KR20190014443A - Microbubble-water generator - Google Patents

Abstract

Provided is a microbubble water generator which can be easily installed in a shower head, a washing machine, or the like used at homes in direct connection with a tap water supply pipe. The microbubble water generator (1A) is connected to a water supply side end portion of a shower hose (2) in a first cylindrical part (4) of a main body case (10), and is connected to a water intake side end portion of a shower head (3) in a second cylindrical part (5). A water intake plate (7) having a plurality of water intake holes (11) is fitted to the first cylindrical part (4). A nozzle arranged in the downstream of the water intake plate (7) includes a first water passage (8a) having a diameter gradually reduced along the flow direction of tap water flowing through the water intake plate (7), and a second water passage (8b) having a diameter gradually increasing along the flow direction of the tap water through the outlet side of the first water passage (8a). In the intake holes (11), a central shaft facing the outlet side is inclined with respect to a central shaft of the intake plate (7) at an entrance side thereof.

Description

[0002] MICROBUBBLE-WATER GENERATOR [0003]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a micro-bubble water generator that includes micro-bubbles in water, and more particularly, to a micro-bubble water generator that can be easily installed in an apparatus or facility using household tap water.

Microbubbles mean microbubbles or nano bubbles (diameters of about 50 to 500 nm) having a diameter of about 100 μm or less, and small blisters (microbubbles) that are finer than pores are stuck in pores or glands, Can effectively remove the contamination contained therein, and has recently been used particularly rapidly in the beauty and health fields.

In addition, the cleaning effect by the electrical action of the minute bubbles has been attracting attention. The surfaces of the fine bubbles are normally charged with negative charges, and the bubbles are spread and floated in the fine bubbles without being merged. On the other hand, contamination by oil, sebum, small foreign matter or the like is usually positively charged and electrically coupled to the object to be cleaned with a negative charge. Therefore, when the minute bubbles having a negative charge are adsorbed by the contamination of the positive charge, they are electrically neutralized, and the contamination becomes easy to separate from the object to be cleaned.

The contamination that is electrically neutralized and separated from the object to be cleaned is adsorbed on the gas-liquid interface of the micro-bubbles, floated to the surface by the buoyancy of the bubbles, and the contamination removed from the object to be cleaned is returned to the object to be cleaned It is cleaned without being attached.

In order to generate water containing a large amount of such minute bubbles, a high-speed shearing method, a pressurizing force collapse method, and a cavitation method have been known, but most of them suck air from the outside by an aspirator method or the like. Or, forced injection. As one of them, a liquid which is accelerated by the accelerating means, and a mixed fluid composed of a gas (a bubble having a diameter of several millimeters) introduced into the casing by the gas-liquid mixing means is cavitated in the casing to generate microbubbles Device is known (see, for example, Patent Document 1).

As a method of generating microbubbles by so-called cavitation method in so-called dissolved air which is not dissolved in water without sucking air from the outside, there is a method in which a cross-sectional area perpendicular to the central axis A first nozzle disposed on the inlet side of the first nozzle and a communication passage provided in communication with the outlet of the first nozzle for continuously passing water from the inlet to the outlet, And a microbubble generator having a gap or a side chamber opened only in the communication passage is known (see, for example, Patent Document 2).

A shower head is known in which a micro bubble generator in which a micro bubble is generated by a cavitation method in dissolved air in water is applied to an effect in terms of beauty and health (see, for example, Patent Document 3 ).

Also known is a washing machine including a fluid ejection device for ejecting micro bubbles to a laundry in a rotary tub, which is applied to a washing machine using a micro bubble generator in a manner of generating a micro bubble in a cavitation manner in a dissolved air (for example, See Patent Document 4).

Japanese Patent Application Laid-Open No. 2007-21343 Japanese Patent Application Laid-Open No. 2009-136864 Japanese Patent Application Laid-Open No. 2016-2196 Japanese Patent Application Laid-Open No. 2016-209331

However, the micro-bubble generator according to Patent Document 1 is not suitable for household use where gas-liquid mixing performed by accelerating the water stored in the tank becomes large in size and a simple type of direct connection type is desired.

Further, in the micro bubble generating device according to Patent Document 2, there is a case in which a sufficient amount of water can not be supplied for use in reducing the pressure by tightening the water column rapidly expanded in the communication path provided with the side chambers by the second nozzle. Therefore, it is necessary to adjust the width size in the direction of the axial flow of the cabin according to the state of the water pressure at that time, so that it can not be installed simply in the shower room of the home.

Patent Literature 3 and Patent Literature 4 do not include a micro bubble generator in advance in a mechanism such as a shower head or a washing machine, and the conventional micro bubble generator can not be installed in such a mechanism.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a micro-bubble water generator which can be easily installed in an apparatus using tap water such as a conventional shower head or a washing machine.

In order to solve the above problems, the present invention provides a micro-bubble water generator for use in a device using tap water introduced through a dedicated hose, the micro bubble water generator comprising: a main body case capable of being connected between a feed side end of the dedicated hose and a take- A water intake plate provided in a flow path of tap water in the main body case and provided with a plurality of water intake holes and a nozzle disposed in the main body case downstream of the water intake plate, And a second water passage which communicates with the outlet side of the first water passage and gradually increases in diameter along the flow of tap water do.

In this case, the take-out hole is inclined with respect to the central axis of the take-out plate, with the central axis extending from the inlet side toward the outlet side. Furthermore, it is sufficient that the water intake holes are formed in a plurality of circularly equidistant spaces.

In the present application, the term " apparatus " means apparatuses and apparatuses using various kinds of water including a shower head, a washing machine, a dishwasher, etc., which are widely used in the home.

The diameter of the maximum diameter portion of each of the first water passage and the second water passage is set such that the first water passage is larger and the length dimension of each of the water passage along the flow direction of the tap water is larger than that of the second water passage Tap water is sharply narrowed in the first water passage and is blown out to the second water passage at a high pressure, so that a large pressure difference is generated, and cavitation bubbles are effectively generated.

Further, by making the thickness dimension of the water intake plate at least 1/4 or more of the diameter dimension, the tap water flows vigorously into the first water passage, and a swirling flow with a high turn ratio is formed in the first water passage, . At this time, since the water intake hole is bent toward the outlet side from the inlet side, twisting occurs in the water intake hole, so that the tap water is introduced into the first water passage as a swirling flow with a higher rotation rate.

If an uneven surface for generating turbulence is formed on the inner surface of the water intake hole, the turbulence when the water flows through the water intake hole is increased, and the dissolved air in the tap water is easily extracted, so that the cavitation bubble can be effectively generated.

In one embodiment, on the outer periphery of the end of the main body case on the connection side with the dedicated hose, a male screw is screwed with a female screw formed on the inner periphery of the feed side end of the dedicated hose. In this case, a female screw threadedly engaged with the female thread of the dedicated hose is formed on the outer periphery at one end, and the inner periphery of the other end is formed with a screw thread engaged with the male thread at the end of the main body case on the connection side with the dedicated hose The end of the main body case on the connection side with the dedicated lake is connected appropriately with the dedicated hose through the first adapter and formed into a versatile shape.

In another embodiment, a female thread is formed on the inner periphery of an end portion of the mechanism body on a connection side with the water intake side end portion of the mechanism and a male screw formed on the outer periphery of the water intake side end portion of the mechanism. Wherein a female screw threadably engaged with the male screw of the mechanism is formed on the outer periphery of one end and a male screw is screwed on the female screw on the connection side of the main body case with the mechanism, The end of the main body case on the connection side with the mechanism is appropriately connected to the mechanism so that the versatility is improved.

Further, in one embodiment, the opening adjusting mechanism for varying the opening area of each of the intake holes is provided. The aperture adjusting mechanism may be an iris diaphragm mechanism formed by overlapping a plurality of diaphragm blades.

According to the microbubble number generator of the present invention, the water droplets discharged obliquely from the take-in holes of the intake plate advance in the downstream while increasing the flow rate by turning the inner wall of the first water passage, Micro cavities derived from cavitation are effectively generated from the dissolved air in the tap water under ordinary water pressure. The micro-bubble water generator of the present invention is connected between a device and a dedicated hose of the device, so that the existing device can be easily used as a device for using fine bubble water.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an external perspective view of a microbubble number generator according to a first embodiment of the present invention,
Fig. 2 is a side cross-sectional view of the microbubble number generator of Fig. 1,
3 is a plan view and a side view of the intake plate,
Fig. 4 is an explanatory diagram of a minute bubble number generator shown in Fig. 1 installed in a showerhead,
Fig. 5 shows an explanatory diagram for installing a minute bubble number generator in a shower head using an adapter,
Fig. 6 shows a schematic diagram for explaining generation of cavitation bubbles in the nozzle section,
7 shows an external perspective view of the microbubble number generator according to the second embodiment of the present invention,
8 is a side cross-sectional view of the microbubble number generator of FIG. 7,
Fig. 9 is an explanatory diagram for installing the micro bubble number generator shown in Fig. 7 in the washing machine,
10 is an external perspective view of a water intake plate having an opening adjusting mechanism for varying the opening area in the water intake hole,
11 is a schematic view for explaining the change in the opening area of the intake port of the intake hole adjusted by the opening adjusting mechanism,
12 is a side view of the water intake plate in which the water intake holes are bent.

Household appliances (machines or appliances) to which tap water provided with the micro-bubble water generator according to the present invention are supplied typically include a washing machine and a shower head.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is an exploded perspective view of a shower head according to a first embodiment of the present invention; Fig. BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a perspective view of a micro-bubble water generator for a showerhead according to the present invention. Fig. 1 (a) and Fig. 1 (b) And the outer appearance of the water generator 1A is shown in a perspective view.

2 is a sectional side view of the configuration of the minute bubble number water generator 1 and the minute bubble water generator 1A is constituted by arranging a cylindrical nozzle 6 in the main body case 10 of the cylinder. The main body case 10 is constituted by a first cylindrical portion 4 and a second cylindrical portion 5 having different diameters in cross section and the outer diameter dimension of the nozzle 6 is approximately equal to the inner diameter dimension of the first cylindrical portion 4 And the nozzle 6 is supported in the main body case 10 in combination with the first cylindrical portion 4. [ The tap water is supplied from the first cylindrical portion 4 and flows to the second cylindrical portion 5 through the nozzle 6.

The circular intake plate 7 is fitted in the first cylindrical portion 4 and disposed in the flow path of the tap water in the main body case 10. The take-off plate 7 has a thickness dimension t of 5 mm with respect to the diameter dimension d of 13.5 mm and a specific dimension ratio of the diameter dimension d and the thickness dimension t will be described later. An annular rubber packing 12 is fitted on the outer periphery of the first cylindrical portion 4.

As shown in Fig. 3 (a), the take-off plate 7 is provided with a take-off hole 11, which is a four-round hole penetrating in an axial direction at regular intervals on a plane, As shown in the side view of Fig. 3 (b), the center axis of the water from the inlet side to the outlet side is inclined with respect to the central axis of the intake plate 7. [ Therefore, each water intake hole 11 is provided in the water intake plate 7 in the form of a diagonal cylinder. In Fig. 3 (b), only one of the water intake holes 11 is represented.

The outer diameter of the nozzle 6 is substantially the same as the inner diameter of the first cylindrical portion 4 and is held in the main body case 10 in a state in which a part of the nozzle 6 is inserted into the first cylindrical portion 4 . The inside of the nozzle (6) is provided with a water supply portion (8) having a shape which is tightened from the left and right ends toward the central portion. That is, the neck portion 9 is formed at the central portion of the water supply portion 8 so as to minimize the diameter of the neck portion. The neck portion 9 is formed in a substantially conical shape . Therefore, the water passing portion 8 is provided with a first water passage 8a whose diameter gradually decreases along the direction in which the tap water flows, and a second water passage 8b which is connected to the outlet side of the first water passage 8a, And a second water passage 8b that gradually increases. The opening diameter of the first water passage 8a of the nozzle 6 is set to be larger than the diameter of the outlet of the second water passage 8b and the first water passage 8a and the second water passage 8b 8b are set longer than the second water passage 8b.

Fig. 4 shows the mounting of the minute bubble number generator 1A on the shower head 3. Fig. The first cylindrical portion 4 has a male thread 4a formed on its outer periphery for connecting to the shower hose 2 and a second cylindrical portion 5 having a large diameter is connected to the shower head 3 on its inner periphery A female thread 5a is formed.

The shower hose 2 is connected to the mixing faucet 12 for mixing the water and the hot water at the end on the water supply side and is connected to the shower head 3 at the end on the water- It is the exclusive hose having the sex. The connection between the shower hose 2 and the shower head 3 is achieved by fitting the take-out side end of the shower head 3 into the connecting portion 2A of the shower hose 2 and inserting the female screw 2a formed on the inner periphery of the connecting portion 2A, And the male screw 3a formed on the outer periphery of the water intake side end portion are connected by screwing. Alternatively, the shower hose 2 may be directly connected to the tap of the tap water to supply only water from the shower head 3. In this case, the faucet is connected directly to the water pipe or through a booster pump or an expensive water tank.

When the fine bubble number water generator 1 is installed in the shower head 3, the shower hose 2 and the shower head 3 are separated from each other so that the connection between the male thread 4a of the first cylindrical portion 4 and the shower hose 2 The female screw 2a of the second cylinder 5 is screwed and the female screw 5a of the second cylindrical portion 5 and the male screw 3a of the shower head 3 are screwed to each other to separate the shower hose 2 and the shower head 3 The micro bubble water generator 1 is arranged and fixed.

The outer diameter of the connecting portion 2A of the shower hose 2 and the inner diameter of the root portion of the shower head 3 can be set to be the same as each other because the shower hose 2 and the shower head 3 are detachable, Dimensions vary by product type or vendor. Therefore, in order to separate the shower hose 2 and the shower head 3 from each other and to install the minute bubble water generator 1 therebetween, if the standard dimensions are not appropriate, the shower hose 2 And a female screw 14b screwed to the male screw 4a of the first cylindrical portion 4 is formed on the inner periphery of the other end of the male screw 14a, which is threadedly engaged with the female screw 2a of the connecting portion 2A of the first cylinder 4, And a female screw 15a threadedly engaged with the male screw 3a of the shower head 3 are formed on the inner periphery of one end and the female screw 5a of the second cylindrical portion is formed on the outer periphery of the other end, And a second adapter 15 having a male thread 15b threadedly engaged with the first adapter 15 are used.

The operation of generating the minute bubble water in the minute bubble number generator 1A having the above-described configuration will be described. Tap water supplied from the mixing stopper 12 to the microbubble water generator 1 first passes through each intake hole 11 of the intake plate 7 but the tap water passes through the intake hole 11 of the comb- And flows out in an oblique direction deviating from the center axial direction of the plate 7. [

As a result, the tap water after passing through the water intake hole 11 is in contact with the inner wall of the first water passage 8a in a diagonal line. Therefore, as shown schematically in FIG. 6, do. Since the first water passage 8a has a constricted structure, the first water passage 8a increases in speed as it approaches the neck portion 9 and is discharged from the neck portion 9 to the second water passage 8b.

The tap water having the increased speed is sprayed at a high pressure in the neck portion 9 and diffused in the second water passage 8b. As a result, a sudden pressure drop occurs, and a small number of minute cavitation bubbles are generated in the tap water by the boiling phenomenon in the second water passage 8b, and the water is injected outside through the shower head 3. At this time, the diameter of the inlet 6a of the nozzle 6 on the inlet side is larger than the diameter of the outlet side of the second water passage 8b and the diameter of the first water passage 8a and the second water passage 8b Is shorter than the second water passage 8b, tap water shrinks sharply and is blown out at a higher pressure, so that a large pressure difference is generated, and cavitation bubbles are effectively generated.

When showering is performed with the fine bubble water generated in the nozzle 6 and blown out from the shower head 3, the fine bubbles penetrate into the pores and scrape sebum contamination. Thus, there is an effect of activating the hair follicles and skin beauty.

Next, embodiments of a household washing machine as a mechanism to which the present invention is applied will be described with reference to the drawings. Fig. 7 is a perspective view showing the external appearance of the micro-bubble water producing machine 1B for a washing machine according to the present invention, and Fig. 8 is a side sectional view. Fig. 8 is a perspective view showing the constituent elements shown in Fig. 2 (first embodiment) The same components are denoted by the same reference numerals. In other words, the water intake plate 7 provided with the intake hole 7 of the comb cylindrical column and the first water passage 1 having the diameter decreasing gradually along the flow direction of the tap water indicated by the arrow in Fig. 7, And a second water passage 8b whose diameter gradually increases along the flow direction of the tap water. With respect to the minute bubble number generator 1B according to the second embodiment, matters not specifically mentioned below are the same as those in the first embodiment.

In the minute bubble water generator 1B, the main body case 20 having the first cylindrical portion 21 and the second cylindrical portion 22 is provided between the first cylindrical portion 21 and the second cylindrical portion 22 And an intermediate portion 23 having a side surface shape in which the nozzle 6 is disposed is provided inside. The second cylindrical portion 22 is constituted by a cylindrical body having a bottom surface with a bottom surface provided with a through hole 25 equivalent to the diameter of the outlet side of the second water passage 8b of the nozzle 6 at the center have. An annular rubber washer 24 is attached to the floor so as to ensure watertightness and to prevent loosening when it is connected to the water supply port 27 of the washing machine 26.

Fig. 9 shows mounting of the minute bubble number water generator 1B to the washing machine 26. Fig. The first cylindrical portion 21 is provided with a male thread 21a on the outer periphery thereof for connecting to the water supply hose 24 and a second cylindrical portion 5 having a large diameter is provided on the inner periphery thereof for connection to the washing machine 26 And a female thread 22a is formed.

The water supply hose 24 is a dedicated hose attached to the washing machine in which the inlet side is connected to the faucet 25 of the tap water and the outlet side is connected to the water supply port 27 of the washing machine 26. Further, the faucet 25 is connected directly to the water pipe or, in the case of a collective house, through a booster pump and an expensive water tank, and supplies tap water.

The water supply port 27 of the washing machine 26 is constituted by a cylindrical body protruding from the bottom surface of the water supply portion recessed from the body surface of the washing machine 26 and has a male thread 27a formed on the outer circumference thereof. The water supply hose 24 is connected to the washing machine 26 by screwing the end of the water supply hose 24 with the male screw 27a. When the micro bubble water generator 1B is installed in the washing machine 26, 24 are connected to the first cylindrical portion 21 instead of the water supply port 27. [ The microbubble number generator 1B is installed in the washing machine 26 by covering the second cylindrical portion 22 on the water supply port 27 and screwing the second cylindrical portion 22 to the male screw 27a.

When the fine bubble water generator 1B can not be connected to the water supply hose 24 or the water feed port 27 because the standard size is not matched even when it is installed in the washing machine, the first and second adapters 14 and 15 ) Is used.

The micro-bubble water generator 1B having the above-described configuration also generates micro-bubble water in the same manner as the above-described micro-bubble water generator 1B and supplies it to the washing machine 26. That is, tap water supplied from the faucet 25 to the micro-bubble water generator 1 is first introduced into the first cylindrical portion 21 to pass through the water intake holes 11 of the water intake plate 7, Through the water take-in hole (9) of the take-out plate (8), and flows out in an oblique direction deviating from the center axial direction of the take-out plate (8). As shown in FIG. 6, the water is guided obliquely to the inner wall of the first water passage 10a of the throttle structure and is pivoted in a spiral shape while moving at a higher speed to the neck 11 and is blown to the second water passage 10b at a high pressure And diffuses in the second water passage 10b. As a result, a sudden pressure drop occurs. As a result of the boiling phenomenon, innumerable micro cavitation bubbles are generated in the second water supply passage 10b and supplied to the washing machine 26 in the tap water.

In the washing machine of the washing machine 26 in which the minute bubble water is injected, the surfaces of the minute bubbles have a negative charge so that the bubbles are spread and floated in the fine bubble water without being merged. On the other hand, for the purpose of washing, the contamination by the sebum or the residual foreign matter adhered to the fibers soaked in the fine bubble water in the washing tub is positively charged, and the fine bubbles are adsorbed by the contamination and electrically neutralized. The dirt removed from the fibers after being electrically neutralized is adsorbed on the gas-liquid interface of the micro-bubbles, floating on the water surface by the buoyancy of the bubbles, so that the dirt removed from the fibers is not adhered to the fibers again in the micro-bubbles. Is achieved.

Therefore, washing with micro-bubble water can be effectively washed without using a detergent, so it is very suitable for a person who has a detergent allergy. More effectively, the detergent may be injected into the minute bubble water, but the amount of the detergent may be small as compared with the case of ordinary water.

Although the minute bubble water generator according to the present invention has been described above with reference to the two embodiments, the shape of the intake hole 11 of the intake plate 7 is not limited to the center axis of the intake plate 7, The tap water passes through the first water passage 8a while being rotated, so that when the water intake hole 11 is formed into a cylindrical shape having a shape along the central axis of the intake plate 7 The speed of blowing from the neck portion 9 to the second water passage 10b is faster and minute cavitation bubbles can be generated in the tap water.

In addition, when generating a swirling flow in the first water passage 8a, a larger number of minute bubbles can be generated in the tap water as the effective swirling flow with a high rotation rate is generated. Therefore, in order to generate an effective swirling flow with a high turnover rate, the length of the take-out hole 11 in the axial direction is sufficiently secured by using the take-off plate 7 having a large thickness. As a reference of the thickness in this case, the ratio (t / d) when the thickness dimension of the intake plate 7 is t and the diameter dimension is d is set to 1/4 or more as shown in Fig. 3 It is good. In this example, the thickness dimension (t) is 5 mm with respect to the diameter dimension (d) of 13.5 mm.

By setting the thickness dimension t of the intake plate to at least 1/4 or more of the diameter d and increasing the distance of the central axis in the depth direction of the intake hole 11, tap water flows out strongly, A swirling flow is formed in the first water passage 8a to effectively generate a large number of minute bubbles.

According to the micro-bubble water generators 1A and 1B according to the present invention, fine bubbles can be effectively generated by cavitation using air contained in tap water supplied to a general household. (0.15 to 0.3 MPa) at a pressure of 1.5 kgf / cm < 2 > in the case of direct connection to the water supply, and the nozzle unit 22 is provided with a water supply pipe It can be made into tap water including air bubbles which are miniaturized by cavitation only by water pressure. The water pressure in this case is preferably 2.0 to 4.0 kgf / cm 2 (0.2 to 0.39 MPa).

Further, in another embodiment shown in Fig. 10, in order to change the water intake capacity by the minute bubble water generators 1A and 1B in accordance with the pressure or flow rate of the supplied tap water, variable intake orifices 28). The variable orifice 28 is an orifice provided with an iris diaphragm mechanism and adapted to change the opening area of the intake hole 7. As shown in Figs. 11 (a) to 11 (c), the iris diaphragm mechanism is generally known as a diaphragm of a camera lens or the like. For example, a plurality of metal pieces 30 ) Is rotated by driving a gear (not shown) to change the area of the opening 14 to four. In this case, the gears of the respective variable orifices 28 are simultaneously driven by rotating a hole diameter adjusting dial provided outside the main body case, and the opening areas of the take-out holes 11 can be adjusted to the same magnitude simultaneously .

When the supply pressure of the tap water is low by providing the variable orifice 28, the opening area of the take-out hole 11 is made small so that the feed pressure can be increased to be introduced into the nozzle 6, It is possible to adjust the feed pressure of the feed roller to a constant value.

12A, the inner wall surface of the hole is an uneven surface 11a, and tap water is discharged from the water intake hole 11 while increasing turbulence. In this embodiment, a plurality of projections are provided to form the uneven surface 11a. When the turbulence degree is improved as described above, the dissolved air in the tap water is easily taken out, and cavitation bubbles can effectively be generated in the nozzle 4. [

Further, as shown in Fig. 12B, the shape of the intake hole 11 may be a shape obtained by providing a curved portion in a comb-like cylinder facing from the inlet side to the outlet side, and adding twist. As a result, twisting occurs in the flow of tap water passing through the water intake hole 11, and a swirling flow with a higher rotation rate can be generated in the first water passage 8a, so that the irregular surface 11a of the inner wall of the water intake hole 11 The turbulence becomes even higher and the effect of generating cavitation bubbles in the nozzle 11 can be improved.

The present invention is not limited to the above-described embodiments, but may be modified in various ways based on the spirit of the present invention. For example, the water intake hole 11 can be provided up to about 20 depending on the flow rate of piping and the like of tap water to be installed. Therefore, when the number of take-out holes 11 is increased, it is preferable to arrange them equally uniformly in the plane of the intake plate 7, rather than being arranged at equal intervals in a circular shape.

The diameter of the inlet side of the first water passage 8a is made larger than the diameter of the outlet side of the second water passage 8b and the distance in the direction of the central axis of the water passage 8 is the second The water passage 8b is made longer, but the water passage 8b may be formed to have a symmetrical shape with the neck 9 as the same diameter. The point is that it is possible to generate a high quality cavitation bubble as an appropriate amount and fine bubbles in relation to the pressure of the tap water blown out from the first water passage 8a and the pressure lowering due to the diffusion in the second water passage 8b .

In order to more effectively generate minute bubbles, the first water passage 8a of the rear nozzle 6 is connected to the second water passage 8b of the nozzle 6 at the front end, 6 may be arranged in series to repeat cavitation generation.

1A; Minute bubble number generator
1B; Minute bubble number generator
2; Special hose (shower hose)
3; Shower Head (Household Appliances)
4; The first cylindrical portion
4a; Male thread
5; The second cylindrical portion
5a; female screw
7; Intake plate
8a; The first water passage
8b; The second water passage
10; Body case
11; Intake hall
14; The first adapter
15; The second adapter
21; The first cylindrical portion
21a; Male thread
22; The second cylindrical portion
22a; female screw
23; Body case
24; Special hose (water supply hose)
26; Washing machine (household appliance)
28; The opening adjustment mechanism
30; Aperture wing

Claims (13)

A micro bubble water generator installed in an apparatus using tap water introduced through a dedicated hose,
A main body case connectable between a water supply side end portion of the dedicated hose and a water intake side end portion of the mechanism,
A water intake plate disposed in the flow path of tap water in the main body case and provided with a plurality of water intake holes (water intake holes)
And a nozzle disposed downstream of the water intake plate in the main body case,
The nozzle
A first water passage which gradually decreases in diameter along the flow direction of the tap water flowing through the water intake plate,
And a second water passage formed on the outlet side of the first water passage and gradually increasing in diameter along the flow direction of the tap water.
The method according to claim 1,
Wherein the water intake hole is inclined with respect to the central axis of the water intake plate, the central axis of which is directed from the inlet side to the outlet side.
3. The method of claim 2,
Wherein the first water passage and the second water passage each have a diameter larger than the diameter of the first water passage and each length dimension along the direction in which tap water flows is set so that the second water passage is larger Micro bubble number generator.
3. The method of claim 2,
Wherein the take-off plate thickness dimension of the intake plate is at least 1/4 of the diameter dimension.
3. The method of claim 2,
Wherein the take-out holes are formed as a plurality of circularly spaced equal intervals.
3. The method of claim 2,
Wherein said water intake hole is curved toward the outlet side from the inlet side of tap water.
3. The method of claim 2,
And an uneven surface for generating turbulence is formed on the inner surface of the water intake hole.
The method according to claim 1,
And a male screw threadably engaged with a female screw formed on an inner periphery of the water supply side end portion of the dedicated hose is formed on an outer periphery of a connection side end portion of the main body case with the dedicated hose.
9. The method of claim 8,
A first adapter having a male screw threadedly engaged with the female thread of the dedicated hose at one end of the outer hose and a female screw threadedly engaged with the male thread of the end of the main body case at the connection side with the special hose, Wherein a connection side end of the main body case with the dedicated hose is connected to the dedicated hose.
The method according to claim 1,
Wherein an end of the mechanism on the connection side with the water intake side end of the mechanism body is formed on the inner periphery with a female screw threadably engaged with the male screw formed on the outer periphery of the water intake side end of the mechanism.
11. The method of claim 10,
And a second adapter having a female screw threadedly engaged with the male screw of the mechanism formed on the inner periphery of the one end and having a male screw threadably engaged with the female screw on the side of the main body case, And an end of the body case on a connection side with the mechanism is connected to the mechanism.
3. The method of claim 2,
And an opening regulating mechanism for varying the opening area of each of the intake holes.
13. The method of claim 12,
Wherein the aperture adjustment mechanism is an iris diaphragm mechanism formed by overlapping a plurality of diaphragm blades.

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