JP2019097881A - shower head - Google Patents

Abstract

To provide a shower head that can reduce unevenness in an amount of microbubbles in liquid discharged from a spray hole.SOLUTION: A shower head 1 comprises a connection part 11 connected to a water supply pipe, and a spray part 12 continuous with the connection part 11. The spray part 12 comprises a microbubble generation part 2, a diffusion part 3, a discharge port 31 penetrating the diffusion part 3, and a water division plate 4 arranged so as to face the diffusion part 3. The microbubble generation part 2 comprises a microbubble generation hole 21 for generating microbubbles in liquid. A storage space 30 for storing the liquid is formed between the diffusion part 3 and the microbubble generation part 2. The diffusion part 3 can diffuse the liquid passed through the microbubble generation hole 21 into the storage space 30. The discharge hole 31 can discharge the liquid to the outside from the inside of the storage space 30. The water division plate 4 comprises a spray hole 421 for spraying the liquid passed through the discharge hole 31.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a shower head.

  Microbubbles having a diameter of several tens of micrometers or less called microbubbles are applied to various fields because they have unique properties that are not found in bubbles of a general size. For example, for the purpose of promoting skin beauty and health, a technique has been proposed in which water or hot water containing microbubbles is sprayed from a shower head.

  For example, Patent Document 1 describes a technique of generating microbubbles by a Venturi tube incorporated in a showerhead and dispersing water or hot water containing the microbubbles from the showerhead. In the shower head of Patent Document 1, downstream of the venturi pipe, there are provided a large number of spray holes and a water distribution plate for spraying water outside the shower head. The water that has passed through the venturi pipe travels straight toward the water distribution plate, and is dispersed out of the shower head from a number of water injection holes provided in the water distribution plate.

JP 2011-115771 A

  As described above, in the shower head of Patent Document 1, the water that has passed through the venturi pipe goes straight toward the water distribution plate and is sprayed out of the shower head through the spray holes. Therefore, at the position facing the outlet of the venturi, the amount of microbubbles in the water discharged from the distribution hole tends to be relatively large. On the other hand, at positions away from the venturi outlet, the amount of microbubbles in the water discharged from the spray holes tends to be relatively small.

  Therefore, when the shower head of Patent Document 1 is used, a portion in contact with water containing a relatively large amount of microbubbles and a portion in contact with water containing a relatively small amount of microbubbles tend to occur on the skin surface. As a result, the action by the microbubbles may be uneven.

  The present invention has been made in view of the above background, and an object of the present invention is to provide a shower head capable of suppressing the deviation of the amount of micro bubbles in the liquid discharged from the spray hole.

One aspect of the present invention is a shower head including a connection portion for connection to a water supply pipe, and a dispersion portion connected to the connection portion for dispersing a liquid supplied from the water supply pipe,
The spreading unit is
A microbubble generation unit having a microbubble generation hole configured to generate microbubbles in the liquid by passing the liquid;
A diffusion portion disposed so as to form a storage space for storing the liquid between the microbubble generation portion and the diffusion portion for diffusing the liquid having passed through the microbubble generation hole into the storage space;
A discharge hole for discharging the liquid from inside the storage space through the diffusion portion;
And a water distribution plate disposed to face the diffusion portion, the water distribution plate including: a distribution hole for distributing the liquid that has passed through the discharge hole;
It is in the shower head.

  The shower head has a diffusion unit between a microbubble generation unit for generating microbubbles and a water distribution plate for dispersing a liquid. The diffusion unit is disposed such that a storage space for storing the liquid is formed between the diffusion unit and the microbubble generation unit, and is configured to be able to diffuse the liquid discharged from the microbubble generation hole into the storage space. It is done.

  In the shower head, the liquid discharged from the micro bubble generation hole goes straight from the micro bubble generation hole, and the direction of the flow is changed by the diffusion portion, and the liquid is diffused into the storage space. Therefore, it is possible to prevent the liquid that has passed through the microbubble generation holes from directly reaching the water distribution plate.

  Moreover, the liquid in the storage space can be stirred by the liquid being diffused into the storage space by the diffusion unit. Therefore, the bias of the amount of microbubbles contained in the liquid can be reduced in the storage space. Then, the liquid in the storage space is discharged from the discharge holes to the water distribution plate side, and further discharged from the water distribution plate from the water distribution plate to the outside of the shower head through the dispersion holes, so that The bias of the amount of micro bubbles can be suppressed.

  As a result of the above, according to the shower head, it is possible to suppress the deviation of the amount of microbubbles in the liquid discharged from the spray hole.

It is a perspective view of a shower head in an example. It is a disassembled perspective view of FIG. It is a front view of a shower head in an example. It is an expansion perspective view of a connection part in the state where an adapter was removed in an example. It is a partially expanded sectional view which shows the principal part of a spraying part in an Example. It is a partially expanded view of the connection part in the VI-VI line arrow cross section of FIG. FIG. 7 is a partially enlarged view showing the positional relationship between the microbubble generation unit and the microbubble amount adjustment unit in a state in which the knob of the outer plate is set to the first position. FIG. 7 is a partially enlarged view showing the positional relationship between the microbubble generation unit and the microbubble amount adjustment unit in a state in which the knob of the outer plate is set to the second position. FIG. 10 is a partially enlarged view showing the positional relationship between the microbubble generation unit and the microbubble amount adjustment unit in a state in which the knob of the outer plate is set to the third position. FIG. 6 is a partial arrow sectional view taken along line X-X in FIG. It is a perspective view of a micro bubble generation part in an example. It is a perspective view of a diffusion part in an example. It is a perspective view of the amount adjustment part of micro bubbles in an Example. It is a top view of an adapter in an example. FIG. 7 is a plan view of another aspect of the adapter. FIG. 10 is a plan view of yet another aspect of the adapter.

  In the shower head, the liquid supplied from the water supply pipe may be, for example, water or hot water. Alternatively, a cartridge containing a drug solution such as a cosmetic may be attached to the shower head, and the drug solution may be mixed with water or hot water in the shower head to disperse water or hot water containing the drug solution from the shower head.

  The liquid supplied from the water supply pipe flows into the shower head from the connection portion and is guided to the microbubble generation portion. Then, the microbubbles are formed in the liquid by passing through the microbubble generation holes provided in the microbubble generation part. The microbubble generation hole may be, for example, an orifice configured to increase the pressure of the liquid on the inlet side and reduce the pressure of the liquid on the outlet side.

  As the reason why the microbubbles are formed in the liquid by the orifice, for example, the following reasons can be considered. At the inlet of the orifice, the cross-sectional area of the flow passage becomes sharply smaller than that on the upstream side of the orifice. Therefore, it is presumed that the pressure of the liquid present near the inlet of the orifice increases, and the amount of gas that can be dissolved in the liquid increases. Therefore, it is presumed that a large amount of gas is dissolved in the liquid present near the inlet of the orifice as compared to the liquid immediately after being supplied from the water supply pipe.

  On the other hand, at the outlet of the orifice, the flow passage cross-sectional area is larger than in the orifice, so the pressure of the liquid is reduced. This is estimated to reduce the amount of gas that can be dissolved in the liquid compared to the liquid present near the inlet of the orifice. Therefore, it is estimated that microbubbles are formed at the outlet of the orifice due to supersaturation of the gas dissolved in the liquid.

  A diffusion unit is disposed downstream of the microbubble generation unit. The diffusion portion is disposed such that a storage space for storing the liquid is formed between the diffusion portion and the microbubble generation portion so that the liquid having passed through the microbubble generation hole can be diffused into the storage space It is configured. The diffusion portion has, for example, a shielding plate disposed to block the flow of the liquid passing through the micro bubble generation hole, and a rectifying plate or the like changing the flow direction of the liquid passing through the micro bubble generation hole It is also good.

  The diffusion unit may be configured to be able to diffuse at least a part of the liquid discharged from the micro bubble generation hole into the storage space. Thus, the liquid discharged from the micro bubble generation hole can be prevented from directly reaching the water dividing plate, and the liquid in the storage space can be stirred. As a result, it is possible to suppress the deviation of the amount of microbubbles in the liquid discharged from the spray hole.

  The diffusion portion is preferably disposed at a position overlapping the microbubble generation hole in a plan view as viewed from the flow direction of the liquid. The liquid that has passed through the microbubble generation hole usually travels straight from the microbubble generation hole. Therefore, by disposing the diffusion portion at a position overlapping the microbubble generation hole, that is, in front of the microbubble generation hole, the flow of the liquid is blocked by the diffusion portion, and the liquid passing through the microbubble generation hole directly reaches the water dividing plate Can be prevented. Furthermore, in this case, the liquid that has passed through the microbubble generation hole can be reliably diffused into the storage space, and the liquid in the storage space can be sufficiently agitated. As a result, it is possible to more effectively suppress the deviation of the amount of microbubbles in the liquid discharged from the spray holes.

  The flow passage cross-sectional area of the discharge holes is preferably 5 to 30% of the flow passage cross-sectional area of the storage space. When the flow passage cross-sectional area of the discharge hole is excessively small, the amount of liquid discharged from the discharge hole tends to be small. Therefore, the amount of liquid sprayed from the shower head may be insufficient. On the other hand, when the flow passage cross-sectional area of the discharge hole is excessively large, the amount of liquid discharged from the discharge hole tends to be large. Therefore, the momentum of the liquid sprayed from the shower head becomes excessively strong, which may cause the user to feel uncomfortable.

  By setting the flow passage cross-sectional area of the discharge hole to the specific range, the amount of liquid discharged from the discharge hole can be made into a range without excess or deficiency, and the occurrence of the above-mentioned problems can be more reliably avoided. Furthermore, by making the flow passage cross-sectional area of the discharge hole the specific range, the residence time of the liquid in the storage space can be made longer, and the liquid in the storage space can be sufficiently agitated. As a result, it is possible to more effectively suppress the deviation of the amount of microbubbles in the liquid discharged from the spray holes.

  In addition, the flow-path cross-sectional area of the discharge hole mentioned above is an opening area of the discharge hole in planar view seen from the storage space side. For example, when the flow passage cross-sectional area of the discharge hole changes according to the position, such as when the opening area of the discharge hole decreases as going from the storage space side to the water distribution plate side, the smallest flow passage cross-sectional area The value is taken as the flow passage cross-sectional area of the discharge hole.

  Similarly, the flow passage cross-sectional area of the storage space is the opening area of the storage space in plan view as viewed from the microbubble generation portion side. Also, for example, when the flow passage cross-sectional area of the storage space changes in accordance with the position, the value of the smallest flow passage cross-sectional area is taken as the flow passage cross-sectional area of the storage space.

  The embodiment of the shower head will be described with reference to FIGS. The shower head 1 includes, as shown in FIGS. 1 and 3, a connection portion 11 for connection to a water supply pipe, and a spray portion 12 connected to the connection portion 11 for dispersing a liquid supplied from the water supply pipe. have. As shown in FIGS. 2 and 5, the dispersing unit 12 includes a microbubble generating unit 2, a diffusing unit 3, a discharge hole 31 penetrating the diffusing unit 3, and a water dividing member disposed facing the diffusing unit 3. And a plate 4.

  As shown in FIGS. 5 and 11, the microbubble generation unit 2 has a microbubble generation hole 21 configured to be able to generate microbubbles in the liquid by passing the liquid. As shown in FIG. 5, the diffusion unit 3 is disposed such that a storage space 30 for storing the liquid is formed between the diffusion unit 3 and the microbubble generation unit 2, and the liquid passing through the microbubble generation unit 2 is It can be diffused into the storage space 30. The discharge hole 31 can discharge the liquid from the inside of the storage space 30 to the outside. The water distribution plate 4 has a spray hole 421 for spraying the liquid that has passed through the discharge hole 31. Hereinafter, the configuration of the shower head 1 of this example will be described in detail.

  As shown in FIG. 1 and FIG. 3, the shower head 1 of the present example is provided with a rod-like grip portion 13, a connection portion 11 provided at one end of the grip portion 13, and the other end of the grip portion 13. And a spray unit 12. The spreader 12 is curved so as to protrude outward in the radial direction of the grip 13. Further, a water dividing plate 4 directed radially outward of the grip portion 13 is disposed at the tip end of the spray portion 12, and the liquid supplied from the water supply pipe is dispersed radially outward of the grip portion 13. It is configured to be able to.

  In the following, when the shower head 1 is disposed such that the spray unit 12 protrudes forward, a portion observable in a plan view seen from the spray unit 12 side is referred to as “front 101” of the shower head 1 The part which can not be done is called "the back 102" of the shower head 1 (refer FIG. 1, FIG. 3). More specifically, the front face 101 of the shower head 1 is a portion visible to the user when the shower head 1 is hung on the hook provided on the wall surface of the bathroom so that the spray unit 12 protrudes forward. It is. Moreover, the back surface 102 of the shower head 1 is a part which faces a wall surface, when the shower head 1 is hung so that the spreading part 12 may protrude ahead on the hook provided in the wall surface of the bathroom.

  As shown in FIG. 1, FIG. 2 and FIG. 6, the connection portion 11 includes an adapter 5 removably connected to a water flow pipe 71 described later and an adapter cover 51 covering the side circumferential surface of the adapter 5. Have. The adapter 5 has various shapes corresponding to the shape of the joint part in the shower hose as a water supply pipe like adapters 5a-5c shown, for example to FIGS. 14-16. The shower head 1 of this example can be connected to various shower hoses by attaching an appropriate adapter 5 according to the shape of the joint portion in the shower hose.

  As shown in FIGS. 1 to 3, the outer wall of the grip 13 and the sprayer 12 in the shower head 1 is composed of an outer tube 6. Moreover, as shown in FIG.5 and FIG.6, the water flow part 7 for distribute | circulating the liquid supplied from a shower hose is arrange | positioned inside the outer tube part 6. As shown in FIG. A gap is formed between the outer pipe portion 6 and the water flow portion 7.

  As shown in FIG. 2, the outer tube portion 6 has an outer tube portion main body 61 opened to the spray portion 12 side and the connection portion 11 side, and an annular shape, and the open end of the outer tube portion body 61 on the spray portion 12 side And an annular lid 62 attached thereto. As shown in FIG. 3 and FIG. 5, the water dividing plate 4 is rotatably fitted in the inside of the annular lid 62.

  As shown in FIG. 5 and FIG. 6, the water flow portion 7 is disposed inside the outer pipe portion 6. The water flow portion 7 includes a water flow pipe 71 extending over the entire length of the grip portion 13 and a cup portion 72 connected to the water flow pipe 71 and disposed in the spray portion 12.

  As shown in FIGS. 4 and 6, an end of the water flow pipe 71 on the connection portion 11 side protrudes from the outer pipe portion main body 61. Moreover, the water flow pipe 71 is connected to the adapter 5 of the connection part 11 via the O-ring 711 as shown in FIG. A strainer 712 is disposed between the water flow pipe 71 and the connection portion 11 to filter out foreign substances in the liquid supplied from the shower hose. Further, on the upstream side of the strainer 712 at the end on the connection portion 11 side of the water flow pipe 71, a check valve 713 for preventing backflow of liquid from the shower head 1 to the shower hose is accommodated in a removable state It is done.

  As shown in FIG. 4, at an end of the water flow pipe 71 on the connection portion 11 side, a flange portion 714 protruding outward in the radial direction of the water flow pipe 71 and a joint portion 715 for connecting to the adapter 5 are provided. It is done. The collar portion 714 is extended over the entire circumference of the water flow pipe 71. Further, in the case where the shower head 1 is disposed such that the back surface 102 of the shower head 1, that is, the spray unit 12 protrudes forward (see FIG. 3), the ridge portion 714 is viewed in plan from the spray unit 12 side. In the part which can not be observed, two notches 716 are provided.

  More specifically, the two notches 716 are spaced apart from each other on the back half of the ridge 714. In addition, the notch 716 is expanded as it goes outward in the circumferential direction of the water flow pipe 71. In the shower head 1 of the present example, a water draining hole 710 is formed between the outer pipe portion main body 61 and the water flow pipe 71 by the notches 716. The drainage hole 710 can discharge the liquid accumulated in the gap between the outer pipe portion 6 and the water flow portion 7 from the back side of the shower head 1.

  As shown in FIG. 5, the end of the water flow pipe 71 on the side of the spray portion 12 is inserted into the cup portion 72. Further, an O-ring 717 is interposed between the water flow pipe 71 and the cup portion 72.

  As shown in FIG.2 and FIG.5, the cup part 72 is exhibiting the cup shape opened to the water dividing plate 4 side. The cup portion 72 has two fastening holes 721 at its bottom surface, and is fastened to the outer tube portion main body 61 via a screw 722 inserted into the fastening hole 721. The opening end 723 of the cup portion 72 is in contact with a substrate 41 of a water dividing plate 4 described later.

  As shown in FIG. 5, the microbubble generation unit 2 and the diffusion unit 3 are accommodated in the cup unit 72. As shown in FIG. 11, the micro-bubble generating unit 2 has three fastening holes 221 in the outer peripheral edge 22 thereof. As shown in FIG. 5, the micro-bubble generating unit 2 is fastened to the cup portion 72 via a screw 222 inserted in the fastening hole 221. Further, an inlet space 20 for temporarily storing the liquid flowing in from the water flow pipe 71 is formed between the cup portion 72 and the microbubble generation portion 2.

  As shown in FIG. 11, the microbubble generation unit 2 has a plurality of microbubble generation holes 21 for generating microbubbles, and a large diameter hole 23 having a flow passage area larger than that of the microbubble generation holes 21. doing. The micro bubble generation hole 21 and the large diameter hole 23 penetrate the micro bubble generation portion 2 and open to both the inlet space 20 and the storage space 30. Further, at the center of the microbubble generation unit 2 in a plan view as viewed from the entrance space 20 side, a shaft portion insertion hole 24 penetrating the microbubble generation unit 2 is provided. A shaft 82 of a microbubble amount adjustment unit 8 described later is inserted into the shaft insertion hole 24.

  As shown in FIGS. 7-9, the micro bubble generation part 2 of this example has eight micro bubble generation holes 21 (21a, 21 b). Of the eight microbubble generation holes 21, the three microbubble generation holes 21 a arranged at the outermost side are located on the outer peripheral side of the adjusting plate 81 described later. Further, the micro bubble generation holes 21 b arranged inside the three micro bubble generation holes 21 a are arranged at positions where they can be covered by the adjusting plate 81.

  The micro bubble generation holes 21 have a circular cross-sectional shape in a plan view as viewed from the flow direction of the liquid. In addition, as shown in FIG. 5, the microbubble generation hole 21 has the smallest opening diameter at the opening end on the inlet space 20 side, and the opening diameter gradually increases toward the storage space 30 side, The opening end on the space 30 side has the largest opening diameter.

  As shown in FIGS. 7-9, the micro bubble generation part 2 of this example has two large diameter holes 23. The large diameter hole 23 has an arc-like cross-sectional shape in a plan view as viewed from the flow direction of the liquid. Although not shown, the large diameter hole 23 has a constant cross-sectional shape over the entire length from the opening end on the inlet space 20 side to the opening end of the storage space 30. In addition, the large diameter hole 23 of this example does not have the function to form a micro bubble. The liquid flowing from the inlet space 20 into the large diameter hole 23 flows out to the storage space without containing the microbubbles.

  As shown in FIG. 5, the diffusion unit 3 is disposed downstream of the microbubble generation unit 2 in the cup unit 72. As shown in FIG. 5, between the diffusion part 3 and the microbubble generation part 2, there is a storage space 30 for temporarily storing the liquid that has passed through the microbubble generation part 2, that is, the liquid containing the microbubbles. It is formed. Further, as shown in FIGS. 2 and 5, an O-ring 321 is interposed between the microbubble generation unit 2 and the diffusion unit 3.

  As shown in FIG. 12, the diffusion portion 3 has three fastening holes 322 at its outer peripheral edge 32. Although not shown in the drawing, the diffusion portion 3 is fastened to the cup portion 72 via a screw 323 (see FIG. 2) inserted in the fastening hole 322. Further, at the center of the diffusion portion 3 in a plan view seen from the storage space 30 side, a shaft holding portion insertion hole 33 penetrating the microbubble generation portion 2 is provided. As shown in FIG. 5, in the shaft holding portion insertion hole 33, a shaft holding portion 412 in a substrate 41 of the water dividing plate 4 described later is inserted.

  As shown in FIG. 12, the diffusion portion 3 has a shield 34 in the form of a disc on the inner side than the outer peripheral edge portion 32. As shown in FIGS. 5 and 10, the shielding plate 34 is disposed at a position overlapping with the microbubble generation hole 21, that is, in front of the microbubble generation hole 21 in a plan view as viewed from the flow direction of the liquid.

  Further, as shown in FIGS. 10 and 12, the shielding plate 34 is provided with four discharge holes 31 for discharging the liquid from inside the storage space 30 through the shielding plate 34. . As shown in FIG. 10, the discharge holes 31 are out of the front of the micro bubble generation holes 21 a and the micro bubble generation holes 21 b in a position not overlapping with the micro bubble generation holes 21 in plan view seen from the flow direction of the liquid. Are placed in the same position.

In the shower head 1 of the present example, the total flow passage cross-sectional area of the discharge holes 31 is in the range of 5 to 30% of the flow passage cross-sectional area of the storage space 30. More specifically, the storage space 30 in the shower head 1 of the present example has a cylindrical shape with the microbubble generation part 2 and the shielding plate 34 as the end faces. The channel cross-sectional area of the storage space 30, that is, the area of the storage space 30 in the plan view seen from the direction of flow of the liquid is 911Mm ^2, the sum of the flow path cross-sectional area of the discharge hole 31 is 74.2mm ^2.

  As shown in FIG. 5, a water dividing plate 4 is disposed downstream of the shielding plate 34. The water distribution plate 4 is rotatably held by the annular lid portion 62 of the outer pipe portion 6. The water distribution plate 4 of this example includes a substrate 41 and a large number of spray holes 421, and is laminated on a rubber plate 42 laminated on the substrate 41 and a rubber plate 42 and exposed on the surface of the shower head 1 And a plate 43. Further, a gap 410 is formed between the substrate 41 and the rubber plate 42. The water distribution plate 4 can distribute the liquid that has flowed into the gap 410 between the substrate 41 and the rubber plate 42 to each of the spray holes 421 and can discharge the liquid from the multiple spray holes 421.

  As shown in FIG. 2, the liquid discharged from the discharge holes 31 is caused to flow into the gap 410 between the substrate 41 and the rubber plate 42 at a position facing the discharge holes 31 of the diffusion portion 3 in the substrate 41. A flow passage hole 411 is provided. Further, as shown in FIG. 5, at the center of the substrate 41 in a plan view seen from the diffusion portion 3 side, a shaft holding portion 412 having a cylindrical shape is provided upright. The shaft holding portion 412 is inserted into a shaft holding portion insertion hole 33 provided in the shielding plate 34. Then, in the shaft holding portion 412, a shaft portion 82 of the microbubble amount adjusting unit 8 described later is inserted.

  The rubber plate 42 is provided with the spray holes 421 and has a large number of protrusions 422 protruding toward the outer plate 43 side. The protrusions 422 are inserted into the through holes 431 provided in the outer plate 43.

  The outer plate 43 has a large number of through holes 431 into which the protrusions 422 of the rubber plate 42 are inserted. Further, as shown in FIG. 1, FIG. 3 and FIG. 5, the outer plate 43 has a knob 432 for rotating the water dividing plate 4 at the outer peripheral edge thereof. As shown in FIG. 3, the water distribution plate 4 of this example can rotate the substrate 41, the rubber plate 42 and the outer plate 43 by turning the knob 432 of the outer plate 43.

  In the shower head 1 of the present example, as shown in FIGS. 2 and 5, the microbubble amount adjustment unit 8 for adjusting the generation amount of microbubbles is provided between the cup portion 72 and the microbubble generation unit 2. It is provided. As shown in FIGS. 7 to 9, the microbubble amount adjustment unit 8 is disposed so as to cover the center of the microbubble generation unit 2 in a plan view as viewed from the inlet space 20 side.

  As shown in FIG. 13, the microbubble amount adjustment unit 8 is disposed at the center of the adjustment plate 81 having a disk shape in a plan view as viewed from the flow direction of the liquid, and the adjustment plate 81. And an axially projecting shaft 82. As shown in FIG. 5, the shaft portion 82 penetrates the microbubble generating portion 2 and is held by a shaft holding portion 412 (described later) provided on the water dividing plate 4. Accordingly, when the water distribution plate 4 is rotated, the adjustment plate 81 can be rotated via the shaft holding portion 412 and the shaft portion 82.

  As shown in FIG. 13, the adjusting plate 81 has, at a part thereof, two through holes 811 penetrating in the thickness direction. Further, at the center of the surface of the adjusting plate 81 on the side of the inlet space 20, a spring accommodating portion 812 recessed from the periphery is formed. Although not shown in the figure, a coil spring 813 (see FIG. 2) is disposed in the spring accommodation portion 812, and the adjustment plate 81 is pressed toward the micro bubble generation portion 2 by the coil spring 813. Further, a packing 814 is provided on the peripheral edge of the opening end on the inlet space 20 side of the microbubble generation hole 21 and the large diameter hole 23, and the packing 814 and the adjustment plate 81 are in sliding contact. Thereby, it is possible to suppress the inflow of the liquid from the gap between the adjustment plate 81 and the microbubble generation part 2 to the microbubble generation hole 21.

  As shown in FIG. 7 to FIG. 9, among the eight micro bubble generation holes 21 (21 a, 21 b), the three micro bubble generation holes 21 a arranged at the outermost side are more than the adjustment plate 81. It is arranged on the outer peripheral side. Since these microbubble generation holes 21a are not covered by the adjusting plate 81, it is possible to make the liquid always flow in the microbubble generation holes 21a and form microbubbles in the liquid. Therefore, the shower head 1 of this example can always discharge the liquid containing the microbubbles from the distribution unit 12.

  Further, the five micro bubble generation holes 21 b arranged at the inner side of the micro bubble generation holes 21 a are arranged at positions that can be covered by the adjusting plate 81. The adjusting plate 81 moves the through hole 811 by rotating in the circumferential direction, and switches between the state in which the micro bubble generation hole 21 b is covered by the adjusting plate 81 and the state in which the micro bubble generating hole 21 b faces the through hole 811 it can.

  When the micro bubble generation hole 21 b is covered by the adjustment plate 81, the micro bubble generation hole 21 b is closed by the adjustment plate 81. Therefore, the liquid can not flow in the micro bubble generation hole 21 b covered by the adjustment plate 81. On the other hand, when the micro bubble generation hole 21 b faces the through hole 811, the micro bubble generation hole 21 b is not closed by the adjusting plate 81. Therefore, the liquid can be circulated in the micro bubble generation hole 21 b facing the through hole 811.

  The two large diameter holes 23 are disposed at positions where they can be covered by the adjusting plate 81, similarly to the micro bubble generation holes 21b described above. Therefore, when the large diameter hole 23 is covered by the adjusting plate 81, the large diameter hole 23 is closed by the adjusting plate 81, so that the liquid can not flow in the large diameter hole 23. On the other hand, when the large diameter hole 23 faces the through hole 811, the large diameter hole 23 is not closed by the adjusting plate 81, so that the liquid can be circulated in the large diameter hole 23.

  In the shower head 1 of this example, the adjustment plate 81 rotates in conjunction with the water distribution plate 4 by turning the knob 432 of the outer plate 43 to turn the water distribution plate 4 so that liquid can flow The number of micro bubble generation holes 21b can be changed. As a result, the amount of microbubbles generated can be adjusted. For example, as shown in FIG. 7, when the knob 432 of the outer plate 43 is at the first position 432a (see FIG. 3), three microbubble generation holes arranged at the outer peripheral side than the adjustment plate 81 The liquid can be made to flow through 21 a and the two large diameter holes 23.

  Further, as shown in FIG. 8, when the knob 432 is at the second position 432b (see FIG. 3), the liquid is supplied to the three microbubble generation holes 21a arranged at the outer peripheral side than the adjusting plate 81. It can be distributed. Furthermore, in this case, the liquid is also supplied to the four microbubble generation holes 21b facing the through hole 811 among the five microbubble generation holes 21b arranged inside the microbubble generation hole 21a. It can be distributed.

  Then, as shown in FIG. 9, when the knob 432 is at the third position 432c (see FIG. 3), the liquid is supplied to the three microbubble generation holes 21a arranged at the outer peripheral side than the adjusting plate 81. It can be distributed. Furthermore, in this case, among the five microbubble generation holes 21b disposed inside the microbubble generation hole 21a, one microbubble generation hole 21b facing the through hole 811 and one The liquid can be made to flow through the large diameter hole 23 of the station.

  Therefore, in the shower head 1 of the present embodiment, the microbubbles are formed in the liquid by the microbubble generation holes 21a regardless of the position of the knob 432 of the water dividing plate 4, and the microbubbles are constantly It is possible to spray liquid containing Also, when the knob 432 is at the first position 432a, the amount of microbubbles generated in the liquid is the smallest, and when the knob 432 is at the second position 432b, the microparts generated in the liquid are The amount of bubbles is the largest. And, when the knob 432 is in the third position 432c, an intermediate amount of microbubbles can be generated in the liquid when in the first position 432a and in the second position 432b. .

  Next, the operation of each part when the liquid is supplied to the shower head 1 of this example will be described. First, the liquid supplied from the connection portion 11 flows through the water flow pipe 71 and flows into the inlet space 20 formed between the cup portion 72 and the microbubble generation portion 2 as shown in FIG. The channel cross-sectional area of the inlet space 20 is the narrowest at its root, and the channel cross-sectional area is wider toward the micro bubble generating portion 2 side.

  The liquid in the inlet space 20 passes through the microbubble generation holes 21 or the large diameter holes 23 in the number according to the positions of the through holes 811 in the adjusting plate 81 to the storage space 30, as shown in FIGS. To flow. At this time, micro bubbles can be formed in the liquid that has passed through the micro bubble generation holes 21.

  The liquid that has flowed into the storage space 30 from the micro bubble generation holes 21 and the large diameter holes 23 travels straight toward the shielding plate 34. As shown in FIGS. 5 and 10, since the shielding plate 34 is provided in front of the microbubble generation hole 21, the liquid flowing into the storage space 30 from the microbubble generation hole 21 strikes the shielding plate 34 and the direction of the flow thereof. Is changed. As a result, the liquid containing the microbubbles can be diffused into the storage space 30. In addition, since the discharge hole 31 is provided at a position deviated from the front of the microbubble generation hole 21, the liquid that has been stirred in the storage space 30 can be discharged from the discharge hole 31.

  The liquid that has passed through the microbubble generation holes 21 or the discharge holes 31 flows into the gaps 410 between the substrate 41 and the rubber plate 42 through the flow path holes 411 in the water distribution plate 4 and is distributed to the spray holes 421. Then, the liquid containing the microbubbles is sprayed from each spray hole 421.

  Next, the operation and effect of this embodiment will be described. The shower head 1 includes a diffusion unit 3 between a microbubble generation unit 2 for generating microbubbles and a water distribution plate 4 for dispersing a liquid. The diffusion unit 3 is disposed such that a storage space 30 for storing a liquid is formed between the diffusion unit 3 and the microbubble generation unit 2, and diffuses the liquid discharged from the microbubble generation hole 21 into the storage space 30. It is configured to be able to

  In the shower head 1, the liquid discharged from the micro bubble generation hole 21 is diffused into the storage space 30 by the diffusion unit 3. Therefore, it is possible to prevent the liquid discharged from the micro bubble generation hole 21 from reaching the water dividing plate 4 directly.

  In addition, by diffusing the liquid into the storage space 30 by the diffusion unit 3, the liquid in the storage space 30 can be agitated, and the deviation of the amount of microbubbles contained in the liquid can be reduced. Then, the liquid in the storage space 30 is discharged from the discharge holes 31 to the outside, and further discharged from the water distribution plate 4 to the outside of the shower head 1 through the distribution holes 421 to be dispersed from the distribution holes 421. It is possible to suppress the deviation of the amount of microbubbles in the liquid.

  Further, the diffusion unit 3 is disposed at a position overlapping the micro bubble generation hole 21 in a plan view as viewed from the flow direction of the liquid. Therefore, the flow of the liquid discharged from the micro bubble generation hole 21 can be blocked by the diffusion unit 3, and the liquid discharged from the micro bubble generation hole 21 can be prevented from directly reaching the water separation plate 4. Furthermore, the liquid discharged from the microbubble generation hole 21 can be reliably diffused into the storage space 30, and the liquid in the storage space 30 can be sufficiently stirred. As a result, it is possible to more effectively suppress the deviation of the amount of microbubbles in the liquid discharged from the spray hole 421.

  Moreover, the flow passage cross-sectional area of the discharge hole 31 is 5 to 30% of the flow passage cross-sectional area of the storage space 30. Therefore, the residence time of the liquid in the storage space 30 can be made longer, and the liquid in the storage space 30 can be sufficiently agitated. As a result, it is possible to more effectively suppress the deviation of the amount of microbubbles in the liquid discharged from the spray hole 421.

  As a result of the above, according to the shower head 1 of the present example, it is possible to suppress the unevenness of the amount of microbubbles in the liquid discharged from the spray holes 421.

  Moreover, the shower head 1 of this example has the connection part 11 provided with the adapter 5 and the adapter cover 51 which covers the side peripheral surface of the adapter 5. FIG. The shower head 1 of this example can be connected to various shower hoses by attaching an appropriate adapter 5 according to the shape of the joint portion in the shower hose. Moreover, the shower head 1 of this example can perform the process for improving the designability, such as painting and provision of the shape for improving the designability, to the adapter cover 51. Thereby, the shape etc. of the adapter 5 can be made comparatively simple, and the increase in the cost by the process for improving the designability can be suppressed.

  The shower head 1 of this example has a water draining hole 710 between the grip portion 13 and the connection portion 11 side, and the water draining hole 710 is provided on the back surface 102 of the shower head 1. When the shower head 1 is hooked to a hook provided on the wall of a bathroom, the shower head 1 usually directs the connecting portion 11 downward and the spreading portion 12 upward so that the spreading portion 12 protrudes forward. Be placed. In this case, the back surface 102 of the shower head faces the wall surface of the bathroom, and is disposed at a position where it is difficult for the user to see. Therefore, by providing the water draining hole 710 on the back surface 102 of the shower head 1, it is difficult for the user of the shower head 1 to visually recognize the liquid accumulated in the gap between the outer pipe portion 6 and the water passing portion 7. It can be discharged from 102.

  Moreover, the shower hose connected to the connection part 11 of the shower head 1 is hanging down from the connection part 11 by dead weight. Therefore, the shower head 1 can cause the liquid discharged from the back surface 102 to flow down the shower hose connected to the outer surface of the shower head 1 and the connection portion 11. As a result of the above, the liquid accumulated in the gap between the outer pipe portion 6 and the water flow portion 7 can be discharged inconspicuously from the user.

The specific aspect of the shower head which concerns on this invention is not limited to the aspect of the Example mentioned above, It can change suitably in the range which does not impair the meaning of this invention.
For example, in the embodiment described above, an example of the shower head 1 of a type in which the connection portion 11 is connected to a shower hose as a water supply pipe and the grip portion 13 is gripped by hand is shown. It can also be configured to be connected directly to a water pipe as a water supply pipe protruding from the ceiling or wall of a bathroom. In this case, the grip portion 13 may not be provided between the connection portion 11 and the scattering portion 12.

  Further, in the embodiment described above, the drain hole 710 is formed by providing the notch 716 in the flange portion 714 of the water flow pipe 71, but the drain hole is formed by providing the notch in the outer pipe portion main body 61. You may In addition, a drain hole can be provided so as to penetrate the collar portion 714.

DESCRIPTION OF SYMBOLS 1 Shower head 11 Connection part 12 Scattering part 2 Micro bubble generation part 21 Micro bubble generation hole 3 Diffusion part 30 Storage space 31 Discharge hole 4 Water distribution plate 421 Scatter hole

Claims (3)

A shower head comprising: a connection portion for connecting to a water supply pipe; and a dispersion portion connected to the connection portion for dispersing a liquid supplied from the water supply pipe,
The spreading unit is
A microbubble generation unit having a microbubble generation hole configured to generate microbubbles in the liquid by passing the liquid;
And a diffusion unit disposed so as to form a storage space for storing the liquid between the microbubble generation unit and the diffusion unit for diffusing the liquid discharged from the microbubble generation hole into the storage space. ,
A discharge hole for discharging the liquid from inside the storage space through the diffusion portion;
And a water distribution plate disposed to face the diffusion portion, the water distribution plate including: a distribution hole for distributing the liquid that has passed through the discharge hole;
shower head.   The shower head according to claim 1, wherein the diffusion unit is disposed at a position overlapping the micro-bubble generation hole in a plan view as viewed from the flow direction of the liquid.   The shower head according to claim 1, wherein a flow passage cross-sectional area of the discharge hole is 5 to 30% of a flow passage cross-sectional area of the storage space.

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