JP5024144B2 - Gas dissolver - Google Patents

Description

  The present invention relates to a gas dissolver provided in a fine bubble generator.

  Conventionally, a fine bubble generator for supplying a liquid containing fine bubbles to a bathtub or the like is known. This fine bubble generator includes a gas introducer, a circulation pump, a gas dissolver, and a bubble generator.

  Gas is supplied from the gas introduction part to the liquid in the water tank such as a bathtub sucked in by the circulation pump, and the gas-liquid mixed fluid is sent to the gas dissolver. In the gas dissolver, the gas in the gas-liquid mixed fluid is dissolved in the liquid by pressurization or the like. Then, a gas solution is sent from the gas dissolver to the bubble generator, in which the gas in the gas solution is precipitated to generate fine bubbles, which are supplied into the water tank.

Here, in order to generate a large amount of fine bubbles in the bubble generator, it is necessary to increase the amount of gas dissolved in the liquid in the gas dissolver. As a method for improving the dissolution rate of a gas in a liquid, contact between the gas and the liquid can be achieved by increasing the pressure in the gas dissolver or by making the spray flow wider as shown in Patent Document 1. It has been proposed to increase the area.
Japanese Patent Laid-Open No. 2007-844

  However, in the above method for increasing the pressure in the gas dissolver, if the circulating pump for sending the gas mixture liquid to the gas dissolver has a high output, the fine bubble generating device becomes large. Further, as in the above-mentioned Patent Document 1, in order to make the spray flow divergent and reach the gas-liquid interface at the end thereof, a long outer edge length is secured at the portion where the spray flow reaches the gas-liquid interface. There is a problem that the gas dissolver becomes large.

  This invention is made | formed in view of this point, The objective is providing the gas dissolver which can improve the melt | dissolution efficiency of the gas to a liquid, suppressing the enlargement of a fine bubble generator. There is.

In order to achieve the above object, a gas dissolver (14) according to a first aspect of the present invention allows a gas-liquid mixed fluid to flow into a casing (41) from an inflow port (50) formed at the upper end. 41) A gas dissolver in which gas in the gas-liquid mixed fluid is dissolved in the liquid and flows out from the outlet (51), wherein the gas-liquid mixed fluid is separated into a liquid layer and a gas layer in the casing. An injection nozzle (44) for injecting the gas-liquid mixed fluid flowing in from the inflow port (50) into the casing (41) through the plurality of injection ports (55) is provided in the casing (41); The gas-liquid mixed fluid is ejected from each ejection port (55) to generate bubbles in the liquid layer. The ejection nozzle (44) is configured so that each ejection port (55) has the casing (41). ) The spray nozzle (44) is provided in the shape of a cylinder. Made are, while having an upstream side portion of the communication hole (54) communicating with the inlet (50) to (57) in the central portion, the communicating hole of the downstream side portion formed by a flat plate extending in the horizontal direction (58) (54), a plurality of fine pores constituting each of the injection ports (55) are provided in the circumferential direction except for the central portion corresponding to (54), and the injection nozzle (44) is connected to the gas liquid from the injection port (55). The mixed fluid is configured to be ejected in a direction that does not interfere with each other in the gas layer.

  According to said structure, the gas-liquid mixed fluid which flowed in from the inflow port (50) is distributed to the several injection port (55) of an injection nozzle (44), and a flow velocity increases and it injects in a casing (41). Is done. Since the gas-liquid mixed fluid ejected from each ejection port (55) generates a large number of bubbles in the liquid layer, these bubbles come into contact with the liquid in the liquid layer and dissolve. By generating a large number of bubbles in the liquid layer, the surface area of the gas (bubbles) per volume in the gas-liquid mixed fluid increases, so the gas-liquid interface area increases and the dissolution of the gas in the liquid is promoted. .

  Here, an increase in the number of bubbles means that if the gas in the gas-liquid mixed fluid is constant, the diameter of the bubbles decreases, so that the number of bubbles increases so that the bubbles are filled in the liquid layer. The liquid interface area increases.

  Further, according to the above configuration, since the gas-liquid mixed fluid is injected into the gas layer from each of the injection ports (55) of the injection nozzle (44), the liquid layer maintains the state in which the gas-liquid mixed fluid has increased the flow velocity. And a large number of bubbles are generated in the liquid layer, and the liquid layer is agitated to promote dissolution of the gas in the liquid.

  Here, when the injection port (55) is also provided in the central portion corresponding to the communication hole (54) communicating with the inflow port (50), the gas-liquid mixed fluid injected from the central injection port Because the jet state is considered to be different from the gas-liquid mixed fluid jetted from the jet port (55) provided in the peripheral part, the generation of bubbles becomes insufficient and the entire liquid layer is efficiently stirred. Can not do it.

  And according to the said 1st invention, since the injection port (55) is provided in the part except the center part corresponding to a communicating hole (54), the gas-liquid mixed fluid which flowed in from the communicating hole (54) distributes The gas-liquid mixed fluid is sprayed from the respective injection ports (55), and the gas-liquid mixed fluid is jetted in the same manner, so that bubbles are sufficiently generated and the gas-liquid mixed fluid is jetted to the peripheral portion of the liquid layer. Is stirred.

  Further, according to the above configuration, since the gas-liquid mixed fluid injected from each injection port (55) does not interfere with each other in the gas layer, the gas-liquid mixed fluid is injected into the liquid layer while the flow velocity is increased, Air bubbles are generated sufficiently.

  A gas dissolver (14) according to a second aspect of the present invention is the gas dissolver (14) according to the first aspect of the present invention, wherein the injection nozzle (44) receives the gas-liquid mixed fluid from the injection port (55). It is configured to be ejected vertically downward toward the liquid layer in the casing (41).

  According to the above configuration, since the gas-liquid mixed fluid having an increased flow velocity is injected directly downward toward the liquid layer, the injected gas-liquid mixed fluid does not collide with the side wall of the casing (41) and the casing (41) It is easy to reach the lower part of the inside, the liquid layer is stirred as a whole, and the bubbles are convectively filled in the liquid layer, so that the dissolution of the gas in the liquid is promoted.

  A gas dissolver (14) according to a third aspect of the present invention is the gas dissolver (14) according to the first aspect of the present invention, wherein the injection nozzle (44) allows the gas-liquid mixed fluid to flow from the injection port (55) to each other. It is comprised so that it may inject with equal flow velocity.

  According to said structure, since the flow velocity of the gas-liquid mixed fluid injected from each injection port (55) is mutually equal, a liquid layer is stirred as a whole.

  A gas dissolver (14) according to a fourth aspect of the present invention is the gas dissolver (14) according to the first aspect of the present invention, wherein the injection nozzle (44) receives the gas-liquid mixed fluid from the injection port (55). The liquid layer in the casing (41) is configured to be sprayed toward the liquid surface peripheral portion.

  According to said structure, a gas-liquid mixed fluid is injected to the peripheral part of the liquid layer in a casing (41), and a liquid layer is stirred as a whole.

  A gas dissolver (14) according to a fifth aspect of the present invention is the gas dissolver (14) according to the first aspect of the present invention, wherein the outflow port (51) is provided at a lower part of the side surface of the casing (41). .

  According to said structure, the gas solution which the bubble generate | occur | produced in the liquid layer melt | dissolved in the liquid flows out from the outflow port (51) provided in the casing (41) lower part. Since the bubbles try to float upward due to buoyancy, the bubbles not dissolved in the liquid are unlikely to flow out from the outlet (51), and the time for the bubbles to convect in the liquid layer becomes long.

  A gas dissolver (14) according to a sixth aspect of the present invention is the gas dissolver (14) according to the fifth aspect of the present invention, wherein the gas dissolver (14) protrudes into the casing (41) and the downstream portion communicates with the outlet (51). A protruding pipe (56) is provided, and an upstream opening (56a) of the protruding pipe (56) opens downward.

  According to the above configuration, since the upstream opening (56a) of the protruding tube (56) opens downward, bubbles that are not dissolved in the liquid are difficult to enter the protruding tube (56), and the bubbles are dissolved in the liquid. The gas dissolved liquid preferentially flows into the protruding tube (56).

  Therefore, according to the present invention, the gas-liquid mixed fluid is ejected from the plurality of ejection ports (55) to generate bubbles in the liquid layer, thereby increasing the gas-liquid interface area. Efficiency can be improved.

  Moreover, since only the injection nozzle (44) is provided in the casing (41), the gas dissolver (14) does not increase in size, and the increase in the size of the fine bubble generator (10) provided with this can be suppressed. it can.

  According to the first aspect of the invention, since the injection port (55) is provided so as to face the gas layer, the gas-liquid mixed fluid can be jetted toward the liquid layer vigorously while the flow rate is increased, A large number of bubbles can be generated in the liquid layer to increase the gas-liquid interface area, and since the liquid layer is stirred, the dissolution efficiency of the gas in the liquid can be further improved.

  In addition, according to the first aspect of the invention, since each of the injection ports (55) is provided in the peripheral portion excluding the central portion corresponding to the communication hole (54) communicating with the inflow port (50), the gas-liquid mixed fluid is The state of the gas-liquid mixed fluid distributed from the inflow port (50) through the communication hole (54) and injected from each injection port (55) is the same as each other, and bubbles can be sufficiently generated, Since the liquid layer is agitated by jetting the gas-liquid mixed fluid to the peripheral part of the liquid layer, the dissolution efficiency of the gas in the liquid can be improved.

  According to the first aspect, since the gas-liquid mixed fluid is injected from the respective injection ports (55) so as not to interfere with each other in the gas layer, the gas-liquid mixed fluid is injected into the liquid layer while the flow rate is increased. Thus, bubbles are sufficiently generated, and the dissolution efficiency of the gas in the liquid can be improved.

  According to the second aspect, since the gas-liquid mixed fluid is jetted vertically downward toward the liquid layer, the gas-liquid mixed fluid easily reaches the lower part in the casing (41), and the entire liquid layer is stirred. Bubbles are filled in the liquid layer, and the dissolution efficiency of the gas in the liquid can be improved.

  According to the third aspect of the invention, the gas-liquid mixed fluid is ejected from the ejection ports (55) at the same flow velocity, so that the liquid layer is totally agitated and the bubbles are filled in the liquid layer. Gas dissolution efficiency can be improved.

  According to the fourth aspect of the invention, since the gas-liquid mixed fluid is sprayed to the liquid surface peripheral portion of the liquid layer, the liquid layer is totally stirred and the bubbles are filled in the liquid layer. The dissolution efficiency can be improved.

  According to the fifth aspect, since the outlet (51) is provided at the lower portion of the casing (41), bubbles that are not dissolved in the liquid are unlikely to flow out of the outlet (51), and convection in the liquid layer of the bubbles Since time becomes long, the dissolution efficiency of the gas in the liquid can be improved.

  According to the sixth aspect of the invention, since the upstream opening of the projecting pipe (56) provided at the outlet (51) is opened downward, undissolved bubbles are further removed from the outlet (51 ), And it is possible to further improve the gas dissolution efficiency in the liquid.

  Embodiments of the present invention will be described in detail with reference to the drawings.

  As shown in FIG. 1, the fine bubble generator (10) provided with the gas dissolver (14) of the present embodiment supplies water (liquid) containing fine bubbles to a water tank (5) such as a bathtub. is there.

  The fine bubble generator (10) includes a circulation channel (11) in which an inlet and an outlet are respectively connected to a water tank (5) and water is circulated. The circulation channel (11) includes, in order from the upstream side to the downstream side, a gas introducer (12), a pump mechanism (13), a gas dissolver (14), and a gas-liquid separator (19). And the bubble generator (16) are connected.

  The gas introducing device (12) introduces air that becomes a bubble source into the circulation channel (11) from the outside. The gas introducing device (12) sucks air by using a negative pressure generated by a water flow inside the gas introducing device (12).

  The pump mechanism (13) is for circulating water in the water tank (5) in the circulation channel (11). The pump mechanism (13) discharges water sucked from the gas introducing device (12) side to the gas dissolving device (14) side. During the discharge, water is pressurized. That is, in this embodiment, the pump mechanism (13) constitutes a means for pressurizing water in the circulation channel (11).

  The gas dissolver (14) dissolves the air introduced by the gas introducer (12) in water or promotes the dissolution of air in water.

  Specifically, as shown in FIG. 2, the gas dissolver (14) includes a casing (41) formed in a vertically long cylindrical shape. The casing (41) has, for example, a diameter D1 = 82 mm and a height H1 = 180 mm. The casing (41) is connected to the circulation channel (11) so as to be vertically long in the vertical direction. An inflow port (50) is provided at the center of the upper surface of the casing (41), while an outflow port (51) is provided at the lower part of the side surface. An inflow pipe (42) is connected to the inflow port (50), and an outflow pipe (43) is connected to the outflow port (51). These inflow pipe (42) and outflow pipe (43) are circulated. It is connected to the flow path (11) and communicates with the inside of the casing (41).

  The inlet (50) is provided with an injection nozzle (44) that communicates with the inflow pipe (42) and projects into the casing (41). The injection nozzle (44) is formed in a cylindrical shape having a diameter D2 = 60 mm and a height H2 = 20 mm, for example, and is connected to the inflow port (50) through a communication pipe (53) communicating with the inflow pipe (42). Has been.

  The upstream side surface portion (57) of the injection nozzle (44) is formed with a circular communication hole (54) communicating with the communication pipe (53) in the circular central portion. That is, the communication hole (54) communicates with the inflow port (50).

  On the other hand, the downstream side surface portion (58) of the injection nozzle (44) is provided with a plurality (24 in the figure) of injection ports (55) as shown in FIG. These injection ports (55) are formed in, for example, holes having a diameter D3 = 2 mm, and are provided in the peripheral portion of the downstream side surface portion (58) excluding the central portion corresponding to the communication hole (54).

  Specifically, as shown in FIG. 3A, a set of six injection ports (55) arranged at equal intervals is set as a set, and a set of four injection ports (55) is equally spaced in the circumferential direction. Is arranged. Further, as shown in FIG. 3B, a set of two injection ports (55) arranged in the radial direction as a set, and a set of 12 injection ports (55) are arranged at equal intervals in the circumferential direction. May be.

  That is, the injection port (55) is provided in the peripheral portion of the downstream side surface portion (58) of the injection nozzle (44), and is arranged symmetrically with respect to the center of the downstream side surface portion (58). The gas-liquid mixed fluid flowing in from (50) is distributed to each injection port (55) through the communication hole (54), and the gas-liquid mixed fluid is injected from the injection port (55) at the same flow velocity. ing.

  The spray nozzle (44) sprays water flowing in from the inflow pipe (42) vertically downward toward the liquid layer so that the water sprayed from the spray ports (55) does not interfere with each other in the air layer. It is configured.

  In the gas dissolver (14), the gas-liquid mixed fluid is separated into a liquid layer and a gas layer in the casing (41), and the liquid level of the liquid layer is always maintained constant. The inflow and outflow amounts of (42) and the outflow pipe (43) are set. The liquid level in the casing (41) is maintained below the downstream side surface part (58) of the injection nozzle (44). That is, the injection port (55) of the injection nozzle (44) is provided so as to face the air layer in the casing (41). For example, the liquid layer constitutes the lower third of the casing (41), and the gas layer constitutes the upper third of the casing (41).

  The outlet (51) of the casing (41) is provided with a protruding pipe (56) whose downstream portion communicates with the outflow pipe (43) and projects into the casing (41). The projecting pipe (56) has a downstream side communicating with the outlet (51), and is formed in a substantially L-shaped cross section, and an upstream side opening (56a) is opened downward.

  In the casing (41), water is jetted from the jet ports (55) of the jet nozzle (44) toward the liquid surface, and a large amount of bubbles are generated in the water and the bubbles are stirred. Thereby, bubbles (air) dissolve in water. Gas dissolved in the gas and bubbles as excess gas that did not dissolve in water flow out from the outlet (51) through the upstream opening (56a) of the protruding tube (56) to separate the gas and liquid. Sent to container (19).

  The gas-liquid separator (19) separates the gas solution discharged from the gas dissolver (14) and bubbles as excess gas.

  Specifically, the gas-liquid separator (19) is formed in a vertically long cylindrical sealed container shape and connected to the circulation channel (11). An exhaust pipe (19a) for discharging excess gas is provided on the upper surface of the gas-liquid separator (19). The gas solution flowing out from the gas dissolver (14) and the excess gas not dissolved in water flow into the gas-liquid separator (19), and the excess gas is separated from the gas solution and discharged from the exhaust pipe (19a). It is supposed to be discharged.

  The bubble generator (16) is for depressurizing water in which air is dissolved to generate fine bubbles. The bubble generator (16) is attached to the side wall surface of the water tank (5) so as to face the water tank (5).

  The bubble generator (16) includes a cylindrical main body (61) as shown in FIG. In the main body (61), an inlet channel (62), a distribution channel (64), and an outlet channel (65) are formed in order from the inlet side (left side in FIG. 4) to the outlet side (right side in FIG. 4). ing. Water flowing out from the gas-liquid separator (19) (water in which air is dissolved) flows into the inlet channel (62). The outlet side of the inlet channel (62) is a channel restricting portion (63) in which the channel becomes narrow, and is connected to the distribution channel (64). The water is depressurized when passing through the flow restrictor (63). Thereby, the air dissolved in water precipitates and becomes fine bubbles (microbubbles). The distribution channel (64) has a larger channel than the channel restricting portion (63), and is connected to a plurality (six in this embodiment) of outlet channels (65). That is, the water that has flowed into the distribution channel (64) is diverted to each outlet channel (65). As shown in FIG. 5, the outlet channels (65) are arranged at equal intervals around the axis of the main body (61). The end of the outlet channel (65) opens into the water of the water tank (5). The water in the water tank (5) is drawn into the circulation channel (11) from the suction port (17) and flows again to the gas introduction device (12).

  The circulation channel (11) is provided with a flow meter (18) on the upstream side of the gas introducer (12). This flow meter (18) constitutes a flow rate measuring means for measuring the flow rate of water circulating through the circulation channel (11). The circulation channel (11) is provided with a flow rate adjusting valve (15) between the suction port (17) and the flow meter (18). The flow rate adjusting valve (15) constitutes a flow rate adjusting means for adjusting the flow rate of the circulation channel (11) by changing the opening degree.

-Operation of microbubble generator-
Next, the operation of the fine bubble generator (10) will be described. In this fine bubble generating device (10), when the pump mechanism (13) is activated, water in the water tank (5) is drawn into the suction port (17) and flows toward the outlet of the circulation channel (11).

  The pump mechanism (13) is adjusted so that the flow rate of the circulation channel (11) is, for example, 10 to 15 liters / minute. In this state, the inside of the casing (41) of the gas dissolver (14) is pressurized to about 0.3 MPa. During operation, the opening degree of the flow rate adjusting valve (15) is adjusted based on the flow rate measured by the flow meter (18).

  The water in the water tank (5) that flows in from the inlet of the circulation channel (11) flows into the gas introducing device (12). In the gas introducing device (12), the sucked air is mixed into water. This gas-liquid mixed fluid flows out of the gas introducing device (12) and flows into the gas dissolving device (14) through the pump mechanism (13).

  In the gas dissolver (14), the gas-liquid mixed fluid flows from the inflow port (50) through the inflow pipe (42) and is injected into the casing (41) from the injection nozzle (44). In the injection nozzle (44), the gas-liquid mixed fluid that has flowed in from the communication hole (54) through the communication pipe (53) is distributed to the respective injection ports (55) and is injected in an increased flow rate. The gas-liquid mixed fluid is jetted from the respective jet ports (55) facing the gas layer in a state where the flow velocity is increased in a vertically downward direction so as not to interfere with each other in the gas layer. The liquid layer is agitated by the jetted gas-liquid mixed fluid, and a large amount of bubbles are filled in the liquid layer.

Here, as in Patent Document 1, the gas-liquid interface area when the gas-liquid mixed fluid is sprayed toward the liquid layer in a divergent form is calculated for the case where the casing (41) of the present embodiment is used. Assuming that the gas-liquid mixed fluid is injected conically into the gas layer constituting the upper third of the casing (41), the gas-liquid interface area is the side area of a cone having a radius of 41 mm and a height of 60 mm. Therefore, S1≈94 cm ² .

On the other hand, in the gas dissolver (14) according to the present embodiment, the gas-liquid interface area when the gas of the volume corresponding to the gas layer in the casing (41) becomes bubbles with a radius of 5 mm is S2 = 1902 cm ² . is there. As shown in FIG. 6, when the gas volume is constant (gas layer volume 317 cm ³ ), the gas-liquid interface area increases as the bubble radius decreases.

  Then, a large amount of bubbles are dissolved in contact with the liquid, and the dissolved gas solution flows from the upstream side opening (56a) into the protruding pipe (56) and from the outlet (51) to the outlet pipe (43 ) Through the gas dissolver (14) and into the gas-liquid separator (19).

  The dissolved gas and the undissolved gas flowing into the gas-liquid separator (19) are separated in the gas-liquid separator (19), and the undissolved gas is discharged from the exhaust pipe (19a). The gas solution separated from the undissolved gas flows out of the gas-liquid separator (19) and flows into the bubble generator (16).

  The water that has flowed into the bubble generator (16) is depressurized when passing through the flow restrictor (63). Thereby, the dissolved air precipitates in the water, and fine bubbles are generated in the water. Thereafter, water containing bubbles flows through the distribution channel (64) and the outlet channel (65) and is ejected into the water tank (5). Thereby, many fine bubbles float in the water of the water tank (5), and the water becomes cloudy.

-Effect of the embodiment-
According to the present embodiment, the gas-liquid mixed fluid flowing in from the inlet (50) is distributed to the plurality of injection ports (55) of the injection nozzle (44) to increase the flow velocity. By ejecting toward the liquid, a large number of bubbles are generated in the liquid layer and the gas-liquid interface area is increased, so that the dissolution efficiency of the gas in the liquid can be improved.

  Moreover, since only the injection nozzle (44) is provided in the casing (41), the gas dissolver (14) does not increase in size, and the increase in the size of the fine bubble generator (10) provided with this can be suppressed. it can.

  Moreover, since the injection port (55) of the injection nozzle (44) is provided so as to face the gas layer, the gas-liquid mixed fluid can be vigorously injected toward the liquid layer while the flow velocity is increased. Bubbles can be generated in the liquid layer to increase the gas-liquid interface area, and the liquid layer is agitated, so that the gas dissolution efficiency in the liquid can be further improved.

  Moreover, since each injection port (55) was provided in the peripheral part except the center part corresponding to the communicating hole (54) communicating with an inflow port (50), the gas-liquid mixed fluid injected from each injection port (55) In the same manner, the bubbles can be sufficiently generated, and the gas-liquid mixed fluid is injected from the peripheral portion of the liquid layer to stir the liquid layer, so that the gas dissolution efficiency in the liquid is improved. be able to.

  In addition, since the gas-liquid mixed fluid was injected from each injection port (55) so as not to interfere with each other in the gas layer, the gas-liquid mixed fluid was injected into the liquid layer with the flow velocity increased, and bubbles were sufficiently generated. The dissolution efficiency of the gas in the liquid can be improved.

  In addition, since the gas-liquid mixed fluid is injected vertically downward toward the liquid layer, the gas-liquid mixed fluid injected to the lower part of the vertically long casing (41) can easily reach, and the entire liquid layer is agitated to generate bubbles. Fills the liquid layer, so that the dissolution efficiency of the gas in the liquid can be improved.

  In addition, since the gas-liquid mixed fluid is injected from the respective injection ports (55) at the same flow rate, the liquid layer is agitated as a whole and bubbles are filled in the liquid layer, thereby improving the dissolution efficiency of the gas in the liquid. be able to.

  Further, since the gas-liquid mixed fluid is sprayed to the liquid surface peripheral portion of the liquid layer, the liquid layer is agitated as a whole and bubbles are filled in the liquid layer, so that the gas dissolution efficiency in the liquid can be improved. .

  In addition, since the outlet (51) is provided in the lower part of the casing (41), bubbles that are not dissolved in the liquid are less likely to flow out of the outlet (51), and the convection time in the liquid layer of the bubbles becomes longer. The gas dissolution efficiency can be improved.

  In addition, since the upstream opening of the protruding pipe (56) provided at the outlet (51) is opened downward, undissolved bubbles are more unlikely to flow out of the outlet (51), and the liquid The gas dissolution efficiency can be further improved.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  That is, a plurality of injection ports (55) of the injection nozzle (44) may be provided in the peripheral portion except the central portion provided with the communication hole (54) communicating with the inflow port (50). The arrangement is not limited.

  In the above embodiment, the protruding pipe (56) is provided at the lower portion of the casing (41). However, the protruding pipe (56) is not necessarily provided, and at least the outlet (51) is provided on the casing (41). What is necessary is just to be provided in the lower part.

    As described above, the present invention is useful for a gas dissolver provided in a liquid microbubble generator.

It is a piping system figure showing the composition of the fine bubble generating device concerning an embodiment. It is a longitudinal cross-sectional view which shows the structure of a gas dissolver. It is the figure which looked at the injection part of the gas dissolver from the exit side. It is a longitudinal cross-sectional view which shows the structure of a bubble generator. It is a front view which shows a bubble generator seeing from the water tank side. It is a graph which shows the relationship between a bubble radius and a gas-liquid interface area.

1 Gas dissolver
41 casing
44 Injection nozzle
50 Inlet
51 Outlet
54 Communication hole
55 Injection port
56 Projection tube
56a Upstream opening
57 Upstream side
58 Downstream side

Claims (6)

The gas-liquid mixed fluid is caused to flow into the casing (41) from the inlet (50) formed at the upper end, and the gas in the gas-liquid mixed fluid is dissolved in the liquid in the casing (41) to thereby become the outlet (51). A gas dissolver that flows out from
The gas-liquid mixed fluid is separated into a liquid layer and a gas layer in the casing,
An injection nozzle (44) for injecting the gas-liquid mixed fluid flowing in from the inflow port (50) into the casing (41) through a plurality of injection ports (55) is provided in the casing (41). (55) is configured such that bubbles are generated in the liquid layer when the gas-liquid mixed fluid is ejected,
The injection nozzle (44) is provided such that each injection port (55) faces the air layer in the casing (41),
The injection nozzle (44) is formed in a cylindrical shape, and has a communication hole (54) communicating with the inflow port (50) in the upstream side surface portion (57) in the center portion, and is formed by a flat plate extending in the horizontal direction. A number of pores constituting each of the injection ports (55) are provided in the circumferential direction in the peripheral portion excluding the central portion corresponding to the communication hole (54) of the downstream side surface portion (58),
The gas dissolver, wherein the jet nozzle (44) is configured to jet the gas-liquid mixed fluid from the jet port (55) in a direction not interfering with each other in the gas layer. The gas dissolver of claim 1,
The jet nozzle (44) is configured such that the gas-liquid mixed fluid is jetted vertically downward toward the liquid layer in the casing (41) from the jet port (55). Gas dissolver. The gas dissolver of claim 1,
The gas dissolver, wherein the injection nozzle (44) is configured such that the gas-liquid mixed fluid is injected from the injection port (55) at an equal flow rate. The gas dissolver of claim 1,
The jet nozzle (44) is configured such that the gas-liquid mixed fluid is jetted from the jet port (55) toward the liquid surface periphery of the liquid layer in the casing (41). Gas dissolver. The gas dissolver of claim 1,
The gas dissolver, wherein the outlet (51) is provided at a lower portion of the side surface of the casing (41). The gas dissolver of claim 5,
A protruding pipe (56) protruding into the casing (41) and having a downstream portion communicating with the outlet (51) is provided, and an upstream opening (56a) of the protruding pipe (56) is directed downward. A gas dissolver characterized by being open.

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