WO2019049650A1 - Microbubble liquid generator - Google Patents
Microbubble liquid generator Download PDFInfo
- Publication number
- WO2019049650A1 WO2019049650A1 PCT/JP2018/030739 JP2018030739W WO2019049650A1 WO 2019049650 A1 WO2019049650 A1 WO 2019049650A1 JP 2018030739 W JP2018030739 W JP 2018030739W WO 2019049650 A1 WO2019049650 A1 WO 2019049650A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- water
- pipe
- nozzle
- bubble liquid
- liquid generator
- Prior art date
Links
- 239000007788 liquid Substances 0.000 title claims abstract description 72
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 213
- 239000008399 tap water Substances 0.000 claims abstract description 75
- 235000020679 tap water Nutrition 0.000 claims abstract description 75
- 230000007423 decrease Effects 0.000 claims abstract description 6
- 230000007246 mechanism Effects 0.000 claims description 16
- 238000003825 pressing Methods 0.000 claims description 7
- 230000002093 peripheral effect Effects 0.000 claims description 5
- 238000004891 communication Methods 0.000 claims description 3
- 238000004519 manufacturing process Methods 0.000 claims description 3
- 230000009467 reduction Effects 0.000 abstract description 3
- 238000000034 method Methods 0.000 description 7
- 239000007789 gas Substances 0.000 description 5
- 230000000694 effects Effects 0.000 description 4
- 238000005304 joining Methods 0.000 description 4
- 230000009471 action Effects 0.000 description 3
- 238000005406 washing Methods 0.000 description 3
- CURLTUGMZLYLDI-UHFFFAOYSA-N Carbon dioxide Chemical compound O=C=O CURLTUGMZLYLDI-UHFFFAOYSA-N 0.000 description 2
- 230000008859 change Effects 0.000 description 2
- 239000012530 fluid Substances 0.000 description 2
- 230000004048 modification Effects 0.000 description 2
- 238000012986 modification Methods 0.000 description 2
- 239000011148 porous material Substances 0.000 description 2
- 230000001133 acceleration Effects 0.000 description 1
- QVGXLLKOCUKJST-UHFFFAOYSA-N atomic oxygen Chemical compound [O] QVGXLLKOCUKJST-UHFFFAOYSA-N 0.000 description 1
- 230000003796 beauty Effects 0.000 description 1
- 238000005452 bending Methods 0.000 description 1
- 238000009835 boiling Methods 0.000 description 1
- 229910002092 carbon dioxide Inorganic materials 0.000 description 1
- 239000001569 carbon dioxide Substances 0.000 description 1
- 238000004140 cleaning Methods 0.000 description 1
- 238000011109 contamination Methods 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 238000009792 diffusion process Methods 0.000 description 1
- 230000036541 health Effects 0.000 description 1
- 239000001257 hydrogen Substances 0.000 description 1
- 229910052739 hydrogen Inorganic materials 0.000 description 1
- 125000004435 hydrogen atom Chemical class [H]* 0.000 description 1
- 230000006872 improvement Effects 0.000 description 1
- 238000002347 injection Methods 0.000 description 1
- 239000007924 injection Substances 0.000 description 1
- 238000009434 installation Methods 0.000 description 1
- 239000000203 mixture Substances 0.000 description 1
- 239000002101 nanobubble Substances 0.000 description 1
- 239000001301 oxygen Substances 0.000 description 1
- 229910052760 oxygen Inorganic materials 0.000 description 1
- 230000000149 penetrating effect Effects 0.000 description 1
- 230000001737 promoting effect Effects 0.000 description 1
- 210000002374 sebum Anatomy 0.000 description 1
- 239000010865 sewage Substances 0.000 description 1
- 210000000106 sweat gland Anatomy 0.000 description 1
Images
Classifications
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F35/00—Accessories for mixers; Auxiliary operations or auxiliary devices; Parts or details of general application
- B01F35/71—Feed mechanisms
- B01F35/712—Feed mechanisms for feeding fluids
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F23/00—Mixing according to the phases to be mixed, e.g. dispersing or emulsifying
- B01F23/20—Mixing gases with liquids
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F25/00—Flow mixers; Mixers for falling materials, e.g. solid particles
- B01F25/40—Static mixers
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F35/00—Accessories for mixers; Auxiliary operations or auxiliary devices; Parts or details of general application
- B01F35/71—Feed mechanisms
-
- B—PERFORMING OPERATIONS; TRANSPORTING
- B01—PHYSICAL OR CHEMICAL PROCESSES OR APPARATUS IN GENERAL
- B01F—MIXING, e.g. DISSOLVING, EMULSIFYING OR DISPERSING
- B01F35/00—Accessories for mixers; Auxiliary operations or auxiliary devices; Parts or details of general application
- B01F35/71—Feed mechanisms
- B01F35/717—Feed mechanisms characterised by the means for feeding the components to the mixer
- B01F35/7179—Feed mechanisms characterised by the means for feeding the components to the mixer using sprayers, nozzles or jets
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03C—DOMESTIC PLUMBING INSTALLATIONS FOR FRESH WATER OR WASTE WATER; SINKS
- E03C1/00—Domestic plumbing installations for fresh water or waste water; Sinks
- E03C1/02—Plumbing installations for fresh water
-
- E—FIXED CONSTRUCTIONS
- E03—WATER SUPPLY; SEWERAGE
- E03C—DOMESTIC PLUMBING INSTALLATIONS FOR FRESH WATER OR WASTE WATER; SINKS
- E03C1/00—Domestic plumbing installations for fresh water or waste water; Sinks
- E03C1/02—Plumbing installations for fresh water
- E03C1/08—Jet regulators or jet guides, e.g. anti-splash devices
- E03C1/084—Jet regulators with aerating means
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A20/00—Water conservation; Efficient water supply; Efficient water use
- Y02A20/40—Protecting water resources
- Y02A20/411—Water saving techniques at user level
Definitions
- the present invention relates to a micro bubble liquid generator that refines a gas contained in a liquid to increase micro bubbles.
- gas means not only air but also oxygen, hydrogen, carbon dioxide gas and the like
- liquid or “liquid” means tap water, underground water, agricultural water, sewage, drainage etc.
- gas is described as air
- liquid or “liquid” is described as an example of tap water.
- micro bubbles are micro bubbles or nano bubbles (about 50 to 500 nm in diameter) with a bubble diameter of about 100 ⁇ m or less, and small bubbles smaller than the pores can effectively remove dirt on pores and sweat glands. It can be used in various fields, especially in beauty and health. And the fine bubble is utilized also for the purpose of promoting the growth of a plant besides these uses.
- the cleaning effect by the electrical action of the fine bubbles is also attracting attention.
- the surface of the microbubbles has a negative charge, and the microbubbles diffuse and float in water without the bubbles coalescing. Contamination due to oil, sebum, fine foreign matter or the like is usually positively charged and is electrically coupled to the object to be cleaned which is negatively charged. Therefore, when the microbubbles carrying a negative charge are adsorbed to the dirt of the positive charge, they are electrically neutralized, and the dirt is easily separated from the object to be cleaned.
- the dirt that has been electrically neutralized and separated from the object to be washed floats on the water surface by the buoyancy of the bubbles while being adsorbed to the gas-liquid interface of the fine bubbles, whereby the dirt removed from the object to be washed is fine bubbles
- the liquid is washed again without being attached to the object to be washed.
- Patent Document 2 a first nozzle on the inlet side for water flow which gradually reduces a cross-sectional area orthogonal to the central axis from the inlet to the outlet, and communication from the outlet of the first nozzle on the inlet side are provided. And a second nozzle on the outlet side for passing water gradually increasing the cross-sectional area orthogonal to the central axis from the inlet toward the outlet, and A microbubble generator having a side chamber is disclosed.
- the micro-bubble generator of Patent Document 2 generates micro-bubbles from dissolved air in water by cavitation without suctioning air from the outside.
- washing machine which performs washing by jetting micro bubbles generated from dissolved air by a cavitation method from a fluid jetting device to laundry in a washing tank (see, for example, Patent Document 4).
- JP 2007-21343 A JP, 2009-136864, A JP, 2016-2196, A JP, 2016-209331, A
- the micro-bubble generating device according to Patent Document 1 is a gas-liquid mixing method performed by accelerating water stored in a tank, and this method increases the size of the device, and a simple type of water pipe direct connection type is required. It is unsuitable for household use.
- the micro-bubble generating device adjusts the width size in the axial flow direction of the side chamber according to the situation of the water pressure, but the size is adjusted by the adjusting mechanism between the first nozzle and the second nozzle.
- the configuration of the entire nozzle is complicated to provide a changing side chamber.
- the present invention aims to provide a micro bubble liquid generator capable of supplying a sufficient amount of water downstream at the time of supply while securing a necessary micro bubble concentration.
- the present invention is a microbubble liquid generator disposed in a water supply pipe, and has a bulging portion connected to the water supply pipe at both ends and partially enlarged in diameter.
- a water pipe, a nozzle disposed at the bulging portion, a support member for holding the nozzle in the bulging portion along the flowing direction of the tap water, and a bulging flow path of the tap water not passing through the nozzle A water passage provided in the support member so as to be formed in the portion, wherein the nozzle has a first water passage whose diameter gradually decreases along the flowing direction of tap water, and an outlet of the first water passage A second water passage which is provided in communication with the side and whose diameter gradually increases along the flowing direction of the tap water, a throttling portion which connects the first water passage and the second water passage, and the first water passage
- an intake plate provided with a plurality of intake holes provided at the inlet portion; The intake hole, the central axis towards the outlet side is inclined with respect to the central axis of the intake
- the water pipe is formed by connecting a first pipe body and a second pipe body each having an enlarged diameter portion at opposite ends, and the bulging portion is the diameter expanded diameter of the first and second pipe bodies. It is good to form by joining of parts.
- the inner diameter of the enlarged diameter portion of the first tubular body is larger than the outer diameter of the enlarged diameter portion of the second tubular body, and is within the enlarged diameter portion of the first tubular body. The support member and the enlarged diameter portion of the second tube are inserted and joined.
- the inner diameter of the enlarged diameter portion of the second tubular body is larger than the outer diameter of the enlarged diameter portion of the first tubular body, and the support member and the first diameter are included in the enlarged diameter portion of the second tubular body.
- the enlarged diameter portion of the tube is inserted and joined.
- the first tubular body may include a pressing member that clamps the outer ring portion with the second tubular body.
- first pipe body and the second pipe body are formed by joining with a pipe joint in a state in which the support member is held between the end faces of the respective enlarged diameter portions.
- the support member includes an inner ring portion holding the nozzle at its inner periphery, an outer ring portion fixed to the bulging portion, and a plurality of ring portions connecting the inner ring and the outer ring. Configure. Therefore, a space between the radial portions becomes a water flow portion, and forms a flow path of tap water which does not pass through the nozzle.
- the support member includes an outer ring portion fixed to the bulging portion, and an inner circumferential wall of the outer ring portion arranged in a circle at equal intervals inside the outer ring portion. And a plurality of nozzle support portions connected to each other and holding the nozzle at the inner periphery.
- a plurality of nozzles are disposed in the bulging portion, and a gap between the outer ring portion and the nozzle support portion is a water flow portion through which tap water not passing through the nozzles flows in the bulging portion and passes through the nozzles Do not form a tap water flow path.
- the water intake hole By bending the water intake hole from the inlet side to the outlet side, the water intake hole is twisted, so that the tap water is introduced into the first water passage as a swirl flow having a higher rotation rate.
- an uneven surface for generating turbulent flow is formed on the inner surface of the water intake hole, the degree of turbulent flow when tap water passes through the water intake hole is increased, and dissolved air in tap water becomes easy to take out, Cavitation bubbles can be generated effectively.
- an uneven surface may be formed on the inner surface of the second water flow passage to generate turbulent flow.
- an opening adjusting mechanism that changes the opening area for each water intake hole be provided so that the tap water fed into the nozzle can be adjusted to an appropriate feeding pressure.
- an iris diaphragm mechanism formed by superposing a plurality of diaphragm blades.
- the bulging portion in which a part of the water flow pipe is expanded is configured to hold the nozzle and to arrange the support member forming the water flow portion. Since the fine bubble liquid rejoins the water that has passed through the water flow part, it is possible to supply a sufficient amount of water per unit time downstream, and the water pressure of the supplied water via the fine bubble liquid generator It is possible to effectively prevent the reduction and the decrease of the amount of water supply per unit time.
- the schematic of the tap water supply system of the house to which the micro-bubble liquid generator which concerns on this invention is applied is shown.
- the side cross-sectional view of a micro-bubble liquid generator is shown.
- the nozzle of a micro-bubble liquid generator is shown with a partially cross-sectional view.
- (A) shows the top view of an intake plate
- (b) shows the side view of an intake plate, respectively.
- the support member is shown in an external perspective view.
- the other embodiment which connects a pipe body using a pipe joint is shown in a partial side view.
- action in a nozzle is shown.
- the modification of the water intake hole of a water intake plate is shown, respectively.
- the nozzle which enabled adjustment of the opening area of a water intake using an opening adjustment mechanism is shown by a perspective view.
- the schematic diagram explaining the change of the opening area of the inlet port of the water intake hole adjusted with an opening adjustment mechanism is shown.
- the side view of the micro-bubble liquid generator of the embodiment which arranges a plurality of nozzles in a bulging part is shown.
- the top view of the support member used for the micro-bubble liquid generator shown in FIG. 11 is shown.
- FIG. 12 is a plan view showing another embodiment of a support member used in the micro-bubble liquid generator shown in FIG.
- FIG. 1 is a schematic view showing a tap water supply system of an individual residence and an apartment building (including an office building) to which the micro-bubble liquid generator 1 according to the present invention is applied.
- the micro-bubble liquid generator 1 in the door-to-door housing 10 is inserted in the middle of the water supply pipe 3 together with the tap water quantity meter (meter) 11, and is disposed downstream of the quantity water quantity meter (meter) 11.
- the water supply pipe 3 is connected to a water supply pipe 12 branched from the water supply main 14 toward the house 10 via a water stop valve 13. Therefore, the micro-bubble liquid generator 1 generates many micro-bubbles in the tap water flowing through the water heater 11, and the generated micro-bubble liquid is branched from the downstream side of the water supply pipe 3. It is supplied from each water tap 15 in the house 10 from the branch water supply pipe 14.
- tap water is provided with a water receiving tank 15 downstream of the same water pipe 12, water stop valve 13 and water heater 11 as described above, and the stored water in the water receiving tank 15 is elevated by the pump 16 After being lifted and stored in the water tank 17, it is supplied to each door by weight.
- the micro-bubble liquid generator 1 in this case is inserted along with the water discharger 11 a in the middle of the water supply pipe 3 of each residence, and the micro-bubble liquid is supplied from each water tap 15.
- FIG. 2 shows a configuration of the micro-bubble liquid generator 1 partially in a side view in cross section.
- the micro bubble liquid generator 1 includes a water flow pipe 2 through which tap water flows in a direction indicated by an arrow, a nozzle 5 disposed in a bulging portion 4 formed in a central portion of the water flow pipe 2, and a nozzle 5 And a supporting member 6 for holding the inside of the bulging portion 4.
- the water flow pipe 2 is formed by connecting the pipe 2A and the pipe 2B, and the ends of the pipe 2A and the pipe 2B facing each other are expanded in diameter.
- the diameter of the enlarged diameter portion of the tube body 2B is larger than the diameter of the expanded diameter portion of the tube body 2A, and the enlarged diameter portion of the tube body 2A is inserted into the enlarged diameter portion of the tube body 2B.
- the screw formed on is screwed and connected.
- the connection portion forms the bulging portion 4 of the water flow pipe 2.
- the ends on the opposite side of the ends provided with the enlarged diameter portions of the pipes 2A and 2B are connected to the water supply pipe 3 by the pipe connection device 18, respectively, and the tap water passing through the water supply pipe 3 flows in the arrow direction.
- the pipe connection device 18 for example, a ring-shaped gasket fitted over the outer periphery of the end of the pipe to be connected, and a pair in which both ends are connected by a fastener so as to hold the gasket.
- a housing type pipe joint configured with the housing of
- FIG. 3 shows the nozzle 5 in a side sectional view and comprises a first cylindrical portion 5a and a second cylindrical portion 5b.
- the first cylindrical portion 5a is formed of a bottomed cylindrical body, and the bottom surface is a second cylindrical portion.
- a hole communicating with 5b is provided in the first cylindrical portion 5a.
- the circular water intake plate 7 is inserted by screwing the side portion of the outer periphery with the inner periphery. At this time, the peripheral edge of the water intake plate 7 is the first cylindrical portion 5a. It is locked at the bottom surrounding the hole.
- a taper 39 is annularly formed at an end on the intake side of the first cylindrical portion 5a so as to easily take in tap water.
- the intake plate 7 has a thickness dimension t of 5 mm, for example, for a diameter dimension d of 13.5 mm.
- the water intake plate 7 for example, four circular water intake holes 8 penetrating in the axial direction at equal intervals on a plane are formed in a circle.
- the number of the water intake holes 8 can be plural (for example, about 2 to 8).
- the intake holes 8 of the 4 round holes which penetrate in an axial direction at equal intervals on a plane at a circle are drilled. As shown in the side view of FIG.
- the water intake hole 8 has a central axis L from the tap water inlet side to the outlet side at a predetermined angle ⁇ with respect to the central axis H of the water intake plate 7.
- ⁇ is bored in the intake plate 7 in the shape of an inclined cylinder inclined at 15 degrees.
- each water intake hole 8 at this time is formed to be directed in the counterclockwise direction in the drawing as shown by the arrow.
- the intake plate 7 is screwed with the first cylindrical portion 5a with the left screw in the same rotational direction as the discharged water flow, so that the screw tightening direction and the released water rotation direction do not coincide with each other.
- FIG. 4B only one of the water intake holes 8 is shown as a representative.
- a first water passage 21 whose inner diameter gradually narrows from the first cylindrical portion 5a toward the central portion, a throttling portion 22 connected to the first water passage 21, and a throttling portion
- a second water passage 23 is formed which is connected to the outlet 22 and whose internal diameter gradually increases toward the outlet side.
- the bore diameter at the inlet side of the first water flow path 21 of the nozzle 5 is set larger than the bore diameter at the outlet side of the second water flow path 23, and between the first water flow path 21 and the second water flow path 23.
- the axial dimension is set longer than the second water passage 8b.
- the diameter and length of the inlet of the first water flow passage 21 can be varied in size depending on the situation in order to control the water pressure and the amount of fine air bubbles generated.
- the throttling portion 22 is provided to connect the ends on the small diameter side of the first and second water passages 21 and 23 with each other.
- the supporting member 6 has an inner ring portion 6a whose inner diameter is equal to the diameter of the outer periphery of the second cylindrical portion 5b of the nozzle 5 and an outer diameter equal to the inner diameter of the enlarged diameter portion of the tube 2B. It is comprised from the outer ring part 6b and the three radial parts 6c which connect the inner ring part 6a and the outer ring part 6b radially so that a central angle may become equal.
- the space between the radial portions 6 c is the water flow portion 11 of the tap water flowing through the water flow pipe 2.
- an external thread 61 is formed to be screwed with the female screw 2a formed on the inner periphery of the enlarged diameter portion of the tube 2B.
- a female screw 62 is formed to be screwed with the male screw 51 provided on the outer periphery of the second cylindrical portion 5 b of the nozzle 5. Therefore, the support member 6 is screwed and fixed to the nozzle 5 inserted into the inner ring portion 6a, and the outer ring portion 6b is screwed into the tubular body 2A, so that the nozzle 5 is expanded in the bulging portion 4 Hold on.
- a pressing member 29 for holding the support member 6 is fixedly attached to the tubular body 2B continuously or intermittently along the inner periphery thereof.
- the pressing member 29 receives the tap water pressure and prevents the water hammer by fulfilling the function of the cushion when the supporting member 6 is moved to the downstream side, which is the left direction in the drawing.
- Such a pressing member 29 is formed of an elastic member such as a spring member or a member having flexibility.
- an external thread 9b is formed to be screwed with the internal thread 2a provided on the inner periphery of the enlarged diameter portion of the tube 2A.
- a female screw 9c is formed to be screwed with the male screw 5c provided on the outer periphery of the two cylindrical portion 5b. Therefore, the support member 6 in this example is fixed by screwing the nozzle 5 inserted into the center hole 9a and screwing the disc 9 into the tube 2A at its outer periphery to expand the nozzle 5 Hold in the outlet 4.
- FIG. 6 shows a further embodiment of the connection of the tubes 2A, 2B in a side view, in which the tubes 19 are used to connect the tubes 2A, 2B.
- the diameter of each enlarged diameter portion of the tubes 2A and 2B is equal, and at the same time, the outer diameter of the support member 6 is also equal to the diameter of each enlarged diameter portion of the tubes 2A and 2B.
- male screws are provided on the outer peripheries of the tubular members 2A and 2B and the supporting member 6, and when the tubular members 2A and 2B sandwich and support the supporting member 6, these male screws are connected continuously. Form a threaded part to be screwed with a female screw provided on the inner circumference of the.
- the pipe joint 19 fixes the state in which the support member 6 is sandwiched by the ends of the enlarged diameter portions of the pipe bodies 2A and 2B.
- both side surfaces of the outer ring portion 6b are sandwiched by the pipes 2A and 2B and fixed by the pipe joint 19.
- the peripheries on both sides of the disc 9 are sandwiched by the pipes 2A and 2B and fixed by the pipe joint 19.
- the tap water flowing in the bulging portion 4 is in high pressure and the flow velocity rises, so most of the tap water flowing in the water flow pipe 2 is the water flowing portion 11 Will pass.
- the amount of water passing through the water passage 11 is about 80% of the whole so that the rest flows to the nozzle 5.
- the water flow rate from the water supply pipe 3 to the bulging portion 4 of the water flow pipe 2 is preferably at least 80% or more.
- each intake hole 8 of the intake plate 7 passes through the intake hole 8 in the shape of a diagonal cylinder, and deviates from the direction of the central axis H of the intake plate 7 and the central axis of the oblique intake hole 8 It is released in the direction of L. Therefore, as described in FIG. 4, the tap water passing through each intake hole 8 is introduced into the first water passage 21 of the nozzle 5 as a swirl flow twisted in the same direction as indicated by the arrows. Ru.
- the tap water having passed through the water intake hole 8 obliquely strikes the inner wall of the first water flow passage 21, and thus advances to the throttling portion 22 while being spirally swirled as schematically shown in FIG.
- the first water passage 21 has a shape in which the inner diameter is narrowed along the flowing direction, when it flows to the throttling portion 22 while increasing the swirling speed toward the throttling portion 22 and passes through the throttling portion 22, It is jetted at high pressure to the second water passage 23 and diffused in the second water passage 23.
- the diameter of the inlet side of the first water flow passage 21 of the nozzle 5 is larger than the diameter of the outlet side of the second water flow passage 23.
- the micro-bubble liquid generated from the tap water passing through the nozzle 5 and the tap water mixed with the water passing portion 11 of the support member 6 without passing through the nozzle 5 Is released to the tube 2B.
- the diameter of the pipe becomes narrow again, so that the speed is increased to flow from the pipe body 2B to the water pipe downstream.
- the bulging portion 4 is provided in the water flow pipe 2 and the nozzle 5 is disposed in the bulging portion 4 so that the flow rate of the tap water is bulging portion 4
- the pressure is increased to increase the passing pressure, and the pressure is branched into a flow passage passing through the water passage 11 and a flow passage passing through the nozzle 5. Then, after branching, in the tubular body 2B, by combining the fine bubble liquid generated by the nozzle 5 and the tap water having passed through the water flow portion 11, a sufficient amount of tap water is downstream per unit time. It is possible to supply to
- the provision of the bulging portion 4 accelerates the flow rate of the tap water.
- tap water is supplied at a minimum water pressure of 1.5 kgf / cm 2 (0.15 MPa), ideally 2.0 to 4.0 kgf / cm 2 (0.2 to 0.39 MPa).
- cavitation in the nozzle 5 may not be effectively performed if the pressure is lower than the lower limit depending on the shape of the bulging portion 4.
- the nozzle 5 in the micro-bubble liquid generator 1 arranges the intake plate 7 provided with the intake hole 8 at the inlet side, and takes in tap water through the intake hole 8 to obtain tap water. I am increasing the flow rate.
- the shape of the water intake hole 8 is an oblique cylinder, and the flow velocity is further raised by rotating the tap water passing through the water intake hole 8 to create a swirl flow. As a result, even if the outer diameter of the bulging portion 4 is large, cavitation is effectively performed because the flow velocity is increased again when taking in the nozzle 5 by providing the guide at the water intake port 8.
- the tap water is discharged from the water intake hole 8 while increasing the degree of turbulent flow.
- a large number of protrusions are provided to form the uneven surface 8a.
- the shape of the water intake hole 8 may be a shape in which a bent portion is provided in an oblique cylinder from the inlet side to the outlet side to add a twist.
- twist is added to the flow of the tap water, and it is possible to generate a swirling flow having a higher rotation rate in the first water passage 8a.
- the inner wall of the water intake hole 8 is made to be the uneven surface 8a, the generation effect of cavitation bubbles in the nozzle 5 is further enhanced in combination with the improvement of the turbulent flow degree.
- the surface of the inner wall of the second water flow passage 23 of the nozzle 5 is also processed to be uneven, when a negative pressure is generated, if the diffused fine bubbles further hit the inner wall surface, the bubbles are promoted to be finer. It is possible to generate tap water containing a high concentration of fine bubbles.
- FIG. 9 is a perspective view showing the nozzle 5 provided with the water intake plate 7 in which the opening area of the water intake hole 7 can be adjusted using the opening adjustment mechanism 24.
- the opening adjustment mechanism 24 is an orifice configured to include an iris diaphragm mechanism so as to change the opening area of the water intake hole 7.
- the iris diaphragm mechanism is generally known as a diaphragm of a camera lens or the like, and as shown in (a) to (d) of FIG.
- the central opening 25 (water intake hole 7) becomes substantially circular.
- the area of the water intake hole 7 is changed in four ways by rotating the plurality of throttle pieces 30 superimposed in this manner by driving a gear (not shown).
- the gears of the opening adjusting mechanisms 24 are simultaneously driven by rotating the hole diameter adjusting dial 37 provided on the outer periphery of the first cylindrical portion 5a of the nozzle 5, and the opening areas of the water intake holes 8 are all the same. It is configured to be adjustable in size.
- the feed pressure of tap water when the feed pressure of tap water is low, the feed pressure can be increased and introduced to the nozzle 5 by reducing the opening area of the water intake hole 8, The feed pressure of the tap water to the nozzle 5 can be adjusted to be constant.
- micro-bubble liquid generator 1 of the said embodiment is comprised by one nozzle 5, by providing the bulging part 4, you may arrange multiple nozzles with a small aperture.
- FIG. 11 is a partial side view showing a micro bubble liquid generator 1A according to an embodiment provided with three nozzles 31.
- the water flow pipe 2 is formed by connecting the first pipe body 2A and the second pipe body 2B each having an enlarged diameter portion at opposite ends, and the bulging portion 4 is formed by joining the respective enlarged diameter portions. It is formed.
- the nozzle 31 has a structure similar to the above-described nozzle 5, the diameter is made smaller because a plurality of nozzles 31 are used.
- the bulging part 4 by joining of a diameter-increased part of each other is formed,
- the receiving portion 38 is formed in the second tubular body 2B, and the supporting member 32 is sandwiched between the receiving portion 38 and the end face of the enlarged diameter portion of the first tubular body 2A.
- the above-mentioned pressing member 29 which is an elastic member for preventing the water hammer is attached to the receiving portion 38 by performing the function of a cushion. It is done.
- the support member 32 in this embodiment is, as shown in FIG. 12, an outer ring portion 33 fixed to the bulging portion 4 by screwing at its peripheral portion, and a circular shape at equal intervals inside the outer ring portion 33. , And are connected by the inner peripheral wall of the outer ring portion 33 and the connection portion 34, and each of the nozzle support portions 35 is provided with three types of nozzle support portions 35 for holding the nozzles 31 by screwing.
- Each nozzle support portion 35 is integrally formed, and each has a shape extending radially from the center of the outer ring portion 33, and the gap between the outer ring portion 33 and the nozzle support portion 35 is bulged. It becomes the water flow part 36 in which the tap water which does not pass the nozzle 31 in the part 4 flows.
- the central portion of the support member 32 overlapping the center of the support member 32 is rolled out to form a central hole 36 a that constitutes a part of the water flow portion 36. Thereby, 80% or more of said water flow rate in the bulging part 4 is ensured.
- the support member 32A may be provided with four nozzle support portions 35 to hold four nozzles 31.
- two nozzles 31 may be provided by arranging two nozzle supports 35 symmetrically with respect to the center hole 36A.
- the micro-bubble liquid generator provided with the support members 32 and 32A capable of supporting the plurality of nozzles 31 has the injection output of the micro-bubble liquid from the nozzles 31, the micro-bubble amount, and the tap water passing through the water passage 36
- the number of nozzles 31 can be adjusted so that the optimal amount of tap water and the concentration of the micro bubble liquid can be secured from the micro bubble liquid generator 1 according to the respective conditions such as the amount of.
- the adjustment may be performed by enlarging or reducing the shape of the nozzles 31 instead of the number of the nozzles 31.
- the present invention is not limited to the above embodiment, and various modifications are possible based on the spirit of the present invention.
- the water intake holes 8 should be in the plane of the water intake plate 7 rather than circularly arranged at equal intervals. It is preferable to arrange uniformly.
- the diameter of the entrance side of the 1st water flow passage 21 is made larger than the diameter of the exit side of the 2nd water flow passage 23, and the above-mentioned embodiment makes the distance in the central axis direction the 2nd water flow passage 23 Is longer, but may be reversed, or may be configured to be symmetrical with the same aperture centered on the narrowed portion 22.
- the point is that the relationship between the pressure of the tap water spouted from the first water passage 21 and the pressure that decreases due to the diffusion in the second water passage 23 makes it possible to obtain an appropriate amount and high quality cavitation bubbles as fine bubbles. It is set so that it can be generated.
- the nozzles 5 may be arranged in series at a certain interval.
- the bulging portion in which a part of the water flow pipe is expanded holds the nozzle and the support member for forming the water flow portion is disposed, so that In order to recombine the fine bubble liquid to be generated with the water passing through the water flow section, it is possible to supply a sufficient amount of water per unit time downstream, and the feed water via the fine bubble liquid generator It is possible to effectively prevent the reduction of water pressure and the decrease of water supply volume per unit time.
- micro bubble liquid generator 1A micro bubble liquid generator 2 water flow pipe 2A 1st pipe body 2B 2nd pipe body 4 bulging part 5 nozzle 6 support member 6a inner ring part 6b outer ring part 6c ring part 7c intake part 7 water intake plate 8 water intake Hole 12 Water pipe 21 first water passage 22 throttling portion 23 second water passage 24 opening adjustment mechanism 29 pressing member 32 support member 33 outer ring portion 35 nozzle support portion
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Abstract
Provided is a microbubble liquid generator with which it is possible to prevent a reduction in water pressure of supplied water and ensure a sufficient amount of water while ensuring the necessary microbubble concentration. A water pipe (2) connected to tap water supply piping (12) has, in a part thereof, an expanded part (4) of which the diameter is enlarged. The expanded part (4) is provided with a support member (6) comprising an inner ring part (6a) for holding a nozzle (5) on the inner periphery thereof, an outer ring part (6b) secured to the expanded part (4), and a plurality of spokes parts (6c) for linking the inner ring part (6a) and the outer ring part (6b). The nozzle (5) comprises, on an inlet-side water intake plate (7), a plurality of water intake holes (8) of which the center axes are inclined with respect to the axis of the water pipe (2) of a tap water supply. Tap water discharged diagonally from each of the water intake holes (8) increases in speed while swirling in a spiral shape on the inner wall of a first water channel (8a) and is ejected into a second water channel (8b). The resulting rapid decrease in pressure generates a microbubble liquid containing a very large number of ultrafine cavitation bubbles. The microbubble liquid is merged with tap water that passes between the spokes parts (6c) opening in the support member (6) without passing through the nozzle (5), and is discharged downstream.
Description
本発明は、液体中に含まれる気体を微細化させて微細気泡を増加させる微細気泡液生成器に関する。
The present invention relates to a micro bubble liquid generator that refines a gas contained in a liquid to increase micro bubbles.
尚、本願において「気体」とは、空気のみならず、酸素、水素、炭酸ガス等を意味し、また、「液」又は「液体」とは、水道水、地下水、農業用水、下水、排水等を意味するが、本願発明を実施する形態においては、「気体」を空気、「液」又は「液体」を水道水の例として説明する。
In the present application, "gas" means not only air but also oxygen, hydrogen, carbon dioxide gas and the like, and "liquid" or "liquid" means tap water, underground water, agricultural water, sewage, drainage etc. In the embodiment of the present invention, “gas” is described as air, and “liquid” or “liquid” is described as an example of tap water.
微細気泡とは、気泡の直径がおよそ100μm以下のマイクロバブルやナノバブル(直径50~500nm程度)のことであり、毛穴よりも微小な小さな泡が毛穴や汗腺の汚れを効果的に除去することができ、特に美容や健康での様々な分野で利用されている。そして、微細気泡は、これらの用途以外でも植物の成長を促進させるなどの目的でも利用されている。
The micro bubbles are micro bubbles or nano bubbles (about 50 to 500 nm in diameter) with a bubble diameter of about 100 μm or less, and small bubbles smaller than the pores can effectively remove dirt on pores and sweat glands. It can be used in various fields, especially in beauty and health. And the fine bubble is utilized also for the purpose of promoting the growth of a plant besides these uses.
また、微細気泡の電気的作用による洗浄効果も注目されている。微細気泡の表面はマイナスの電荷を有しており、気泡どうしが合体することなく、微細気泡は、水中に拡散・浮遊している。これに対し、油や皮脂、細かい異物等による汚れは通常プラスに帯電して、マイナスの電荷を帯びた被洗浄物と電気的に結合している。よって、マイナスの電荷を帯びている微細気泡がプラス電荷の汚れに吸着すると電気的に中和されて、汚れを被洗浄物から分離しやすい状態となる。そして、電気的に中和されて被洗浄物から分離した汚れは、微細気泡の気液界面に吸着したまま気泡の浮力によって水面に浮上することで、被洗浄物から除去された汚れが微細気泡液中で再び被洗浄物に付着されることなく洗浄されていく。
In addition, the cleaning effect by the electrical action of the fine bubbles is also attracting attention. The surface of the microbubbles has a negative charge, and the microbubbles diffuse and float in water without the bubbles coalescing. Contamination due to oil, sebum, fine foreign matter or the like is usually positively charged and is electrically coupled to the object to be cleaned which is negatively charged. Therefore, when the microbubbles carrying a negative charge are adsorbed to the dirt of the positive charge, they are electrically neutralized, and the dirt is easily separated from the object to be cleaned. Then, the dirt that has been electrically neutralized and separated from the object to be washed floats on the water surface by the buoyancy of the bubbles while being adsorbed to the gas-liquid interface of the fine bubbles, whereby the dirt removed from the object to be washed is fine bubbles The liquid is washed again without being attached to the object to be washed.
このような微細気泡を含有する液体を生成するには、高速せん断方式、加圧圧壊方式、キャビテーション方式などが知られているが、その多くが、アスピレータ方式などで、外部から空気を吸引している。或いは、強制注入している。例えば、特許文献1には、加速手段にて加速される液体、及び気液混合手段によりケーシングに導入される気体(直径が数ミリ程度の気泡)から成る混合流体をケーシング内にキャビテーションを起こさせて、マイクロバブルを発生するマイクロバブル発生装置が開示されている。
There are known high-speed shear method, pressure crush method, cavitation method, etc. to generate the liquid containing such fine bubbles, but many of them suck air from the outside by aspirator method etc. There is. Or it is injecting forcibly. For example, in Patent Document 1, cavitation is caused in the casing of a mixed fluid composed of a liquid to be accelerated by the acceleration means and a gas (bubbles having a diameter of several millimeters) introduced into the casing by the gas-liquid mixing means. There is disclosed a micro-bubble generator that generates micro-bubbles.
また、特許文献2には、入口から出口に向かってその中心軸に直交する断面積を漸減する通水用入口側の第1ノズルと、入口側の第1ノズルの出口から連通して設けられた連通路を介して連続して配設され、入口から出口に向かってその中心軸に直交する断面積を漸増する通水用出口側の第2ノズルと、前記連通路にのみ開口した隙間又は側室とを有するマイクロバブル発生装置が開示されている。この特許文献2のマイクロバブル発生装置は、外部から空気を吸入することなしに、水の中の溶存空気からキャビテーション方式によってマイクロバブルを発生させている。
Further, in Patent Document 2, a first nozzle on the inlet side for water flow which gradually reduces a cross-sectional area orthogonal to the central axis from the inlet to the outlet, and communication from the outlet of the first nozzle on the inlet side are provided. And a second nozzle on the outlet side for passing water gradually increasing the cross-sectional area orthogonal to the central axis from the inlet toward the outlet, and A microbubble generator having a side chamber is disclosed. The micro-bubble generator of Patent Document 2 generates micro-bubbles from dissolved air in water by cavitation without suctioning air from the outside.
そして、水の中の溶存空気からキャビテーション方式によってマイクロバブルを発生させる方式のマイクロバブル発生器を備えるシャワーヘッドが知られている(例えば、特許文献3を参照)。
And the shower head provided with the micro bubble generator of the system which generates a micro bubble from the dissolved air in water by a cavitation system is known (for example, refer patent document 3).
また、溶存空気からキャビテーション方式によって発生させたマイクロバブルを流体噴射装置から洗濯槽内の洗濯物に対して噴射して洗濯を行う洗濯機も知られている(例えば、特許文献4を参照)。
There is also known a washing machine which performs washing by jetting micro bubbles generated from dissolved air by a cavitation method from a fluid jetting device to laundry in a washing tank (see, for example, Patent Document 4).
しかしながら、特許文献1によるマイクロバブル発生装置は、タンクに貯留した水を加速して行う気液混合方式であり、この方式は、装置が大型化し、水道管直結型の簡易なタイプが要求される家庭用には不向きである。
However, the micro-bubble generating device according to Patent Document 1 is a gas-liquid mixing method performed by accelerating water stored in a tank, and this method increases the size of the device, and a simple type of water pipe direct connection type is required. It is unsuitable for household use.
特許文献2によるマイクロバブル発生装置は、水道圧の状況に応じて側室の軸流方向での幅サイズを調整しているが、第1ノズルと第2ノズルとの間に、調整機構によってサイズが変更する側室を設けるためにノズル全体の構成が複雑となっている。
The micro-bubble generating device according to Patent Document 2 adjusts the width size in the axial flow direction of the side chamber according to the situation of the water pressure, but the size is adjusted by the adjusting mechanism between the first nozzle and the second nozzle. The configuration of the entire nozzle is complicated to provide a changing side chamber.
また、特許文献3及び特許文献4においては、水道水の流路に絞りを設けて、キャビテーションにより微細気泡を発生させているが、水道水が絞りを通過することで必要な水量を確保できないことがある。
Moreover, in patent document 3 and patent document 4, although the throttle is provided in the flow path of tap water and fine bubbles are generated by cavitation, the tap water can not secure the necessary amount of water by passing through the throttle. There is.
上記点より本発明は、必要な微細気泡濃度を確保しつつ、供給時には十分な水量を下流へ供給することができる微細気泡液生成器を提供することを目的としている。
From the above point, the present invention aims to provide a micro bubble liquid generator capable of supplying a sufficient amount of water downstream at the time of supply while securing a necessary micro bubble concentration.
上記課題を解決するために、本発明は、水道配管に配設される微細気泡液生成器であって、両端で前記水道配管に接続されて一部に拡径された膨出部を有する通水管と、前記膨出部に配置されるノズルと、前記膨出部内において前記ノズルを水道水が流れる方向に沿って保持する支持部材と、前記ノズルを通過しない水道水の流路を前記膨出部内に形成するよう前記支持部材に設けられる通水部と、を備えて、前記ノズルは、水道水の流れる方向に沿って径が漸次縮小する第1通水路と、前記第1通水路の出口側に連通して設けられ水道水の流れる方向に沿って径が漸次増大する第2通水路と、前記第1通水路と前記第2通水路とを繋ぐ絞り部と、前記第1通水路の入口部に設けられる複数の取水孔が設けられる取水プレートと、を有して、前記取水孔は、その入口側から出口側に向けての中心軸が前記取水プレートの中心軸に対し傾斜させている。
In order to solve the above problems, the present invention is a microbubble liquid generator disposed in a water supply pipe, and has a bulging portion connected to the water supply pipe at both ends and partially enlarged in diameter. A water pipe, a nozzle disposed at the bulging portion, a support member for holding the nozzle in the bulging portion along the flowing direction of the tap water, and a bulging flow path of the tap water not passing through the nozzle A water passage provided in the support member so as to be formed in the portion, wherein the nozzle has a first water passage whose diameter gradually decreases along the flowing direction of tap water, and an outlet of the first water passage A second water passage which is provided in communication with the side and whose diameter gradually increases along the flowing direction of the tap water, a throttling portion which connects the first water passage and the second water passage, and the first water passage And an intake plate provided with a plurality of intake holes provided at the inlet portion; The intake hole, the central axis towards the outlet side is inclined with respect to the central axis of the intake plate from the inlet side.
前記通水管は、対峙する端部にそれぞれ拡径部を有する第1管体と第2管体とを接続して成り、前記膨出部は、前記第1及び第2管体の前記拡径部どうしの接合により形成するとよい。このときの、ある実施形態では、前記第1管体の前記拡径部の内径は、前記第2管体の前記拡径部の外径より大きく、前記第1管体の前記拡径部内に前記支持部材と前記第2管体の前記拡径部を挿入して接合して形成する。又は、前記第2管体の前記拡径部の内径は、前記第1管体の前記拡径部の外径より大きく、前記第2管体の前記拡径部内に前記支持部材と前記第1管体の前記拡径部を挿入して接合して形成する。そして、前記第1管体は、前記第2管体とで前記外環部を挟持する押え部材を備えるとよい。
The water pipe is formed by connecting a first pipe body and a second pipe body each having an enlarged diameter portion at opposite ends, and the bulging portion is the diameter expanded diameter of the first and second pipe bodies. It is good to form by joining of parts. At this time, in one embodiment, the inner diameter of the enlarged diameter portion of the first tubular body is larger than the outer diameter of the enlarged diameter portion of the second tubular body, and is within the enlarged diameter portion of the first tubular body. The support member and the enlarged diameter portion of the second tube are inserted and joined. Alternatively, the inner diameter of the enlarged diameter portion of the second tubular body is larger than the outer diameter of the enlarged diameter portion of the first tubular body, and the support member and the first diameter are included in the enlarged diameter portion of the second tubular body. The enlarged diameter portion of the tube is inserted and joined. The first tubular body may include a pressing member that clamps the outer ring portion with the second tubular body.
また、他の実施形態では、前記第1管体と前記第2管体とは、それぞれの前記拡径部の端面どうしで前記支持部材を挟持している状態で管継手によって接合して形成する。
In another embodiment, the first pipe body and the second pipe body are formed by joining with a pipe joint in a state in which the support member is held between the end faces of the respective enlarged diameter portions. .
そして、前記支持部材は、前記ノズルをその内周で保持する内環部と、前記膨出部に固定される外環部と、前記内環と前記外環とを繋ぐ複数の輻部とで構成する。よって、輻部どうしの間が通水部となり、前記ノズルを通過しない水道水の流路を形成する。
The support member includes an inner ring portion holding the nozzle at its inner periphery, an outer ring portion fixed to the bulging portion, and a plurality of ring portions connecting the inner ring and the outer ring. Configure. Therefore, a space between the radial portions becomes a water flow portion, and forms a flow path of tap water which does not pass through the nozzle.
前記支持部材の別の実施例は、前記膨出部に固定される外環部と、前記外環部の内側に等間隔で円状に並べて配置されると共に前記外環部の内周壁とに連結されて、それぞれが前記ノズルを内周で保持する複数のノズル支持部とを備える。この場合、複数のノズルを膨出部に配置して、外環部とノズル支持部との間の隙間が、膨出部内でノズルを通過しない水道水が流れる通水部となり、前記ノズルを通過しない水道水の流路を形成する。
Another embodiment of the support member includes an outer ring portion fixed to the bulging portion, and an inner circumferential wall of the outer ring portion arranged in a circle at equal intervals inside the outer ring portion. And a plurality of nozzle support portions connected to each other and holding the nozzle at the inner periphery. In this case, a plurality of nozzles are disposed in the bulging portion, and a gap between the outer ring portion and the nozzle support portion is a water flow portion through which tap water not passing through the nozzles flows in the bulging portion and passes through the nozzles Do not form a tap water flow path.
前記取水孔を入口側から出口側に向けて屈曲形成することで、取水孔には捻じれが生じるため、水道水はより回転率の高い旋回流となって第1通水路へ導入される。
By bending the water intake hole from the inlet side to the outlet side, the water intake hole is twisted, so that the tap water is introduced into the first water passage as a swirl flow having a higher rotation rate.
そして、前記取水孔の内面には乱流を発生するための凹凸面を形成すれば、水道水が取水孔を通過するときの乱流度が高まり、水道水中の溶存空気が取り出しやすくなるため、キャビテーション気泡が効果的に発生させることができる。同様に、前記第2通水路の内面に乱流を発生するための凹凸面を形成するとよい。
Then, if an uneven surface for generating turbulent flow is formed on the inner surface of the water intake hole, the degree of turbulent flow when tap water passes through the water intake hole is increased, and dissolved air in tap water becomes easy to take out, Cavitation bubbles can be generated effectively. Similarly, an uneven surface may be formed on the inner surface of the second water flow passage to generate turbulent flow.
また、前記取水孔ごとに開口面積を可変する開口調節機構を設けて、ノズルへ送り込む水道水を適切な送給圧に調整可能にするとよい。最適な開口調節機構の例として、複数枚の絞り羽根を重ね合わせて形成される虹彩絞り機構がある。
In addition, it is preferable that an opening adjusting mechanism that changes the opening area for each water intake hole be provided so that the tap water fed into the nozzle can be adjusted to an appropriate feeding pressure. As an example of the optimum aperture adjustment mechanism, there is an iris diaphragm mechanism formed by superposing a plurality of diaphragm blades.
本発明による微細気泡液生成器は、通水管の一部が拡径された膨出部でノズルを保持すると共に通水部を形成する支持部材を配置する構成としたことで、ノズルで生成される微細気泡液は通水部を通過した水と再度合流するために、下流へは単位時間あたりで十分な水量を供給することが可能であり、微細気泡液生成器を経由した供給水の水圧低減と単位時間当たりの供給水量の低下を有効に防止することを可能とした。
In the micro-bubble liquid generator according to the present invention, the bulging portion in which a part of the water flow pipe is expanded is configured to hold the nozzle and to arrange the support member forming the water flow portion. Since the fine bubble liquid rejoins the water that has passed through the water flow part, it is possible to supply a sufficient amount of water per unit time downstream, and the water pressure of the supplied water via the fine bubble liquid generator It is possible to effectively prevent the reduction and the decrease of the amount of water supply per unit time.
本発明の実施形態を図面を参照して説明する。図1は、本発明に係る微細気泡液生成器1を適用した戸別住宅及び集合住宅(オフィスビルも含む)の水道水供給系統を概略図で示している。
Embodiments of the present invention will be described with reference to the drawings. FIG. 1 is a schematic view showing a tap water supply system of an individual residence and an apartment building (including an office building) to which the micro-bubble liquid generator 1 according to the present invention is applied.
戸別住宅10における微細気泡液生成器1は、水道水の量水器(メーター)11と共に給水管3の途中に挿入されて、量水器(メーター)11の下流に配置されている。給水管3は、水道本管14から戸別住宅10に向けて分岐された水道配管12に止水栓13を介して接続されている。したがって、微細気泡液生成器1は、量水器11を通って流れてきた水道水中において多くの微細気泡を生成し、生成された微細気泡液は、給水管3の下流側から分岐形成された分岐給水管14から戸別住宅10内の各水道栓15から供給される。
The micro-bubble liquid generator 1 in the door-to-door housing 10 is inserted in the middle of the water supply pipe 3 together with the tap water quantity meter (meter) 11, and is disposed downstream of the quantity water quantity meter (meter) 11. The water supply pipe 3 is connected to a water supply pipe 12 branched from the water supply main 14 toward the house 10 via a water stop valve 13. Therefore, the micro-bubble liquid generator 1 generates many micro-bubbles in the tap water flowing through the water heater 11, and the generated micro-bubble liquid is branched from the downstream side of the water supply pipe 3. It is supplied from each water tap 15 in the house 10 from the branch water supply pipe 14.
図示の集合住宅20では、水道水は、上記したのと同じ水道配管12,止水栓13,量水器11の下流に受水槽15を設け、受水槽15の貯留水をポンプ16により高置水槽17に持ち上げられて貯蔵されてから、重量により各戸に供給される。この場合の微細気泡液生成器1は、各住居の給水管3の途中に子量水器11aと共に挿入されて、微細気泡液は各水道栓15から供給される。
In the illustrated apartment complex 20, tap water is provided with a water receiving tank 15 downstream of the same water pipe 12, water stop valve 13 and water heater 11 as described above, and the stored water in the water receiving tank 15 is elevated by the pump 16 After being lifted and stored in the water tank 17, it is supplied to each door by weight. The micro-bubble liquid generator 1 in this case is inserted along with the water discharger 11 a in the middle of the water supply pipe 3 of each residence, and the micro-bubble liquid is supplied from each water tap 15.
尚、集合住宅やオフィスビルにおいては、水道配管12から下流の水道水供給系統には、その建物の規模に応じて種々のタイプがある。例えば、(1)受水槽15を設けずに量水器11の先のポンプ16で高置水槽17へ直接揚水するタイプ、(2)受水槽15のみで各戸に設けるポンプで戸別に揚水するタイプ、(3)戸別住宅と同じく単なる水道直結タイプ、(4)受水槽15とポンプ16と高置水槽17とを備えるタイプがある。(4)のタイプでも、上記の集合住宅20のように高置水槽17から自然落下で供給するタイプと、各戸に設けるポンプで供給するタイプとがある。しかし、何れのタイプであっても、量水器を通った後に微細気泡液生成器1を設置することになる。
In addition, in a housing complex or an office building, there are various types of tap water supply systems downstream from the water pipe 12 according to the scale of the building. For example, (1) a type in which the water pump 15 directly pumps water to the elevated water tank 17 without the water receiving tank 15 and (2) a type in which the water tank 15 alone pumps the water separately in each door (3) There is a simple water supply direct connection type similar to a single-family house, and (4) a type provided with a water receiving tank 15, a pump 16, and an elevated water tank 17. Even in the type of (4), there are types such as the type supplied by free fall from the elevated water tank 17 as in the above-mentioned apartment complex 20 and the type supplied by the pump provided in each door. However, regardless of the type, the micro-bubble liquid generator 1 is installed after passing through the water meter.
図2は、微細気泡液生成器1の構成を、一部が断面の側面図で示している。微細気泡液生成器1は、水道水が矢印で示す方向で流れていく通水管2と、通水管2の中央部に形成されている膨出部4に配置されているノズル5と、ノズル5を膨出部4内に保持する支持部材6とで構成されている。
FIG. 2 shows a configuration of the micro-bubble liquid generator 1 partially in a side view in cross section. The micro bubble liquid generator 1 includes a water flow pipe 2 through which tap water flows in a direction indicated by an arrow, a nozzle 5 disposed in a bulging portion 4 formed in a central portion of the water flow pipe 2, and a nozzle 5 And a supporting member 6 for holding the inside of the bulging portion 4.
通水管2は、管体2Aと管体2Bとを接続して形成され、管体2Aと管体2Bとは、互いに対峙している端部がそれぞれ拡径されている。管体2Bの拡径部の径は、管体2Aの拡径部の径よりも大きく、管体2Aの拡径部が管体2Bの拡径部に挿入されて、それぞれの内周及び外周に形成されたネジを螺合させて接続している。よって、管体2A,2Bが互いの拡径部で接続されたとき、その接続箇所が通水管2の膨出部4を形成する。
The water flow pipe 2 is formed by connecting the pipe 2A and the pipe 2B, and the ends of the pipe 2A and the pipe 2B facing each other are expanded in diameter. The diameter of the enlarged diameter portion of the tube body 2B is larger than the diameter of the expanded diameter portion of the tube body 2A, and the enlarged diameter portion of the tube body 2A is inserted into the enlarged diameter portion of the tube body 2B. The screw formed on is screwed and connected. Thus, when the pipe bodies 2A and 2B are connected at their enlarged diameter portions, the connection portion forms the bulging portion 4 of the water flow pipe 2.
管体2A,2Bの拡径部を備える端部と反対側の端部は、それぞれ配管接続装置18によって給水管3に接続されて、給水管3を通る水道水は矢印方向に流れていく。配管接続装置18としては、例えば、接続すべき管体の端部外周に亘って嵌合されたリング状のガスケットと、このガスケットを抱持するようにして両端部が固着具により連結された一対のハウジングとで構成されるハウジング型管継手が用いられる場合もある。
The ends on the opposite side of the ends provided with the enlarged diameter portions of the pipes 2A and 2B are connected to the water supply pipe 3 by the pipe connection device 18, respectively, and the tap water passing through the water supply pipe 3 flows in the arrow direction. As the pipe connection device 18, for example, a ring-shaped gasket fitted over the outer periphery of the end of the pipe to be connected, and a pair in which both ends are connected by a fastener so as to hold the gasket. There is also a case where a housing type pipe joint configured with the housing of
図3は、ノズル5を側断面図で示し、第1円筒部5aと第2円筒部5bとから成り、第1円筒部5aは有底円筒体で構成されて、底面には第2円筒部5bと連通する孔部が設けられている。第1円筒部5aには、円形の取水プレート7が外周の側部がその内周と螺合して嵌め込まれて、このとき取水プレート7は、その面側の周縁が第1円筒部5aの前記孔部を囲む底面で係止される。第1円筒部5aの取水側の端部には、水道水を取り込みやすいようテーパ39が環状に形成されている。
FIG. 3 shows the nozzle 5 in a side sectional view and comprises a first cylindrical portion 5a and a second cylindrical portion 5b. The first cylindrical portion 5a is formed of a bottomed cylindrical body, and the bottom surface is a second cylindrical portion. A hole communicating with 5b is provided. In the first cylindrical portion 5a, the circular water intake plate 7 is inserted by screwing the side portion of the outer periphery with the inner periphery. At this time, the peripheral edge of the water intake plate 7 is the first cylindrical portion 5a. It is locked at the bottom surrounding the hole. A taper 39 is annularly formed at an end on the intake side of the first cylindrical portion 5a so as to easily take in tap water.
本例では、取水プレート7は、例えば、直径寸法dが13.5mmに対して、厚さ寸法tを5mmとしている。取水プレート7には、平面上に等間隔で軸方向に貫通する例えば4個の丸孔の取水孔8が円状に穿設されている。尚、この取水孔8の数は、複数(例えば、2乃至8程度)とすることができる。そして、この取水プレート7は、図4(a)に示すように、平面上に等間隔で軸方向に貫通する4個の丸孔の取水孔8が円状に穿設されている。取水孔8は、図4(b)の側面図で示すように、水道水の入口側から出口側に向けての中心軸線Lが取水プレート7の中心軸線Hに対して、所定の角度αで、例えば15度で傾斜させた斜円柱の形状で取水プレート7に穿設されている。
In this example, the intake plate 7 has a thickness dimension t of 5 mm, for example, for a diameter dimension d of 13.5 mm. In the water intake plate 7, for example, four circular water intake holes 8 penetrating in the axial direction at equal intervals on a plane are formed in a circle. In addition, the number of the water intake holes 8 can be plural (for example, about 2 to 8). And as this intake plate 7 is shown to Fig.4 (a), the intake holes 8 of the 4 round holes which penetrate in an axial direction at equal intervals on a plane at a circle are drilled. As shown in the side view of FIG. 4 (b), the water intake hole 8 has a central axis L from the tap water inlet side to the outlet side at a predetermined angle α with respect to the central axis H of the water intake plate 7. For example, it is bored in the intake plate 7 in the shape of an inclined cylinder inclined at 15 degrees.
このときの各取水孔8の傾斜方向は、矢印で示すように同図で左回りの方向に向いて形成されている。これにより、水平方向に送られてくる水道水は、各取水孔8を通過することで傾斜した方向に放出されるため、水道水流にひねりが加えられることになる。よって、取水プレート7は、放出する水流と同じ回転方向の左ネジで第1円筒部5aと螺合させることで、ネジの締め付け方向と放出する水流の回転方向とが一致して緩むことがない。尚、図4(b)では、取水孔8の1つだけを代表して示している。
The inclination direction of each water intake hole 8 at this time is formed to be directed in the counterclockwise direction in the drawing as shown by the arrow. As a result, since the tap water sent in the horizontal direction is discharged in the inclined direction by passing through the respective intake holes 8, a twist is added to the tap water flow. Therefore, the intake plate 7 is screwed with the first cylindrical portion 5a with the left screw in the same rotational direction as the discharged water flow, so that the screw tightening direction and the released water rotation direction do not coincide with each other. . In FIG. 4B, only one of the water intake holes 8 is shown as a representative.
ノズル5の第2円筒部5bには、第1円筒部5aから中心部にいくにしたがい内径が徐々に狭まる第1通水路21と、第1通水路21に接続する絞り部22と、絞り部22に接続し出口側に向け内径が徐々に広がる第2通水路23とが形成されている。
In the second cylindrical portion 5b of the nozzle 5, a first water passage 21 whose inner diameter gradually narrows from the first cylindrical portion 5a toward the central portion, a throttling portion 22 connected to the first water passage 21, and a throttling portion A second water passage 23 is formed which is connected to the outlet 22 and whose internal diameter gradually increases toward the outlet side.
本例においては、ノズル5の第1通水路21の入口側の口径は、第2通水路23の出口側の口径より大きく設定されており、第1通水路21と第2通水路23との軸方向の寸法は第2通水路8bより長く設定されている。尚、この第1通水路21の入り口の口径と長さは、水圧や微細気泡の発生量をコントロールするため、状況に応じて種々のサイズが考えられる。
In this example, the bore diameter at the inlet side of the first water flow path 21 of the nozzle 5 is set larger than the bore diameter at the outlet side of the second water flow path 23, and between the first water flow path 21 and the second water flow path 23. The axial dimension is set longer than the second water passage 8b. The diameter and length of the inlet of the first water flow passage 21 can be varied in size depending on the situation in order to control the water pressure and the amount of fine air bubbles generated.
そして、絞り部22は、第1及び第2通水路21,23の径の小さい側の端部どうしを連通するよう設けられている。
The throttling portion 22 is provided to connect the ends on the small diameter side of the first and second water passages 21 and 23 with each other.
支持部材6は、図5で示すように、内径寸法がノズル5の第2円筒部5bの外周の径と等しい内環部6aと、外径寸法が管体2Bの拡径部の内径と等しい外環部6bと、内環部6aと外環部6bとを中心角が均等となるよう放射状に接続する3本の輻部6cとから構成されている。この輻部6cどうしの間が通水管2を流れる水道水の通水部11となる。
As shown in FIG. 5, the supporting member 6 has an inner ring portion 6a whose inner diameter is equal to the diameter of the outer periphery of the second cylindrical portion 5b of the nozzle 5 and an outer diameter equal to the inner diameter of the enlarged diameter portion of the tube 2B. It is comprised from the outer ring part 6b and the three radial parts 6c which connect the inner ring part 6a and the outer ring part 6b radially so that a central angle may become equal. The space between the radial portions 6 c is the water flow portion 11 of the tap water flowing through the water flow pipe 2.
そして、支持部材6の外環部6bの外周には、管体2Bの拡径部の内周に形成されたメネジ2aと螺合するオネジ61が形成されて、内環部6aの内周には、ノズル5の第2円筒部5bの外周に設けられているオネジ51と螺合するメネジ62が形成されている。よって、支持部材6は、内環部6aに挿入されるノズル5と螺合して固定すると共に、外環部6bを管体2A内にネジ止めすることで、ノズル5を膨出部4内に保持する。
Then, on the outer periphery of the outer ring portion 6b of the support member 6, an external thread 61 is formed to be screwed with the female screw 2a formed on the inner periphery of the enlarged diameter portion of the tube 2B. A female screw 62 is formed to be screwed with the male screw 51 provided on the outer periphery of the second cylindrical portion 5 b of the nozzle 5. Therefore, the support member 6 is screwed and fixed to the nozzle 5 inserted into the inner ring portion 6a, and the outer ring portion 6b is screwed into the tubular body 2A, so that the nozzle 5 is expanded in the bulging portion 4 Hold on.
管体2Bには、支持部材6を保持するための押え部材29が、その内周に沿って連続又は間欠して固定で取り付けられている。押え部材29は、水道水圧を受けて、支持部材6が図では左方向となる下流側へ移動したとき、クッションの作用を果たすことでウオーターハンマーを防止している。このような押え部材29は、バネ材又は可撓性を有する部材等による弾性部材で構成される。
A pressing member 29 for holding the support member 6 is fixedly attached to the tubular body 2B continuously or intermittently along the inner periphery thereof. The pressing member 29 receives the tap water pressure and prevents the water hammer by fulfilling the function of the cushion when the supporting member 6 is moved to the downstream side, which is the left direction in the drawing. Such a pressing member 29 is formed of an elastic member such as a spring member or a member having flexibility.
そして、円板9の外周には、管体2Aの拡径部の内周に設けられたメネジ2aと螺合するオネジ9bが形成されて、中心孔9aの内周には、ノズル5の第2円筒部5bの外周に設けられているオネジ5cと螺合するメネジ9cが形成されている。よって、この例での支持部材6は、中心孔9aに挿入されるノズル5を螺合して固定すると共に、円板9をその外周で管体2A内にネジ止めすることによりノズル5を膨出部4内に保持する。
Then, on the outer periphery of the disc 9, an external thread 9b is formed to be screwed with the internal thread 2a provided on the inner periphery of the enlarged diameter portion of the tube 2A. A female screw 9c is formed to be screwed with the male screw 5c provided on the outer periphery of the two cylindrical portion 5b. Therefore, the support member 6 in this example is fixed by screwing the nozzle 5 inserted into the center hole 9a and screwing the disc 9 into the tube 2A at its outer periphery to expand the nozzle 5 Hold in the outlet 4.
図6は、管体2A,2Bの接続についての他の実施例を側面図で示し、この実施例では、管継手19を用いて管体2A,2Bを接続している。ここでは管体2A,2Bの各拡径部の径は等しく、それと共に支持部材6の外径もこの管体2A,2Bの各拡径部の径と等しくしている。そして、管体2A,2Bと支持部材6のそれぞれの外周にはオネジが設けられており、管体2A,2Bで支持部材6を挟持して接合したとき、これらオネジは連続して管継手19の内周に設けられたメネジと螺合するネジ部を形成する。これにより、管体2A,2Bの互いの拡径部の端部で支持部材6を挟み込んだ状態を管継手19によって固定される。この場合、図2で示す支持部材6であれば、外環部6bの両側面を管体2A,2Bで挟み込んで管継手19により固定し、また、図3に示す支持部材6であれば、円板9の両側の周縁を管体2A,2Bで挟み込んで管継手19により固定する。
FIG. 6 shows a further embodiment of the connection of the tubes 2A, 2B in a side view, in which the tubes 19 are used to connect the tubes 2A, 2B. Here, the diameter of each enlarged diameter portion of the tubes 2A and 2B is equal, and at the same time, the outer diameter of the support member 6 is also equal to the diameter of each enlarged diameter portion of the tubes 2A and 2B. Then, male screws are provided on the outer peripheries of the tubular members 2A and 2B and the supporting member 6, and when the tubular members 2A and 2B sandwich and support the supporting member 6, these male screws are connected continuously. Form a threaded part to be screwed with a female screw provided on the inner circumference of the. As a result, the pipe joint 19 fixes the state in which the support member 6 is sandwiched by the ends of the enlarged diameter portions of the pipe bodies 2A and 2B. In this case, in the case of the supporting member 6 shown in FIG. 2, both side surfaces of the outer ring portion 6b are sandwiched by the pipes 2A and 2B and fixed by the pipe joint 19. In the case of the supporting member 6 shown in FIG. The peripheries on both sides of the disc 9 are sandwiched by the pipes 2A and 2B and fixed by the pipe joint 19.
上記構成において、給水管3から水道水が通水管2の膨出部4へ到達すると、水道水は、ノズル5を通過する流路と、支持部材6bの通水部11を通過する流路とに分岐される。そして、ノズル5を通過する水道水からは微細気泡液が生成され、生成された微細気泡液は通水部11を通過する水道水と混合されて、下流の通水管2へと送られる。よって、通水管2内に膨出部4を設けて水道水の流れを分岐させたことで、水量を減少させることなく、微細気泡液を含む水道水を下流へ送ることができる。
In the above configuration, when the tap water reaches the bulging portion 4 of the water flow pipe 2 from the water supply pipe 3, the tap water passes through the nozzle 5 and the flow path passing through the water flow portion 11 of the support member 6b Bifurcated. Then, a fine bubble liquid is generated from the tap water passing through the nozzle 5, and the generated fine bubble liquid is mixed with the tap water passing through the water passage 11 and sent to the downstream water flow pipe 2. Therefore, by providing the bulging part 4 in the water flow pipe 2 and branching the flow of the tap water, it is possible to send the tap water containing the fine bubble liquid downstream without reducing the amount of water.
この場合、ノズル4の流路は絞られているために、膨出部4を流れる水道水は高圧となって流速が上昇することから、通水管2を流れる水道水の多くは通水部11を通過することになる。しかし、通水部11を通過する水量が多いと、ノズル5で生成された微細気泡液と下流で混合されたとき微細気泡の十分な濃度を維持できなくなる。よって、膨出部4において通水部11を通過する水量は、全体の80%前後として残りがノズル5へ流れるよう構成するのが好ましい。さらに、給水管3から通水管2の膨出部4への通水率は少なくとも80%以上を確保するのがよい。
In this case, since the flow path of the nozzle 4 is narrowed, the tap water flowing in the bulging portion 4 is in high pressure and the flow velocity rises, so most of the tap water flowing in the water flow pipe 2 is the water flowing portion 11 Will pass. However, when the amount of water passing through the water passage 11 is large, it is not possible to maintain a sufficient concentration of the fine bubbles when mixed with the fine bubble liquid generated by the nozzle 5 downstream. Therefore, it is preferable that the amount of water passing through the water flow portion 11 in the bulging portion 4 is about 80% of the whole so that the rest flows to the nozzle 5. Furthermore, the water flow rate from the water supply pipe 3 to the bulging portion 4 of the water flow pipe 2 is preferably at least 80% or more.
ここで、ノズル5での微細気泡液生成作用について説明する。取水プレート7の各取水孔8を通過する水道水は、斜円柱の形状の取水孔8を通過することで、取水プレート7の中心軸線Hの方向からは外れて斜めの取水孔8の中心軸線Lの方向へ放出されていく。したがって、図4で述べたように、各取水孔8を通過する水道水は、矢印で示すように同一方向にひねられた旋回流となって、ノズル5の第1通水路21へと導入される。
Here, the micro bubble liquid production | generation effect | action in the nozzle 5 is demonstrated. The tap water passing through each intake hole 8 of the intake plate 7 passes through the intake hole 8 in the shape of a diagonal cylinder, and deviates from the direction of the central axis H of the intake plate 7 and the central axis of the oblique intake hole 8 It is released in the direction of L. Therefore, as described in FIG. 4, the tap water passing through each intake hole 8 is introduced into the first water passage 21 of the nozzle 5 as a swirl flow twisted in the same direction as indicated by the arrows. Ru.
これにより、取水孔8を通過した水道水は、第1通水路21の内壁に斜めから突き当たるため、図7で模式的に示すように螺旋状に旋回しながら絞り部22へ進む。そして、第1通水路21は、流れる方向に沿って内径を狭めた形状であるため、絞り部22に向けて近づくほど旋回の速度を上げながら絞り部22へ流れ、絞り部22を通過すると、第2通水路23へ高圧で噴出されて、第2通水路23内で拡散される。
As a result, the tap water having passed through the water intake hole 8 obliquely strikes the inner wall of the first water flow passage 21, and thus advances to the throttling portion 22 while being spirally swirled as schematically shown in FIG. Then, since the first water passage 21 has a shape in which the inner diameter is narrowed along the flowing direction, when it flows to the throttling portion 22 while increasing the swirling speed toward the throttling portion 22 and passes through the throttling portion 22, It is jetted at high pressure to the second water passage 23 and diffused in the second water passage 23.
よって、水道水には急激な圧力低下が生じて、沸騰現象により無数の微細なキャビテーション気泡が第2通水路23内に発生し管体2Bへと放出される。このとき、ノズル5の第1通水路21の入口側の口径が第2通水路23の出口側の口径より大きくなる。
Therefore, a rapid pressure drop occurs in the tap water, and innumerable fine cavitation bubbles are generated in the second water passage 23 by the boiling phenomenon and released to the pipe body 2B. At this time, the diameter of the inlet side of the first water flow passage 21 of the nozzle 5 is larger than the diameter of the outlet side of the second water flow passage 23.
そして、管体2Bでは、ノズル5を通過する水道水から生成された微細気泡液と、ノズル5を通過せずに支持部材6の通水部11を通過して水道水とが混合された後、管体2Bへ放出される。このとき、水道水は、管体2Bの拡径部を通過すると再び管口径が細くなるために、速度を速めて管体2Bから下流の水道配管へ流れる。
Then, in the tubular body 2B, the micro-bubble liquid generated from the tap water passing through the nozzle 5 and the tap water mixed with the water passing portion 11 of the support member 6 without passing through the nozzle 5 , Is released to the tube 2B. At this time, when the tap water passes through the enlarged diameter portion of the pipe body 2B, the diameter of the pipe becomes narrow again, so that the speed is increased to flow from the pipe body 2B to the water pipe downstream.
このように、キャビテーション気泡を発生させるのに、水道水の流路を絞ると絞り部での圧力損失が大きくなって、単位時間あたりで十分な量の水道水を下流へ供給できなくなる虞がある。そのため、本発明に係る微細気泡液生成器1においては、通水管2に膨出部4を設けて、膨出部4にノズル5を配置することで、水道水の流れる速度を膨出部4で高めて通過する圧力を増大させて、通水部11を通過する流路とノズル5を通過する流路とに分岐させている。そして、分岐後は、管体2Bにおいて、ノズル5で生成された微細気泡液と、通水部11を通過した水道水とを合流させることで、単位時間あたりで十分な量の水道水を下流へ供給できるようにしている。
As described above, if the flow path of the tap water is narrowed to generate the cavitation bubbles, the pressure loss in the narrowed portion becomes large, and there is a possibility that a sufficient amount of tap water can not be supplied downstream per unit time. . Therefore, in the micro-bubble liquid generator 1 according to the present invention, the bulging portion 4 is provided in the water flow pipe 2 and the nozzle 5 is disposed in the bulging portion 4 so that the flow rate of the tap water is bulging portion 4 The pressure is increased to increase the passing pressure, and the pressure is branched into a flow passage passing through the water passage 11 and a flow passage passing through the nozzle 5. Then, after branching, in the tubular body 2B, by combining the fine bubble liquid generated by the nozzle 5 and the tap water having passed through the water flow portion 11, a sufficient amount of tap water is downstream per unit time. It is possible to supply to
一方で、膨出部4を設けることで水道水の流れる速度を加速させることになる。一般的に、水道水は、1.5kgf/cm2(0.15MPa)を下限水圧とし、理想的には2.0乃至4.0kgf/cm2(0.2乃至0.39MPa)で供給されるが、膨出部4の形状次第でこの下限水圧を下回ると、ノズル5内でのキャビテーションが有効に行われないことがある。
On the other hand, the provision of the bulging portion 4 accelerates the flow rate of the tap water. In general, tap water is supplied at a minimum water pressure of 1.5 kgf / cm 2 (0.15 MPa), ideally 2.0 to 4.0 kgf / cm 2 (0.2 to 0.39 MPa). However, cavitation in the nozzle 5 may not be effectively performed if the pressure is lower than the lower limit depending on the shape of the bulging portion 4.
そのため、本発明に係る微細気泡液生成器1でのノズル5は、取水孔8が設けられている取水プレート7を入口側に配置して、取水孔8を通して水道水を取り込むことで水道水の流速を高めている。しかも、取水孔8の形状を斜円柱にして、取水孔8を通過する水道水に回転を加え旋回流とすることで、さらに流速を上げている。これにより、膨出部4の外径が大きくても、取水口8にガイドを設けることによりノズル5に取り込む際には流速が再び速まるために効果的にキャビテーションが行われる。
Therefore, the nozzle 5 in the micro-bubble liquid generator 1 according to the present invention arranges the intake plate 7 provided with the intake hole 8 at the inlet side, and takes in tap water through the intake hole 8 to obtain tap water. I am increasing the flow rate. Moreover, the shape of the water intake hole 8 is an oblique cylinder, and the flow velocity is further raised by rotating the tap water passing through the water intake hole 8 to create a swirl flow. As a result, even if the outer diameter of the bulging portion 4 is large, cavitation is effectively performed because the flow velocity is increased again when taking in the nozzle 5 by providing the guide at the water intake port 8.
取水孔8を図8(a)に示すように孔の内壁表面を凹凸面8aとすることで、水道水は乱流度を上げながら取水孔8から放出される。本例では多数の突起を設けて凹凸面8aを形成している。このように乱流度を向上させると水道水中の溶存空気が取り出しやすくなり、ノズル5内でキャビテーション気泡が効果的に発生させることができる。
By making the inner wall surface of the hole into a concavo-convex surface 8a as shown in FIG. 8A, the tap water is discharged from the water intake hole 8 while increasing the degree of turbulent flow. In this example, a large number of protrusions are provided to form the uneven surface 8a. When the degree of turbulent flow is improved in this manner, dissolved air in tap water can be easily taken out, and cavitation bubbles can be effectively generated in the nozzle 5.
さらに、取水孔8の形状を図8(b)に示すように、入口側から出口側に向けての斜円柱に屈曲部を設けて捻じれを加えた形状とするとよい。これにより、取水孔8の中を通過した時点で水道水の流れには捻りが加わり、第1通水路8aではより回転率の高い旋回流を発生させることができる。この場合も、取水孔8の内壁を凹凸面8aとすれば乱流度の向上と相俟って、ノズル5内でのキャビテーション気泡の発生効果がいっそう高まる。
Furthermore, as shown in FIG. 8 (b), the shape of the water intake hole 8 may be a shape in which a bent portion is provided in an oblique cylinder from the inlet side to the outlet side to add a twist. Thereby, when passing through the water intake hole 8, twist is added to the flow of the tap water, and it is possible to generate a swirling flow having a higher rotation rate in the first water passage 8a. Also in this case, if the inner wall of the water intake hole 8 is made to be the uneven surface 8a, the generation effect of cavitation bubbles in the nozzle 5 is further enhanced in combination with the improvement of the turbulent flow degree.
また、ノズル5の第2通水路23の内壁の表面も凹凸加工すれば、負圧が発生する際に、拡散した微細気泡がさらにこの内壁面と当たると、気泡の微細化が促進されて、微細気泡を高濃度に含む水道水を生成できる。
In addition, if the surface of the inner wall of the second water flow passage 23 of the nozzle 5 is also processed to be uneven, when a negative pressure is generated, if the diffused fine bubbles further hit the inner wall surface, the bubbles are promoted to be finer. It is possible to generate tap water containing a high concentration of fine bubbles.
また、地域又は場所による水道事情、或いは高架水槽を使用する集合住宅等では適切な供給圧が得られない場合には、取水孔7の開口面積を設置時に調整できるようにするとよい。図9は、開口調節機構24を用いて、取水孔7の開口面積を調整可能にした取水プレート7を備えるノズル5を斜視図で示している。開口調節機構24は、虹彩絞り機構を備えて、取水孔7の開口面積を変化させることができるように構成されたオリフィスである。虹彩絞り機構は、カメラレンズの絞り等で一般に知られているもので、図10の(a)から(d)までに示すように、例えば中央の開口25(取水孔7)が略円形となるように重ね合わされた複数の絞り片30をギア(図示せず)の駆動で回動させることにより、取水孔7の面積を4通りに変化させる。この場合、各開口調節機構24のギアは、ノズル5の第1円筒部5aの外周に設けた孔径調節ダイアル37を回転することにより同時に駆動されて、各取水孔8の開口面積は一斉に同じ大きさに調整可能なよう構成している。
In addition, it is preferable that the opening area of the water intake hole 7 can be adjusted at the time of installation when an appropriate supply pressure can not be obtained in a water supply situation depending on the area or place, or a collective housing using an elevated water tank. FIG. 9 is a perspective view showing the nozzle 5 provided with the water intake plate 7 in which the opening area of the water intake hole 7 can be adjusted using the opening adjustment mechanism 24. The opening adjustment mechanism 24 is an orifice configured to include an iris diaphragm mechanism so as to change the opening area of the water intake hole 7. The iris diaphragm mechanism is generally known as a diaphragm of a camera lens or the like, and as shown in (a) to (d) of FIG. 10, for example, the central opening 25 (water intake hole 7) becomes substantially circular. The area of the water intake hole 7 is changed in four ways by rotating the plurality of throttle pieces 30 superimposed in this manner by driving a gear (not shown). In this case, the gears of the opening adjusting mechanisms 24 are simultaneously driven by rotating the hole diameter adjusting dial 37 provided on the outer periphery of the first cylindrical portion 5a of the nozzle 5, and the opening areas of the water intake holes 8 are all the same. It is configured to be adjustable in size.
このような開口調節機構24を設けることで、水道水の送給圧が低い場合には、取水孔8の開口面積を小さくすることで送給圧を高めてノズル5へ導入することができ、ノズル5への水道水の送給圧を一定に調節することができる。
By providing such an opening adjustment mechanism 24, when the feed pressure of tap water is low, the feed pressure can be increased and introduced to the nozzle 5 by reducing the opening area of the water intake hole 8, The feed pressure of the tap water to the nozzle 5 can be adjusted to be constant.
上記実施形態の微細気泡液生成器1は1個のノズル5で構成しているが、膨出部4を設けることで口径の小さいノズルを複数配置してもよい。
Although the micro-bubble liquid generator 1 of the said embodiment is comprised by one nozzle 5, by providing the bulging part 4, you may arrange multiple nozzles with a small aperture.
図11は、3個のノズル31を備える実施形態の微細気泡液生成器1Aを一部側面図で示す。同図において、上述の図2(第1実施形態)にそれぞれ示した構成要素と同様の構成要素については、同一の符号が付されている。すなわち、通水管2は、対峙する端部にそれぞれ拡径部を有する第1管体2Aと第2管体2Bとを接続して成り、それぞれの拡径部どうしの接合により膨出部4が形成される。また、ノズル31は、上記したノズル5と同様な構造を有するが、複数使用することから径を小さくしている。
FIG. 11 is a partial side view showing a micro bubble liquid generator 1A according to an embodiment provided with three nozzles 31. As shown in FIG. In the figure, components similar to the components shown in FIG. 2 (first embodiment) described above are denoted by the same reference numerals. That is, the water flow pipe 2 is formed by connecting the first pipe body 2A and the second pipe body 2B each having an enlarged diameter portion at opposite ends, and the bulging portion 4 is formed by joining the respective enlarged diameter portions. It is formed. Moreover, although the nozzle 31 has a structure similar to the above-described nozzle 5, the diameter is made smaller because a plurality of nozzles 31 are used.
そして、図2で説明した構成と同様に、第1管体2Aを第2管体2Bに挿入して螺合させて互いの拡径部の接合による膨出部4を形成しているが、この場合、第2管体2Bには受部38が形成されており、支持部材32はこの受部38と第1管体2Aの拡径部の端面とで挟持されて、膨出部4内に保持される。さらに、受部38には、支持部材6が水道水圧を受けて下流側へ移動したとき、クッションの作用を果たすことで、ウオーターハンマーを防止するための弾性部材である前述の押え部材29が装着されている。
And although the 1st tube 2A is inserted into the 2nd tube 2B and screwed together similarly to the composition explained in Drawing 2, the bulging part 4 by joining of a diameter-increased part of each other is formed, In this case, the receiving portion 38 is formed in the second tubular body 2B, and the supporting member 32 is sandwiched between the receiving portion 38 and the end face of the enlarged diameter portion of the first tubular body 2A. Will be held by Furthermore, when the support member 6 receives tap water pressure and moves to the downstream side, the above-mentioned pressing member 29 which is an elastic member for preventing the water hammer is attached to the receiving portion 38 by performing the function of a cushion. It is done.
この実施形態での支持部材32は、図12で示すように、膨出部4にその周縁部で螺合により固定される外環部33と、外環部33の内側に等間隔で円状に並べて配置されると共に外環部33の内周壁と連結部34で連結されて、それぞれがノズル31を内周で螺合により保持する3通りのノズル支持部35とを備える。各ノズル支持部35は一体で構成されて、外環部33の中心からそれぞれが放射状に延出する形状となっており、外環部33とノズル支持部35との間の隙間が、膨出部4内でノズル31を通過しない水道水が流れる通水部36となる。また、支持部材32の中心と重なる支持部材32の中心部は刳り抜かれて、通水部36の一部を構成する中心孔36aが形成される。これにより、膨出部4での上記の通水率80%以上を確保している。
The support member 32 in this embodiment is, as shown in FIG. 12, an outer ring portion 33 fixed to the bulging portion 4 by screwing at its peripheral portion, and a circular shape at equal intervals inside the outer ring portion 33. , And are connected by the inner peripheral wall of the outer ring portion 33 and the connection portion 34, and each of the nozzle support portions 35 is provided with three types of nozzle support portions 35 for holding the nozzles 31 by screwing. Each nozzle support portion 35 is integrally formed, and each has a shape extending radially from the center of the outer ring portion 33, and the gap between the outer ring portion 33 and the nozzle support portion 35 is bulged. It becomes the water flow part 36 in which the tap water which does not pass the nozzle 31 in the part 4 flows. Further, the central portion of the support member 32 overlapping the center of the support member 32 is rolled out to form a central hole 36 a that constitutes a part of the water flow portion 36. Thereby, 80% or more of said water flow rate in the bulging part 4 is ensured.
口径の大きい通水管2の場合には、図13に示すように、支持部材32Aは4通りのノズル支持部35を備えて4個のノズル31を保持するようにしてもよい。また、中心孔36Aを基準に2通りのノズル支持部35を対称に配置して、2個のノズル31を備える構成であってもよい。
In the case of the water flow pipe 2 having a large diameter, as shown in FIG. 13, the support member 32A may be provided with four nozzle support portions 35 to hold four nozzles 31. Alternatively, two nozzles 31 may be provided by arranging two nozzle supports 35 symmetrically with respect to the center hole 36A.
このように、複数のノズル31を支持可能な支持部材32,32Aを備える微細気泡液生成器は、ノズル31からの微細気泡液の噴出力、微細気泡量及び通水部36を通過する水道水の量等の各条件に応じて、微細気泡液生成器1から最適な水道水量と微細気泡液濃度が確保できるように、ノズル31の数を調整することができる。尚、ノズル31の数ではなく、ノズル31の形状を拡大又は縮小することで調整しても良い。
As described above, the micro-bubble liquid generator provided with the support members 32 and 32A capable of supporting the plurality of nozzles 31 has the injection output of the micro-bubble liquid from the nozzles 31, the micro-bubble amount, and the tap water passing through the water passage 36 The number of nozzles 31 can be adjusted so that the optimal amount of tap water and the concentration of the micro bubble liquid can be secured from the micro bubble liquid generator 1 according to the respective conditions such as the amount of. The adjustment may be performed by enlarging or reducing the shape of the nozzles 31 instead of the number of the nozzles 31.
本発明は上記実施形態に限定されるものではなく、本発明の趣旨に基づき種々の変形が可能である。例えば、取水孔8は、設置される水道水の配管等の流量に応じて、多数の取水孔8を設ける必要があるときには、円状に等間隔で配置するよりも、取水プレート7の平面に一様に配置するのが好ましい。
The present invention is not limited to the above embodiment, and various modifications are possible based on the spirit of the present invention. For example, when it is necessary to provide a large number of water intake holes 8 depending on the flow rate of the tap water piping etc. to be installed, the water intake holes 8 should be in the plane of the water intake plate 7 rather than circularly arranged at equal intervals. It is preferable to arrange uniformly.
そして、ノズル5においても、上記実施形態は、第1通水路21の入口側の口径を第2通水路23の出口側の口径より大きくして、中心軸方向での距離は第2通水路23の方を長く構成しているが、逆でもよく、或いは同一口径として絞り部22を中心に対称となる形状で構成してもよい。要は、第1通水路21から噴出される水道水の圧力と、第2通水路23内での拡散による低下する圧力との関係で、適切な量と微細気泡としての高品質のキャビテーション気泡が生成できるように設定するものである。
And also in the nozzle 5, the diameter of the entrance side of the 1st water flow passage 21 is made larger than the diameter of the exit side of the 2nd water flow passage 23, and the above-mentioned embodiment makes the distance in the central axis direction the 2nd water flow passage 23 Is longer, but may be reversed, or may be configured to be symmetrical with the same aperture centered on the narrowed portion 22. The point is that the relationship between the pressure of the tap water spouted from the first water passage 21 and the pressure that decreases due to the diffusion in the second water passage 23 makes it possible to obtain an appropriate amount and high quality cavitation bubbles as fine bubbles. It is set so that it can be generated.
そして、さらに効率良く微細気泡を生成するには、ノズル5をある程度の間隔を空けて直列に配置してもよい。
Then, in order to generate the fine bubbles more efficiently, the nozzles 5 may be arranged in series at a certain interval.
以上詳しく説明したように、本微細気泡液生成器は、通水管の一部が拡径された膨出部でノズルを保持すると共に通水部を形成する支持部材を配置した構成により、ノズルで生成される微細気泡液は通水部を通過した水と再度合流するために、下流へは単位時間あたりで十分な水量を供給することが可能であり、微細気泡液生成器を経由した供給水の水圧低減と単位時間当たりの供給水量の低下を有効に防止することを可能とした。
As described above in detail, in the fine bubble liquid generator, the bulging portion in which a part of the water flow pipe is expanded holds the nozzle and the support member for forming the water flow portion is disposed, so that In order to recombine the fine bubble liquid to be generated with the water passing through the water flow section, it is possible to supply a sufficient amount of water per unit time downstream, and the feed water via the fine bubble liquid generator It is possible to effectively prevent the reduction of water pressure and the decrease of water supply volume per unit time.
1 微細気泡液生成器
1A 微細気泡液生成器
2 通水管
2A 第1管体
2B 第2管体
4 膨出部
5 ノズル
6 支持部材
6a 内環部
6b 外環部
6c 輻部
7 取水プレート
8 取水孔
12 水道配管
21 第1通水路
22 絞り部
23 第2通水路
24 開口調節機構
29 押え部材
32 支持部材
33 外環部
35 ノズル支持部 DESCRIPTION OFSYMBOLS 1 micro bubble liquid generator 1A micro bubble liquid generator 2 water flow pipe 2A 1st pipe body 2B 2nd pipe body 4 bulging part 5 nozzle 6 support member 6a inner ring part 6b outer ring part 6c ring part 7c intake part 7 water intake plate 8 water intake Hole 12 Water pipe 21 first water passage 22 throttling portion 23 second water passage 24 opening adjustment mechanism 29 pressing member 32 support member 33 outer ring portion 35 nozzle support portion
1A 微細気泡液生成器
2 通水管
2A 第1管体
2B 第2管体
4 膨出部
5 ノズル
6 支持部材
6a 内環部
6b 外環部
6c 輻部
7 取水プレート
8 取水孔
12 水道配管
21 第1通水路
22 絞り部
23 第2通水路
24 開口調節機構
29 押え部材
32 支持部材
33 外環部
35 ノズル支持部 DESCRIPTION OF
Claims (15)
- 水道配管に配設される微細気泡液生成器であって、
両端で前記水道配管に接続されて一部に拡径された膨出部を有する通水管と、
前記膨出部に配置されるノズルと、
前記膨出部内において前記ノズルを水道水が流れる方向に沿って保持する支持部材と、
前記ノズルを通過しない水道水の流路を前記膨出部内に形成するよう前記支持部材に設けられる通水部と、
を備えて、
前記ノズルは、
水道水の流れる方向に沿って径が漸次縮小する第1通水路と、
前記第1通水路の出口側に連通して設けられ水道水の流れる方向に沿って径が漸次増大する第2通水路と、
前記第1通水路と前記第2通水路とを繋ぐ絞り部と、
前記第1通水路の入口部に設けられる複数の取水孔が設けられる取水プレートと、
を有して、
前記取水孔は、その入口側から出口側に向けての中心軸が前記取水プレートの中心軸に対し傾斜させていることを特徴とする微細気泡液生成器。 A micro bubble liquid generator disposed in a water pipe,
A water pipe having a bulging portion which is connected to the water pipe at both ends and is partially expanded in diameter;
A nozzle disposed at the bulging portion;
A support member for holding the nozzle in a direction in which tap water flows in the bulging portion;
A water passage portion provided on the support member to form a flow path of tap water not passing through the nozzle in the bulging portion;
Equipped with
The nozzle is
The first water passage whose diameter gradually decreases along the flow direction of the tap water,
A second water passage which is provided in communication with the outlet side of the first water passage and whose diameter gradually increases along the flowing direction of the tap water;
A throttling portion connecting the first water passage and the second water passage;
An intake plate provided with a plurality of intake holes provided at an inlet portion of the first water passage;
Have
The micro bubble liquid generator according to claim 1, wherein a central axis of the intake hole from an inlet side to an outlet side is inclined with respect to a central axis of the intake plate. - 前記通水管は、対峙する端部にそれぞれ拡径部を有する第1管体と第2管体とを接続して成り、前記膨出部は、前記第1及び第2管体の前記拡径部どうしの接合により形成される請求項1に記載の微細気泡液生成器。 The water pipe is formed by connecting a first pipe body and a second pipe body each having an enlarged diameter portion at opposite ends, and the bulging portion is the diameter expanded diameter of the first and second pipe bodies. The micro-bubble liquid generator according to claim 1, which is formed by bonding parts to each other.
- 前記第1管体の前記拡径部の内径は、前記第2管体の前記拡径部の外径より大きく、前記第1管体の前記拡径部内に前記支持部材と前記第2管体の前記拡径部を挿入して接合される請求項2に記載の微細気泡液生成器。 The inner diameter of the enlarged diameter portion of the first tube body is larger than the outer diameter of the enlarged diameter portion of the second tube body, and the support member and the second tube body are in the enlarged diameter portion of the first tube body The micro bubble liquid generator according to claim 2, which is joined by inserting the enlarged diameter portion of
- 前記第1管体と前記第2管体とは、それぞれの前記拡径部の端面どうしで前記支持部材を挟持している状態で管継手によって接合される請求項2に記載の微細気泡液生成器。 The micro bubble liquid production according to claim 2, wherein the first pipe body and the second pipe body are joined by a pipe joint in a state in which the support member is held between the end faces of the respective enlarged diameter portions. vessel.
- 前記支持部材は、
前記ノズルをその内周で保持する内環部と、
前記膨出部に固定される外環部と、
前記内環部と前記外環部とを繋ぐ複数の輻部と、
を備える請求項1に記載の微細気泡液生成器。 The support member is
An inner ring portion which holds the nozzle at its inner periphery;
An outer ring portion fixed to the bulging portion;
A plurality of spokes connecting the inner ring portion and the outer ring portion;
The micro-bubble liquid generator according to claim 1, comprising: - 前記通水管は、対峙する端部にそれぞれ拡径部を有する第1管体と第2管体とを接続して成り、
前記第1管体又は前記第2管体の前記拡径部の内径は、前記第2管体又は前記第1管体の前記拡径部の外径より大きく、前記第1管体又は前記第2管体の前記拡径部内に前記第2管体又は前記第1管体の前記拡径部を挿入して接合されて、
前記支持部材は、前記外環部の外周が前記第2管体又は前記第1管体の外周と共に前記第1管体又は前記第2管体の内周に固定されることを特徴とする請求項5に記載の微細気泡液生成器。 The water pipe is formed by connecting a first pipe and a second pipe each having an enlarged diameter portion at opposite ends thereof,
The inner diameter of the enlarged diameter portion of the first tube or the second tube is larger than the outer diameter of the enlarged diameter portion of the second tube or the first tube, and the first tube or the first tube The enlarged diameter portion of the second tube or the first tube is inserted into and joined to the enlarged diameter portion of the two-tubes,
The outer periphery of the outer ring portion is fixed to the inner periphery of the first pipe or the second pipe together with the outer periphery of the second pipe or the first pipe, in the support member. 6. A fine bubble liquid generator according to item 5. - 前記第1管体又は前記第2管体は、前記第2管体又は前記第1管体とで前記外環部を挟持する押え部材を備える請求項6に記載の微細気泡液生成器。 The micro bubble liquid generator according to claim 6, wherein the first pipe or the second pipe includes a pressing member configured to hold the outer ring portion with the second pipe or the first pipe.
- 前記通水管は、対峙する端部にそれぞれ拡径部を有する第1管体と第2管体とを接続して成り、
前記第1管体と前記第2管体とは、それぞれの前記拡径部の端面どうしで前記外環部の両側の面の周縁部を挟持している状態で管継手によって接合される請求項5に記載の微細気泡液生成器。 The water pipe is formed by connecting a first pipe and a second pipe each having an enlarged diameter portion at opposite ends thereof,
The first pipe body and the second pipe body are joined by a pipe joint in a state in which the peripheral edge portions of the surfaces on both sides of the outer ring portion are held between the end faces of the respective enlarged diameter portions. 5. The micro bubble liquid generator according to 5. - 前記支持部材は、
前記膨出部に固定される外環部と、
前記外環部の内側に等間隔で円状に並べて配置されると共に前記外環部の内周壁とに連結されて、それぞれが前記ノズルを内周で保持する複数のノズル支持部と、
を備える請求項1に記載の微細気泡液生成器。 The support member is
An outer ring portion fixed to the bulging portion;
A plurality of nozzle support parts which are arranged in a circle at equal intervals inside the outer ring part and connected to the inner peripheral wall of the outer ring part, each holding the nozzle on the inner circumference;
The micro-bubble liquid generator according to claim 1, comprising: - 前記取水孔は、円状に等間隔で複数設けられた請求項1に記載の微細気泡液生成器。 The micro air bubble liquid generator according to claim 1, wherein a plurality of the water intake holes are provided circularly at equal intervals.
- 前記取水孔の内面には乱流を発生するための凹凸面を形成した請求項1に記載の微細気泡液生成器。 The micro bubble liquid generator according to claim 1, wherein an uneven surface for generating turbulent flow is formed on an inner surface of the water intake hole.
- 前記第2通水路の内面には乱流を発生するための凹凸面を形成した請求項1に記載の微細気泡液生成器。 The micro bubble liquid generator according to claim 1, wherein an uneven surface for generating turbulent flow is formed on an inner surface of the second water passage.
- 前記取水孔を水道水の入口側から出口側に向けて屈曲形成された請求項1に記載の微細気泡液生成器。 The micro bubble liquid generator according to claim 1, wherein the water intake hole is bent from the inlet side to the outlet side of the tap water.
- 前記取水孔ごとに開口面積を可変する開口調節機構を備える請求項1に記載の微細気泡液生成器。 The micro bubble liquid generator according to claim 1, further comprising an opening adjusting mechanism that changes an opening area for each water intake hole.
- 前記開口調節機構は、複数枚の絞り羽根を重ね合わせて形成される虹彩絞り機構であることを特徴とする請求項14に記載の微細気泡液生成器。 The micro bubble liquid generator according to claim 14, wherein the aperture adjustment mechanism is an iris diaphragm mechanism formed by overlapping a plurality of diaphragm blades.
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JP2017170299A JP6960281B2 (en) | 2017-09-05 | 2017-09-05 | Fine bubble liquid generator |
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Cited By (5)
Publication number | Priority date | Publication date | Assignee | Title |
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JP7142386B1 (en) | 2021-06-15 | 2022-09-27 | 荒川工業株式会社 | fine bubble generator |
JP2023008752A (en) * | 2021-07-01 | 2023-01-19 | 株式会社塩 | Internal structure, fluid property changing device and utilization device thereof |
TWI829174B (en) * | 2021-07-01 | 2024-01-11 | 日商鹽股份有限公司 | Internal structure, fluid characteristic changing device, and device utilizing the fluid characteristic changing device |
WO2024116591A1 (en) * | 2022-11-29 | 2024-06-06 | 東芝ライフスタイル株式会社 | Fine bubble generator, and washing apparatus |
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JP7143382B2 (en) * | 2020-10-13 | 2022-09-28 | 株式会社富士計器 | Union type micro-bubble water generator for water pipes |
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KR102631420B1 (en) * | 2023-04-14 | 2024-01-30 | 이성수 | Ultra-fine bubble generator for tap water without inflow external air and system including the same |
KR102711808B1 (en) | 2023-09-05 | 2024-09-30 | 이성수 | Ultra-fine bubble generator for shower and shower apparatus containing the same |
Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH07303822A (en) * | 1994-05-12 | 1995-11-21 | Yamaha Living Tec Kk | Bubble generation device |
WO2011108032A1 (en) * | 2010-03-05 | 2011-09-09 | 国立大学法人東北大学 | Ballast water treatment device, system for rendering ballast water harmless using the device, and method therefor |
KR20130112225A (en) * | 2012-04-03 | 2013-10-14 | 염충식 | Shower head |
JP3209280U (en) * | 2016-12-21 | 2017-03-09 | 株式会社富士計器 | Household water treatment equipment |
Family Cites Families (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP2007307450A (en) * | 2006-05-17 | 2007-11-29 | Yamaha Motor Co Ltd | Bubble generating device |
CN101101087B (en) * | 2006-07-05 | 2011-06-15 | 稻田太一 | Pipe system for producing super fine air bubble in water |
JP2009136864A (en) * | 2007-11-16 | 2009-06-25 | Nippon Sozai Kk | Microbubble generator |
CN203030456U (en) * | 2012-11-02 | 2013-07-03 | 中航商用航空发动机有限责任公司 | Atomizing nozzle device |
KR20160075587A (en) * | 2013-10-23 | 2016-06-29 | 가부시키가이샤 어스리퓨어 | Microbubble generating device and contaminated water purifying system provided with microbubble generating device |
JP6384765B2 (en) * | 2013-10-31 | 2018-09-05 | 日之出産業株式会社 | Microbubble forming method and microbubble forming apparatus |
CN204502827U (en) * | 2015-03-27 | 2015-07-29 | 倪来发 | A kind of device for generation of nano bubble |
-
2017
- 2017-09-05 JP JP2017170299A patent/JP6960281B2/en active Active
-
2018
- 2018-08-21 CN CN201880055937.5A patent/CN111093817B/en active Active
- 2018-08-21 WO PCT/JP2018/030739 patent/WO2019049650A1/en active Application Filing
Patent Citations (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JPH07303822A (en) * | 1994-05-12 | 1995-11-21 | Yamaha Living Tec Kk | Bubble generation device |
WO2011108032A1 (en) * | 2010-03-05 | 2011-09-09 | 国立大学法人東北大学 | Ballast water treatment device, system for rendering ballast water harmless using the device, and method therefor |
KR20130112225A (en) * | 2012-04-03 | 2013-10-14 | 염충식 | Shower head |
JP3209280U (en) * | 2016-12-21 | 2017-03-09 | 株式会社富士計器 | Household water treatment equipment |
Cited By (8)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
JP7142386B1 (en) | 2021-06-15 | 2022-09-27 | 荒川工業株式会社 | fine bubble generator |
WO2022264568A1 (en) * | 2021-06-15 | 2022-12-22 | 荒川工業株式会社 | Microbubble generator |
JP2022190862A (en) * | 2021-06-15 | 2022-12-27 | 荒川工業株式会社 | fine bubble generator |
JP2023008752A (en) * | 2021-07-01 | 2023-01-19 | 株式会社塩 | Internal structure, fluid property changing device and utilization device thereof |
TWI829174B (en) * | 2021-07-01 | 2024-01-11 | 日商鹽股份有限公司 | Internal structure, fluid characteristic changing device, and device utilizing the fluid characteristic changing device |
JP7558572B2 (en) | 2021-07-01 | 2024-10-01 | 株式会社塩 | Internal structure, fluid property changing device and device using same |
WO2024116591A1 (en) * | 2022-11-29 | 2024-06-06 | 東芝ライフスタイル株式会社 | Fine bubble generator, and washing apparatus |
JP7564262B2 (en) | 2023-01-31 | 2024-10-08 | 株式会社富士計器 | Microbubble water header pipe supply system |
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JP6960281B2 (en) | 2021-11-05 |
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JP2019042700A (en) | 2019-03-22 |
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