JP2012130901A - Bubble generator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a bubble generator, which is suitable for a shower nozzle, a plughole for tap water, a pipe for a bathroom, a water tank, and further for a tableware washer, and a watering shower used for gardening, being able to generate micro bubbles.SOLUTION: The bubble generator is composed of an upstream body 10, which is provided in the first passage 11 that narrows downward, a shunting piece 30, which is housed in the first passage 11 and is provided with many liquid passing holes 31, and a downstream body 20 which is attached to the upstream body 10 and is provided with the second passage 21 that widens downstream, and the downstream end of the first passage 11 faces the upstream end of the second passage 21.

Description

  The present invention relates to a bubble generator that is interposed between a pressure liquid supply member and a discharge member, and generates minimal bubbles in the liquid discharged from the discharge member.

  For example, if bubbles are mixed in water discharged by a faucet or shower nozzle, effects such as enhancing the cleaning effect, stimulating the skin, or preventing water splashing can be obtained. This is well known in Patent Document 1 or Patent Document 2.

  The formation of bubbles proposed in these Patent Documents 1 and 2 is made by forming a negative pressure generating portion in the flow of tap water and introducing outside air into the negative pressure generating portion. The size of the bubbles is at most millimeters (hereinafter referred to as millibubbles or microbubbles). For example, Patent Document 3 shows that if this microbubble is made into a micron-sized bubble (hereinafter referred to as microbubble or microbubble), the cleaning effect and the like are further enhanced.

In general, the definition of “microbubble” is variously defined depending on the field, but it is consistent that the diameter does not include 1 mm or more, and those having a diameter of less than 1 μm are called nanobubbles. Bubbles having a diameter between are defined as microbubbles. In the present invention, microbubbles defined in this way are referred to as microbubbles, and bubbles having a diameter of 1 mm or more are referred to as microbubbles.

JP 2010-7315 A, Abstract JP 2009-274026 A, Summary JP 2009-78140 A, Summary

  Patent Document 3 proposes a “body care washing water supply device” for the purpose of “care of various parts of the body such as hair washing or massage more efficiently in a shorter time”. As shown in FIG. 8, the “care cleaning water supply device” “cleans the body from the raw water supply unit as a cleaning water supply device that performs body care using cleaning water in which bubbles are mixed with raw water”. From the nozzle, the water pipe 12 leading to the washing water pouring part, the fine bubble generator installed in the water pipe for mixing and dissolving the fine bubbles in the raw water, and the raw water in which the generated fine bubbles are mixed and dissolved from the nozzle Accelerates and sprays into raw water, mixes microbubbles with a diameter of about 1-50 μm, and provides cleaning water generating unit 29 installed in water piping to generate dissolved cleaning water, and provided in the water piping extraction portion Water for pouring washed water And those having a structure that Note body wash water received that is received flush water issued constituting comprises a ".

And, as shown in paragraph 0018 of the document 3, the “fine bubble generator 15 for generating microbubbles having a diameter of about 1 to 50 μm” in Patent Document 3 ... the purified water supplied from the inlet 15a, the vortex pump 39 for sucking the air, the motor 40 for driving the vortex pump 39, and the air discharged from the vortex pump 39 are mixed and stirred with the raw water to obtain the raw water A shearing / stirring unit 41 for dissolving air, a gas-liquid mixing / separating means 42 for separating undissolved gas contained in the air-mixed solution, and an air-dissolved liquid discharged from the means 42 are discharged and decompressed to form fine bubbles However, as shown in paragraph 0010 of the document 3, “the fine bubble generating device generates vortex and shear by stirring the raw water. A device for mixing the fine bubbles which so-called microbubbles, it is provided that "intended to dissolve.

  In other words, the “fine bubble generating device” proposed in Patent Document 3 not only has a complicated configuration as described above, but also “a device that generates vortex and shear by stirring raw water”. However, it is unclear whether it is an apparatus that “mixes and dissolves microbubbles that become microbubbles”.

  Therefore, the present inventors can not only generate or generate microbubbles, that is, microbubbles with a simple configuration, but also a shower nozzle 200, a faucet for tap water, a bathroom, a water tank, and a dishwasher. As a result of various investigations on how to make a bubble generator suitable for watering showers used for plumbing and gardening, etc., the present invention has been completed.

  That is, the object of the present invention is to generate a very small bubble, and can be used for a shower nozzle 200, a faucet for tap water, piping to a bathroom or a water tank or a dishwasher, and a watering shower used for gardening. The object is to provide a suitable bubble generator with a simple construction.

In order to solve the above problems, first, the means taken by the invention according to claim 1 will be described with reference numerals used in the description of the best mode described below.
“In between the pressure liquid supply member 210 and the discharge member 200 that discharges the liquid fed from the pressure fluid supply member 210, a very small bubble is contained in the liquid discharged from the discharge member 200. A bubble generator 100 for generating
An upstream main body 10 provided with a first flow path 11 that narrows toward the downstream side, a diversion piece 30 that is accommodated in the first flow path 11 and provided with a large number of liquid passage holes 31, and an upstream main body 10 It is constituted by the downstream main body 20 provided with the second flow path 21 attached and spreading toward the downstream side,
The bubble generator 100, wherein the downstream end of the first flow path 11 is opposed to the upstream end of the second flow path 21 "
It is.

That is, the bubble generator 100 according to claim 1 includes a pressure liquid supply member 210 such as a water faucet and the pressure fluid supply member 210 via, for example, the first flow path 11 as shown in FIG. It is interposed between a discharge member 200 such as a shower nozzle that discharges the supplied liquid. The bubble generator 100 is applied to various devices, and is not limited to the shower nozzle 200 illustrated in FIG. 1, but includes a tap for tap water, a bathroom, a water tank, and a dishwasher. It can be applied to plumbing, etc., watering showers used for gardening, etc.

Furthermore, the bubble generator 100 is applied or applied to the following various fields or devices.
・ Beauty and beauty, pet washing field
・ Bathroom field (Improvement of washing and heat retention as a micro bubble bath)
・ Nursing care field or nursing facility (improvement in washing and heat retention as a shower)
・ Fishery product cleaning field (detergency can be expected)
・ Laundry machine and coin laundry field (Improvement of clothes washability by installing on piping)
・ Agriculture, food factories (promoting the cultivation of agricultural products, sterilization effect can be expected)
・ Provide to research institutes such as universities as microbubble generators ・ Washing shower nozzles for gas stations
・ Cosmetics field (cleaning effect can be expected)

And this bubble generator 100 produces | generates a micro bubble in liquids, such as a tap water discharged from the discharge member 200, and hot water. Therefore, the liquid to which the bubble generator 100 is applied is not limited to shower water or washing water, but may be other liquids that are preferable when extremely small bubbles are generated, for example, liquid fertilizer or processing liquid.

  As shown in FIGS. 2 to 7, the bubble generator 100 includes an upstream main body 10 provided with a first flow path 11 that narrows toward the downstream side, and a large number of passages housed in the first flow path 11. The diverting piece 30 is provided with a liquid hole 31 and the downstream main body 20 is provided with a second flow path 21 that is attached to the upstream main body 10 and expands toward the downstream side. In addition, the bubble generator 100 is configured so that the liquid that has flowed into the first flow path 11 of the upstream main body 10 is smoothly fed into the second flow path 21 of the downstream main body 20. The downstream end of the second channel 21 is opposed to the upstream end of the second flow path 21.

That is, as shown by the arrow in FIG. 5, the bubble generator 100 includes a downstream main body positioned on the lower side in the drawing in the liquid fed from the pressure liquid supply member 210 to the upstream main body 10 side. During the feeding from 20 to the second flow path 21, micro bubbles are generated inside, and the micro bubbles are mixed into the liquid discharged from the second flow path 21. Note that the bubble generator 100 shown in FIG. 1 is upside down from the bubble generator 100 shown in FIG.

  In the bubble generator 100, the microbubbles are generated as follows. First, the liquid fed into the upstream main body 10 is discharged into the first flow path 11 while being diverted by flowing into the respective liquid flow holes 31 of the diversion piece 30. Since the first flow path 11 is narrowed toward the downstream side, the liquid discharged into the first flow path 11 is sent toward the downstream side while being compressed. Since the downstream end of the first flow path 11 is opposed to the upstream end of the second flow path 21 formed in the downstream main body 20, the liquid flows from the first flow path 11 to the second flow. It flows into the path 21. Since the second flow path 21 is widened toward the downstream side, the pressure of the liquid suddenly drops at the downstream end thereof.

  In each of the above steps, the liquid is not only subjected to various shear stresses, but also pressurized and released, so that cavitation occurs in the liquid. In addition, each of these forces may cause a flow of a complicated shape in the bubble generator 100, so that these forces themselves are not only relatively large, but also the first flow path 11 and the second flow. Since it is hung or released within an extremely short path in the path 21, that is, within a short time, when the gas component dissolved in the liquid appears as bubbles by cavitation, it is extremely minute. Bubbles, that is, microbubbles.

  According to the inventor's experiment, it is considered that cavitation is generated in the liquid by using the bubble generator 100 for the following reason. When this bubble generator 100 is used, when the liquid passes through the opening 11a of the first flow path 11 of the upstream main body 10, a gas axis (vacuum axis) is formed at the center of the liquid flow by the action of the swirling flow. . On the other hand, when the liquid is discharged from the opening 21a of the downstream main body 20 to the second flow path 21, it is considered that the liquid flows in the central portion by the surrounding liquid wall. Therefore, it is considered that the liquid to be drawn to the gas shaft side collides with the liquid ejected radially from the opening 21a, and the gas on the gas shaft is sheared to generate micro bubbles. .

  In general, vapor and bubbles generated by cavitation are absorbed into the liquid again within a short time, but the bubbles generated in the bubble generator 100 according to the present invention are microbubbles called microbubbles. It is not absorbed into the liquid again within a short time due to its surface tension or the like. In other words, microbubbles, that is, microbubbles remain in the liquid discharged from the second flow path 21, and if this liquid is used as shower water from the shower nozzle 200, for example, Hair washing and body washing can be performed with high detergency.

  Therefore, in the bubble generator 100 according to the first aspect of the present invention, a very small bubble can be generated and used for shower nozzles 200, faucets for tap water, pipes for bathrooms, water tanks, and dishwashers, and gardening. It is suitable for watering showers.

In order to solve the above-mentioned problem, the means taken by the invention according to claim 2 is the bubble generator 100 according to claim 1 described above.
“A surface roughness Ra of at least one of the contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 that are in contact with each other is set to 0.2 to 6.3,
The outside air can be introduced into the inside through a minute gap between the contact surfaces 15 and 25. "
It is.

  As described in the bubble generator 100 of the first aspect, the bubble generator 100 according to the second aspect includes the upstream main body 10 provided with the first flow path 11 that narrows toward the downstream side, A diverting piece 30 accommodated in one flow path 11 and provided with a large number of liquid passage holes 31, and a downstream main body 20 provided with a second flow path 21 attached to the upstream main body 10 and extending toward the downstream side. In order to smoothly feed the liquid that has flowed into the first flow path 11 of the upstream main body 10 into the second flow path 21 of the downstream main body 20, the first flow path 11. The downstream end of the second channel 21 is opposed to the upstream end of the second flow path 21.

That is, in the bubble generator 100, as shown by the arrow in FIG. 5, the liquid fed from the pressure liquid supply member 210 to the upstream main body 10 side is the downstream main body 20 positioned on the lower side in the figure. When the second flow path 21 is fed to the upper end of the figure, a negative pressure is generated in the feed liquid.

On the other hand, as shown in FIGS. 5 and 6, the surface roughness Ra of at least one of the contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 that are in contact with each other is set to 0.2. Since ˜6.3, a fine gap is formed between the contact surfaces 15 and 25. Therefore, when a negative pressure is generated in the supplied liquid when the liquid supplied to the upstream main body 10 is supplied to the downstream main body 20, the contact surface 15 is generated by the negative pressure. -Outside air will be introduced into the bubble generator 100 from the minute gaps between 25.

  Here, the surface roughness Ra of at least one of the contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 must be 0.2 to 6.3. It is as follows. First, if the surface roughness RA of the contact surface 15 of the upstream main body 10 or the contact surface 25 of the downstream main body 20 is smaller than 0.2, the clearance between the contact surfaces 15 and 25 is small and the introduction of outside air is reduced. This is not only because it cannot be performed, but also because processing to such surface roughness is costly and has little meaning. On the other hand, if the surface roughness Ra of the contact surface 15 of the upstream main body 10 or the contact surface 25 of the downstream main body 20 is larger than 6.3, the gap between the contact surfaces 15 and 25 becomes too large, and the outside air However, this type of bubble generator 100 may cause “liquid leakage”.

  The surface roughness Ra must be 0.2 to 6.3 on at least one of the contact surface 15 of the upstream body 10 and the contact surface 25 of the downstream body 20, The contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 are not necessarily required. However, if the surface roughness Ra of both the abutment surface 15 of the upstream main body 10 and the abutment surface 25 of the downstream main body 20 is set to 0.2 to 6.3, generation control of microbubbles described later is performed. It is natural that it becomes easy.

The outside air introduced into the bubble generator 100 through the gap between the contact surfaces 15 and 25 having the surface roughness as described above is in the liquid at the boundary between the upstream original 10 and the downstream original 20. Therefore, the microbubbles are mixed with the microbubbles into the liquid discharged from the second flow channel 21 of the downstream side 20 originally. It becomes. This microbubble is known, for example, in the above-mentioned Patent Documents 1 and 2.

  Therefore, in the bubble generator 100 according to the second aspect, micro bubbles and micro bubbles can be generated at the same time, and a shower nozzle 200, a faucet for tap water, a bathroom, a water tank, and a pipe for a dishwasher, etc. It is suitable for watering showers used for gardening.

In order to solve the above-mentioned problem, the means taken by the invention according to claim 3 is the bubble generator 100 according to claim 1 or 2,
“The axial center of each liquid flow hole 31 of the diverting piece 30 is inclined with respect to the axial center of the diverting piece 30”.
It is.

  That is, in the bubble generator 100 according to claim 3, as shown in FIG. 4A and FIG. 5, the axial center of each liquid flow hole 31 of the flow dividing piece 30 is set to the axial center of the flow dividing piece 30. In this way, the liquid flowing through each liquid passage hole 31 is further given a force for generating a very small bubble.

  When each liquid passage hole 31 is inclined with respect to the axial center of the flow dividing piece 30, the liquid flowing in the axial direction of the flow dividing piece 30 is turned, and the turning force with respect to the liquid advances. As a result of abrupt application of shear stress accompanying the change of direction, the fragmentation of bubbles by cavitation is further promoted, and the generation of microbubbles is further promoted.

  Therefore, the bubble generator 100 according to claim 3 exhibits the same function as that of claim 1 or claim 2 and further promotes the generation of microbubbles.

Furthermore, in order to solve the above-mentioned problem, the means taken by the invention according to claim 4 is the bubble generator 100 according to any one of claims 1 to 3,
"A space 40 is formed between the upstream main body 10 and the downstream main body 20"
It is.

  As shown in FIG. 5, the bubble generator 100 according to claim 4 is configured such that a space 40 is formed between the upstream main body 10 and the downstream main body 20, and is opposed to each other. The downstream end of the first flow path 11 and the upstream end of the second flow path 21 are once opened in the space 40. In particular, the fact that the downstream end of the first flow path 11 is opened in the space 40 generates a negative pressure due to the venturi effect in the liquid flowing out from the downstream end of the first flow path 11. It is.

  If the downstream end of the first flow path 11 and the upstream end of the second flow path 21 are open in the space 40, the liquid is the downstream end of the first flow path 11. When flowing from the space 40 to the space 40 and when flowing from the space 40 to the upstream end of the second flow path 21, the structural resistance of the bubble generator 100 and the pressure change are suddenly received. The cause of the occurrence of cavitation with respect to this liquid, and the bubble is more fragmented.

  Therefore, the bubble generator 100 according to the fourth aspect of the present invention exhibits the same function as that of any one of the first to third aspects of the present invention, and further promotes the generation of extremely small bubbles.

Further, the means taken by the invention according to claim 5 is the bubble generator 100 according to any one of claims 1 to 4.
“The size of the opening 11 a located at the downstream end of the first flow path 11 is made smaller than the opening 21 a located at the upstream end of the second flow path 21.
It is.

  In the bubble generator 100 of this fifth aspect, as shown in FIG. 5, the size of the opening 11 a located at the downstream end of the first flow path 11 is positioned at the upstream end of the second flow path 21. Thus, when the liquid flows out from the downstream end of the first flow path 11 to the space 40, the liquid flows from the space 40 to the upstream end of the second flow path 21. At this time, the structural resistance of the bubble generator 100 and the pressure change are more rapidly applied to the liquid, causing the occurrence of cavitation to the liquid and increasing the fragmentation of the bubbles. -ing

  Therefore, the bubble generator 100 according to claim 5 exhibits the same function as that according to any one of claims 1 to 4 and further promotes the generation of microbubbles. .

And in order to solve the said subject, the means which the invention which concerns on Claim 6 took about the bubble generator 100 of the said Claim 4 or Claim 5,
“An outside air intake member 50 having an intake port 51 communicating with the space 40 is attached to the upstream side main body 10 or the downstream side main body 20 so that the micro bubbles and the micro bubbles can be generated in the liquid. thing"
It is.

  That is, as shown in FIG. 5, the bubble generator 100 according to claim 6 is provided with an outside air intake member 50 having an intake port 51 communicating with the space 40. The outside air intake member 50 is As long as the intake port 51 communicates with the space 40, it may be attached to either the upstream main body 10 or the downstream main body 20.

  The outside air intake member 50 communicates with the space 40 via the intake 51, and a negative pressure is generated in the space 40 when liquid flows out from the downstream end of the first flow path 11. Therefore, while the bubble generator 100 is functioning, the negative pressure in the space 40 is applied to the outside air intake member 50 via the intake port 51. When this negative pressure is applied to the outside air intake member 50, the outside air intake member 50 introduces outside air into the space 40 through the inlet 51, and this outside air is minutely generated by the liquid flow in the space 40. It becomes a bubble.

  Since the bubble generator 100 itself generates microbubbles, the liquid flowing out from the downstream main body 20 is caused by the microbubbles and outside air introduced through the outside air intake member 50. The formed microbubbles are mixed.

  Therefore, the bubble generator 100 according to claim 6 can generate both types of bubbles, ie, micro bubbles and micro bubbles. The shower nozzle 200, a faucet for tap water, a bathroom, a water tank, a dishwasher, etc. It is suitable for plumbing and watering showers used for gardening.

As described above, in the present invention,
“In between the pressure liquid supply member 210 and the discharge member 200 that discharges the liquid fed from the pressure fluid supply member 210, a very small bubble is contained in the liquid discharged from the discharge member 200. A bubble generator 100 for generating
An upstream main body 10 provided with a first flow path 11 that narrows toward the downstream side, a diversion piece 30 that is accommodated in the first flow path 11 and provided with a large number of liquid passage holes 31, and an upstream main body 10 It is constituted by the downstream main body 20 provided with the second flow path 21 attached and spreading toward the downstream side,
The downstream end of the first flow path 11 is opposed to the upstream end of the second flow path 21 "
The main feature of the structure is that it can generate extremely small bubbles, shower nozzles 200, faucets for tap water, piping to bathrooms and water tanks and dishwashers, and watering used for gardening. The bubble generator 100 suitable for a shower can be provided with a simple configuration.

It is a perspective view which shows the state which applied the bubble generator 100 which concerns on this invention between the shower nozzle 200 and the water tap 210. FIG. 2 is an enlarged perspective view of the bubble generator 100. FIG. 2 is a front view of the bubble generator 100. FIG. The bubble generator 100 is shown, (a) is a plan view and (very small bubble) is a bottom view. 2 is a longitudinal sectional view of the bubble generator 100. FIG. It is the longitudinal cross-sectional view which expanded and showed a part of bubble generator 100 shown in FIG. 1 shows an enlarged view of a diversion piece 30 constituting the bubble generator 100, where (a) is a front view, (very small bubbles) is a perspective view seen from above, and (micro bubbles) is a perspective view seen from below. FIG. FIG. 10 is a route diagram showing the technique of Patent Document 3.

  Next, the invention according to each claim configured as described above will be described with respect to the bubble generator 100 which is the embodiment shown in the drawings. The bubble generator 100 of this embodiment is described in each of the above claims. It includes all the inventions concerned.

  In FIG. 1, a bubble generator 100 according to the present invention is connected to the lower end of a shower nozzle 200 via its downstream main body 20, and the upstream main body 10 of this bubble generator 100 is connected to one end of a hose 220. The state is shown. Of course, the other end of the hose 220 is connected to the water tap 210. The water faucet 210 corresponds to the diversion piece 30 described above, and the shower nozzle 200 corresponds to the space 40. In the present embodiment, the hose 220 is connected by the connecting portion 13 of the upstream main body 10 and is connected to the shower nozzle 200 by the connecting portion 23 of the downstream main body 20.

  As shown in FIGS. 2 to 7, the bubble generator 100 includes an upstream main body 10 provided with a first flow path 11 that narrows toward the downstream side, and a plurality of bubble generators 100 housed in the first flow path 11. This is composed of a diversion piece 30 provided with a liquid passage hole 31 and a downstream main body 20 provided with a second flow path 21 attached to the upstream main body 10 and extending toward the downstream side. Further, as shown in FIG. 5, the bubble generator 100 is configured such that the downstream end portion of the first flow path 11 faces the upstream end portion of the second flow path 21. The bubble generator 100 shown in FIG. 5 is represented upside down from that shown in FIG.

  The upstream main body 10 and the downstream main body 20 are connected to each other by the second flow paths 21 and 24, and a packing 16 is interposed in the connecting portion to prevent liquid leakage. . In the bubble generator 100 of the present embodiment, when the upstream main body 10 and the downstream main body 20 are connected, a space is formed between the upstream main body 10 and the downstream main body 20 as shown in FIG. 40 is formed. The size of the opening 11 a located at the downstream end of the first flow path 11 formed in the upstream main body 10 is equal to the opening located at the upstream end of the second flow path 21 formed in the downstream main body 20. It is smaller than 21a.

  A placement step 12 is formed at a portion of the upstream main body 10 located at the opening end of the first flow path 11 (the upper end side of the first flow path 11 in FIG. 5). A shunt piece 30 is housed and placed on 12. As shown in FIG. 4A, the diversion piece 30 has a large number of liquid passage holes 31, and these liquid passage holes 31 have their axes centered on the bubble generator 100. It is inclined to it. Further, on the upper and lower sides of the diversion piece 30, rectifying protrusions 32 are formed so as to protrude, and the side surfaces of the rectifying protrusions 32 are inclined. This inclined state is assumed to be close to the inclined state of the inner surface of the first flow path 11, so that a staying portion is not formed largely in the liquid flow flowing through the first flow path 11. This inclined state is steep for the lower rectifying protrusion 32 in FIG. 5 and is gentle for the upper rectifying protrusion 32.

Here, in the bubble generator 100 according to the present embodiment, as shown in FIGS. 5 and 6, either the abutment surface 15 of the upstream main body 10 or the abutment surface 25 of the downstream main body 20 that abut each other. At least one surface roughness Ra is set to 0.2 to 6.3. For this reason, a fine gap is formed between the contact surfaces 15 and 25. Therefore, when a negative pressure is generated in the liquid supplied to the downstream main body 20 when the liquid supplied to the upstream main body 10 is supplied to the downstream main body 20, the negative pressure causes the space between the contact surfaces 15 and 25. The outside air is introduced into the bubble generator 100 through the minute gap.

In the bubble generator 100 of this embodiment, as shown in FIGS. 5 and 6, a packing 16 for preventing liquid leakage is interposed between the contact surfaces 15 and 25, and this packing is provided. 16 has an inverted U-shaped cross section. This packing 16 is easy to allow the introduction of outside air from the gap between the contact surfaces 15 and 25, and conversely, it is easy to prevent liquid leakage due to liquid pressure from the inside of the bubble generator 100.

  As shown in FIGS. 1 to 7, the bubble generator 100 of the present embodiment also includes an outside air intake member 50. The outside air intake member 50 is a part of the bubble generator 100 by connecting the intake port 51 to the downstream main body 20 side, and the inside thereof can communicate with the space 40 described above. It is. Note that the intake port 51 of the outside air intake member 50 may be connected to the upstream main body 10 as long as it can communicate with the space 40.

  As shown in FIG. 5, the outside air intake member 50 includes a valve body 52 housed in a portion constituting the outside of the intake port 51, and a valve seat 54 with which the valve body 52 abuts. A spring 53 is disposed on the bubble generator 100 side of the valve body 52, and the spring 53 always biases the valve body 52 to the opposite side of the bubble generator 100. Further, the urging force of the spring 53 is adjusted by an adjusting screw 55 that protrudes outside and is integrated with the valve body 52. Further, the outside air intake member 50 allows the outside and the inside of the space 40 to communicate with each other through the periphery of the adjustment screw 55 when the valve body 52 is not in contact with the valve seat 54.

  Now, if the biasing force of the spring 53 is reduced by adjusting the adjustment screw 55, the outside air intake member 50 is in a state in which outside air can be sufficiently taken in even if the negative pressure in the space 40 is not large. If the urging force of 53 is increased, outside air cannot be taken in unless the negative pressure in the space 40 is increased. Of course, even when the outside air is not taken in by the outside air intake member 50, that is, when the microbubbles are not generated, it is needless to say that the “miniature bubbles” themselves are generated by the basic structure of the bubble generator 100. Yes.

  The outside air intake member 50 also has a “check valve” function. That is, when an abnormal pressure is generated on the first flow path 11 or the second flow path 21 side, this pressure is applied to the valve body 52 via the intake port 51, so that the valve body 52 contacts the valve seat 54. This prevents liquid leakage.

  In addition, when attaching this external air intake member 50 to the bubble generator 100, or assembling the valve body 52 and the valve seat 54, it is needless to say that packing is employed at appropriate positions as necessary.

DESCRIPTION OF SYMBOLS 100 Bubble generator 10 Upstream side main body 11 1st flow path 11a Opening 12 Mounting step part 13 Connection part 14 Attachment screw 15 Contact surface 16 Packing 20 Downstream side main body 21 2nd flow path 21a Opening 23 Attachment part 24 Attachment screw 25 Contact surface 30 Dividing piece 31 Fluid passage hole 32 Rectification protrusion 40 Space 50 Outside air intake member 51 Inlet 52 Valve body 53 Spring 54 Valve seat 55 Adjustment screw 200 Discharge member (shower nozzle)
210 Pressure liquid supply member (water tap)
220 hose

  The present invention relates to a bubble generator that is interposed between a pressure liquid supply member and a discharge member, and generates minimal bubbles in the liquid discharged from the discharge member.

  For example, if bubbles are mixed in water discharged by a faucet or shower nozzle, effects such as enhancing the cleaning effect, stimulating the skin, or preventing water splashing can be obtained. This is well known in Patent Document 1 or Patent Document 2.

  The formation of bubbles proposed in these Patent Documents 1 and 2 is made by forming a negative pressure generating portion in the flow of tap water and introducing outside air into the negative pressure generating portion. The size of the bubbles is at most millimeters (hereinafter referred to as millibubbles or microbubbles). For example, Patent Document 3 shows that if this microbubble is made into a micron-sized bubble (hereinafter referred to as microbubble or microbubble), the cleaning effect and the like are further enhanced.

In general, the definition of “microbubble” is variously defined depending on the field, but it is consistent that the diameter does not include 1 mm or more, and those having a diameter of less than 1 μm are called nanobubbles. Bubbles having a diameter between are defined as microbubbles. In the present invention, microbubbles defined in this way are referred to as microbubbles, and bubbles having a diameter of 1 mm or more are referred to as microbubbles.

JP 2010-7315 A, Abstract JP 2009-274026 A, Summary JP 2009-78140 A, Summary

  Patent Document 3 proposes a “body care washing water supply device” for the purpose of “care of various parts of the body such as hair washing or massage more efficiently in a shorter time”. As shown in FIG. 8, the “care cleaning water supply device” “cleans the body from the raw water supply unit as a cleaning water supply device that performs body care using cleaning water in which bubbles are mixed with raw water”. From the nozzle, the water pipe 12 leading to the washing water pouring part, the fine bubble generator installed in the water pipe for mixing and dissolving the fine bubbles in the raw water, and the raw water in which the generated fine bubbles are mixed and dissolved from the nozzle Accelerates and sprays into raw water, mixes microbubbles with a diameter of about 1-50 μm, and provides cleaning water generating unit 29 installed in water piping to generate dissolved cleaning water, and provided in the water piping extraction portion Water for pouring washed water And those having a structure that Note body wash water received that is received flush water issued constituting comprises a ".

And, as shown in paragraph 0018 of the document 3, the “fine bubble generator 15 for generating microbubbles having a diameter of about 1 to 50 μm” in Patent Document 3 ... the purified water supplied from the inlet 15a, the vortex pump 39 for sucking the air, the motor 40 for driving the vortex pump 39, and the air discharged from the vortex pump 39 are mixed and stirred with the raw water to obtain the raw water A shearing / stirring unit 41 for dissolving air, a gas-liquid mixing / separating means 42 for separating undissolved gas contained in the air-mixed solution, and an air-dissolved liquid discharged from the means 42 are discharged and decompressed to form fine bubbles However, as shown in paragraph 0010 of the document 3, “the fine bubble generating device generates vortex and shear by stirring the raw water. A device for mixing the fine bubbles which so-called microbubbles, it is provided that "intended to dissolve.

  In other words, the “fine bubble generating device” proposed in Patent Document 3 not only has a complicated configuration as described above, but also “a device that generates vortex and shear by stirring raw water”. However, it is unclear whether it is an apparatus that “mixes and dissolves microbubbles that become microbubbles”.

  Therefore, the present inventors can not only generate or generate microbubbles, that is, microbubbles with a simple configuration, but also a shower nozzle 200, a faucet for tap water, a bathroom, a water tank, and a dishwasher. As a result of various investigations on how to make a bubble generator suitable for watering showers used for plumbing and gardening, etc., the present invention has been completed.

  That is, the object of the present invention is to generate a very small bubble, and can be used for a shower nozzle 200, a faucet for tap water, piping to a bathroom or a water tank or a dishwasher, and a watering shower used for gardening. The object is to provide a suitable bubble generator with a simple construction.

In order to solve the above problems, first, the means taken by the invention according to claim 1 will be described with reference numerals used in the description of the best mode described below.
“In between the pressure liquid supply member 210 and the discharge member 200 that discharges the liquid fed from the pressure fluid supply member 210, a very small bubble is contained in the liquid discharged from the discharge member 200. A bubble generator 100 for generating
An upstream main body 10 provided with a first flow path 11 that narrows toward the downstream side, a diversion piece 30 that is accommodated in the first flow path 11 and provided with a large number of liquid passage holes 31, and an upstream main body 10 It is constituted by the downstream main body 20 provided with the second flow path 21 that is attached and spreads toward the downstream side ,
While making the downstream end of the first flow path 11 face the upstream end of the second flow path 21 ,
The surface roughness Ra of at least one of the contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 that are in contact with each other is set to 0.2 to 6.3,
A bubble generator 100 characterized in that outside air can be introduced into the inside through a minute gap between the contact surfaces 15 and 25 ".
It is.

That is, the bubble generator 100 according to claim 1 includes a pressure liquid supply member 210 such as a water faucet and the pressure fluid supply member 210 via, for example, the first flow path 11 as shown in FIG. It is interposed between a discharge member 200 such as a shower nozzle that discharges the supplied liquid. The bubble generator 100 is applied to various devices, and is not limited to the shower nozzle 200 illustrated in FIG. 1, but includes a tap for tap water, a bathroom, a water tank, and a dishwasher. It can be applied to plumbing, etc., watering showers used for gardening, etc.

Furthermore, the bubble generator 100 is applied or applied to the following various fields or devices.
・ Beauty and beauty, pet washing field
・ Bathroom field (Improvement of washing and heat retention as a micro bubble bath)
・ Nursing care field or nursing facility (improvement in washing and heat retention as a shower)
・ Fishery product cleaning field (detergency can be expected)
・ Laundry machine and coin laundry field (Improvement of clothes washability by installing on piping)
・ Agriculture, food factories (promoting the cultivation of agricultural products, sterilization effect can be expected)
・ Provide to research institutes such as universities as microbubble generators ・ Washing shower nozzles for gas stations
・ Cosmetics field (cleaning effect can be expected)

And this bubble generator 100 produces | generates a micro bubble in liquids, such as a tap water discharged from the discharge member 200, and hot water. Therefore, the liquid to which the bubble generator 100 is applied is not limited to shower water or washing water, but may be other liquids that are preferable when extremely small bubbles are generated, for example, liquid fertilizer or processing liquid.

  As shown in FIGS. 2 to 7, the bubble generator 100 includes an upstream main body 10 provided with a first flow path 11 that narrows toward the downstream side, and a large number of passages housed in the first flow path 11. The diverting piece 30 is provided with a liquid hole 31 and the downstream main body 20 is provided with a second flow path 21 that is attached to the upstream main body 10 and expands toward the downstream side. In addition, the bubble generator 100 is configured so that the liquid that has flowed into the first flow path 11 of the upstream main body 10 is smoothly fed into the second flow path 21 of the downstream main body 20. The downstream end of the second channel 21 is opposed to the upstream end of the second flow path 21.

That is, as shown by the arrow in FIG. 5, the bubble generator 100 includes a downstream main body positioned on the lower side in the drawing in the liquid fed from the pressure liquid supply member 210 to the upstream main body 10 side. During the feeding from 20 to the second flow path 21, micro bubbles are generated inside, and the micro bubbles are mixed into the liquid discharged from the second flow path 21. Note that the bubble generator 100 shown in FIG. 1 is upside down from the bubble generator 100 shown in FIG.

  In the bubble generator 100, the microbubbles are generated as follows. First, the liquid fed into the upstream main body 10 is discharged into the first flow path 11 while being diverted by flowing into the respective liquid flow holes 31 of the diversion piece 30. Since the first flow path 11 is narrowed toward the downstream side, the liquid discharged into the first flow path 11 is sent toward the downstream side while being compressed. Since the downstream end of the first flow path 11 is opposed to the upstream end of the second flow path 21 formed in the downstream main body 20, the liquid flows from the first flow path 11 to the second flow. It flows into the path 21. Since the second flow path 21 is widened toward the downstream side, the pressure of the liquid suddenly drops at the downstream end thereof.

  In each of the above steps, the liquid is not only subjected to various shear stresses, but also pressurized and released, so that cavitation occurs in the liquid. In addition, each of these forces may cause a flow of a complicated shape in the bubble generator 100, so that these forces themselves are not only relatively large, but also the first flow path 11 and the second flow. Since it is hung or released within an extremely short path in the path 21, that is, within a short time, when the gas component dissolved in the liquid appears as bubbles by cavitation, it is extremely minute. Bubbles, that is, microbubbles.

  According to the inventor's experiment, it is considered that cavitation is generated in the liquid by using the bubble generator 100 for the following reason. When this bubble generator 100 is used, when the liquid passes through the opening 11a of the first flow path 11 of the upstream main body 10, a gas axis (vacuum axis) is formed at the center of the liquid flow by the action of the swirling flow. . On the other hand, when the liquid is discharged from the opening 21a of the downstream main body 20 to the second flow path 21, it is considered that the liquid flows in the central portion by the surrounding liquid wall. Therefore, it is considered that the liquid to be drawn to the gas shaft side collides with the liquid ejected radially from the opening 21a, and the gas on the gas shaft is sheared to generate micro bubbles. .

  In general, vapor and bubbles generated by cavitation are absorbed into the liquid again within a short time, but the bubbles generated in the bubble generator 100 according to the present invention are microbubbles called microbubbles. It is not absorbed into the liquid again within a short time due to its surface tension or the like. In other words, microbubbles, that is, microbubbles remain in the liquid discharged from the second flow path 21, and if this liquid is used as shower water from the shower nozzle 200, for example, Hair washing and body washing can be performed with high detergency.

Accordingly, the bubble generator 100 according to the first aspect, first, poles can generate small bubbles, pipe shower nozzle 200, the water faucet for tap water, bathroom or aquarium more to dishwashers or the like, It is suitable for watering showers used for gardening.

In the bubble generator 100 according to claim 1,
“A surface roughness Ra of at least one of the contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 that are in contact with each other is set to 0.2 to 6.3,
Outside air can be introduced into the inside through a minute gap between the contact surfaces 15 and 25. ' '
It was a thing.

This bubble generator 100, as described above above, the upstream-side body 10 provided with the first flow path 11 narrowed toward the downstream side, a number of which are housed in the first passage 11 passing The diverting piece 30 provided with the liquid hole 31 and the downstream main body 20 provided with the second flow path 21 attached to the upstream main body 10 and extending toward the downstream side, and the upstream main body In order to smoothly feed the liquid that has flowed into the first flow path 11 into the second flow path 21 of the downstream main body 20, the downstream end of the first flow path 11 is connected to the second flow path 21. It is made to oppose the upstream edge part.

That is, in the bubble generator 100, as shown by the arrow in FIG. 5, the liquid fed from the pressure liquid supply member 210 to the upstream main body 10 side is the downstream main body 20 positioned on the lower side in the figure. When the second flow path 21 is fed to the upper end of the figure, a negative pressure is generated in the feed liquid.

On the other hand, as shown in FIGS. 5 and 6, the surface roughness Ra of at least one of the contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 that are in contact with each other is set to 0.2. Since ˜6.3, a fine gap is formed between the contact surfaces 15 and 25. Therefore, when a negative pressure is generated in the supplied liquid when the liquid supplied to the upstream main body 10 is supplied to the downstream main body 20, the contact surface 15 is generated by the negative pressure. -Outside air will be introduced into the bubble generator 100 from the minute gaps between 25.

  Here, the surface roughness Ra of at least one of the contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 must be 0.2 to 6.3. It is as follows. First, if the surface roughness RA of the contact surface 15 of the upstream main body 10 or the contact surface 25 of the downstream main body 20 is smaller than 0.2, the clearance between the contact surfaces 15 and 25 is small and the introduction of outside air is reduced. This is not only because it cannot be performed, but also because processing to such surface roughness is costly and has little meaning. On the other hand, if the surface roughness Ra of the contact surface 15 of the upstream main body 10 or the contact surface 25 of the downstream main body 20 is larger than 6.3, the gap between the contact surfaces 15 and 25 becomes too large, and the outside air However, this type of bubble generator 100 may cause “liquid leakage”.

  The surface roughness Ra must be 0.2 to 6.3 on at least one of the contact surface 15 of the upstream body 10 and the contact surface 25 of the downstream body 20, The contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 are not necessarily required. However, if the surface roughness Ra of both the abutment surface 15 of the upstream main body 10 and the abutment surface 25 of the downstream main body 20 is set to 0.2 to 6.3, generation control of microbubbles described later is performed. It is natural that it becomes easy.

The outside air introduced into the bubble generator 100 through the gap between the contact surfaces 15 and 25 having the surface roughness as described above is in the liquid at the boundary between the upstream original 10 and the downstream original 20. Therefore, the microbubbles are mixed with the microbubbles into the liquid discharged from the second flow channel 21 of the downstream side 20 originally. It becomes. This microbubble is known, for example, in the above-mentioned Patent Documents 1 and 2.

Accordingly, the bubble generator 100 according to the first aspect, pipes made simultaneously generate minimum foam and microfoam, shower nozzle 200, the water faucet for tap water, into the bathroom or aquarium more dishwashers, etc. It is suitable for watering showers used for gardening.

In order to solve the above-mentioned problem, the means taken by the invention according to claim 2 is the bubble generator 100 according to claim 1 described above.
“The axial center of each liquid flow hole 31 of the diverting piece 30 is inclined with respect to the axial center of the diverting piece 30”.
It is.

That is, in the bubble generator 100 according to the second aspect , as shown in FIG. 4A and FIG. In this way, the liquid flowing through each liquid passage hole 31 is further given a force for generating a very small bubble.

  When each liquid passage hole 31 is inclined with respect to the axial center of the flow dividing piece 30, the liquid flowing in the axial direction of the flow dividing piece 30 is turned, and the turning force with respect to the liquid advances. As a result of abrupt application of shear stress accompanying the change of direction, the fragmentation of bubbles by cavitation is further promoted, and the generation of microbubbles is further promoted.

Therefore, the bubble generator 100 according to the second aspect of the present invention not only exhibits the same function as that of the first aspect but also further promotes the generation of microbubbles.

Furthermore, in order to solve the above-mentioned problem, the means taken by the invention according to claim 3 is the bubble generator 100 according to any one of claims 1 to 2 ,
"A space 40 is formed between the upstream main body 10 and the downstream main body 20"
It is.

As shown in FIG. 5, the bubble generator 100 according to claim 3 is configured such that a space 40 is formed between the upstream main body 10 and the downstream main body 20 and is opposed to each other. The downstream end of the first flow path 11 and the upstream end of the second flow path 21 are once opened in the space 40. In particular, the fact that the downstream end of the first flow path 11 is opened in the space 40 generates a negative pressure due to the venturi effect in the liquid flowing out from the downstream end of the first flow path 11. It is.

  If the downstream end of the first flow path 11 and the upstream end of the second flow path 21 are open in the space 40, the liquid is the downstream end of the first flow path 11. When flowing from the space 40 to the space 40 and when flowing from the space 40 to the upstream end of the second flow path 21, the structural resistance of the bubble generator 100 and the pressure change are suddenly received. The cause of the occurrence of cavitation with respect to this liquid, and the bubble is more fragmented.

Therefore, the bubble generator 100 according to the third aspect exhibits the same function as that of any one of the first and second aspects, and further promotes the generation of microbubbles.

Further, the means taken by the invention according to claim 4 is the bubble generator 100 according to any one of claims 1 to 3 ,
“The size of the opening 11 a located at the downstream end of the first flow path 11 is made smaller than the opening 21 a located at the upstream end of the second flow path 21.
It is.

In the bubble generator 100 according to the fourth aspect , as shown in FIG. 5, the size of the opening 11 a located at the downstream end of the first flow path 11 is set at the upstream end of the second flow path 21. Thus, when the liquid flows out from the downstream end of the first flow path 11 to the space 40, the liquid flows from the space 40 to the upstream end of the second flow path 21. At this time, the structural resistance of the bubble generator 100 and the pressure change are more rapidly applied to the liquid, causing the occurrence of cavitation to the liquid and increasing the fragmentation of the bubbles. -ing

Therefore, the bubble generator 100 according to the fourth aspect exhibits the same function as that according to any one of the first to third aspects, and further promotes the generation of microbubbles. .

And in order to solve the said subject, the means which the invention which concerns on Claim 5 took about the bubble generator 100 of the said Claim 3 or Claim 4 ,
“An outside air intake member 50 having an intake port 51 communicating with the space 40 is attached to the upstream side main body 10 or the downstream side main body 20 so that the micro bubbles and the micro bubbles can be generated in the liquid. thing"
It is.

That is, as shown in FIG. 5, the bubble generator 100 according to claim 5 is provided with an outside air intake member 50 having an intake port 51 communicating with the space 40, and the outside air intake member 50 is As long as the intake port 51 communicates with the space 40, it may be attached to either the upstream main body 10 or the downstream main body 20.

  The outside air intake member 50 communicates with the space 40 via the intake 51, and a negative pressure is generated in the space 40 when liquid flows out from the downstream end of the first flow path 11. Therefore, while the bubble generator 100 is functioning, the negative pressure in the space 40 is applied to the outside air intake member 50 via the intake port 51. When this negative pressure is applied to the outside air intake member 50, the outside air intake member 50 introduces outside air into the space 40 through the inlet 51, and this outside air is minutely generated by the liquid flow in the space 40. It becomes a bubble.

  Since the bubble generator 100 itself generates microbubbles, the liquid flowing out from the downstream main body 20 is caused by the microbubbles and outside air introduced through the outside air intake member 50. The formed microbubbles are mixed.

Accordingly, the bubble generator 100 according to claim 5 can generate both types of bubbles, that is, microbubbles and microbubbles. The shower nozzle 200, a faucet for tap water, a bathroom, a water tank, a dishwasher, etc. It is suitable for plumbing and watering showers used for gardening.

As described above, in the present invention,
“In between the pressure liquid supply member 210 and the discharge member 200 that discharges the liquid fed from the pressure fluid supply member 210, a very small bubble is contained in the liquid discharged from the discharge member 200. A bubble generator 100 for generating
An upstream main body 10 provided with a first flow path 11 that narrows toward the downstream side, a diversion piece 30 that is accommodated in the first flow path 11 and provided with a large number of liquid passage holes 31, and an upstream main body 10 It is constituted by the downstream main body 20 provided with the second flow path 21 that is attached and spreads toward the downstream side ,
While making the downstream end of the first flow path 11 face the upstream end of the second flow path 21 ,
The surface roughness Ra of at least one of the contact surface 15 of the upstream main body 10 and the contact surface 25 of the downstream main body 20 that are in contact with each other is set to 0.2 to 6.3,
The outside air can be introduced into the inside through a minute gap between the contact surfaces 15 and 25. "
The main feature of the structure is that it can generate extremely small bubbles, shower nozzles 200, faucets for tap water, piping to bathrooms and water tanks and dishwashers, and watering used for gardening. The bubble generator 100 suitable for a shower can be provided with a simple configuration.

It is a perspective view which shows the state which applied the bubble generator 100 which concerns on this invention between the shower nozzle 200 and the water tap 210. FIG. 2 is an enlarged perspective view of the bubble generator 100. FIG. 2 is a front view of the bubble generator 100. FIG. The bubble generator 100 is shown, (a) is a plan view and (very small bubble) is a bottom view. 2 is a longitudinal sectional view of the bubble generator 100. FIG. It is the longitudinal cross-sectional view which expanded and showed a part of bubble generator 100 shown in FIG. 1 shows an enlarged view of a diversion piece 30 constituting the bubble generator 100, where (a) is a front view, (very small bubbles) is a perspective view seen from above, and (micro bubbles) is a perspective view seen from below. FIG. FIG. 10 is a route diagram showing the technique of Patent Document 3.

  Next, the invention according to each claim configured as described above will be described with respect to the bubble generator 100 which is the embodiment shown in the drawings. The bubble generator 100 of this embodiment is described in each of the above claims. It includes all the inventions concerned.

  In FIG. 1, a bubble generator 100 according to the present invention is connected to the lower end of a shower nozzle 200 via its downstream main body 20, and the upstream main body 10 of this bubble generator 100 is connected to one end of a hose 220. The state is shown. Of course, the other end of the hose 220 is connected to the water tap 210. The water faucet 210 corresponds to the diversion piece 30 described above, and the shower nozzle 200 corresponds to the space 40. In the present embodiment, the hose 220 is connected by the connecting portion 13 of the upstream main body 10 and is connected to the shower nozzle 200 by the connecting portion 23 of the downstream main body 20.

  As shown in FIGS. 2 to 7, the bubble generator 100 includes an upstream main body 10 provided with a first flow path 11 that narrows toward the downstream side, and a plurality of bubble generators 100 housed in the first flow path 11. This is composed of a diversion piece 30 provided with a liquid passage hole 31 and a downstream main body 20 provided with a second flow path 21 attached to the upstream main body 10 and extending toward the downstream side. Further, as shown in FIG. 5, the bubble generator 100 is configured such that the downstream end portion of the first flow path 11 faces the upstream end portion of the second flow path 21. The bubble generator 100 shown in FIG. 5 is represented upside down from that shown in FIG.

  The upstream main body 10 and the downstream main body 20 are connected to each other by the second flow paths 21 and 24, and a packing 16 is interposed in the connecting portion to prevent liquid leakage. . In the bubble generator 100 of the present embodiment, when the upstream main body 10 and the downstream main body 20 are connected, a space is formed between the upstream main body 10 and the downstream main body 20 as shown in FIG. 40 is formed. The size of the opening 11 a located at the downstream end of the first flow path 11 formed in the upstream main body 10 is equal to the opening located at the upstream end of the second flow path 21 formed in the downstream main body 20. It is smaller than 21a.

  A placement step 12 is formed at a portion of the upstream main body 10 located at the opening end of the first flow path 11 (the upper end side of the first flow path 11 in FIG. 5). A shunt piece 30 is housed and placed on 12. As shown in FIG. 4A, the diversion piece 30 has a large number of liquid passage holes 31, and these liquid passage holes 31 have their axes centered on the bubble generator 100. It is inclined to it. Further, on the upper and lower sides of the diversion piece 30, rectifying protrusions 32 are formed so as to protrude, and the side surfaces of the rectifying protrusions 32 are inclined. This inclined state is assumed to be close to the inclined state of the inner surface of the first flow path 11, so that a staying portion is not formed largely in the liquid flow flowing through the first flow path 11. This inclined state is steep for the lower rectifying protrusion 32 in FIG. 5 and is gentle for the upper rectifying protrusion 32.

Here, in the bubble generator 100 according to the present embodiment, as shown in FIGS. 5 and 6, either the abutment surface 15 of the upstream main body 10 or the abutment surface 25 of the downstream main body 20 that abut each other. At least one surface roughness Ra is set to 0.2 to 6.3. For this reason, a fine gap is formed between the contact surfaces 15 and 25. Therefore, when a negative pressure is generated in the liquid supplied to the downstream main body 20 when the liquid supplied to the upstream main body 10 is supplied to the downstream main body 20, the negative pressure causes the space between the contact surfaces 15 and 25. The outside air is introduced into the bubble generator 100 through the minute gap.

In the bubble generator 100 of this embodiment, as shown in FIGS. 5 and 6, a packing 16 for preventing liquid leakage is interposed between the contact surfaces 15 and 25, and this packing is provided. 16 has an inverted U-shaped cross section. This packing 16 is easy to allow the introduction of outside air from the gap between the contact surfaces 15 and 25, and conversely, it is easy to prevent liquid leakage due to liquid pressure from the inside of the bubble generator 100.

  As shown in FIGS. 1 to 7, the bubble generator 100 of the present embodiment also includes an outside air intake member 50. The outside air intake member 50 is a part of the bubble generator 100 by connecting the intake port 51 to the downstream main body 20 side, and the inside thereof can communicate with the space 40 described above. It is. Note that the intake port 51 of the outside air intake member 50 may be connected to the upstream main body 10 as long as it can communicate with the space 40.

  As shown in FIG. 5, the outside air intake member 50 includes a valve body 52 housed in a portion constituting the outside of the intake port 51, and a valve seat 54 with which the valve body 52 abuts. A spring 53 is disposed on the bubble generator 100 side of the valve body 52, and the spring 53 always biases the valve body 52 to the opposite side of the bubble generator 100. Further, the urging force of the spring 53 is adjusted by an adjusting screw 55 that protrudes outside and is integrated with the valve body 52. Further, the outside air intake member 50 allows the outside and the inside of the space 40 to communicate with each other through the periphery of the adjustment screw 55 when the valve body 52 is not in contact with the valve seat 54.

  Now, if the biasing force of the spring 53 is reduced by adjusting the adjustment screw 55, the outside air intake member 50 is in a state in which outside air can be sufficiently taken in even if the negative pressure in the space 40 is not large. If the urging force of 53 is increased, outside air cannot be taken in unless the negative pressure in the space 40 is increased. Of course, even when the outside air is not taken in by the outside air intake member 50, that is, when the microbubbles are not generated, it is needless to say that the “miniature bubbles” themselves are generated by the basic structure of the bubble generator 100. Yes.

  The outside air intake member 50 also has a “check valve” function. That is, when an abnormal pressure is generated on the first flow path 11 or the second flow path 21 side, this pressure is applied to the valve body 52 via the intake port 51, so that the valve body 52 contacts the valve seat 54. This prevents liquid leakage.

  In addition, when attaching this external air intake member 50 to the bubble generator 100, or assembling the valve body 52 and the valve seat 54, it is needless to say that packing is employed at appropriate positions as necessary.

DESCRIPTION OF SYMBOLS 100 Bubble generator 10 Upstream side main body 11 1st flow path 11a Opening 12 Mounting step part 13 Connection part 14 Attachment screw 15 Contact surface 16 Packing 20 Downstream side main body 21 2nd flow path 21a Opening 23 Attachment part 24 Attachment screw 25 Contact surface 30 Dividing piece 31 Fluid passage hole 32 Rectification protrusion 40 Space 50 Outside air intake member 51 Inlet 52 Valve body 53 Spring 54 Valve seat 55 Adjustment screw 200 Discharge member (shower nozzle)
210 Pressure liquid supply member (water tap)
220 hose

Claims (6)

Bubble generation that is interposed between a pressure liquid supply member and a discharge member that discharges the liquid fed from the pressure fluid supply member, and generates minimal bubbles in the liquid discharged from the discharge member A vessel,
An upstream main body provided with a first flow path that narrows toward the downstream side, a diversion piece housed in the first flow path and provided with a large number of liquid passage holes, and attached to the upstream main body, It is composed of a downstream main body provided with a second flow path that extends toward the downstream side,
A bubble generator, wherein a downstream end of the first flow path is opposed to an upstream end of the second flow path. The surface roughness Ra of at least one of the contact surface of the upstream main body and the contact surface of the downstream main body that contact each other is set to 0.2 to 6.3,
2. The bubble generator according to claim 1, wherein outside air can be introduced into the inside through a minute gap between the contact surfaces.   The bubble generator according to claim 1 or 2, wherein the axis of each flow hole of the diversion piece is inclined with respect to the axis of the diversion piece.   The bubble generator according to any one of claims 1 to 3, wherein a space is formed between the upstream main body and the downstream main body.   The size of the opening located at the downstream end of the first flow path is made smaller than the opening located at the upstream end of the second flow path. The bubble generator according to crab.   An outside air intake member having an intake port communicating with the space is attached to the upstream main body or the downstream main body so that the micro bubbles and micro bubbles can be generated in the liquid. The bubble generator according to claim 4 or 5.

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