The present invention relates to a shower head configured to generate an air bubble-liquid mixture by mixing the air (air bubbles) into a liquid, or forma liquid into a mist of liquid droplets in which air bubbles are mixed, and jet the air bubble-liquid mixture or the mist of liquid droplets.
As a technology of mixing the air into a liquid, Patent Literature 1 discloses a shower apparatus. In the shower apparatus, the liquid is jetted through a plurality of nozzle portions into a reduced tapered portion. When the liquid is jetted through the nozzle portions, the air is introduced through air inlets into the reduced tapered portion.
In the shower apparatus of Patent Literature 1, as a result of collision of the liquid and the air with the reduced tapered portion, air bubbles are mixed into the liquid.
[PTL 1] Japanese Unexamined Patent Application Publication No. 2002-102100
However, in Patent Literature 1, as a result of collision of the liquid and the air with the reduced tapered portion, the air bubbles are mixed into the liquid. Thus, there is the possibility that a sufficient volume of the air bubbles cannot be mixed into the liquid.
The present invention provides a shower head capable of mixing a sufficient volume of air bubbles into a liquid.
The present invention provides a shower head configured to form a liquid into a mist of liquid droplets in which air bubbles are mixed.
According to a first aspect of the present invention, there is provided a shower head including
a shower main body including
an inflow passage into which a liquid is caused to flow, and
an outflow passage through which the liquid having flowed into the inflow passage is caused to flow out, the inflow passage being opened to one end of the shower main body, the outflow passage being opened to the other end of the shower main body;
a shower nozzle mounted to the other end of the shower main body, the shower nozzle including a shower nozzle plate;
a shower cylindrical portion, which has one cylinder end closed by the shower nozzle plate, is protruded to the outflow passage side, and defines an air bubble mixing space into which the liquid flowed out through the outflow passage is caused to flow from the other cylinder end of the shower cylindrical portion; and a plurality of air bubble-liquid mixture jetting holes formed in the shower nozzle plate so as to be opened in the air bubble mixing space and configured to cause an air bubble-liquid mixture to jet out of the air bubble mixing space therethrough; and
air bubble-liquid mixture generating means configured to generate the air bubble-liquid mixture by mixing the air into the liquid, the air bubble-liquid mixture generating means including
a flow-adjustment piece arranged in the air bubble mixing space in the shower cylindrical portion; and
a plurality of air introduction passages formed in the shower nozzle, and configured to cause the air to flow into the air bubble mixing space therethrough, the flow-adjustment piece including
a flow-adjustment nozzle disk arranged in the air bubble mixing space at a distance from the shower nozzle plate, and fixed to the shower cylindrical portion so as to close the other cylinder end of the shower cylindrical portion;
a plurality of flow-adjustment-piece plates formed on the flow-adjustment nozzle disk, and arranged in the air bubble mixing space between the shower nozzle plate and the flow-adjustment nozzle disk; and a plurality of liquid throttle holes formed in a portion of the flow-adjustment nozzle disk between the flow-adjustment-piece plates, and configured to cause the liquid flowed out through the outflow passage to jet into the air bubble mixing space therethrough, wherein the liquid throttle holes are formed to pass through the flow-adjustment nozzle disk so that a hole center line of each of the liquid throttle holes is arranged in parallel to a cylinder center line of the shower cylindrical portion, wherein the flow-adjustment-piece plates are protruded from the flow-adjustment nozzle disk toward the shower nozzle, and are arranged with a mixing gap separating from the shower nozzle plate, wherein the flow-adjustment-piece plates are arranged to extend from a plate center line of the flow-adjustment nozzle disk toward the shower cylindrical portion, wherein each of the flow-adjustment-piece plates causes the liquid jetted through the liquid throttle holes to flow turbulently and flow into the mixing gap on a protruding end side protruding toward the shower nozzle, wherein the air introduction passages are opened in the shower nozzle, and wherein the air introduction passages are formed to pass through the shower cylindrical portion between the protruding end of each of the flow-adjustment-piece plates and the flow-adjustment nozzle disk in a direction orthogonal to the cylinder center line of the shower cylindrical portion and are opened into the air bubble mixing space.
According to a second aspect of the present invention, in the shower head according to the first aspect described above, the flow-adjustment-piece plates are arranged at equal intervals in the circumferential direction of the flow-adjustment nozzle disk.
According to a third aspect of the present invention, in the shower head according to the first aspect described above, the flow-adjustment piece includes four flow-adjustment-piece plates, and the four flow-adjustment-piece plates are arranged at equal intervals in the circumferential direction of the flow-adjustment nozzle disk.
According to a fourth of the present invention, in the shower head according to any one of the first to third aspects described above, the flow-adjustment-piece plates are each formed into a rectangular shape, and the flow-adjustment-piece plates each include flow-adjustment flat surfaces each formed into a rectangular shape so as to be parallel to each other with an interval equal to a thickness of each of the flow-adjustment-piece plates in the circumferential direction of the flow-adjustment nozzle disk, and a flow inclined surface formed to incline and extend from the protruding end of each of the flow-adjustment-piece plates toward one of the flow-adjustment flat surfaces and the flow-adjustment nozzle disk.
According to a fifth of the present invention, in the shower head according to any one of the first to fourth aspects described above, the plurality of liquid throttle holes are arranged at equal intervals on each of a plurality of circles having different radii with a plate center line of the flow-adjustment nozzle disk being a center.
According to a sixth aspect of the present invention, in the shower head according to any one of the first to fifth aspects described above, the air introduction passages are arranged at equal intervals in the circumferential direction of the shower cylindrical portion.
According to a seventh aspect of the present invention, in the shower head according to any one of the first to sixth aspects described above, the air introduction passages are adjacent to the flow-adjustment nozzle disk, and are opened into the air bubble mixing space.
In a seventh aspect described above, the following configuration may also be adopted. Specifically, the air introduction passages are arranged at equal intervals in the circumferential direction of the shower cylindrical portion. Further, the air introduction passages each have a flow passage width larger than a plate width of each of the flow-adjustment-piece plates in the circumferential direction of the shower cylindrical portion, and are opened into the air bubble mixing space.
According to an eighth aspect of the present invention, in the shower head according to any one of the first to the seventh aspects described above, the shower head further includes flow passage switching means arranged between the air bubble-liquid mixture generating means and the outflow passage and in the outflow passage of the shower main body; and mist generating means arranged on the shower nozzle plate on an outer side of the air bubble-liquid mixture jetting holes, and configured to form the liquid, which is caused to flow into the mist generating means through the flow passage switching means, into a mist of liquid droplets, the mist generating means including a plurality of mist throttle holes, which are formed to pass through the shower nozzle plate on the outer side of the air bubble-liquid mixture jetting holes, and are opened between the shower nozzle plate and the flow passage switching means; and a plurality of mist guides, which are each formed into a conical spiral shape, and each include a plurality of spiral surfaces each having the same spiral shape, the mist throttle holes are each formed into a conical hole passing through the shower nozzle plate and having a diameter gradually reducing from the outflow passage side, the spiral surfaces are arranged between a cone bottom flat surface and a cone upper surface of each of the mist guides to cross a cone side surface of each of the mist guides, and are each formed into a spiral shape having a diameter gradually reducing from the cone bottom flat surface toward the cone upper surface, each of the mist guides is inserted into each of the mist throttle holes from the cone upper surface with a gap between the cone side surface and a conical inner peripheral surface of each of the mist throttle holes, each of the mist guides is fitted in each of the mist throttle holes so as to define a plurality of mist flow passages each having a spiral shape between the spiral surfaces and the conical inner peripheral surface, the mist flow passages are opened into each of the mist throttle holes, and are opened between the shower nozzle and the flow passage switching means, and the flow passage switching means allows connection between the liquid throttle holes and the outflow passage, or allows connection between the mist throttle holes and the outflow passage.
According to a ninth aspect of the present invention, in the shower head according to the eighth aspect described above, the mist generating means includes a plurality of mist guides, which are each formed into a conical spiral shape, and each include first and second spiral surfaces each having the same spiral shape, the first and second spiral surfaces are arranged between the cone bottom flat surface and the cone upper surface to cross the cone side surface of each of the mist guides, the first and second spiral surfaces are arranged so as to be point symmetrical with respect to a cone center line of each of the mist guides, the first and second spiral surfaces are each formed into a spiral shape having a diameter gradually reducing from the cone bottom flat surface toward the cone upper surface, each of the mist guides is inserted into each of the mist throttle holes from the cone upper surface with the gap between the cone side surface and the conical inner peripheral surface of each of the mist throttle holes, each of the mist guides defines first and second mist flow passages each having a spiral shape between the first and second spiral surfaces and the conical inner peripheral surface, and the first and second mist flow passages are opened in each of the mist throttle holes, and are opened between the shower nozzle and the flow passage switching means.
According to a tenth aspect of the present invention, in the shower head according to the eighth or ninth aspect described above, the mist throttle holes are arranged at equal intervals on a circle that has a center along the cylinder center line of the shower cylindrical portion and is located on the outer side of the air bubble-liquid mixture jetting holes.
According to an eleventh of the present invention, in the shower head according to the tenth aspect described above, the mist generating means includes a guide ring having a radius equal to a radius of the circle on which the mist throttle holes are arranged, the mist guides are arranged at equal intervals in the circumferential direction of the guide ring, each of the mist guides is fixed integrally with the guide ring so that the cone bottom flat surface is abutted on the guide ring, the guide ring is externally fitted to the shower cylindrical portion from the other cylinder end, and is arranged on the outer side of the air bubble-liquid mixture jetting holes, and, along with the insertion of the mist guides into the mist throttle holes, the guide ring is brought into abutment against the shower nozzle plate from the outflow passage side.
According to a twelfth aspect of the present invention, there is provided a shower head, including a shower main body including an inflow passage into which a liquid is caused to flow, and an outflow passage through which the liquid having flowed into the inflow passage is caused to flow out, the inflow passage being opened to one end of the shower main body, the outflow passage being opened to the other end of the shower main body; a shower nozzle mounted to the other end of the shower main body; and mist generating means arranged on the shower nozzle, and configured to form the liquid having flowed out through the outflow passage into a mist of liquid droplets, the mist generating means including a plurality of mist throttle holes, which are formed to pass through the shower nozzle, and communicate with the outflow passage; and a plurality of mist guides, which are each formed into a conical spiral shape, and each include a plurality of spiral surfaces having the same spiral shape, wherein the mist throttle holes are each formed into a conical hole passing through the shower nozzle and having a diameter gradually reducing from the outflow passage side, wherein the spiral surfaces are arranged between a cone bottom flat surface and a cone upper surface of each of the mist guides to cross a cone side surface of each of the mist guides, and are each formed into a spiral shape having a diameter gradually reducing from the cone bottom flat surface toward the cone upper surface, wherein each of the mist guides is inserted into each of the mist throttle holes from the cone upper surface with a gap between the cone side surface and a conical inner peripheral surface of each of the mist throttle holes, wherein each of the mist guides is fitted in each of the mist throttle holes so as to define a plurality of mist flow passages each having a spiral shape between the spiral surfaces and the conical inner peripheral surface, and wherein the mist flow passages are opened into each of the mist throttle holes, and communicate with the outflow passage.
According to a thirteenth aspect of the present invention, in the shower head according to the twelfth aspect described above, the mist generating means includes a plurality of mist guides, which are each formed into a conical spiral shape, and each include first and second spiral surfaces each having the same spiral shape, the first and second spiral surfaces are arranged between the cone bottom flat surface and the cone upper surface to cross the cone side surface of each of the mist guides, the first and second spiral surfaces are arranged so as to be point symmetrical with respect to a cone center line of each of the mist guides, the first and second spiral surfaces are each formed into a spiral shape having a diameter gradually reducing from the cone bottom flat surface toward the cone upper surface, each of the mist guides is inserted into each of the mist throttle holes from the cone upper surface with the gap between the cone side surface and the conical inner peripheral surface of each of the mist throttle holes, each of the mist guides defines first and second mist flow passages each having a spiral shape between the first and second spiral surfaces and the conical inner peripheral surface, and the first and second mist flow passages are opened into each of the mist throttle holes, and communicate with the outflow passage.
According to the first aspect of the present invention, the liquid is caused to flow into the inflow passage from the one end of the shower main body, and the liquid is caused to flow through the inflow passage into the outflow passage. The liquid is caused to flow out through the outflow passage into the liquid throttle holes of the flow-adjustment piece. Through the liquid throttle holes, the liquid having flowed out through the outflow passage is jetted into the air bubble mixing space. Through the liquid throttle holes, the liquid is jetted into the air bubble mixing space toward the shower nozzle plate. In the air bubble mixing space (or in the shower cylindrical portion), the liquid is jetted between the shower nozzle and the flow-adjustment nozzle disk while flowing (being adjusted in flow) in parallel to the cylinder center line of the shower cylindrical portion.
When the liquid is jetted into the air bubble mixing space, due to the flow of the liquid, the air is introduced through the air introduction passages into the air bubble mixing space. The air is caused to flow (jet) into the air bubble mixing space between the protruding ends of the flow-adjustment-piece plates and the flow-adjustment nozzle disk. The air is caused to flow (jet) between the flow-adjustment-piece plates in the air bubble mixing space.
The liquid jetted through the liquid throttle holes, and the air caused to flow (jet) out through the air introduction passages are mixed in the air bubble mixing space. In the air bubble mixing space, the liquid and the air are caused to flow turbulently on the protruding end side of each of the flow-adjustment-piece plates, and flow into the mixing gap between the flow-adjustment-piece plates and the shower nozzle plate.
Thus, in the mixing gap within the air bubble mixing space, due to the turbulent flow, the air mixed into the liquid is broken (divided) into micrometer-sized air bubbles (microbubbles) and nanometer-sized air bubbles (ultrafine bubbles).
The micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) mix with and dissolve in the liquid.
The air bubble-liquid mixture, in which the micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) are mixed, is jetted from the air bubble-liquid mixture jetting holes to the outside.
As described above, according to the first aspect of the present invention, the liquid throttle holes, the flow-adjustment-piece plates, and the air introduction passages of the flow-adjustment piece allow a sufficient volume of the micrometer-sized and nanometer-sized air bubbles (microbubbles and ultrafine bubbles) to be mixed and dissolved into the liquid.
In international standards “ISO20480-1” by International Organization for Standardization (ISO), an air bubble of from equal or greater than one micrometer to a hundred micrometer (μm) is defined as a “microbubble”, and an air bubble of less than one micrometer is defined as an “ultrafine bubble” (the same applies in the following description).
According to the second aspect of the present invention, the liquid is jetted from the liquid throttle holes toward between the flow-adjustment-piece plates.
According to the third aspect of the present invention, the liquid is jetted equally from the liquid throttle holes toward between the four flow-adjustment-piece plates. The four flow-adjustment-piece plates allow a sufficient volume of the micrometer-sized and nanometer-sized air bubbles (microbubbles and ultrafine bubbles) to be mixed and dissolved into the liquid.
According to the fourth aspect of the present invention, the flow inclined surfaces of the flow-adjustment-piece plates lead the liquid (adjusted in flow) jetted from the liquid throttle holes to the protruding ends of the flow-adjustment-piece plates, which allows the liquid and the air to flow turbulently into the mixing gap.
According to the fifth of the present invention, the liquid is jetted equally from each of the liquid throttle holes throughout the air bubble mixing space.
According to the sixth aspect of the present invention, the air is equally flowed (jetted) out between the flow-adjustment-piece plates through the air introduction passages.
According to the seventh aspect of the present invention, the air is flowed out into the air bubble mixing space from each of the air introduction passages adjacent to the flow-adjustment nozzle disk, which allows the air to be mixed into the liquid at the same time as the liquid is jetted from the liquid throttle holes.
According to the eighth aspect of the present invention, the flow passage switching means allows connection (communication) between the liquid throttle holes and the outflow passage, or allows connection (communication) between the mist throttle holes and the outflow passage.
The mist throttle holes and the outflow passages are connected to flow the liquid from the one end of the shower main body into the inflow passage and to flow the liquid from the inflow passage into the outflow passage. The liquid is caused to flow through the outflow passage into the mist throttle holes. In the mist throttle holes, the liquid is caused to flow through the mist flow passages having a spiral shape into the mist throttle holes. Further, the mist of liquid droplets is jetted from each of the mist throttle holes to the outside through the mist throttle holes.
The liquid is increased in pressure by flowing through the mist flow passages having a spiral shape, and is jetted into the mist throttle holes through the mist flow passages. Thus, the liquid jetted through the mist flow passages into the mist throttle holes flows turbulently at high pressure. Further, when the mist of liquid droplets is jetted from the mist throttle holes, an outlet side of each of the mist throttle holes (a side from which the mist of liquid droplets is jetted) is brought into a negative pressure state.
With the outlet side of each of the mist throttle holes brought into the negative pressure state, when the liquid, which is jetted into the mist throttle holes through the mist flow passages and flows turbulently at high pressure, passes through the outlet portion of each of the mist throttle holes, the air bubbles are separated out due to reduced pressure, and the air that is taken in at the time of jetting is broken up (divided) by the turbulent flow. Thus, the liquid is formed into the mist of liquid droplets in which the micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) are mixed and dissolved.
The mist of liquid droplets in which the air bubbles are mixed is jetted from the mist throttle holes to the outside.
According to the eighth aspect described above, the mist guides and the mist throttle holes allow the mist of liquid droplets in which the micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) are mixed and dissolved to be jetted to the outside.
According to the ninth aspect of the present invention, the plurality of minimum mist flow passages (spiral surfaces) allow the liquid to be formed into a sufficient mist of liquid droplets. With point symmetrical arrangement of the first and second spiral surfaces, the first and second mist flow passages are arranged so as to be opposed to (face to face) each other at the cone upper surface.
With this arrangement, the high-pressure liquid jetted into each of the mist throttle holes through the first and second mist flow passages is caused to collide with the cone upper surface and thereby is formed into the mist of liquid droplets in which a sufficient volume of the micrometer-sized air bubbles (microbubbles) and a sufficient volume of the nanometer-sized air bubbles (ultrafine bubbles) are mixed and dissolved.
According to the tenth aspect of the present invention, the liquid having flowed out through the outflow passage is distributed equally in the peripheral direction of the shower cylindrical portion, and is flowed into the mist throttle holes (or into the mist flow passages).
According to the eleventh aspect of the present invention, the mist guides are fixed to the guide ring, which prevents the mist guides from getting into the mist throttle holes due to the flow of the liquid even when the liquid is flowed through the outflow passage into the mist throttle holes.
According to the twelfth aspect of the present invention, the liquid is flowed from the one end of the shower main body into the inflow passage, and the liquid is caused to flow through the inflow passage into the outflow passage. The liquid is caused to flow through the outflow passage into the mist throttle holes. In the mist throttle holes, the liquid is caused to flow through the mist flow passages each having a spiral shape into the mist throttle holes. Further, the mist of liquid droplets is jetted from the mist throttle holes to the outside.
The liquid is increased in pressure by flowing through the mist flow passages each having a spiral shape, and is jetted into the mist throttle holes through the mist flow passages. Thus, the liquid jetted through the mist flow passages into the mist throttle holes flows turbulently at high pressure. Further, when the mist of liquid droplets is jetted from the mist throttle holes, an outlet side of each of the mist throttle holes (a side from which the mist of liquid droplets is jetted) is brought into a negative pressure state.
With the outlet side of each of the mist throttle holes brought into the negative pressure state, when the liquid, which is jetted into the mist throttle holes through the mist flow passages and flows turbulently at high pressure, passes through the outlet portion of each of the mist throttle holes, the air bubbles are separated out due to reduced pressure, and the air that is taken in at the time of jetting is broken (divided) by the turbulent flow. Thus, the liquid is formed into the mist of liquid droplets in which the micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) are mixed and dissolved.
The mist of liquid droplets in which the air bubbles are mixed is jetted from the mist throttle holes to the outside.
According to the twelfth aspect described above, the mist guides and the mist throttle holes allow the mist of liquid droplets in which the micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) are mixed and dissolved can be jetted to the outside.
According to the thirteenth aspect of the present invention, the plurality of minimum mist flow passages (spiral surfaces) allow the liquid to be formed into a sufficient mist of liquid droplets. With point symmetrical arrangement of the first and second spiral surfaces, the first and second mist flow passages are arranged so as to be opposed to (face to face) each other at the cone upper surface.
With this arrangement, the high-pressure liquid jetted into each of the mist throttle holes through the first and second mist flow passages is caused to collide with the cone upper surface, and thereby is formed into the mist of liquid droplets in which a sufficient volume of the micrometer-sized air bubbles (microbubbles) and a sufficient volume of the nanometer-sized air bubbles (ultrafine bubbles) are mixed and dissolved.
A shower head according to the present invention is described with reference to
A shower head X is configured to generate an air bubble-liquid mixture by mixing the air (air bubbles) into a liquid, or forma liquid into mist-like liquid droplets in which air bubbles are mixed, and jet the air bubble-liquid mixture or the mist-like (atomized) liquid droplets.
The liquid is water or hot water (the same applies in the following description). The air bubble-liquid mixture is air bubble-water mixture or air bubble-hot water mixture generated by mixing the air into water or hot water, or water or hot water in which microbubbles or ultrafine bubbles are mixed (the same applies in the following description).
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The inflow passage 9 is opened in the outflow passage 10 on the dome top 7A side of the head portion 7.
The one end 6A of the handle portion 6 (or the one end 1A of the shower main body 1) is connected to a water supply hose (not shown), and the liquid is caused to flow through the water supply hose into the inflow passage 9.
As shown in
This configuration allows the liquid to flow through the inflow passage 9 into the outflow passage 10 and the liquid is caused to flow out from the other end 1B of the shower main body 1 (or from the circular end 7B of the head portion 7).
As shown in
One of the fixing protruding portions 11 is arranged at a highest point 7a of the head portion 7. The other two fixing protruding portions 11 are arranged with angular intervals of 90 degrees on both side positions of the highest point 7a in the peripheral direction (circumferential direction) of the outflow passage 10.
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The base protruding portion 13 has a screw hole 15. As shown in
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The first handle cylindrical portion 31 (small-diameter cylindrical portion) and the second handle cylindrical portion 32 (large-diameter cylindrical portion) are arranged concentrically with each other with a cylinder center line B (a center line) of the switching handle 21 being a center, and are formed integrally with each other.
The first handle cylindrical portion 31 is reduced in diameter, and extends from one cylinder end 32A of the second handle cylindrical portion 32 in a direction of the cylinder center line B of the switching handle 21.
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The handle groove 40 is formed to extend from the one cylinder end 32A to the other cylinder end 32B of the second handle cylindrical portion 32, and has a groove depth in the direction of the cylinder center line B of the switching handle 21.
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The handle hole 33 is formed to pass through the first handle cylindrical portion 31 and the second handle cylindrical portion 32 in the direction of the cylinder center line B of the switching handle 21. The handle hole 33 is opened to one cylinder end 31A of the first handle cylindrical portion 31 and the other cylinder end 32B of the second handle cylindrical portion 32.
As shown in
The large-diameter hole portion 33A is opened to the other cylinder end 32B of the second handle cylindrical portion 32. The medium-diameter hole portion 33B is formed between the large-diameter hole portion 33A and the small-diameter hole portion 33C. The medium-diameter hole portion 33B is reduced in diameter at a first hole step portion 33D as compared to the large-diameter hole portion 33A, and is continuous with the small-diameter hole portion 33C.
The small-diameter hole portion 33C is reduced in diameter at a second hole step portion 33E as compared to the medium-diameter hole portion 33B, and is opened to the one cylinder end 31A of the first handle cylindrical portion 31.
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One of the first retaining grooves 35 is arranged at a position corresponding to the shower protruding portion 38 in the peripheral direction of the switching handle 21.
The first retaining grooves 35 are formed to extend between the first hole step portion 33D and the second hole step portion 33E in the direction of the cylinder center line B of the switching handle 21. The first retaining grooves 35 each have a groove width H1 in the peripheral direction (circumferential direction) of the switching handle 21, and are each opened in an inner peripheral surface of the medium-diameter hole portion 33B.
As shown in
One of the second retaining grooves 36 is arranged at a position corresponding to the mist protruding portion 39 in the peripheral direction of the switching handle 21. The second retaining grooves 36 are each located at a center between the first retaining grooves 35 in the peripheral direction of the switching handle 21, and are arranged with angular intervals of 90 degrees between the first retaining grooves 35.
The second retaining grooves 36 are formed to extend from the first hole step portion 33D toward the second hole step portion 33E side in the direction of the cylinder center line B of the switching handle 21. The second retaining grooves 36 each have a groove width H2 in the peripheral direction of the switching handle 21, and are each opened in the inner peripheral surface of the medium-diameter hole portion 33B. The groove width H2 of each of the second retaining grooves 36 is smaller than the groove width H1 of each of the first retaining grooves 35 (groove width H2<groove width H1).
As shown in
The handle protrusion 37 is formed integrally on an outer peripheral surface of the first handle cylindrical portion 31. The handle protrusion 37 is formed to protrude from the outer peripheral surface of the first handle cylindrical portion 31 to the handle groove 40 in the direction orthogonal to the cylinder center line B of the switching handle 21.
The handle protrusion 37 is formed to extend between the one cylinder end 31A of the first handle cylindrical portion 31 and the one cylinder end 32A of the second handle cylindrical portion 32 in the direction of the cylinder center line B of the switching handle 21. The handle protrusion 37 includes a protrusion end surface 37A (a flat end surface) that is flush with the one cylinder end 31A of the first handle cylindrical portion 31.
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The first base cylindrical portion 45 and the second base cylindrical portion 46 are arranged concentrically with each other with a cylinder centerline C (a center line) of the switching base 22 being a center. The first base cylindrical portion 45 and the second base cylindrical portion 46 are formed integrally with each other.
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The sealing groove 54 is arranged concentrically with the first base cylindrical portion 45 with the cylinder center line C of the switching base 22 being a center. The sealing groove 54 is formed along the entire outer peripheral surface of the first base cylindrical portion 45. The sealing groove 54 has a groove depth in the direction orthogonal to the cylinder center line C of the switching base 22, and is opened in the outer peripheral surface of the first base cylindrical portion 45.
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The second base cylindrical portion 46 has a plurality of (three) base regulating grooves 55, 56, and 57.
As shown in
With regard to the base regulating grooves 55 to 57, on both sides of one base regulating groove 55 in the peripheral direction of the switching base 22, the other two base regulating grooves 56 and 57 are arranged. Each of the base regulating grooves 56 and 57 is arranged with an angular interval of 90 degrees between the base regulating groove 55 and each of the base regulating grooves 56 and 57 in the peripheral direction of the switching base 22.
The base regulating grooves 55, 56, and 57 are each formed to extend between the one cylinder end 45A of the first base cylindrical portion 45 and one cylinder end 46A of the second base cylindrical portion 46 in the direction of the cylinder centerline C of the switching base 22, and are each opened to the one cylinder end 46A of the second base cylindrical portion 46.
The base regulating grooves 55 to 57 each have a groove depth in the direction orthogonal to the cylinder center line C of the switching base 22, and are each opened in an outer peripheral surface of the second base cylindrical portion 46.
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The base hole 48 includes a small-diameter hole portion 48A and a large-diameter hole portion 48B. The small-diameter hole portion 48A is formed to pass through the first base cylindrical portion 45, and is opened to the base annular plate 47. The large-diameter hole portion 48B is increased in diameter at a hole step portion 48C as compared to the small-diameter hole portion 48A, and is opened to the one cylinder end 46A of the second base cylindrical portion 46.
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The fixing cylindrical portion 49 is arranged in the base cylindrical portions 45 and 46 with an annular space Y between the fixing cylindrical portion 49 and inner peripheral surfaces of the base cylindrical portions 45 and 46 in the direction orthogonal to the cylinder center line C of the switching base 22. The fixing cylindrical portion 49 is formed to extend from the hole step portion 48C of the base hole 48 toward the one cylinder end 46A side of the second base cylindrical portion 46 in the direction of the cylinder center line C of the switching base 22, and protrudes from the one cylinder end 46A of the second base cylindrical portion 46. The fixing cylindrical portion 49 includes a cylinder end surface 49A (a flat end surface) that is flush with the hole step portion 48C of the base hole 48.
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With regard to the bolt receiving hole 58, the large-diameter hole portion 58A is opened to the one cylinder end surface 49A of the fixing cylindrical portion 49, and communicates with the small-diameter hole portion 48A of the base hole 48. The small-diameter hole portion 58B is arranged between the large-diameter hole portion 58A and the medium-diameter hole portion 58C. The small-diameter hole portion 58B is formed to be reduced in diameter as compared to the large-diameter hole portion 58A. The medium-diameter hole portion 58C is increased in diameter as compared to the small-diameter hole portion 58B, and is opened to the other cylinder end 49B of the fixing cylindrical portion 49.
As shown in
The first rib portions 50 are arranged with an angular interval of 180 degrees in the peripheral direction of the switching base 22 (including the base cylindrical portions 45 and 46). With regard to the first rib portions 50, one of the first rib portions 50 is arranged at a position corresponding to the base regulating groove 55 (one of the base regulating grooves).
The first rib portions 50 are each formed to extend between the hole step portion 48C of the base hole 48 and the one cylinder end 46A of the second base cylindrical portion 46 in the direction of the cylinder center line C of the switching base 22. The first rib portions 50 are fixed to the base cylindrical portions 45 and 46 and the fixing cylindrical portion 49, and are formed integrally with the base cylindrical portions 45 and 46 and the fixing cylindrical portion 49. The first rib portions 50 each have a rib width hA in the peripheral direction of the switching base 22.
The first rib portions 50 each include a rib flat surface 50A that is flush with the cylinder end surface 49A of the fixing cylindrical portion 49 (or the hole step portion 48C).
As shown in
The second rib portions 51 are arranged with an angular interval of 180 degrees in the peripheral direction of the switching base 22 (including the base cylindrical portions 45 and 46). The second rib portions 51 are each located at a center between the first rib portions 50 in the peripheral direction of the switching base 22, and are arranged at positions respectively corresponding to the base regulating grooves 56 and 57 (the other two base regulating grooves).
The second rib portions 51 are each formed to extend between the hole step portion 48C of the base hole 48 and the one cylinder end 46A of the second base cylindrical portion 46 in the direction of the cylinder center line C of the switching base 22. The second rib portions 51 are fixed to the base cylindrical portions 45 and 46 and the fixing cylindrical portion 49, and are formed integrally with the base cylindrical portions 45 and 46 and the fixing cylindrical portion 49. The second rib portions 51 each have a rib width hB in the peripheral direction of the switching base 22. The rib width hB of each of the second rib portions 51 is larger than the rib width hA of each of the first rib portions 50 (rib width hB>rib width hA).
The second rib portions 51 each include a rib flat surface 51A that is flush with the cylinder end surface 49A of the fixing cylindrical portion 49 (or the hole step portion 48C).
This configuration, as shown in
As shown in
The base protrusions 59 and 60 are arranged between the base hole 48 (or the small-diameter hole portion 48A) and the outer peripheral surface of the base annular plate 47 in the direction orthogonal to the cylinder center line C of the switching base 22.
The base protrusions 59 are arranged with an angular interval of 180 degrees in the peripheral direction of the switching base 22. The base protrusions 59 and 60 are arranged (in a concyclic manner) on a circle that has a center along the cylinder center line C of the switching base 22 and is located on an outer side of the base hole 48.
The base protrusions 59 and 60 are each formed to protrude from the other cylinder end 45B of the first base cylindrical portion 45 and the base annular plate 47 in the direction of the cylinder center line C of the switching base 22.
As shown in
The base protrusion 59 includes a first base regulating flat surface 59A located at a base distance HA from a base longitudinal straight line LX that is orthogonal to the cylinder center line C of the switching base 22 and passes a center of the base regulating groove 55. The first base regulating flat surface 59A is formed in parallel to the base longitudinal straight line LX.
The base protrusion 59 includes a second base regulating flat surface 59B located at the base distance HA from a base transverse straight line LY that is orthogonal to the cylinder center line C of the switching base (or the base longitudinal straight line LX) and passes a center of each of the base regulating grooves 56 and 57. The second base regulating flat surface 59B is formed in parallel to the base transverse straight line LY.
As shown in
The base protrusion 60 includes a third base regulating flat surface 60A located at a base distance HB from the base transverse straight line LY. The third base regulating flat surface 60A is formed in parallel to the base transverse straight line LY.
The base protrusion 60 includes a fourth base regulating flat surface 60B located at the base distance HB from the base longitudinal straight line LX. The fourth base regulating flat surface 60B is formed in parallel to the base longitudinal straight line LX. The base distance HB is a dimension (distance) equal to the base distance HA (base distance HA=base distance HB).
As shown in
As shown in
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As shown in
The valve seat holes 64 and 65 are each formed to pass through the valve seat disk 63 in a direction of the cylinder center line D of the switching valve seat element 25, and are each opened in a disk front flat surface 63A and a disk back flat surface 63B of the valve seat disk 63. The valve seat holes 64 and 65 communicate with an inside of the valve seat cylindrical portion 62.
As shown in
The first regulating protrusions 66 are arranged on both sides of a valve seat straight line LB that is orthogonal to the cylinder center line D of the switching valve seat element 25 and passes the hole center line E of each of the valve seat holes 64 and 65. As shown in
This configuration, as shown in
In the direction of the cylinder center line D of the switching valve seat element 25, the first regulating protrusions 66 are each formed to protrude from the other cylinder end 62B of the valve seat cylindrical portion 62 and extend away from the valve seat disk 63.
As shown in
The second regulating protrusions 67 are arranged on the both sides of the valve seat straight line LB. Each of the second regulating protrusions 67 is arranged at the distance HC/2 from the valve seat straight line.
This configuration allows the second regulating protrusions 67 to be arranged with the insertion interval HC in the peripheral direction of the switching valve seat element 25.
In the direction of the cylinder center line D of the switching valve seat element 25, the second regulating protrusions 67 are each formed to protrude from the other cylinder end 62B of the valve seat cylindrical portion 62 and extend away from the valve seat disk 63.
As shown in
The spring receiving protruding portions 68 are arranged concentrically with the valve seat cylindrical portion 62 with the cylinder center line D of the switching valve seat element 25 being a center. As shown in
The spring receiving protruding portions 68 are formed integrally with the valve seat disk 63. The spring receiving protruding portions 68 are formed to protrude from the disk back flat surface 63B of the valve seat disk 63 into the valve seat cylindrical portion 62 in the direction of the cylinder center line D of the switching valve seat element 25.
As shown in
As shown in
As shown in
As shown in
The valve element annular plate 72 is arranged concentrically with the first valve element cylindrical portion 71 with a cylinder center line F (a center line) of the switching valve element 27 (or the first valve element cylindrical portion 71) being a center. The valve element annular plate 72 is formed integrally with the first valve element cylindrical portion 71 so as to close one cylinder end 71A of the first valve element cylindrical portion 71.
As shown in
The second valve element cylindrical portion 73 is formed to protrude from the valve element annular plate 72 in a direction of the cylinder center line F of the switching valve element 27. An outer diameter D3 of the second valve element cylindrical portion 73 is smaller than the inner diameter d3 of the first valve element cylindrical portion 71 (the outer diameter D3<the inner diameter d3).
The second valve element cylindrical portion 73 has a shower outflow hole 87. The shower outflow hole 87 is arranged concentrically with the second valve element cylindrical portion 73 with the cylinder center line F of the switching valve element 27 being a center. The shower outflow hole 87 is formed to pass through the second valve element cylindrical portion 73 in the direction of the cylinder center line F of the switching valve element 27 (or the first valve element cylindrical portion 71). The shower outflow hole 87 is opened to one cylinder end 73A and the other cylinder end 73B of the second valve element cylindrical portion 73.
As shown in
As shown in
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As shown in
The cylindrical valve elements 76 and 77 are formed integrally with the central cylindrical portion 75.
The cylindrical valve elements 76 and 77 are formed integrally with the valve element disk 74 so as to be fixed to the disk back flat surface 74B of the valve element disk 74. The cylindrical valve elements 76 and 77 are each formed to extend from the disk back flat surface 74B of the valve element disk 74 into the first valve element cylindrical portion 71 in the direction of the cylinder center line F of the switching valve element 27 (or the first valve element cylindrical portion 71). The cylindrical valve elements 76 and 77 are each formed to protrude from the first valve element cylindrical portion 71 in the direction of the cylinder centerline F of the switching valve element 27.
Cylinder ends 76A and 77A of the cylindrical valve elements 76 and 77 and a cylinder end 75A of the central cylindrical portion 75, which protrude from the first valve element cylindrical portion 71, are formed into flat end surfaces that are flush with each other.
As shown in
As shown in
The hole diameter d5 of the valve element hole 88 is larger than the hole diameter d4 of each of the valve seat holes 64 and 65 (the hole diameter d5<the hole diameter d4).
As shown in
As shown in
As shown in
As shown in
As shown in
The valve element flow passage 78 is opened inside of the valve element hole 88 on the one cylinder end 76A side of the cylindrical valve element 76. The valve element flow passage 78 is formed to extend helically along an outer peripheral surface of the central cylindrical portion 75 while inclining toward a disk front flat surface 74A of the valve element disk 74 from a portion on the one cylinder end 76A side of the cylindrical valve element 76 on which the valve element flow passage 78 is opened inside of the valve element hole 88.
The valve element flow passage 78 is formed to extend to a position above the cylindrical valve element 77 (or above the valve element hole 90) and with an angular interval of 90 degrees from the portion on the one cylinder end 76A side of the cylindrical valve element 76, on which the valve element flow passage 78 is opened inside of the valve element hole 88, in the peripheral direction of the switching valve element 27. The valve element flow passage 78 is located at the position above the cylindrical valve element 77 in the disk front flat surface 74A of the valve element disk 74.
The valve element flow passage 78 is opened in the disk front flat surface 74A of the valve element disk 74 between the portion on the one cylinder end 76A side of the cylindrical valve element 76 and the cylindrical valve element 77, and communicates with the small-diameter hole portion 87B of the shower outflow hole 87.
In the upper half of the valve element disk 74, the valve element flow passage 78 is formed by recessing (or protruding) a portion of the valve element disk 74 adjacent to the central cylindrical portion 75 into a helical shape toward the one cylinder end 76A side of the cylindrical valve element 76 along the outer peripheral surface of the central cylindrical portion 75.
Thus, the valve element flow passage 78 is formed into a helical flow passage extending from the portion on the one cylinder end 76A side of the cylindrical valve element 76 to the position above the cylindrical valve element 77 (or above the valve element hole 90) along the outer peripheral surface of the central cylindrical portion 75.
As shown in
The valve element flow passage 79 is opened inside of the valve element hole 90 on the one cylinder end 77A side of the cylindrical valve element 77. The valve element flow passage 79 is formed to extend helically along the outer peripheral surface of the central cylindrical portion 75 while inclining toward the disk front flat surface 74A of the valve element disk 74 from a portion on the one cylinder end 77A side of the cylindrical valve element 77 on which the valve element flow passage 79 is opened inside of the valve element hole 90.
The valve element flow passage 79 is formed to extend to a position above the cylindrical valve element 76 (or above the valve element hole 88) and with an angular interval of 90 degrees from the portion on the one cylinder end 77A side of the cylindrical valve element 77, on which the valve element flow passage 79 is opened inside of the valve element hole 90, in the peripheral direction of the switching valve element 27. The valve element flow passage 79 is located at the position above the cylindrical valve element 76 in the disk front flat surface 74A of the valve element disk 74.
The valve element flow passage 79 is opened in the disk front flat surface 74A of the valve element disk 74 between the portion on the one cylinder end 77A side of the cylindrical valve element 77 and the cylindrical valve element 76, and communicates with the small-diameter hole portion 87B of the shower outflow hole 87.
In the lower half of the valve element disk 74, the valve element flow passage 79 is formed by recessing (or protruding) a portion of the valve element disk 74 adjacent to the central cylindrical portion 75 into a helical shape toward the one cylinder end 77A side of the cylindrical valve element 77 along the outer peripheral surface of the central cylindrical portion 75.
Thus, the valve element flow passage 79 is formed into a helical flow passage extending from the portion on the one cylinder end 77A side of the cylindrical valve element 77 to the position above the cylindrical valve element 76 (or above the valve element hole 88) along the outer peripheral surface of the central cylindrical portion 75.
As shown in
The first valve element protruding portions 80 are each formed to have a width hC/2 on each side thereof with respect to the valve element longitudinal straight line LC, and have a protruding width hC in the peripheral direction of the switching valve element 27. The protruding width hC of each of the first valve element protruding portions 80 is set smaller than the groove width hA of each of the first retaining grooves 35 (of the switching handle 21).
As shown in
As shown in
The second valve element protruding portions 81 are each formed to have a width hD/2 on each side thereof with respect to the valve element longitudinal straight line LD, and have a protruding width hD in the peripheral direction of the switching valve element 27. The protruding width hD of each of the second valve element protruding portions 81 is set smaller than the groove width hB of each of the second retaining grooves 36 (of the switching handle 21).
As shown in
The outer outflow holes 82 are formed to pass through the valve element annular plate 72 in the direction of the cylinder center line F of the switching valve element 27, and are opened in a disk front flat surface 72A and a disk back flat surface 72B of the valve element annular plate 72.
This configuration allows the outer outflow holes 82 to communicate with an inside of the first valve element cylindrical portion 71 on an outer side of each of the cylindrical valve elements 76 and 77.
As shown in
The first handle regulating protruding portions 83 are formed to extend between the outer peripheral surface of the cylindrical valve element 76 and the inner peripheral surface of the first valve element cylindrical portion 71, and are formed integrally with the cylindrical valve element 76 and the first valve element cylindrical portion 71.
The first handle regulating protruding portions 83 are arranged on both sides of the valve element transverse straight line LC in the peripheral direction of the switching valve element 27. The first handle regulating protruding portions 83 each include a valve element regulating flat surface 83A located at a valve element distance HD from the valve element transverse straight line LC. The valve element regulating flat surface 83A is formed in parallel to the valve element transverse straight line LC. The valve element distance HD is equal to the base distance HA of the base protrusion 59 and the base distance HB of the base protrusion 60 (of the switching base 22).
The first handle regulating protruding portions 83 are each formed to protrude from the disk back flat surface 72B of the valve element annular plate 72 and the disk back flat surface 74B of the valve element disk 74 toward the one cylinder end 76A side of the cylindrical valve element 76 in the direction of the cylinder center line F of the switching valve element 27.
As shown in
The second handle regulating protruding portions 85 are formed to extend between the outer peripheral surface of the cylindrical valve element 77 and the inner peripheral surface of the first valve element cylindrical portion 71, and are formed integrally with the cylindrical valve element 77 and the first valve element cylindrical portion 71.
The second handle regulating protruding portions 85 are arranged on the both sides of the valve element transverse straight line LC in the peripheral direction of the switching valve element 27. The second handle regulating protruding portions 85 each include a valve element regulating flat surface 85A located at the valve element distance HD from the valve element transverse straight line LC. The valve element regulating flat surface 85A is formed in parallel to the valve element transverse straight line LC.
The second handle regulating protruding portions 85 are formed to protrude from the disk back flat surface 72B of the valve element annular plate 72 and the disk back flat surface 74B of the valve element disk 74 toward the one cylinder end 77A side of the cylindrical valve element 77 in the direction of the cylinder center line F of the switching valve element 27.
As shown in
The sealing rings 28 are fitted in the sealing groove 89 of the cylindrical valve element 76 and the sealing groove 91 of the cylindrical valve element 77, respectively. The sealing rings 28 are arranged in the sealing grooves 89 and 91 so as to protrude from the cylinder end 76A of the cylindrical valve element 76 and the cylinder end 77A of the cylindrical valve element 77.
As shown in
In the flow passage switching means 2, as shown in
As shown in
The switching base 22 is arranged so that the base annular plate 47 is inserted in the medium-diameter hole portion 33B of the switching handle 21, and that the first base cylindrical portion 45 and the sealing gasket 23 are inserted in the small-diameter hole portion 33C of the switching handle 21. As shown in
The base annular plate 47 is brought into abutment against the second hole step portion 33E of the switching handle 21 in the medium-diameter hole portion 33B of the handle hole 33, thereby placing the switching base 22 concentrically with the switching handle 21.
When the switching base 22 is placed in the switching handle 21, the one cylinder end 46A of the second base cylindrical portion 46 of the switching base 22 and the sealing ring 24 (or the sealing groove 54) are arranged to protrude from the one cylinder end 31A of the first handle cylindrical portion 31 of the switching handle 21, and extend in the direction of the cylinder center line B of the switching handle 21.
Further, when the switching base 22 is placed in the switching handle 21, as shown in
Thus, the switching handle 21 is freely turn around the switching base 22.
The switching handle 21 is turned under a state in which the small-diameter hole portion 33C of the handle hole 33 is in sliding contact with the sealing gasket 23 in the switching base 22.
As shown in
As shown in
Thus, in the flow passage switching means 2, the switching base 22 is placed in the switching handle 21 so that the handle unit HU is assembled.
In the flow passage switching means 2, as shown in
As shown in
As shown in
With regard to the handle unit HU, the second base cylindrical portion 46 of the switching base 22 is inserted into the shower cylindrical portion 8 (or into the outflow passage 10) from the cylinder end 46A, and the first handle cylindrical portion 31 of the switching handle 21 is inserted into the guide protruding portion 12 and the shower space 7C.
In the handle unit HU, as shown in
Thus, the switching base 22 is mounted to the head portion 7 of the shower main body 1 so as to be unturnable.
As shown in
In the handle unit HU, the second base cylindrical portion 46 of the switching base 22 is inserted in the outflow passage 10 under a state in which the sealing ring 24 is held in press-contact with the inner peripheral surface of the shower cylindrical portion 8 (or the outflow passage 10). The handle unit HU is placed on the handle portion 6 under a state in which the one cylinder end 46A of the second base cylindrical portion 46 is held in abutment against the hole step portion 10C of the outflow passage 10.
In the handle unit HU, as shown in
Thus, the bolt receiving hole 58 of the switching base 22 communicates with the screw hole 15 of the base protruding portion 13.
In the handle unit HU, as shown in
When the handle unit HU is thus arranged in the shower space 7C and the outflow passage 10 of the shower main body 1, as shown in
In the handle unit HU, as shown in
In the flow passage switching means 2, as shown in
As shown in
A bolt shank 29A is inserted into the large-diameter hole portion 58A and the small-diameter hole portion 58B (or the bolt receiving hole 58) of the fixing cylindrical portion 49 so that the fixing screw bolt 29 is screwed into the screw hole 15 of the base protruding portion 13 (or the shower main body 1). A bolt head 29B is inserted into the large-diameter hole portion 58A of the fixing cylindrical portion 49 so that the fixing screw bolt 29 is arranged to be held in abutment against the hole step portion 58D.
Through turning of the fixing screw bolt 29, the second base cylindrical portion 46 of the switching base 22 is fastened to the base protruding portion 13.
Thus, as shown in
The switching handle 21 of the handle unit HU is mounted to the shower main body so as to be freely turnable.
In the switching base 22 of the handle unit HU, as shown in
As shown in
As shown in
Thus, as shown in
In the flow passage switching means 2, as shown in
As shown in
The switching valve seat element 25 is inserted in the small-diameter hole portion 48A of the switching base 22 under a state in which the first rib portions 50 of the switching base are located between the first regulating protrusions 66 (within the base distance HA) and between the second regulating protrusions 67 (within the base distance HA).
As shown in
As shown in
The switching valve seat element 25 is inserted in the small-diameter hole portion 48A of the switching base 22 while compressing the coil spring 30, which is received within the spring receiving protruding portions 68, toward the switching base 22 side.
As shown in
Thus, the switching valve seat element 25 is arranged in the switching base 22 and the shower main body 1 (or the head portion 7) so as to be unturnable. The switching valve seat element 25 is freely movable in the direction of the cylinder center C of the switching base 22.
As shown in
As shown in
In the flow passage switching means 2, as shown in
As shown in
As shown in
As shown in
Thus, the switching valve element 27 is mounted to the switching handle 21 so as to be unturnable, and is turned together with the switching handle 21.
As shown in
As shown in
Thus, as shown in
The cylindrical valve elements 76 and 77 (or the valve element holes 88 and 90) communicate with the outflow passage 10 and the inflow passage 9 through the valve seat holes 64 and 65 of the switching valve seat element 25 and the base flow passages Z of the switching base 22.
As shown in
Thus, as shown in
As shown in
The valve element flow passages 78 and 79 of the switching valve element 27 communicate with the outflow passage 10 and the inflow passage 9 through the valve element holes 88 and 90, the valve seat holes 64 and 65 of the switching valve seat element 25, and the base flow passages Z of the switching base 22.
The valve element flow passages 78 and 79 communicate with the large-diameter hole portion 33A (or the handle hole 33) of the switching handle 21 through the shower outflow hole 87 of the second valve element cylindrical portion 73.
As shown in
With this configuration, the outer outflow holes 82 communicate with the outflow passage 10 and the inflow passage 9 through the valve seat holes 64 and 65 of the switching valve element 27 and the base inflow passages Z of the switching base 22.
Thus, as shown in
In the shower head X, as shown in
As shown in
The shower nozzle 3 includes a nozzle outer cylindrical portion 95, a shower nozzle plate 96, a shower cylindrical portion 97 (nozzle inner cylindrical portion), a plurality of air bubble-liquid mixture jetting holes 98, and a sealing ring 103.
As shown in
As shown in
As shown in
As shown in
As shown in
The shower nozzle plate 96 is fixed to the one cylinder end 95A of the nozzle outer cylindrical portion 95, and is formed integrally with the nozzle outer cylindrical portion 95.
As shown in
The shower cylindrical portion 97 (spray cylindrical portion) is arranged concentrically with the nozzle outer cylindrical portion 95 and the shower nozzle plate 96 with the cylinder center line H of the shower nozzle 3 being a center. The shower cylindrical portion 97 is arranged in the nozzle outer cylindrical portion 95 with a mist annular space YM between an inner peripheral surface of the nozzle outer cylindrical portion 95 and the shower cylindrical portion 97 in the direction orthogonal to the cylinder center line H of the shower nozzle 3.
One cylinder end 97A of the shower cylindrical portion 97 is closed by the shower nozzle plate 96, and the shower cylindrical portion 97 is formed integrally with the shower nozzle plate 96. The shower cylindrical portion 97 is formed to protrude from a disk back flat surface 96B of the shower nozzle plate 96 into the nozzle outer cylindrical portion 95 in the direction of the cylinder center line H of the shower nozzle 3.
As shown in
As shown in
As shown in
As shown in
The large-diameter hole portion 102A is opened to the one cylinder end 97B of the shower cylindrical portion 97. The medium-diameter hole portion 102B is arranged between the large-diameter hole portion 102A and the small-diameter hole portion 102C. The medium-diameter hole portion 102B is reduced in diameter at a first hole step portion 102D as compared to the large-diameter hole portion 102A, and is formed to extend toward the shower nozzle plate 96 side. The small-diameter hole portion 102C is reduced in diameter at a second hole step portion 102E as compared to the medium-diameter hole portion 102B, and is formed to extend to the shower nozzle plate 96 (or the disk back flat surface 96B).
With this configuration, the shower cylindrical portion 97 defines an air bubble mixing space BR into which the liquid flows from the other cylinder end 97B. The air bubble mixing space BR is defined in the shower cylindrical portion 97 by the nozzle hole 102.
As shown in
As shown in
The air bubble-liquid mixture jetting holes 98 are formed in the shower nozzle plate 96. The air bubble-liquid mixture jetting holes 98 are formed to pass through the shower nozzle plate 96 in the direction of the cylinder center line H of the shower nozzle 3, and are opened into the air bubble mixing space BR in the shower cylindrical portion 97.
As shown in
As shown in
The sealing ring 103 is externally fitted to the nozzle outer cylindrical portion 95, and is fitted in the sealing groove 99. The sealing ring 103 is arranged in the sealing groove 99 so as to protrude from the outer peripheral surface of the nozzle outer cylindrical portion 95.
In the shower head X, the air bubble-liquid mixture generating means 4 (the air bubble generating unit) is configured to generate the air bubble-liquid mixture by mixing the air (air bubbles) into the liquid.
As shown in
As shown in
As shown in
As shown in
As shown in
The flow-adjustment annular plate 115 is arranged at the other cylinder end 113B of the flow-adjustment cylindrical portion 113 along an entire outer peripheral surface of the flow-adjustment cylindrical portion 113, and is formed integrally with the flow-adjustment cylindrical portion 113. The flow-adjustment annular plate 115 is formed to protrude from the outer peripheral surface of the flow-adjustment cylindrical portion 113 in a direction orthogonal to the cylinder center line J of the flow-adjustment piece 111 (or the flow-adjustment cylindrical portion 113).
As shown in
The flow-adjustment-piece plates 116 are each formed into a rectangular shape (rectangle). The flow-adjustment-piece plates 116 are arranged at equal angular intervals of 90 degrees in the circumferential direction of the flow-adjustment nozzle disk 114 (or the flow-adjustment piece 111).
The flow-adjustment-piece plates 116 are formed to protrude by a plate width HS from a disk front flat surface 114A of the flow-adjustment nozzle disk 114 in a direction of the cylinder center line J (the center line) of the flow-adjustment piece 111. The flow-adjustment-piece plates 116 are each formed to protrude in a direction orthogonal to the flow-adjustment nozzle disk 114 so as to be away from the other cylinder end 113B of the flow-adjustment cylindrical portion 113.
As shown in
The flow-adjustment-piece plates 116 each have a plate thickness TS in the peripheral direction of the flow-adjustment nozzle disk 114 (or the peripheral direction of the flow-adjustment piece 111).
As shown in
The flow-adjustment flat surfaces 116A and 116B are each formed into a rectangular shape so as to be parallel to each other with an interval equal to the plate thickness TS in the peripheral direction of the flow-adjustment nozzle disk 114.
As shown in
As shown in
The liquid throttle holes 117 are each formed into a conical hole having a diameter gradually reducing from the disk back flat surface 114B toward the disk front flat surface 114A of the flow-adjustment nozzle disk 114 in the direction of the plate center line J of the flow-adjustment nozzle disk 114 (or the cylinder center line of the flow-adjustment piece 111).
As shown in
On each of the circles CG, CH, and CI, the plurality of liquid throttle holes 117 are arranged at equal intervals (equal pitches) in the peripheral direction (circumferential direction) of the flow-adjustment nozzle disk 114 (or the flow-adjustment piece 111).
As shown in
In the air bubble-liquid mixture generating means 4, as shown in
The air introduction passages 112 are arranged on a circle CJ that has a center along the cylinder center line H (the center line) of the shower nozzle 3 and is located on an outer side of the air bubble-liquid mixture jetting holes 98. The air introduction passages 112 are arranged at equal angular intervals of 120 degrees in the peripheral direction of the shower nozzle 3 (or the shower cylindrical portion 97).
The air introduction passages 112 are opened in a disk front surface 96A of the shower nozzle plate 96. As shown in
The air introduction passages 112 are opened into the air bubble mixing space BR in the shower cylindrical portion 97. The air introduction passages 112 are adjacent to the second hole step portion 112E of the shower cylindrical portion 97, and are opened in the medium-diameter hole portion 102B (or in the nozzle hole 102).
As shown in
The flow-adjustment piece 111 is arranged concentrically with the shower cylindrical portion 97 with the cylinder center line H of the shower nozzle 3 being a center. The flow-adjustment piece 111 is arranged in the air bubble mixing space BR in the shower cylindrical portion 97. The flow-adjustment piece 111 is press-fitted (inserted) into the nozzle hole 102 (or into the large-diameter hole portion 102A and the medium-diameter hole portion 102B) of the shower cylindrical portion 97 from the flow-adjustment-piece plates 116.
The flow-adjustment cylindrical portion 113 of the flow-adjustment piece 111 is press-fitted (inserted) into the medium-diameter hole portion 102B of the shower cylindrical portion 97. The flow-adjustment cylindrical portion 113 is press-fitted (inserted) into the medium-diameter hole portion 102B (or the nozzle hole 102) of the shower cylindrical portion 97 with a gap between the disk back flat surface 114B of the flow-adjustment nozzle disk 114 and the second hole step portion 102E of the nozzle hole 102 in the cylinder centerline H of the shower nozzle 3. At this time, as shown in
The flow-adjustment annular plate 115 of the flow-adjustment piece 111 is press-fitted (inserted) into the large-diameter hole portion 102A of the shower cylindrical portion 97, and is brought into abutment against the first hole step portion 102D.
Thus, as shown in
As shown in
As shown in
As shown in
As shown in
With this configuration, through the air introduction passages 112, the air flows into the air bubble mixing space BR from the direction orthogonal to the hole center line M of each of the liquid throttle holes 117.
As shown in
Thus, as shown in
In the shower head X, the mist generating means 5 (the mist generating unit) is configured to form the liquid into the mist of liquid droplets in which the air bubbles are mixed.
As shown in
As shown in
As shown in
As shown in
With this configuration, the plurality of mist throttle holes 121 are arranged in the shower nozzle 3 on the outer side of the air bubble-liquid mixture jetting holes 98 (or the air bubble-liquid mixture generating means 4).
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
The guide protrusions 125 are arranged on the circle CL of the guide ring 123. The guide protrusions 125 are arranged at equal angular intervals of 30 degrees in the circumferential direction of the guide ring 123. The guide protrusions 125 are formed to protrude in a direction orthogonal to a center line K of the mist ring body 122 (or the guide ring 123), and are formed integrally with the guide ring 123.
As shown in
The first and second spiral surfaces 127 and 128 are each formed into the same spiral shape. The first and second spiral surfaces 127 and 128 are arranged between the cone bottom flat surface 124B and the cone upper surface 124A to cross the cone side surface 124C.
The first and second spiral surfaces 127 and 128 are arranged so as to be point symmetrical with respect to a cone center line L. The second spiral surface 128 is arranged at a position turned about the cone center line L by an angle of 180 degrees from a position of the first spiral surface 127.
The first and second spiral surfaces 127 and 128 are each formed into a spiral shape having a diameter gradually reducing from the cone bottom flat surface 124B toward the cone upper surface 124A, and are formed to extend to the cone upper surface 124A.
The first and second spiral surfaces 127 and 128 are arranged so as to be opposed to each other at the cone upper surface 124A.
As shown in
As shown in
As shown in
As shown in
With this configuration, the mist guides 124 and the guide ring 123 form the mist ring body 122. The mist ring body 122 includes the guide ring 123, the mist guides 124, and the guide protrusions 125 formed integrally with each other.
In the mist generating means 5, as shown in
As shown in
As shown in
Each of the mist guides 124 is inserted into each of the mist throttle holes 121 from the cone upper surface 124A. Each of the mist guides 124 is arranged in each of the mist throttle holes 121 so that the cone center line L is aligned with a hole center line N of each of the mist throttle holes 121. Each of the mist guides 124 is inserted into each of the mist throttle holes 121 from the cone upper surface 124A with a gap between the cone side surface 124C and a conical inner peripheral surface 121A of each of the mist throttle holes 121. Each of the mist guides 124 is fitted in each of the mist throttle holes 121 so that the cone bottom flat surface 124B side (or the cone side surface 124C on the cone bottom flat surface 124B side) is held in abutment against the conical inner peripheral surface 121A of each of the mist throttle holes 121.
Thus, each of the mist guides 124 is fitted in each of the mist throttle holes 121 so as to define first and second mist flow passages 51 and 52 each having a spiral shape between the first and second spiral surfaces 127 and 128 and the conical inner peripheral surface 121A of each of the mist throttle holes 121 and between the cone side surface 124C and the conical inner peripheral surface 121A. Each of the mist guides 124 and each of the mist throttle holes 121 define the first and second mist flow passages 51 and 52 each having a spiral shape (helical shape) along the first and second spiral surfaces 127 and 128. As shown in
As shown in
As shown in
Thus, the sealing ring 130 is freely brought into abutment against the guide protrusions 125 of the mist ring body 122, thereby preventing the mist ring body 122 from slipping off.
As shown in
As shown in
As shown in
As shown in
The nozzle unit NU is arranged so that the threaded portion 100 of the shower nozzle 3 is screwed into the threaded portion 34 of the switching handle 21. Through turning of the nozzle unit NU, the nozzle outer cylindrical portion 95 of the shower nozzle 3 is received in the large-diameter hole portion 33A (or in the handle hole) of the switching handle 21. The shower nozzle 3 is turned until the other cylinder end 95B of the nozzle outer cylindrical portion 95 is brought into abutment against the first valve element protruding portions 80 of the switching valve element 27.
At this time, the sealing ring 103 of the shower nozzle 3 is brought into in press-contact with the large-diameter hole portion 33A of the switching handle 21, thereby sealing the large-diameter hole portion 33A in a liquid-tight manner.
Thus, the shower nozzle 3 of the nozzle unit NU is fixed to the switching handle 21, and is fitted to the other end 1B of the shower main body 1.
In the shower nozzle 3, the shower nozzle plate 96 defines a liquid inflow space RP in the outflow passage 10. The liquid inflow space RP is a space sealed in a liquid-tight manner, and the liquid is caused to flow into the liquid inflow space RP through the outflow passage 10.
In the nozzle unit NU, as shown in
Thus, the shower cylindrical portion 97 of the shower nozzle 3 is inserted in the large-diameter hole portion 87A (or the shower outflow hole 87) of the switching valve element 27 so as to protrude toward the outflow passage 10 side (into the liquid inflow space RP). The liquid (liquid in a liquid inflow space PR) having flowed out through the outflow passage 10 and having flowed out through the switching valve element 27 is caused to flow from the other cylinder end 97B (or the liquid throttle holes 117 of the flow-adjustment piece 111) into the air bubble mixing space BR in the shower cylindrical portion 97.
When the shower nozzle 3 of the nozzle unit NU is fixed to the switching handle 21, the shower nozzle 3, the flow-adjustment piece 111 (of the air bubble-liquid mixture generating means 4), the mist ring body 122 (of the mist generating means 5), and the switching valve element 27 are freely turnable together with the switching handle 21 with respect to the switching valve seat element 25, the switching base 22, and the shower main body 1.
As shown in
Thus, as shown in
As shown in
In the flow passage switching means 2, the switching valve seat element 25 and the switching valve element 27 are arranged between the flow-adjustment piece 111 and the outflow passage 10 and within the liquid inflow space RP, and the switching base 22 is arranged in the outflow passage 10.
As shown in
In the mist generating means 5, the mist throttle holes 121 are each opened to the outflow passage 10 side and in the liquid inflow space RP between the shower nozzle plate 96 and the flow passage switching means 2 (or the switching valve element 27).
With this configuration, the mist throttle holes 121 are each formed to pass through the shower nozzle plate 96 while gradually reducing a diameter from the outflow passage 10 side (or the liquid inflow space BR side).
The mist throttle holes 121 each communicate with the outflow passage 10 through the outer outflow holes 82 of the switching valve element 27, the valve seat holes 64 and 65 of the switching valve seat element 25, and the base inflow passages Z of the switching base 22 (or the liquid inflow space PR).
In the mist generating means 5, as shown in
The guide ring 123 and the guide protrusions 125 are brought into abutment against the disk back flat surface 96B of the shower nozzle plate 96 from the outflow passage 10 side (or the liquid inflow space PR side or the mist annular space YM side).
As shown in
When the shower nozzle 3 is turned, the switching valve element 27 and the switching valve seat element 25 are pressed toward the switching base 22 side, thereby compressing the coil spring 30. The compressed coil spring 30 urges the switching valve seat element 25 to the switching valve element 27 by a spring force, thereby bringing the valve seat disk 63 (or the disk front flat surface 63A) into press-contact with the sealing rings 28 of the cylindrical valve elements 76 and 77.
Thus, the sealing rings 28 connect the valve element hole 88 of the cylindrical valve element 76 and the valve element hole 90 of the cylindrical valve element 77 to the valve seat holes 64 and 65 in a liquid-tight manner, respectively.
When the nozzle unit NU (including the shower nozzle 3, the air bubble-liquid mixture generating means 4, and the mist generating means 5) and the flow passage switching means 2 (including the switching handle 21, the switching base 22, the switching valve seat element 25, and the switching valve element 27) are thus mounted to the shower main body 1 (or the head portion 7), as shown in
At the shower position P1, as shown in
At the shower position P1, as shown in
At the shower position P1, the flow passage switching means 2 connects the liquid throttle holes 117 of the air bubble-liquid mixture generating means 4 to the outflow passage 10. The liquid throttle holes 117 of the flow-adjustment piece 111 each communicate with the outflow passage 10 of the shower main body 1 through the valve element flow passages 78 and 79 and the valve element holes 88 and 90 of the switching valve element 27, the valve seat holes 64 and 65 of the switching valve seat element 25, and the base inflow passages Z of the switching base 22.
At the shower position P1, as shown in
As shown in
The liquid having flowed into the inflow passage 9 is caused to flow into the outflow passage 10. Through the outflow passage 10, the liquid having flowed from the inflow passage 9 is caused to flow out. As shown in
As shown in
In the switching valve element 27, as shown in
At this time, as shown in
The liquid having flowed into the shower outflow hole 87 is jetted into the air bubble mixing space BR through the liquid throttle holes 117 of the flow-adjustment piece 111 (or the air bubble-liquid mixture generating means 4). Thus, through the liquid throttle holes 117, the liquid having flowed out through the outflow passage 10 is jetted into the air bubble mixing space BR.
At this time, as shown in
When the liquid is jetted into the air bubble mixing space BR, due to the jet of the liquid, the air is introduced through the air introduction passages 112 into the air bubble mixing space BR. Through the air introduction passages 112, the air is caused to flow between the flow-adjustment-piece plates 116 in the air bubble mixing space BR.
As shown in
Thus, the air introduced into the air bubble mixing space BR is mixed into the liquid at the same time as the liquid is jetted through the liquid throttle holes 117.
In the air bubble mixing space BR, the liquid and the air flow turbulently by being introduced by the protruding ends 116D along the flow inclined surfaces 118 of the flow-adjustment-piece plates 116, and then flow into the mixing gap GP between the protruding ends 116D of the flow-adjustment-piece plates 116 and the shower nozzle plate 96.
Thus, on the protruding end 116D side protruding toward the shower nozzle 3 (or the shower nozzle plate 96), each of the flow-adjustment-piece plates 116 causes the liquid jetted through the liquid throttle holes 117 to flow turbulently and flow into the mixing gap GP.
In the mixing gap GP within the air bubble mixing space BR, due to the turbulent flow, the air mixed into the liquid is broken (divided) into micrometer-sized air bubbles (microbubbles) and nanometer-sized air bubbles (ultrafine bubbles).
The micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) mix with and dissolve in the liquid.
The liquid (air bubble-liquid mixture), in which the micrometer-sized air bubbles and the nanometer-sized air bubbles are mixed, is jetted to the outside through the air bubble-liquid mixture jetting holes 98 of the shower nozzle plate 96. Through the air bubble-liquid mixture jetting holes 98, the air bubble-liquid mixture is jetted out of the air bubble mixing space BR.
As shown in
The switching valve element 27 (of the flow passage switching means 2), the shower nozzle 3, the flow-adjustment piece 111 (of the air bubble-liquid mixture generating means 4), and the mist ring body 122 (of the mist generating means 5) are turned at the same time as the switching handle 21 is turned.
Thus, the shower head X is turned from the shower position P1 to the mist position P2.
At the mist position P2, as shown in
At this time, along with turning of the switching valve element 27, the sealing rings 28 are brought into slide-contact with the valve seat disk 63 (or the disk front flat surface 63A) of the switching valve seat element 25 so that the cylindrical valve elements 76 and 77 are closed. Due to the spring force of the coil spring 30, the valve seat disk 63 of the switching valve seat element 25 is held in press-contact with the sealing rings 28 in the closed cylindrical valve elements 76 and 77.
Thus, the sealing rings 28 seal the valve element holes 88 and 90 in a liquid-tight manner, and block (close) the valve element holes 88 and 90 from the valve seat holes 64 and 65 of the switching valve seat element 25.
At the mist position P2, the flow passage switching means 2 connects the mist throttle holes 121 (of the mist ring body 122) of the mist generating means 5 to the outflow passage 10. The mist throttle holes 121 (of the mist ring body 122) communicate with the outflow passage 10 of the shower main body 1 through the liquid inflow space RP between the switching valve element 27 and the shower nozzle 3, the outer outflow holes 82 of the switching valve element 27, the valve seat holes 64 and 65 of the switching valve seat element 25, and the base inflow passages Z of the switching base 22.
At the mist position P2, as shown in
As shown in
The liquid having flowed into the inflow passage 9 is caused to flow into the outflow passage 10. Through the outflow passage 10, the liquid having flowed from the inflow passage 9 is caused to flow out. As shown in
As shown in
The liquid flows through the liquid inflow space PR into the mist throttle holes 121.
As shown in
The liquid is increased in pressure by flowing through the first and second mist flow passages 51 and 52 each having a spiral shape, and is jetted into the mist throttle holes 121 through the first and second mist flow passages 51 and 52.
Thus, the liquid jetted into the mist throttle holes 121 through the first and second mist flow passages 51 and 52 flows turbulently at high pressure. Further, when the mist of liquid droplets is jetted through the mist throttle holes 121, an outlet side of each of the mist throttle holes 121 (side from which the mist of liquid droplets is jetted) is brought into a negative pressure state.
With the outlet side of each of the mist throttle holes 121 brought into the negative pressure state, when the liquid, which is jetted into the mist throttle holes 121 through the first and second mist flow passages 51 and 52 and flows turbulently at high pressure, passes through the outlet portion of each of the mist throttle holes 121, the air bubbles are separated due to reduced pressure, and the air that is taken in at the time of jetting is broken (divided) by the turbulent flow. Thus, the liquid is formed into the mist of liquid droplets in which the micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) are mixed and dissolved.
Further, at the cone upper surface 124A of each of the mist guides 124, the liquid is jetted into each of the mist throttle holes 121 through the first and second mist flow passages 51 and 52 opposed to each other, and collides with the mist guide 124 and the shower nozzle plate 96, thereby being formed into the mist of liquid droplets in which a sufficient volume of air bubbles is mixed. The mist of liquid droplets in which the air bubbles are mixed is jetted through each of the mist throttle holes 121. Through each of the mist throttle holes 121, the mist of liquid droplets in which the air bubbles are mixed is jetted to the outside.
Thus, the mist generating means 5 forms the liquid having flowed out through the outflow passage 10 into the mist of liquid droplets in which the air bubbles are mixed.
The shower head X is thus set to the shower position P1 or the mist position P2 through forward and reverse turning of the switching handle 21 within an angle range of 90 degrees.
At this time, as shown in
When the shower head X is switched to the shower position P1 or the mist position P2, the shower head X can jet the air bubble-liquid mixture at the shower position P1, and can jet the mist of liquid droplets, in which the air bubbles are mixed, at the mist position P2.
In the shower head X, the number of the flow-adjustment-piece plates 116 is not limited to four. It is only required that the number of the flow-adjustment-piece plates 116 be plural, for example, three, five, or six and soon. The plurality of flow-adjustment-piece plates 116 are formed on the flow-adjustment nozzle disk 114 at equal intervals in the peripheral direction of the flow-adjustment nozzle disk 114.
In the shower head X, the number of the spiral surfaces of the mist guide 124 is not limited to two. It is only required that the number of the spiral surfaces of the mist guide 124 be plural, for example, three, four, or five and so on. The plurality of spiral surfaces are formed on the mist guide 124 (or the cone side surface 124C) at equal intervals in the peripheral direction with the cone center line L of the mist guide 124 being a center.
For the shower head X, a “shower test” of generating the air bubble-liquid mixture (air bubble-water mixture) was carried out under a condition in which the shower nozzle 3 and the liquid generating means 4 (including the flow-adjustment piece 111 and the air introduction passages 112) were used.
For the shower head X, a “mist test” of generating the mist of liquid droplets (mist of water droplets) was carried out under a condition in which the mist generating means 5 (including the mist throttle holes 121 and the mist guides 124) was used.
In the “shower test” and the “mist test”, similarly to the description with reference to
<1> “Shower Test”
The “shower test” was carried out in Example 1, Example 2, Example 3, and Comparative Example 1.
(1) Shower Nozzle
The “shower nozzle 3” was common (the same) in Example 1, Example 2, Example 3, and Comparative Example 1.
The “shower nozzle 3” in Example 1, Example 2, Example 3, and Comparative Example 1 is described with reference to
The “shower nozzle 3” in Example 1, Example 2, Example 3, and Comparative Example 1 has the following configuration.
Total number of the air bubble-liquid mixture jetting holes 98: 36
Hole diameter of each of the air bubble-liquid mixture jetting holes 98 (conical hole): 1.4 mm (opened in the disk front surface 96A)
Hole diameter of each of the air bubble-liquid mixture jetting holes 98 (conical hole): 1.8 mm (opened in the disk back flat surface 96B)
Radius r3 of the circle CD: 3.5 mm.
Radius r4 of the circle CE: 6.2 mm.
Radius r5 of the circle CF: 8.7 mm.
Number of the air bubble-liquid mixture jetting holes 98 arranged on the circle CD: 6 (arranged at equal pitches in the peripheral direction of the shower cylindrical portion 97)
Number of the air bubble-liquid mixture jetting holes 98 arranged on the circle CE: 12 (arranged at equal pitches in the peripheral direction of the shower cylindrical portion 97)
Number of the air bubble-liquid mixture jetting holes 98 arranged on the circle CF: 18 (arranged at equal pitches in the peripheral direction of the shower cylindrical portion 97)
Inner diameter d5 of the small-diameter hole portion of the handle hole 33: 6.2 mm
(2) Flow-Adjustment Piece
The “flow-adjustment piece 111” in Example 1 is described with reference to
The “flow-adjustment piece 111” in Example 1 has the following configuration.
Total number of the liquid throttle holes 117: 40
Hole diameter da of each of the liquid throttle holes 117: 0.6 mm (opened in the disk front flat surface 114A)
Hole diameter db of each of the liquid throttle holes 117: 1.0 mm (opened in the disk back flat surface 114B)
Radius r6 of the circle CG: 4.0 mm
Radius r7 of the circle CH: 6.0 mm
Radius r8 of the circle CI: 9.0 mm
Number of the liquid throttle holes 117 arranged on the circle CG: 8 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that two holes are formed in each region between the flow-adjustment-piece plates 116)
Number of the liquid throttle holes 117 arranged on the circle CH: 12 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that three holes are formed in each region between the flow-adjustment-piece plates 116)
Number of the liquid throttle holes 117 arranged on the circle CI: 20 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that five holes are formed in each region between the flow-adjustment-piece plates 116)
Piece height of the flow-adjustment piece 111: 8.2 mm
Number of the flow-adjustment-piece plates 116: 4 (arranged at equal angular intervals of 90 degrees in the peripheral direction of the flow-adjustment nozzle disk 114)
Plate width HS of the flow-adjustment-piece plate 116: 4.0 mm
Plate length LS of the flow-adjustment-piece plate 116: 9.2 mm
Plate thickness TS of the flow-adjustment-piece plate 116: 1.4 mm
Radius rX (of the arc) of the flow inclined surface 118: 1.0 mm
The “flow-adjustment piece 111” in Example 2 is described with reference to
The “flow-adjustment piece 111” in Example 2 has the following configuration.
Total number of the liquid throttle holes 117: 48
Hole diameter da of each of the liquid throttle holes 117: 0.6 mm (opened in the disk front flat surface 114A)
Hole diameter db of each of the liquid throttle holes 117: 1.0 mm (opened in the disk back flat surface 114B)
Radius r6 of the circle CG: 2.0 mm
Radius r7 of the circle CH: 4.0 mm
Radius r8 of the circle CI: 6.0 mm
Radius r9 of the circle CM: 9.0 mm
Number of the liquid throttle holes 117 arranged on the circle CG: 4 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that one hole is formed in each region between the flow-adjustment-piece plates 116)
Number of the liquid throttle holes 117 arranged on the circle CH: 8 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that two holes are formed in each region between the flow-adjustment-piece plates 116)
Number of the liquid throttle holes 117 arranged on the circle CI: 16 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that four holes are formed in each region between the flow-adjustment-piece plates 116)
Number of the liquid throttle holes 117 arranged on the circle CM: 20 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that five holes are formed in each region between the flow-adjustment-piece plates 116)
The “flow-adjustment piece 111” in Example 2 is the same as the “flow-adjustment piece 111” in Example 1 with regard to the piece height of the flow-adjustment piece 111, the number of the flow-adjustment-piece plates 116, the plate width HS of each of the flow-adjustment-piece plates 116, the plate length LS of each of the flow-adjustment-piece plates 116, the plate thickness TS of each of the flow-adjustment-piece plates 116, and the radius rX (of the arc) of the flow inclined surface 118.
The “flow-adjustment piece 111” in Example 3 is described with reference to
The “flow-adjustment piece 111” in Example 3 has the following configuration.
Total number of the liquid throttle holes 117: 52
Hole diameter da of each of the liquid throttle holes 117: 0.6 mm (opened in the disk front flat surface 114A)
Hole diameter db of each of the liquid throttle holes 117: 1.0 mm (opened in the disk back flat surface 114B)
Radius r6 of the circle CG: 2.0 mm
Radius r7 of the circle CH: 4.0 mm
Radius r8 of the circle CI: 6.0 mm
Radius r9 of the circle CM: 9.0 mm
Number of the liquid throttle holes 117 arranged on the circle CG: 4 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that one hole is formed in each region between the flow-adjustment-piece plates 116)
Number of the liquid throttle holes 117 arranged on the circle CH: 8 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that two holes are formed in each region between the flow-adjustment-piece plates 116)
Number of the liquid throttle holes 117 arranged on the circle CI: 16 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that four holes are formed in each region between the flow-adjustment-piece plates 116)
Number of the liquid throttle holes 117 arranged on the circle CM: 24 (arranged at equal pitches in the peripheral direction of the flow-adjustment nozzle disk 114 so that six holes are formed in each region between the flow-adjustment-piece plates 116)
The “flow-adjustment piece 111” in Example 3 is the same as the “flow-adjustment piece 111” in Example 1 with regard to the piece height of the flow-adjustment piece 111, the number of the flow-adjustment-piece plates 116, the plate width HS of each of the flow-adjustment-piece plates 116, the plate length LS of each of the flow-adjustment-piece plates 116, the plate thickness TS of each of the flow-adjustment-piece plates 116, and the radius rX (of the arc) of the flow inclined surface 118.
Unlike the “flow-adjustment piece” in Example 1, Example 1, and Example 3, the “flow-adjustment piece” in Comparative Example 1 is a “flow-adjustment piece without a flow-adjustment-piece plate”, in which the flow-adjustment-piece plates are not formed on the flow-adjustment nozzle disk.
The “flow-adjustment piece” in Comparative Example 1 is the same as that in Example 1 with regard to the number of the liquid throttle holes, the hole diameter of each of the liquid throttle holes, the radii r6 to r8 of the circles CG to CI, and the number of the liquid throttle holes arranged on each of the circles CG to CI.
(3) Air Introduction Passage
The “air introduction passage 112” is common (the same) in Example 1, Example 2, Example 3, and Comparative Example 1.
The “air introduction passage 112” in Example 1, Example 2, Example 3, and Comparative Example 1 is described with reference to
The “air introduction passage 112” in Example 1, Example 2, Example 3, and Comparative Example 1 has the following configuration.
Number of the air introduction passages: 3
Radius of the circle CJ: 12.25 mm
The air introduction passages 112 were arranged on the circle CJ, and were arranged at equal angular intervals (equal pitches) of 120 degrees in the circumferential direction of the circle CJ (or the shower nozzle 3).
(4) Air Bubble Mixing Space and Mixing Gap
Similarly to the description with reference to
The “air bubble mixing space BR” is common (the same) in Example 1, Example 2, Example 3, and Comparative Example 1, and has the following configuration.
Hole diameter d5 of the air bubble mixing space: 6.2 mm
Hole length LK of the air bubble mixing space: 7.0 mm
The “mixing gap GP” is common (the same) in Example 1, Example 2, and Example 3, and has the following configuration.
Mixing gap GP: 2.8 mm
(5) Arrangement and Opening Dimension of Air Introduction Passage
Similarly to the description with reference to
The “air introduction passage” in Example 1, Example 2, Example 3, and Comparative Example 1 has the following configuration.
Opening width AH: 5.05 mm
Opening height AL: 0.8 mm
The opening width is a dimension in the peripheral direction of the shower cylindrical portion. The opening height is a dimension in the direction of the cylinder center line of the shower cylindrical portion.
(6) Liquid, Static Liquid Pressure (Hydrostatic Pressure) of Liquid, and Liquid Feeding Rate (Water Feeding Rate)
The “liquid”, “static liquid pressure (hydrostatic pressure) of the liquid”, and a “liquid feeding rate (water feeding rate)” are the same in Example 1, Example 2, Example 3, and Comparative Example 1.
In Example 1, Example 2, Example 3, and Comparative Example 1, the following is employed.
Liquid: tap water (water),
Static liquid pressure (hydrostatic pressure) of the liquid (water): 0.2 MPa (megapascals)
Liquid feeding rate (water feeding rate) of the liquid (water): 9.2 liters/minute (9.2 liters per minute)
In Example 1, Example 2, Example 3, and Comparative Example 1, under a condition in which the “hydrostatic pressure” was 0.2 MPa and the “water feeding rate” was 9.2 liters/minute, the tap water was caused to flow into the inflow passage and jetted through the air bubble-liquid mixture jetting holes.
(7) Measurement of Quantity of Air Bubbles
In the “shower test”, the air bubble-water mixture was jetted through the air bubble-liquid mixture jetting holes, and a quantity of air bubbles mixed into the air bubble-water mixture was measured.
In Example 1, the quantity of air bubbles (bubble quantity) including the micrometer-sized air bubbles (microbubbles) and the nanometer-sized air bubbles (ultrafine bubbles) was measured in a case in which the air bubble-water mixture was jetted at a rate of 8 liters/minute and a rate of 10 liters/minute.
In Example 2, the quantity of air bubbles (bubble quantity) including the microbubbles and the ultrafine bubbles was measured in a case in which the air bubble-water mixture was jetted at a rate of 10 liters/minute.
In Example 3, the quantity of air bubbles (bubble quantity) including the microbubbles and the ultrafine bubbles was measured in a case in which the air bubble-water mixture was jetted at a rate of 10 liters/minute.
In Comparative Example 1, the quantity of air bubbles (bubble quantity) including the microbubbles and the ultrafine bubbles was measured in a case in which the air bubble-water mixture was jetted at a rate of 10 liters/minute.
In Example 1, Example 2, Example 3, and Comparative Example 1, the quantity of air bubbles (bubble quantity) contained per a milliliter (ml) of the air bubble-water mixture was measured.
In Example 1, Example 2, Example 3, and Comparative Example 1, a total quantity of microbubbles and a microbubble diameter of the microbubbles largest in quantity were measured.
In Example 1, Example 2, Example 3, and Comparative Example 1, a total quantity of ultrafine bubbles and an ultrafine bubble diameter of ultrafine bubbles largest in quantity were measured.
In Example 1, a minimum microbubble diameter and a quantity of microbubbles each having the minimum microbubble diameter were measured.
Measurement results of the microbubbles in Example 1, Example 2, Example 3, and Comparative Example 1 are shown in “Table 1”.
In Example 1, the minimum microbubble diameter was 4.44 micrometers (μm), and a quantity of the microbubbles smallest in quantity was 1,200/milliliter.
In Example 1, as shown in “Table 1”, at the rate of 10 liters/minute, the diameter of the microbubbles largest in quantity was 28.67 micrometers (μm), the quantity of the microbubbles largest in quantity was 6,060/milliliter, and the total quantity of microbubbles was 8,492/milliliter.
In Example 1, as shown in “Table 1”, at the rate of 8 liters/minute, the diameter of the microbubbles largest in quantity was 29.12 micrometers (μm), the quantity of the microbubbles largest in quantity was 3,918/milliliter, and the total quantity of microbubbles was 4,634/milliliter.
In Example 2, as shown in “Table 1”, the diameter of the microbubbles largest in quantity was 27.92 micrometers (μm), the quantity of the microbubbles largest in quantity was 2,653/milliliter, and the total quantity of microbubbles was 3,509/milliliter.
In Example 3, as shown in “Table 1”, the diameter of the microbubbles largest in quantity was 27.92 micrometers (μm), the quantity of the microbubbles largest in quantity was 4,707/milliliter, and the total quantity of microbubbles was 6,023/milliliter.
In Comparative Example 1, as shown in “Table 1”, the diameter of the microbubbles largest in quantity was 7.19 micrometers (μm), the quantity of the microbubbles largest in quantity was 595/milliliter, and the total quantity of microbubbles was 1,722/milliliter.
In Example 1, Example 2, and Example 3, as compared to Comparative Example 1, the diameter of the microbubbles largest in quantity can be increased.
In Example 1, Example 2, and Example 3, as compared to Comparative Example 1, a sufficient volume of the microbubbles largest in quantity can be mixed into water (liquid). In particular, in Example 1, at the rate of 10 liters/minute, the diameter of the microbubbles largest in quantity was 28.67 micrometers (μm), and the quantity of the microbubbles largest in quantity was 6,060/milliliter. Thus, as compared to Example 2, Example 3, and Comparative Example 1, the sufficient volume of the microbubbles largest in quantity can be mixed into water (liquid), and hence significant effects can be expected.
In Example 1, Example 2, and Example 3, as compared to Comparative Example 1, the sufficient volume of microbubbles can be mixed into water (liquid).
Thus, when the plurality of flow-adjustment-piece plates 116 are formed on the flow-adjustment nozzle disk 114 as in the “flow-adjustment piece” in Example 1, Example 2, and Example 3, the sufficient volume of microbubbles can be mixed into water (liquid).
Measurement results of the ultrafine bubbles in Example 1, Example 2, Example 3, and Comparative Example 1 are shown in “Table 2”.
In Example 1, as shown in “Table 2”, at the rate of 10 liters/minute, the diameter of ultrafine bubbles largest in quantity was 98 nanometers (nm), the quantity of ultrafine bubbles largest in quantity was 140,000/milliliter, and the total quantity of ultrafine bubbles was 27,000,000/milliliter.
In Example 1, as shown in “Table 2”, at the rate of 8 liters/minute, the diameter of ultrafine bubbles largest in quantity was 136.9 nanometers (nm), the quantity of ultrafine bubbles largest in quantity was 730,000/milliliter, and the total quantity of ultrafine bubbles was 13,000,000/milliliter.
In Example 2, as shown in “Table 2”, the diameter of ultrafine bubbles largest in quantity was 134.5 nanometers (nm), the quantity of ultrafine bubbles largest in quantity was 290,000/milliliter, and the total quantity of ultrafine bubbles was 5,400,000/milliliter.
In Example 3, as shown in “Table 2”, the diameter of ultrafine bubbles largest in quantity was 128.8 nanometers (nm), the quantity of ultrafine bubbles largest in quantity was 160,000/milliliter, and the total quantity of ultrafine bubbles was 3,800,000/milliliter.
In Comparative Example 1, as shown in “Table 2”, the diameter of ultrafine bubbles largest in quantity was 150.8 nanometers (nm), the quantity of ultrafine bubbles largest in quantity was 440,000/milliliter, and the total quantity of ultrafine bubbles was 6,500,000/milliliter.
In Example 1, Example 2, and Example 3, the diameter of ultrafine bubbles largest in quantity was 90 to 136.9 nanometers, and the quantity of ultrafine bubbles largest in quantity was 140,000 to 730,000/milliliter. Thus, the sufficient volume of ultrafine bubbles largest in quantity can be mixed into water (liquid).
In Example 1, Example 2, and Example 3, the total quantity of ultrafine bubbles was 730,000 to 2,700,000/milliliter. Thus, the sufficient volume of ultrafine bubbles can be mixed into water (liquid).
In particular, in Example 1, as compared to Example 2, Example 3, and Comparative Example 1, the sufficient volume of ultrafine bubbles largest in quantity can be mixed into water (liquid).
In Example 1, as compared to Example 2, Example 3, and Comparative Example 1, the sufficient quantity of ultrafine bubbles in total can be mixed into water (liquid).
<2> “Mist Test”
The mist test was carried out in Example 4 and Comparative Example 2.
(1) Mist Throttle Hole
The “mist throttle hole” was common (the same) in Example 4 and Comparative Example 2.
The “mist throttle hole 121 (conical hole)” in Example 4 and Comparative Example 2 is described with reference to
The “mist throttle hole 121” in Example 4 has the following configuration.
Number of the mist throttle holes 121: 12
Radius of the circle CK: 18.4 mm
Hole diameter dM of each of the mist throttle holes 121: 0.96 mm (opened in the disk front surface 96A)
Hole diameter dF of each of the mist throttle holes 121: 4.0 mm (opened in the disk back flat surface 96B)
Hole length of each of the mist throttle holes 121: 5.8 mm
The mist throttle holes 121 were arranged on the circle CK, and were arranged at equal angular intervals (equal pitches) of 30 degrees in the peripheral direction of the circle CK (or the shower nozzle 3).
(2) Mist Guide (Conical Spiral) and Guide Ring
The “mist guide 124” in Example 4 is described with reference to
The “mist guide 124” in Example 4 has the following configuration.
Number of the mist guides: 12
Number of the spiral surfaces: 2 (first and second spiral surfaces)
Guide height GL: 3.5 mm
Maximum bottom width GH: 8.95 mm
Ring diameter D8 of the circle CL of the guide ring 123: 18.4 mm
Each of the mist guides 124 was formed integrally with the guide ring 123 so that the cone center line L thereof was located on the circle CL. The mist guides 124 were arranged on the guide ring 123 at equal angular intervals of 30 degrees in the peripheral direction of the circle CL.
Each of the mist guides 124 was inserted into each of the mist throttle holes 121 from the cone upper surface 124A, and was fitted in each of the mist throttle holes 121 with the gap between the cone side surface 124C and the conical inner peripheral surface 121A of each of the mist throttle holes 121.
Thus, each of the mist guides 124 was fitted to the shower nozzle 3 (or the shower nozzle plate 96), thereby defining the first and second mist flow passages 51 and 52 between the first and second spiral surfaces 127 and 128 and the conical inner peripheral surface 121A of each of the mist throttle holes 121.
In Comparative Example 2, there is employed mist generating means “without a mist guide”, in which the mist guides are not inserted into the mist throttle holes, respectively.
(3) Liquid, Static Liquid Pressure (Hydrostatic Pressure) of Liquid, and Liquid Feeding Rate (Water Feeding Rate)
In Example 4 and Comparative Example 2, the following is employed.
Liquid: tap water (water)
Static liquid pressure (hydrostatic pressure) of the liquid (water): 0.2 MPa (megapascals)
Liquid feeding rate (water feeding rate) of the liquid (water): 7.4 liters/minute (7.4 liters per minute)
In Example 4 and Comparative Example 2, under a condition in which the “hydrostatic pressure” was 0.2 MPa and the “water feeding rate” was 7.4 liters/minute, the tap water was caused to flow into the inflow passage and jetted through the mist throttle holes.
(4) Measurement of Quantity of Air Bubbles
In the “mist test”, a quantity of air bubbles mixed into a mist of water droplets (liquid droplets) jetted through the mist throttle holes was measured.
In Example 4 and Comparative Example 2, a total quantity of the micrometer-sized air bubbles (microbubbles) and a total quantity of the nanometer-sized air bubbles (ultrafine bubbles) were measured in a case in which the mist of water droplets was jetted at a rate of 4 liters/minute.
In Example 4 and Comparative Example 2, the quantity of air bubbles (bubble quantity) contained per a milliliter (ml) of the mist of water droplets was measured.
In Example 4 and Comparative Example 2, a total quantity of ultrafine bubbles and an ultrafine bubble diameter of ultrafine bubbles largest in quantity were measured.
Measurement results of the microbubbles in Example 4 and Comparative Example 2 are shown in “Table 3”.
In Example 4, as shown in “Table 3”, the diameter of microbubbles largest in quantity was 11.52 micrometers (μm), the quantity of the microbubbles largest in quantity was 21,079/milliliter, and the total quantity of microbubbles was 27,022/milliliter.
In Comparative Example 2, as shown in “Table 3”, the diameter of the microbubbles largest in quantity was 3.24 micrometers (μm), the quantity of the microbubbles largest in quantity was 1,680/milliliter, and the total quantity of microbubbles was 2,637/milliliter.
In Example 4, as compared to Comparative Example 2, a sufficient volume of the microbubbles largest in quantity can be mixed into the mist of water droplets (the liquid droplets).
In Example 4, as compared to Comparative Example 2, the sufficient quantity of microbubbles in total can be mixed into the mist of water droplets (the liquid droplets).
Thus, in the “mist test”, when the mist guides each having a conical spiral shape (a truncated conical spiral shape) are fitted in the mist throttle holes, respectively, the sufficient volume of microbubbles can be mixed into the mist of water droplets (liquid droplets).
Measurement results of the ultrafine bubbles in Example 4 and Comparative Example 2 are shown in “Table 4”.
In Example 4, as shown in “Table 4”, the diameter of ultrafine bubbles largest in quantity was 124.1 nanometers (nm), the quantity of ultrafine bubbles largest in quantity was 710,000/milliliter, and the total quantity of ultrafine bubbles was 14,000,000/milliliter.
In Comparative Example 2, as shown in “Table 4”, the diameter of ultrafine bubbles largest in quantity was 128.1 nanometers (nm), the quantity of ultrafine bubbles largest in quantity was 360,000/milliliter, and the total quantity of ultrafine bubbles was 6,600,000/milliliter.
In Example 4, as compared to Comparative Example 2, a sufficient volume of ultrafine bubbles largest in quantity can be mixed into the mist of water droplets (liquid droplets).
In Example 4, as compared to Comparative Example 2, the sufficient quantity of ultrafine bubbles in total can be mixed into the mist of water droplets (liquid droplets).
The present invention is most suitable for jetting the air bubble-liquid mixture or the mist of liquid droplets.
Number | Date | Country | Kind |
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2018-136811 | Jul 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/005866 | 2/18/2019 | WO | 00 |
Number | Date | Country | |
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Parent | PCT/JP2018/036465 | Sep 2018 | US |
Child | 17051253 | US |