BUBBLE-GENERATING STRUCTURE, AND SHOWERHEAD THAT INCLUDES THAT STRUCTURE

Abstract

Using a simple structure, a new function is added to a liquid such as tap water by taking a gas into the liquid. The bubble-generating structure of the present invention includes (1) a water-discharging nozzle, which is provided inside a pipe, (2) a receiving member, which is situated a specified distance from the water-discharging nozzle and which includes a flow path for passing liquid emitted from the water-discharging nozzle, and (3) an air hole provided in such a way as to take air into a space between the water-discharging nozzle and the receiving member. By taking in air due to a suction force that is generated when the liquid passes along the flow path, bubbles are generated in the liquid. When such a structure for generating bubbles in the liquid is included in a showerhead, a person taking a shower using the showerhead can have a healthy and comfortable feeling while showering.

Description

FIELD OF THE INVENTION

The present invention relates to a structure for causing a liquid to contain bubbles and then to emit the liquid, and to a showerhead that includes that structure.

BACKGROUND OF THE INVENTION

A normal showerhead that is used when taking a shower is equipped with a switching lever or a push button so as to control the volume and strength of the tap water to be emitted. In addition, a filter or the like can be installed in a showerhead in order to emit the tap water in a misty form, to activate the tap water by using ceramics or the like, or to remove harmful chlorine and so on from the tap water. Japanese Published Patent Application No. H11-151457 discloses a spray nozzle and a shower apparatus that uses that spray nozzle. In the spray nozzle described in that application, the spray nozzle's swirl holes swirl a liquid (i.e. create a swirling flow), and the spray nozzle's central hole forms a flow along the central axis of the swirling flow, so that—even if the liquid's pressure is low—sprayed water particles can be fine and uniform and the spraying angle can be large. Also, in the shower apparatus disclosed in Japanese Published Patent Application No. 2001-333867, a plurality of spray nozzles are provided inside a showerhead, an emission port is provided in front of each of the spray nozzles, and air ports are provided behind the spray nozzles. Thus, misty warm water is emitted from the spray nozzles, and the emitted misty water (mists) entrains air from the air ports. Accordingly, both misty warm water and air are supplied to the person who is showering. In addition, the mists emitted from the plurality of spray nozzles collide with each other in an airflow, and thereby generate negative ions.

• • Patent Document 1: Japanese Published Patent Application No. H11-151457
  • Patent Document 2: Japanese Published Patent Application No. 2001-333867

SUMMARY OF THE INVENTION

One objective of the prevent invention is to cause a liquid (such as tap water) to contain a gas (such as air) and to generate bubbles, so that a new function is added to the liquid.

The bubble-generating structure of the present invention includes a water-discharging nozzle, which is provided inside a pipe, a receiving member, which is situated a specified distance from the water-discharging nozzle and which includes a flow path for passing the liquid emitted from the water-discharging nozzle, and an open air hole that takes air into the space between the water-discharging nozzle and the receiving member, and wherein the structure bubbles are generated in the liquid due to the air taken in by the suction force that is generated when the liquid passes along the flow path.

The showerhead of the present invention, in which a mounting member—to be mounted to a tap-water outlet—is provided at the base end of a tubular outer member, with the showerhead includes a water-discharging nozzle, which is provided in the mounting member and which has a diameter smaller than that of the tap-water outlet, and a receiving member, which is situated a specified distance from and opposite to the water-discharging nozzle, and which includes a flow path for passing the liquid emitted from the water-discharging nozzle, and wherein the showerhead air is taken in at the place where the outer member contacts the mounting member, and due to the suction force that is generated when the tap water emitted from the water-discharging nozzle passes along the flow path, the air is taken in and the water is discharged.

In addition, the mounting member has

• a mounting part that is screwed to a screw part provided inside the outer member, a flange that contacts the water-inlet end of the outer member, a mounting part that projects outward from the flange, a vertical groove on the outside of the mounting part, and an open air hole at the top of the groove.

Furthermore, the showerhead of the present invention is configured such that a head part having a water-discharging piece for discharging tap water is screwed by a grip part that cab be gripped by a person's hand, and the showerhead includes of a suction member that sucks air into the suction member. The suction member has a water-discharging nozzle inside a tubular member, and a receiving member, which is situated a specified distance from and opposite to the water-discharging nozzle, and to which receiving member a flow path is provided for passing the liquid emitted from the water-discharging nozzle. There are provided, at the place where the head part contacts the gripping part, a first through-hole, which is provided through the wall of the tubular member and is located between the water-discharging nozzle and the receiving member; an indentation, which is formed at one part of the head part, and a second through-hole, which takes in air through the indentation; and air is taken in through the first and second through-holes, due to the suction force that is generated when tap water emitted from the water-discharging nozzle passes along the flow path, so that the water is discharged.

In addition, the showerhead of the present invention has at an intermediate part of the receiving member's flow path, a space whose diameter is larger than the diameters of other portions of the flow path.

When there is provided a configuration wherein a water-discharging nozzle is arranged inside a tubular body, a receiving member is arranged at a specified distance from the water-discharging nozzle, and air can be taken into a space between the water-discharging nozzle and the receiving member, it is possible to generate bubbles in a liquid that passes through the tubular body. Such a liquid, which has taken in air, contains a large amount of bubbles. Therefore, the liquid can be utilized, for example, by being incorporated in a liquid-purifying device or the like.

In addition, such a structure that generates bubbles inside a showerhead, stimulates ceramics arranged inside the showerhead, and the tap water discharged from the showerhead contains a large amount of bubbles. This gives a healthy and comfortable feeling to a person who takes a shower using this showerhead.

Furthermore, when a space having an enlarged diameter is provided at an intermediate part of the receiving member's flow path, tap water becomes agitated in that space, and therefore, generation of bubbles is facilitated.

When, at an intermediate part of the receiving member's flow path, there is a space whose diameter is larger than the diameters of other portions of the flow path, tap water becomes agitated in that space, which facilitates the generation of bubbles.

Still other objects and advantages of the present invention will become readily apparent to those skilled in the art from the following detailed description, wherein the preferred embodiments of the invention are shown and described, simply by way of illustration of the best mode contemplated of carrying out the invention. As will be realized, the invention is capable of other and different embodiments, and its several details are capable of modifications in various obvious aspects, all without departing from the invention. Accordingly, the drawings and description thereof are to be regarded as illustrative in nature, and not as restrictive.

BRIEF EXPLANATION OF THE DRAWINGS

The present invention is illustrated by way of example, and not by limitation, in the figures of the accompanying drawings, wherein elements having the same reference numeral designations represent like elements throughout and wherein:

FIGS. 1( a) and 1(b) two different bubble-generating structures of the present invention.

FIG. 2 shows the showerhead of the first embodiment of the present invention.

FIG. 3 shows the base-end member of the showerhead.

FIG. 4 shows the base-end member of the variational embodiment of the showerhead.

FIG. 5( a) is a plane view of the interior structure of the showerhead of the first embodiment when the base-end member is in contact with the receiving member inside the outer member, and FIG. 5(b) is a front view thereof.

FIG. 6 shows the showerhead of the second embodiment of the present invention.

FIG. 7 shows a suction member of the second embodiment.

FIG. 8 shows a showerhead, of the third embodiment, having a bubble-generating structure.

FIG. 9 is a cross-sectional view of a showerhead of the forth embodiment, having a bubble-generating structure.

FIG. 10 shows a bubble-generating structure of the other embodiment.

FIG. 11 shows the interior structure of the bubble-generating structure shown in FIG. 10.

FIG. 12 shows a face view of the water-discharging piece of the showerhead of the present invention.

FIG. 13 shows the water-discharging piece of the showerhead shown in FIG. 12.

FIG. 14 shows piping that includes a bubble-generating structure.

EXPLANATIONS OF THE ALPHANUMERIC CHARACTERS USED IN THE FIGURES

• 2 water-discharging nozzle
• 4 receiving member
• 4 d flow path
• 5 air hole
• 7 cartridge
• 7 a ceramic ball
• 8 ventilation hole
• 10 pipe
• 13 reverse-flow-prevention member
• 14 air-intake device
• 15 second through-hole
• 15 a indentation
• 18 plate-like member
• 20 showerhead
• 20 b water-discharging piece
• 21 base-end member
• 30 suction member
• 30 a first through-hole
• 40 piping

DETAILED DESCRIPTION OF THE INVENTION

FIGS. 1( a) and 1(b) respectively show two different bubble-generating structures of the present invention.

The bubble-generating structure shown in FIG. 1(a) includes

• a water-discharging nozzle 2, which is provided on the water-inlet end of the structure and has a diameter smaller than that of the water (liquid)-discharge end of the structure, and
• a receiving member 4, which is provided at a distance of about 1 cm-2 cm from the water-discharging nozzle 2 (the exact distance can vary, depending on the purpose for which the structure will be used), and
• both the water-discharging nozzle 2 and the receiving member 4 are provided inside a tubular pipe 10 that has an air hole 5; and
• a receiving surface 4a—which is situated opposite the water-discharging nozzle 2—of the receiving member 4 is formed in a way so as to be indented in the direction in which the liquid flows. The receiving member 4 also has a flow path 4d in the center of the receiving surface 4a, for collecting and passing the water emitted from the water-discharging nozzle 2. The flow path 4d has a diameter larger than that of the water-discharging nozzle 2, so that water can easily pass along the flow path 4d. The bubble-generating structure in FIG. 1(b) is basically identical to the structure shown in FIG. 1(a), but it has—at the intermediate part of the flow path 4d (not identified in FIG. 1 (b)) of the receiving member 4—a space 4e whose diameter is larger than the diameter of the flow path 4d.

In the bubble-generating structure of the present invention, water A (shown by arrows in FIG. 1) bursts into the pipe 10 from the water-discharging nozzle 2, and the main stream of that bursting water plunges into the flow path 4d of the receiving member 4, which causes the surrounding air to flow out together with the water A, and therefore the inside pressure of the pipe 10 is temporarily reduced. However, because the air hole 5 is provided in the pipe 10, air continues to be supplied into the pipe 10. Thus, the air, which has been made to flow out together with the water A, is agitated together with the water A in the flow path 4d of the receiving member 4. Therefore, by the time that the air is discharged from the receiving member 4, the water has come to contain a large amount of bubbles. Incidentally, in the space 4e shown in FIG. 1(b), particles of the water A, which flows along the walls of the space 4e, collide with each other in the center part of the space 4e, and they are agitated together with the air that has been taken inside the tubular pipe 10. Therefore, by the time that the water A is discharged from the receiving member 4, the water A contains a large amount of bubbles.

FIG. 2 shows a showerhead 20 of the first embodiment of the present invention. The showerhead 20 has a water-discharging piece 20b at its top and a base-end member 21 at its base (FIG. 3 shows an enlarged view of the base-end member 21). A bubble-generating structure, consisting of the base-end member 21 and the receiving member 4, is provided inside the hollow, outer member 20a of the showerhead body. Tap water that has passed through the receiving member 4 then passes—in the form of water containing a large amount of bubbles—through a cartridge 7 that is filled with ceramic balls 7a. The outer member 20a and the base-end member 21 of the showerhead body are screwed to each other, which means they can be attached to and detached from each other. Therefore, the cartridge 7 and other parts that are inside the showerhead body, can be replaced by new ones.

The base-end member 21 has an inside mounting part 21b that is screwed to the outer member 20a, a flange 21a that contacts the water-inlet end of the outer member 20a, and an outside mounting part 21c that is formed so as to be mounted to a tap-water outlet via a hose or the like. The base-end member 21 has—inside the mounting part 21b—a water-discharging nozzle 2 that has a diameter smaller than that of the water inlet. A groove part 5a that is inclined in the mounting direction is provided at one part of the outside of the inside mounting part 21b, and the top of the outside has an opening that constitutes the air hole 5. Although FIG. 2 shows that the outer periphery of the mounting part 21c is threaded, one part of the outer periphery of the mounting part 21c can be projected (as shown in FIG. 4) so that the mounting part 21c can be fitted with and mounted to—in a one-touch manner—a tap-water outlet.

The receiving member 4 has an O-ring mounting groove 4c on its outside. While an O-ring 12 is fitted with the groove 4c, the receiving member 4 is mounted to the inside of the outer member 20a. Also, the receiving member 4a—which is opposite the water-discharging nozzle 2—of the receiving member 4 is indented in the direction in which the liquid flows. The flow path 4d, having a diameter larger than that of the water-discharging nozzle 2, is formed so as to penetrate through the center of the receiving surface 4a.

FIG. 5 shows the condition when the base-end member 21 is in contact with the receiving member 4 inside the outer member 20a. FIGS. 5(a) and 5(b) are a plane view and a front view, respectively. As shown in FIG. 5, even when the receiving member 4 is in contact with the base-end member 21, the air hole 5 is open. Accordingly, even when the base-end member 21 is screwed to and mounted with the outer member 20a of the showerhead body, the place where the flange 21a contacts the outer member 20a is not sealed by an O-ring or the like, and therefore a small space 22 exists there. Air can be taken through this small space 22 into the flow path 4d of the receiving member 4. Incidentally, under the condition that the receiving member 4 is in contact with the base-end member 21, the distance from the top of the water-discharging nozzle 2 to the inlet of the flow path of the receiving member 4 is about 1 cm. The base-end member 21 that has the water-discharging nozzle 2 can be integratedly formed with the receiving member 4, so that the base-end member 21 and the receiving member 4 have a unified shape. It is also possible to configure the showerhead 20 such that the diameter of the flow path of the receiving member 4 is enlarged at its intermediate part—as shown in FIG. 1—so as to form a large space there.

As described above, the showerhead 20 of the present invention is constituted such that tap water passes through the receiving member 4, comes to contain a large amount of bubbles, and then passes through the cartridge 7, which is filled with ceramic balls 7a that activate the tap water. Furthermore, by the time that the water is discharged from the receiving member 4, the water has come to contain a large amount of bubbles, and this gives a healthy and comfortable feeling to a person who takes a shower using this showerhead.

FIG. 6 shows the showerhead 20 of another embodiment.

This showerhead 20 includes

• a hollow, head member 20c that has a water-discharging piece 20b for discharging tap water,
• a hollow, gripping part 20d which is grippable with a hand and screwed with the head member 20c,
• a suction member 30 (see FIG. 7) which sucks air into the inside so as to generate bubbles, and
• a cartridge 7 filled with ceramic balls 7a.

As shown in FIG. 7, the suction member 30 has of

• a water-discharging nozzle 30b inside a tubular member 30e, and
• a receiving member 30c, to which a flow path 30d is provided,wherein
• the receiving member 30c is opposed to, and spaced from, the water-discharging nozzle 30b at an interval of about 5 mm.

A first through-hole 30a is provided between the water-discharging nozzle 30b and the receiving member 30c, in a way to penetrate through the wall of the tubular member 30e.

Also, an indentation 15a is provided to one part of a head member 20c at the place where the head member 20c contacts the gripping member 20d. Further, a second through-hole 15 is provided at a portion that is screwed to the gripping part 20d, so that air can be taken in from the indentation 15a.

As a result, air can be taken in through the first and second through-holes (30a, 15) due to the suction force that is generated when the tap water emitted from the water-discharging nozzle 30b passes along the flow path 30d, so that the water can be discharged. In this embodiment's showerhead 20, bubbles are generated after the tap water has passed through the ceramic balls 7a, and therefore tap water discharged from the water-discharging piece 20b contains a large amount of bubbles.

FIGS. 8 and 9 respectively show showerheads 20 in other embodiments. The showerhead 20 shown in FIG. 8 is formed in a detachable manner, by screwing a shower-generating head part 16 to a grip part 16a. The grip part 16a is a transparent cylindrical member in which an air hole 5 is formed, and the grip part 16a includes a water-discharging nozzle 2, a receiving member 4 that has a receiving part 3, and a cartridge 7 that is filled with ceramic balls 7a. The water-discharging nozzle 2 is a funnel-like member whose diameter gradually decreases in the discharge direction (i.e., the nozzle's top), and the water-discharging nozzle 2 is configured such that tap water (shown by the darker arrows in FIG. 8) that is supplied via a water inlet 17 (the showerhead's base end, to which tap water is supplied) bursts out from the water-discharging nozzle 2. Also, the receiving member 4 includes a receiving part 3 that is formed like a funnel so as to receive the bursting-out tap water, and the receiving member 4 is formed in such a way that its diameter gradually increases in the discharge direction (i.e., the direction in which the water flows). In addition, a small space is provided between the water-discharging nozzle 2 and the receiving part 3. As a result, due to the bursting flow of the tap water from the water-discharging nozzle 2 to the receiving member 4, air can be taken in from the air hole 5.

The air supplied from the air hole 5 is drawn to the tap water that bursts out from the water-discharging nozzle 2, and the air and water are mixed in the receiving member 4. The tap water, which has become bubbly, is taken into the ceramics cartridge 7, where it collides hard with the ceramic balls 7a. As a result, the tap water is activated under the influence of the ceramic balls 7a. That is to say, the bubbly tap water collides with the ceramic balls 7a, which stimulates the ceramic balls 7, which then effectively exert an activating action, such as generation of far infrared rays, on the tap water. Also, the tap water, part of which has become bubbly, is emitted from the water-discharging piece 20b of the shower generating head part 16. In this manner, because the tap water, part of which has become bubbly, is emitted from the showerhead 20, that water feels soft to a person taking a shower using the showerhead 20. Furthermore, because the tap water, part of which has become bubbly, is emitted from the showerhead 20, a user of the showerhead 20 can wash his or her body using only one-half of the amount of tap water usually used, which saves water and eliminates waste.

The showerhead 20 shown in FIG. 9 is a stationary type that is directly mounted to a wall or the like of a bathing room. It does not have a grip part that can be gripped by a person's hand. However, even that type of showerhead 20 can be provided with a bubble-generating structure that includes a water-discharging nozzle 2, a receiving member 4 that has a receiving part 3, and an air hole 5. It is possible to take bubbly tap water into a ceramics cartridge 7 and to make the tap water collide hard with the ceramic balls 7a.

FIG. 10 shows a bubble-generating structure of another embodiment that is arranged in a showerhead. As shown in FIG. 10, the bubble-generating structure in this embodiment has—inside a tubular case 1—a water-discharging nozzle 2 and an enlarged-diameter member 6 whose diameter increases in the discharge direction.

The top of the water-discharging nozzle 2 is connected to the bottom 9 of the enlarged-diameter member 6. The bottom 9 of the enlarged-diameter member 6 has a diameter larger than that of the top of the water-discharging nozzle 2, and ventilation holes 8 are provided around the place at which the bottom 9 of the enlarged-diameter member 6 connects with the top of the water-discharging nozzle 2.

FIG. 11 shows that a reverse-flow-prevention member 13, which is made of a flexible material such as rubber, is provided inside the bottom 9 of the enlarged-diameter member 6 and is adhered to the bottom 9. In this reverse-flow-prevention member 13, a portion corresponding to a water-passing port 12 is cut away, while portions corresponding to the ventilation holes 8 are not cut away, but are cut to have U-shapes so that they have larger diameters than those of the outer peripheries of the ventilation holes 8. As a result, tap water flowing in from the water-discharging nozzle 2 is allowed to enter the enlarged-diameter member 6. Air, being drawn to the tap water that bursts in through the water-discharging nozzle 2, flows in through the ventilation holes 8. In addition, reverse flow of the tap water through the ventilation holes 8 is prevented. By providing such a bubble-generating structure to the showerhead 20, it is possible to cause the discharged tap water to contain a large amount of bubbles.

FIGS. 12 and 13 show the structure of the showerhead's water-discharging piece 20b, in which a plate-like member 19 that has nozzle-like holes 2b is overlaid on a plate-like member 18 having nozzle-like holes 2a. The nozzle-like holes 2a and 2b are spaced slightly apart, so that air holes 5e are formed. Air, which comes in from the spaces between the nozzle-like holes 2a and 2b, is supplied into the air holes 5e.

Accordingly, due to the outflow of the tap water squirting out of the water-discharging piece 20b, the air bursts out of the air holes 5e. Thus, the tap water mixes with the air, and water that feels soft to a person using the showerhead is discharged.

FIG. 14 shows piping 40 that is used for purifying lake water or river water. Inside the piping 40 is provided the above-mentioned bubble-generating structure—i.e., the water-discharging nozzle 2, the receiving member 4, and the air hole 5. Depending on where the piping 40 is to be installed, the water or the liquid passing through the piping might not be allowed to leak out. For this reason, an air-intake device 14, in which a return-check valve is installed, is provided in the air hole 5.

Furthermore, the air-intake device 14 can include a flowmeter or filter (not shown), and the air-intake device 14 can be connected with a compressed-gas cylinder, so as to aggressively feed in compressed air and to adjust the amount of bubbles contained in the discharging water or other liquid. In addition, what is to be mixed in the bubble-generating structure is not limited to the combination of water and air. Depending on the purpose, the combination can be any of the following, as appropriate: water and hydrogen or ozone; cooking oil and nitrogen gas; drinking water and carbon dioxide gas; and so on. As a result, the bubble-generating structure can be utilized in purifying liquids, preventing oxidation of oil, and manufacturing health drinks—which activities are conducted in a food manufacturing plant, a purification facility, or other comparable place. The bubble-generating structure can also be utilized—by using chlorine gas—in purifying water in a swimming pool and so on.

It will be readily seen by one of ordinary skill in the art that the present invention fulfils all of the objects set forth above. After reading the foregoing specification, one of ordinary skill in the art will be able to affect various changes, substitutions of equivalents and various aspects of the invention as broadly disclosed herein. It is therefore intended that the protection granted hereon be limited only by definition contained in the appended claims and equivalents thereof.

Claims

1. A bubble-generating structure, comprising: a water-discharging nozzle, which is provided inside a pipe,a receiving member, which is situated a specified distance from the water-discharging nozzle and which includes a flow path for passing liquid emitted from the water-discharging nozzle, andan air hole that takes air into a space between the water-discharging nozzle and the receiving member,whereinbubbles are generated in the liquid due to air taken in by a suction force that is generated when the liquid passes along the flow path.

2. A showerhead, in which a mounting member—to be mounted to a tap-water outlet—is provided at the base end of a tubular outer member, said showerhead comprising: a water-discharging nozzle, which is provided in the mounting member and which has a diameter smaller than that of the tap-water outlet, anda receiving member, which is situated a specified distance from and opposite to the water-discharging nozzle, and which includes a flow path for passing liquid emitted from the water-discharging nozzle,whereinair is taken in at the place where the outer member contacts the mounting member, and due to the suction force that is generated when the tap water emitted from the water-discharging nozzle passes along the flow path, the air is taken in and the water is discharged.

3. The showerhead as described in claim 2, wherein the mounting member includes a mounting part to be screwed with a screw part provided inside the outer member,a flange that contacts the water-inlet end of the outer member,a mounting part that projects outward from the flange,a vertical groove on the outside of the mounting part, andan air hole at the top of the groove.

4. A showerhead configured such that a head part having a water-discharging piece for discharging tap water is screwed to a grip part that can be gripped by a person's hand, wherein said showerhead includesa suction member that sucks air into itself;the suction member includesa water-discharging nozzle inside a tubular member,a receiving member, which is situated a specified distance from and opposite to the water-discharging nozzle, and which includes a flow path for passing the liquid emitted from the water-discharging nozzle, andthere are provided, at the place where the head part contacts the gripping part, a first through-hole, which is provided through the wall of the tubular member and is located between the water-discharging nozzle and the receiving member; an indentation, which is formed at one part of the head part, and a second through-hole, which takes in air through the indentation; and air is taken in through the first and second through-holes, due to the suction force that is generated when tap water emitted from the water-discharging nozzle passes along the flow path, so that the water is discharged.

5. The showerhead as described in claim 2, wherein there is provided, at an intermediate part of the receiving member's flow path, a space whose diameter is larger than the diameters of other portions of the flow path.

6. The showerhead as described in claim 3, wherein there is provided, at an intermediate part of the receiving member's flow path, a space whose diameter is larger than the diameters of other portions of the flow path.

7. The showerhead as described in claim 4, wherein there is provided, at an intermediate part of the receiving member's flow path, a space whose diameter is larger than the diameters of other portions of the flow path.