JP2014150822A - Pulse shower device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a pulse shower device which can secure the smooth rotation motion of an impeller and has excellent durability.SOLUTION: A pulse shower device 45 comprises a spray plate 62 having a plurality of shower holes 64 which penetrate the external face from the internal face, and an impeller 72 which is arranged at the upstream side of the spray plate 62, and rotationally moves around a shaft by making a water flow abut on blades 108. The pulse shower device intermittently discharges shower water in a pulse state from the shower holes 64 by the rotation of the impeller 72. A protrusion 124 protruding toward the impeller 72 side is formed at the spray plate 62, and an apex of the protrusion 124 is made to serve as an abutment part 126 which abuts on a supported face 130 at the spray plate 62 side of the impeller 72 opposing the apex at the rotation center, and supports the impeller 72.

Description

  The present invention relates to a shower device, and more particularly to a pulse shower device that intermittently discharges shower water from a shower hole in a pulsed manner.

  Conventionally, as a shower device, a watering plate having a plurality of shower holes penetrating from the inner surface to the outer surface, and an impeller provided on the upstream side of the watering plate and rotating around an axis by applying a water flow to the blades are provided. A pulse shower device that intermittently discharges shower water from a shower hole in a pulsed manner by rotation of an impeller is known.

For example, Patent Document 1 below discloses a structure in which an impeller is provided inside a shower head, and shower water is intermittently discharged from the shower hole of the water spray plate by the rotational movement of the impeller.
Patent Document 2 below also discloses a structure in which an impeller is provided in the shower head, and shower water is intermittently discharged from the shower hole of the water spray plate by the rotational movement of the impeller.

However, those disclosed in Patent Literature 1 and Patent Literature 2 have a large contact area between the support portion of the water spray plate and the supported portion of the impeller with respect to the impeller and a large frictional resistance, and smooth rotation of the impeller. There is a risk of being disturbed.
Further, a large amount of wear debris (wear debris) is generated, and the wear debris is caught in the contact surface between the support portion and the supported portion, thereby further hindering the smooth rotation of the impeller.

  In particular, when the amount of wear debris caught between the support part and the supported part is accumulated due to the progress of wear, the rotational movement of the impeller gradually becomes dull, and finally the rotation becomes insufficient. It may be difficult to ensure the pulse shower function and the service life may be reached.

Japanese Utility Model Publication No. 5-39664 JP 2011-161023 A

  The present invention has been made for the purpose of providing a pulse shower apparatus capable of ensuring a smooth rotational motion of an impeller and having excellent durability against the background described above.

  Thus, according to the first aspect of the present invention, a watering plate provided with a plurality of shower holes penetrating from the inner surface to the outer surface, and provided on the upstream side of the watering plate, is rotated around an axis by applying a water flow to the blades. An impeller, and a pulse shower device that intermittently discharges shower water from the shower hole by the rotation of the impeller, the sprinkler plate is provided with a protrusion that protrudes toward the impeller side, The top portion of the protrusion is formed as a contact portion that contacts the supported surface on the watering plate side of the impeller facing the top portion at the center of rotation and supports the impeller.

  According to a second aspect of the present invention, in the first aspect, an inclined surface or a curved surface that is inclined or curved toward the shower hole is provided around the contact portion.

  According to a third aspect of the present invention, there is provided a watering plate having a plurality of shower holes penetrating from the inner surface to the outer surface, an impeller provided on the upstream side of the watering plate, and rotating around an axis by applying a water flow to the blades. A pulse shower device that intermittently discharges shower water from the shower hole in a pulsed manner by the rotation of the impeller, wherein the impeller is provided with a protrusion protruding toward the watering plate, and the top of the protrusion The abutment side support surface of the water spray plate facing the top portion at the center of rotation and a contact portion supported by the support surface, and including the support surface of the water spray plate The entire surface of the impeller side that overlaps the impeller in plan view is a flat surface.

Effects and effects of the invention

As described above, according to the first aspect of the present invention, the projection that protrudes toward the impeller side is provided on the sprinkler plate, and the top of the projection is brought into contact with the supported surface of the impeller on the sprinkler plate side at the center of rotation to support the impeller. It is a contact part. Here, the supported surface can be a flat surface.
According to this first aspect, it is possible to make the contact portion contact with a contact area as small as possible, such as making the contact portion contact with the supported surface of the impeller in a point shape.
In addition, according to the first aspect, since the contact portion is brought into contact with the supported surface at the rotation center of the impeller, smooth rotation of the impeller can be ensured.

When the contact portion is brought into contact with the supported surface of the impeller at the rotation center of the impeller, the frictional resistance generated between the contact portion and the supported surface is small, and the smooth rotation of the impeller is substantially Is not disturbed.
Even if the abutting portion or the supported surface of the impeller is worn, the amount of generated wear debris is very small, and even if the wear debris is caught between the abutting portion and the supported surface, Since the contact area between the contact portion and the supported surface is very small and the amount of biting into the contact surface is very small, many wear debris are generated as in the case of conventional pulse shower devices. As compared with the case where the bite is bitten over a wide contact area, the adverse effect of the wear residue on the rotation of the impeller is extremely small.
Therefore, according to Claim 1, smooth rotation of an impeller can be ensured over a long period of time, and durability of a pulse shower apparatus can be improved.

According to the first aspect, the upper portion of the protrusion can have a cross-sectional (longitudinal cross-sectional) mountain shape, and the top can be a contact portion.
In this case, the upper portion of the protrusion can be formed in a circular arc shape or other continuous curved shape. Alternatively, as a cone shape such as a cone shape or a pyramid shape, the apex as the apex or the peripheral portion including the apex can be used as the contact portion.
In these cases, the contact portion can be brought into contact with the supported surface of the impeller in a point contact manner or a state close thereto.

Next, according to a second aspect of the present invention, an inclined surface or a curved surface that is inclined or curved toward the shower hole is provided around the contact portion in the first aspect.
According to the second aspect, even when the abutting portion and the supported surface of the impeller are worn and wear debris is generated, the wear debris is guided toward the shower hole by the inclined surface or the curved surface ( It is guided to the shower hole on the flow of water toward the shower hole) and is discharged from the shower hole to the outside together with the shower water. It can be prevented or suppressed more reliably.

In the second aspect of the present invention, when the upper part of the protrusion has a circular arc shape or other curved shape, or a conical shape such as a cone shape or a pyramid shape, the peripheral surface following the apex is the inclined surface or curved surface of claim 2 It can be.
In some cases, the lower peripheral surface of the protrusion can be formed as an inclined surface or a curved surface.
Alternatively, a bulging portion is provided from the inner surface of the water spray plate toward the impeller, the protrusion is raised from the bulging portion, and the peripheral surface of the bulging portion is formed as the inclined surface or the curved surface. You can also.

On the other hand, according to the third aspect of the present invention, the impeller is provided with a protrusion that protrudes toward the sprinkler plate, and the top of the protrusion abuts the support surface of the sprinkler plate on the impeller side at the rotation center and is supported by the support surface. The surface of the impeller side that includes the support surface of the watering plate and that is the contact portion, and the entire portion that overlaps the impeller in plan view is a flat surface.
Also in the third aspect, the contact portion on the impeller side can be brought into contact with the support surface of the water spray plate in a point-like manner, for example, with a contact area as small as possible. The same effect can be obtained.

Also in the third aspect, the lower portion of the protrusion can be formed in the same shape as the upper portion of the protrusion in the first aspect, such as a cross section (vertical cross section) of a mountain shape and a top portion thereof as a contact portion.
The apex or the peripheral part including the apex as the apex can be used as the contact part.
Thereby, a contact part can be made to contact in the point contact or the state close | similar to this with respect to the support surface of a watering board.

  In Claim 3, it is a surface by the side of an impeller including the said support surface of a watering board, and the whole part which overlaps with an impeller by planar view is made into a flat surface, By doing in this way, Even when the top portion of the projection protruding in the direction, that is, the abutting portion is worn and wear debris is generated, the wear debris can be well escaped to the shower hole and discharged to the outside.

It is the figure which showed the water tap provided with the pulse shower apparatus of one Embodiment of this invention. It is the figure which showed the structure of the front-end | tip part of the water discharging pipe of FIG. It is sectional drawing of the pulse shower apparatus of the embodiment. It is the perspective view which decomposed | disassembled and showed the component of the pulse shower apparatus of FIG. It is the figure which showed the impeller of FIG. 4 from the different direction. (A) It is the schematic diagram which showed the relationship between the impeller and shower hole of the embodiment. (B) It is the figure which showed the shower hole interruption | blocking part and shower hole opening | release part of the impeller. It is the figure which showed the principal part of other embodiment of this invention.

Next, embodiments of the present invention will be described in detail with reference to the drawings.
In FIG. 1, 10 is a faucet (in this example, a hot and cold water mixing faucet, which may be simply referred to as a faucet hereinafter), 12 is a water discharge unit installed in an exposed state on the counter, and 14 is arranged under the counter The control function unit 16 is a temperature control function unit arranged further below.
The temperature control function part 16 has a hot water / water mixing valve 20 connected to a pair of crank legs 18 on the water side and hot water side protruding from the wall, inside the cover 22.

The hot and cold water mixing valve 20 mixes water and hot water supplied from the water-side and hot water-side crank legs 18 at a predetermined ratio, and supplies the mixed water toward the water discharger 12 upward in the drawing.
A temperature control handle 24 protrudes downward from the hot water / water mixing valve 20 in the figure.

The control function unit 14 includes an electromagnetic valve 28 as a water discharge valve inside the cover 26 and a control board 30 that controls the operation thereof.
The control function unit 14 opens or closes the electromagnetic valve 28 under the control of the control board 30, thereby causing water discharge and water stop from the water discharge unit 12.

The water discharger 12 includes a water discharge pipe 32 that stands on the counter, and an operation panel 38 that extends laterally from the root of the water discharge pipe 32 along the counter.
The operation panel 38 is provided with an operation switch 50 for changing the water discharge form.
Here, the operation switch 50 is a water discharge switch that continuously discharges or stops water from the water discharge port 40 by a manual operation regardless of whether or not a human body detection sensor 42 described below is detected.

  On the upper end side of the water discharge pipe 32, a pulse shower device (hereinafter simply referred to as a shower device) 45 including a cylindrical water discharge port 40 is provided, and further, an inserted hand or the like is detected at an upper position thereof. A human body detection sensor 42 is provided.

The faucet 10 in this example is an automatic faucet, and when the human body detection sensor 42 detects a hand or the like, the electromagnetic valve 28 is opened under the control of the control board 30 in the control function unit 14, The mixed water from the hot and cold water mixing valve 20 in the adjustment function unit 16 is automatically discharged from the water discharge port 40.
Further, when the human body is not detected, the electromagnetic valve 28 is closed, and water discharge from the water discharge port 40 is automatically stopped.

From the water discharge pipe 32, a male screw pipe 34 extends downward.
The water discharge pipe 32 and the operation panel 38 are attached and fixed to the counter by the male screw pipe 34 and the tightening nut 36.
Specifically, the male screw tube 34 is inserted through the mounting hole of the counter and protrudes to the back side thereof, and a tightening nut 36 is screwed into the protruding portion, and this is tightened to the back side of the counter via the triangular packing 37. The water discharge pipe 32 and the operation panel 38 are installed in a fixed state on the counter.

Inside the water discharge pipe 32, a water supply tube 44 whose one end is connected to the water discharge port 40 and the human body detection sensor 42, respectively, and the sensor wiring 46 pass.
The water supply tube 44 and the sensor wiring 46 respectively extend downward from the water discharge pipe 32 through the inside of the male screw pipe 34.
Similarly, the switch wiring 52 extending from the operation panel 38 extends downward through the male screw pipe 34.
The water supply tube 44 is connected to the solenoid valve 28 of the control function unit 14, and the sensor wiring 46 and the switch wiring 52 are also connected to the control board 30 of the control function unit 14.
The water discharge pipe 32 is also provided with a pull bar 48 for operating a pop-up drain plug that opens and closes a drain port of a water tank (not shown).

As shown in FIG. 2, a holding member 54 that holds a shower device 45 including a water discharge port 40 and a human body detection sensor 42 is disposed at the distal end portion of the water discharge pipe 32, and is fixed to the main body of the water discharge pipe 32. .
The holding member 54 has a tubular connection portion 56, and the water supply tube 44 is connected to the connection portion 56 in an inserted state.
The holding member 54 also has a closing portion 58, and the opening 60 at the distal end portion of the water discharge pipe 32 is closed at the closing portion 58.

On the lower surface of the water discharge port 40, a water spray plate 62 constituting an element of the shower device 45 is provided.
A large number of shower holes 64 penetrating from the inner surface to the outer surface (lower surface) are arranged in the watering plate 62 so as to form a double concentric circle.
In the figure, 64-1 indicates an outer peripheral shower hole, and 64-2 indicates an inner peripheral shower hole.

3 and 4 show a specific configuration of the shower apparatus.
As shown in the figure, the shower device 45 includes a cylindrical water discharge port 40 as a case, a cap 66, a nozzle sheet 68, a nozzle sheet presser 70, an impeller 72, and a water flow injection member 74 disposed on the inside. And have.
Here, each member other than the nozzle sheet 68 is made of a hard resin.

As shown in FIG. 3, the water discharge port 40 has a cylindrical small-diameter portion 76 at the top in the drawing. A male screw portion 78 is provided on the outer peripheral surface of the small diameter portion 76.
On the other hand, the holding member 54 is provided with a corresponding cylindrical portion 80. An internal thread portion 82 is provided on the inner peripheral surface of the cylindrical portion 80.
The water discharge port 40 is assembled and held in the holding member 54 by screw coupling of the male screw portion 78 of the small diameter portion 76 and the female screw portion 82 of the cylindrical portion 80.
The water outlet 40 and the holding member 54 are sealed in a watertight manner by a ring-shaped elastic seal member 84 as shown in FIG.

The cap 66 has a cylindrical peripheral wall portion 86 and a bottom portion 88.
A number of insertion holes 90 corresponding to the shower holes 64 are provided in the bottom portion 88 so as to penetrate the bottom portion 88.
On the other hand, the peripheral wall portion 86 is provided with a male screw portion 92 on the outer peripheral surface.
The cap 66 is screwed into the female screw portion 94 formed on the inner peripheral surface of the lower portion on the large diameter side of the water discharge port 40 at the male screw portion 92, and is screwed to the water discharge port 40.

As shown in FIG. 4, the cap 66 is provided with notched vertical grooves 101 at three locations in the circumferential direction of the peripheral wall portion 86.
The cap 66 is watertightly sealed between the cap 101 and the water discharge port 40 by an elastic O-ring 102 as shown in FIG.

In this embodiment, the water spray plate 62 has a three-layer structure including a bottom portion 88 of the cap 66, a sheet portion 96 of the nozzle sheet 68 superimposed on the bottom portion 88, and a nozzle sheet presser 70 superimposed thereon. ing.
The nozzle sheet 68 is made of rubber (may be made of another elastomer material). The nozzle sheet 68 includes a sheet portion 96 and a number of nozzle portions 98 protruding downward from the sheet portion 96. Each nozzle portion 98 is inserted through an insertion hole 90 formed in the bottom portion 88 of the resin cap 66, and each tip portion protrudes downward.
The plurality of nozzle portions 98 have nozzle holes 64A therein, and the lower portions of the shower holes 64 are formed by the nozzle holes 64A.

The sheet portion 96 of the nozzle sheet 68 has a curved shape such that the lower surface in the drawing is convex downward and the upper surface in the drawing is concave downward, and the nozzle portion 98 has a shape that rises perpendicularly from the lower surface. Is formed integrally with the seat portion 96.
Correspondingly, the lower surface of the nozzle presser 70 has a convex curved surface corresponding to the concave curved surface of the sheet portion 96 of the nozzle sheet 68.

The nozzle sheet presser 70 is provided with a plurality of through-holes 64B communicating with the nozzle holes 64A and forming the upper part of the shower holes 64.
In this nozzle sheet presser 70, as shown in FIG. 4, pressed portions 104 that receive a force from the presser foot 120 in a water jet member 74, which will be described later, protrude radially outward at three locations in the circumferential direction. Is provided.
The nozzle sheet presser 70 is incorporated in the cap 66 so that the pressed parts 104 are fitted in the groove 101 of the cap 66.

An impeller 72 is rotatably arranged on the upper side (upstream side) of the nozzle sheet presser 70 in the drawing.
As shown in FIG. 5, the impeller 72 has a bottomed cylindrical fitting portion 106 having a shape in which the lower end in the drawing is closed at the center, and this fitting portion 106 is a water jet member. 74 is fitted to a shaft 118 described later.
The impeller 72 is rotated around the shaft portion 118 based on the fitting between the shaft portion 118 and the fitting portion 106.

The impeller 72 has many blades 108 extending in a partial spiral shape from the center side toward the outer peripheral side at a constant pitch in the circumferential direction.
The impeller 72 also has a shower hole blocking portion 110 that extends at a predetermined circumferential length along the inner surface of the nozzle sheet presser 70 on the lower surface side in the drawing and partially closes the lower surface of the impeller 72 in the drawing. .
The shower hole blocking unit 110 partially covers and blocks the many communication holes 64B of the nozzle sheet presser 70, that is, the many shower holes 64.

The impeller 72 also includes a shower hole opening portion 112 opened toward the inner surface of the water spray plate 62, specifically, the inner surface of the nozzle sheet presser 70, in a portion excluding the shower hole blocking portion 110. Has two separate places.
Here, the pair of shower hole opening portions 112 extends while maintaining substantially the same width dimension from the inner peripheral end to the outer peripheral end.
Here, the ratio of the width dimension (circumferential length) X ₁ (see FIG. 6) of the inner circumferential side end to the total circumferential length on the same circumference is 0.18, and the width dimension of the outer circumferential end ( circumferential length) X _2, the ratio to the total perimeter on the same circumference is 0.06.

  The impeller 72 is also provided with an annular connecting portion 114 that connects the outer peripheral end of each blade 108 and the shower hole blocking portion 110 so as to stand up from the shower hole blocking portion 110.

In FIG. 3, a water jet member 74 is disposed on the upper side of the impeller 72 in the drawing.
The water flow injection member 74 introduces water flowing from the upstream side into the injection hole 116 and allows it to pass therethrough. Then, the passing water is applied as a jet water flow to the blades 108 of the lower impeller 72 in the figure, and the impeller 72 is rotationally driven.
Here, the direction of the injection hole 116 is determined so that the injection water flow hits the concave surface side of the blade 108 forming a partial spiral shape of the impeller 72.
The water flow injection member 74 has a shaft portion 118 protruding downward from the central portion thereof, and the fitting portion 106 of the impeller 72 is rotatably fitted to the shaft portion 118.

As shown in FIG. 4, the water jet member 74 is also provided with a presser leg 120 that falls downward from three places in the circumferential direction on the outer peripheral portion.
These presser legs 120 are fitted downward into the vertical grooves 101 of the cap 66, and the lower ends of the presser legs 120 are pressed against the pressed portions 104 of the nozzle sheet presser 70, thereby pressing them downward. That is, a downward force is applied to the nozzle sheet presser 70.
The nozzle sheet presser 70 receives the downward force and presses the nozzle sheet 68 toward the bottom 88 of the cap 66.

In this embodiment, at the center of the nozzle sheet presser 70, that is, the rotation center of the impeller 72, as shown in FIG. 4, a projection 124 is provided that protrudes upward from the inner surface 122 in the drawing toward the impeller 72. ing.
The upper part of the protrusion 124 has a cross-sectional (vertical cross-sectional) mountain shape. Specifically, here, the upper part has a partial spherical shape, and the cross-sectional shape is an arc shape with a radius R.

And the vertex is made to contact | abut on the lower surface of the impeller 72 in the rotation center of the impeller 72, as shown in the partial enlarged view of FIG.
That is, here, the apex of the projection 124 forms a contact portion 126 that contacts the supported surface 130 that is a part of the lower surface of the impeller 72 and supports the impeller 72 from below.

In this embodiment, the entire impeller 72 has a flat surface in the direction perpendicular to the axis that is orthogonal to the axis of the impeller 72, and thus the supported surface 130 is also a flat surface.
Similarly, the entire inner surface (upper surface in the drawing) of the nozzle sheet presser 70 is also a flat surface.
However, in some cases, a portion other than the supported surface 130 on the lower surface of the impeller 72 may have another shape.

The protrusion 124 forms a curved surface that moves toward the inner surface 122 of the nozzle sheet presser 70 as it moves away from the contact portion 126, specifically, an arc surface 128 here.
This arc surface 128 is directed toward the inner surface 122 of the nozzle sheet retainer 70 when the abutting portion 126 and the supported surface 130 are worn with the rotational movement of the impeller 72, that is, the communication hole. It has the function of guiding the discharge toward 64B (that is, the shower hole 64).

The shower device 45 of this embodiment can be assembled as follows.
First, the nozzle sheet 68, the nozzle sheet presser 70, the impeller 72, and the water flow injection member 74 are stored in the cap 66.
In that state, the cap 66 is screwed upward with respect to the cylindrical water discharge port 40. Then, the nozzle sheet 68, the nozzle sheet retainer 70, the impeller 72, and the water flow injection member 74 are lifted, and the water flow injection member 74 hits the shoulder portion 132 (see FIG. 3) of the water discharge port 40, and the cap 66 The internal members, specifically, the nozzle sheet 68, the nozzle sheet presser 70, the impeller 72, and the water flow injection member 74 are fixed.

  At this time, a downward force is applied to the presser foot 120 of the water jet member 74 by the upward screwing force of the cap 66, and the presser foot 120 presses the nozzle sheet presser 70 against the nozzle sheet 68, thereby pressing it downward.

In this state, when water flows from the upstream side, the water flows through the injection hole 116 of the water flow injection member 74, and at that time, the passing water becomes the injection water flow and hits the blade 108 of the impeller 72, Rotate this.
And the shower hole 64 is interrupted | blocked and open | released intermittently by the rotational motion of the impeller 72, and shower water is intermittently discharged from the shower hole 64 in a pulse form.

As described above, according to the present embodiment, the contact portion 126 can be brought into contact with the supported surface 130 of the impeller 72 in a dot shape.
In addition, in the present embodiment, since the contact portion 126 is brought into contact with the supported surface 130 at the rotation center of the impeller 72, smooth rotation of the impeller 72 can be ensured.

When the contact portion 126 is brought into contact with the supported surface 130 of the impeller 72 at the rotation center of the impeller 72, the frictional resistance generated between the contact portion 126 and the supported surface 130 is small, and the impeller 72 The smooth rotation is not substantially inhibited.
Even if the contact portion 126 and the supported surface 130 of the impeller 72 are worn, the amount of generated wear debris is very small, and the wear residue is bitten between the contact portion 126 and the supported surface 130. Even if it is inserted, the contact area between the contact portion 126 and the supported surface 130 is very small, and the amount of biting into the contact surface is very small. Compared with the case where the wear residue is bitten over a wide contact area, the adverse effect of the wear residue on the rotation of the impeller 72 is extremely small.
Therefore, according to this embodiment, the smooth rotation of the impeller 72 can be ensured over a long period of time, and the durability of the pulse shower device 45 can be enhanced.

  In the present embodiment, an arc surface (partial spherical surface) 128 as a curved surface having a cross-sectional shape curved toward the shower hole 64 is provided around the contact portion 126, and the contact portion 126 and the impeller are provided. Even when the supported surface 130 of 72 is worn and wear debris is generated, the wear debris is guided toward the shower hole 64 by the arc surface 128 (the shower hole rides on the flow of water toward the shower hole 64). 64) and discharged to the outside together with the shower water from the shower hole 64, it is possible to more reliably prevent or inhibit the smooth rotation of the impeller 72 due to the remaining wear debris remaining. it can.

Next, FIG. 7 shows another embodiment of the present invention.
In this example, at the rotation center of the impeller 72, a protrusion 134 is provided that protrudes from the lower surface of the impeller 72 in the drawing toward the water spray plate 62, specifically toward the nozzle sheet presser 70.
Here, the shape of the protrusion 134 is the same as that of the protrusion 124 shown in FIG. 3 except that the vertical direction in the drawing is opposite. However, other shapes are also possible.

Also in this example, as shown in the partially enlarged view of FIG. 7, the apex of the protrusion 134 is brought into contact with the upper surface of the nozzle sheet presser 70, that is, the inner surface 122 thereof.
Here, the apex of the protrusion 134 abuts on a support surface 136 that is a part of the inner surface 122 of the nozzle sheet presser 70, and forms a contact portion 138 that is supported by the support surface 136.

  In this embodiment, the entire lower surface of the impeller 72 (excluding the protrusion 134) and the entire upper surface (inner surface 122) of the nozzle sheet retainer 70 (excluding the portion where the pressed portion 104 is formed) This is the same as the first embodiment shown in FIGS. 3 to 6 in that a flat surface is formed in the direction perpendicular to the axis that is orthogonal to the axis.

  However, when the nozzle sheet presser 70 has a shape projecting radially outward from the impeller 72 in a plan view, the entire portion of the inner surface 122 of the nozzle sheet presser 70 that overlaps the impeller 72 in a plan view It is also possible to make a flat surface, and a portion protruding radially outward from the impeller 72 in a plan view may be a surface having a shape different from such a flat surface.

  In the embodiment shown in FIG. 7, the contact portion 138 on the impeller 72 side is made as small as possible, for example, in contact with the support surface 136 on the nozzle sheet presser 70 side, that is, the water spray plate 62 side. It is possible to make contact with the contact area, and the same effect as the first embodiment shown in FIGS. 3 to 6 can be obtained.

  In the embodiment of FIG. 7, the inner surface 122 including the support surface 136 of the nozzle sheet presser 70 is a flat surface in detail, and the entire portion overlapping the impeller 72 in plan view is a flat surface. Even when the wear is worn, the worn debris can be released to the communication hole 64B of the nozzle sheet presser 70, that is, the shower hole 64, and discharged to the outside.

  Although the embodiment of the present invention has been described in detail above, this is merely an example, and the present invention can be configured in various forms without departing from the spirit of the present invention.

45 Shower device 62 Sprinkler plate 64 Shower hole 72 Impeller 108 Blade 124, 134 Protrusion 126, 138 Contact portion 128 Arc surface (curved surface)
130 Supported surface 136 Supported surface

Claims (3)

A watering plate having a plurality of shower holes penetrating from the inner surface to the outer surface;
An impeller provided on the upstream side of the sprinkling plate and rotating around the axis by applying a water flow to the blades, and the pulse of intermittently discharging shower water from the shower hole by the rotation of the impeller In the shower device,
The sprinkler plate is provided with a protrusion that protrudes toward the impeller, and the top of the protrusion abuts the supported surface of the impeller opposite the top at the sprinkler plate side at the center of rotation. A pulse shower device characterized in that it comprises a contact portion for supporting.   2. The pulse shower apparatus according to claim 1, wherein an inclined surface or a curved surface that is inclined or curved toward the shower hole is provided around the contact portion. A watering plate having a plurality of shower holes penetrating from the inner surface to the outer surface;
An impeller provided on the upstream side of the sprinkling plate and rotating around the axis by applying a water flow to the blades, and the pulse of intermittently discharging shower water from the shower hole by the rotation of the impeller In the shower device,
The impeller is provided with a protrusion that protrudes toward the sprinkler plate, and the top of the protrusion abuts the support surface of the sprinkler plate that faces the top at the impeller side at the center of rotation. A contact portion supported by
A pulse shower apparatus characterized in that the surface of the water spray plate on the impeller side including the support surface and the entire portion overlapping the impeller in a plan view is a flat surface.

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