitrary number of vibration generating elements according to the application, so that a single vibration is generated. It is also possible to configure a water discharge device including an element.

  In the embodiment of the present invention described above, the shape of the passage in the vibration generating element has been described using terms such as “width” and “height” for convenience, but these terms refer to the vibration generating element. The direction in which it is provided is not specified, and the vibration generating element can be used in any direction. For example, the vibration generating element can be used with the “height” direction in the above-described embodiment oriented in the horizontal direction.

DESCRIPTION OF SYMBOLS 1 Shower head which is the water discharging apparatus of 1st Embodiment of this invention 2 Shower head main body 4 Vibration generating element 4a Water discharge port 4b Gutter part 4c Groove 4d Inlet 4e Front end surface 6 Water flow path forming member 6a Shower hose connection member 6b Packing 8 Vibration generating element holding member 8a Element insertion hole 10a Water supply passage 10b Swirl passage 10c First rectification portion 10d Second rectification portion 12 Step portion (peeling portion)
DESCRIPTION OF SYMBOLS 13 Plane part 14 Hot water collision part 30 Vibration generating element 30a Water outlet 30b Spout 30c Groove 30d Inlet 30e Front end surface 32a Water supply passage 32b Swirl passage 32c First rectification part 32d Second rectification part 32e Tapered part 33 Plane part 34 Hot water Collision part 36 Step part (peeling part)
38 vibration generating element 39 second rectifying unit 39a side wall surface 39b base end wall surface 40 vibration generating element 40a water outlet 40b flange 40c groove 40d inflow port 40e distal end surface 42a water supply passage 42b vortex street passage 42c first rectifying portion 42d second rectification Part 43 Plane part 44 Hot and cold collision part 46 Step part (peeling part)
DESCRIPTION OF SYMBOLS 50 Vibration generating element 50a Water outlet 50b Gutter part 50c Groove 50d Inflow port 50e Front end surface 52a Water supply path 52b Vortex line path 52c 1st rectification part 52d 2nd rectification part 53 Plane part 54 Hot water collision part 56 Step part
60 vibration generating element 60a water outlet 60b flange 60c groove 60d inflow port 60e front end surface 62a water supply passage 62b vortex street passage 62c first rectifying portion 62d second rectifying portion 63 flat portion 64 hot water collision portion 66 step portion (peeling portion)
102 Injection nozzle 102a Injection port 104 Feedback flow path 110 Front chamber 110a Wall surface 110b Wall surface 112 Outlet 114 Inlet hole 116 Obstacle

Claims (6)

A water discharge device for discharging hot water from a water discharge port while reciprocatingly vibrating,
A water discharge device body;
A vibration generating element that is provided in the water discharge device main body and discharges the supplied hot and cold water while reciprocally vibrating in a predetermined vibration plane;
The vibration generating element is
A water supply passage through which hot water supplied from the water discharge device body flows, and
It is arranged at the downstream end of the water supply passage so as to close a part of the cross section of the water supply passage, and the hot water guided by the water supply passage collides with the downstream side alternately. Hot water collision part that generates vortex of
A vortex street passage that is provided downstream of the water supply passage and guides the vortex formed by the hot water collision portion while growing;
A passage which is provided on the downstream side of the vortex street passage and suppresses the turbulence in the direction parallel to the vibration plane and the turbulence in the direction perpendicular to the vibration plane in the flow of hot water passing through the vortex street passage. 1 rectifier,
Provided on the downstream side of the first rectifying unit, the disturbance of the flow of hot water that has passed through the first rectifying unit in the direction orthogonal to the vibration plane is suppressed, and the disturbance in the direction parallel to the vibration plane is not suppressed. A second rectification unit;
A water discharge device characterized by comprising:   The water discharge device according to claim 1, wherein the second rectification unit is configured to have a width wider than a width at a downstream end of the first rectification unit.   The water discharge device according to claim 1, wherein the second rectification unit is configured by two plane parts arranged in parallel to the vibration plane.   The water discharge device according to claim 2, wherein the second rectification unit is configured by two plane parts arranged in parallel to the vibration plane.   The width of the vortex street passage is configured to be constant, and the width of the first rectifying section is narrower than the width of the vortex street passage. Water discharge device.   The water discharge device main body includes a discharge opening for inserting the second rectification unit of the vibration generating element, and the vibration generation element is arranged such that the second rectification unit is in contact with an edge of the discharge opening. The water discharging apparatus according to any one of claims 1 to 5, which is attached to the water discharging apparatus main body.