JP2019198857A - Gas-liquid mixer - Google Patents

Abstract

To provide a technology capable of efficiently using gas introduced into a gas-liquid mixer.SOLUTION: A gas-liquid mixer comprises: a tank having an inflow port and an outflow port; a first mixing case housed in the tank, the first mixing case comprising an agitation unit with an inner peripheral wall thereof having a rotary surface shape, an exhaust nozzle provided downstream of the agitation unit, and a water introduction passage which is open along the tangential direction of the inner peripheral wall of the agitation part; a second mixing case having a water receiving unit provided between the outflow port and the exhaust nozzle, and a cylindrical sidewall connected to the water receiving unit and extending upward from the water receiving unit; and a communication air passage which connects a layer of air collected in an upper part in the tank and the inside of the agitation unit of the first mixing case. Water flowing into the tank is introduced into the agitation unit from the inflow port via the water introduction passage of the first mixing case.SELECTED DRAWING: Figure 5

Description

  The technology disclosed in the present specification relates to a gas-liquid mixing device.

  Patent Document 1 includes a stirring portion having an inner peripheral wall having a rotating surface shape, a spout provided on the downstream side of the stirring portion, and a water introduction path that opens along the tangential direction of the inner peripheral wall of the stirring portion. There is disclosed a gas-liquid mixing device comprising: a first mixing case provided; a second mixing case provided with a stirring portion having an inner peripheral wall having a rotating surface shape; and a spout provided downstream of the stirring portion. Yes. When the gas-liquid mixed water flowing into the stirring unit of the first mixing case passes through the first mixing case and the second mixing case, the air is dissolved in water.

International Publication No. 2001/097958

  A part of the air contained in the gas-liquid mixed water flowing into the cylindrical portion of the first mixing case does not dissolve in water even if it passes through the first mixing case and the second mixing case. In the gas-liquid mixing device of Patent Document 1, air that has not dissolved in water even after passing through the first mixing case and the second mixing case (hereinafter referred to as “undissolved air”) is mixed with water. In this state, it is discharged from the second mixing case to the discharge location. In this specification, the technique which can utilize the gas in a gas-liquid mixing apparatus efficiently is provided.

  In this specification, the gas-liquid mixing apparatus which dissolves air in water is disclosed. The gas-liquid mixing apparatus includes a tank having an inlet and an outlet, a first mixing case accommodated in the tank, an agitation part having an inner peripheral wall having a rotating surface shape, and a downstream side of the agitation part A first mixing case provided with a jet port provided in the water and a water introduction path that opens along a tangential direction of the inner peripheral wall of the stirring unit, and water provided between the outlet and the jet port A second mixing case comprising: a receiving portion; and a cylindrical side wall connected to the water receiving portion and extending upward from the water receiving portion; a layer of air accumulated in the tank; A communication air path connecting the inside of the stirring unit of one mixing case, and water flowing into the tank is introduced into the stirring unit from the inlet through the water introduction path of the first mixing case. .

  According to said structure, the water which flows in into a tank flows out to the lower part of a tank through a 1st mixing case (specifically stirring part) and a 2nd mixing case, turning swirling air. . A swirl flow is formed in the first mixing case and the second mixing case. The water ejected from the outlet of the first mixing case into the second mixing case collides with the water receiving part of the second mixing case, and then rises along the side wall of the second mixing case, and the upper end of the side wall is Through the bottom of the tank. In this case, the undissolved air is separated from the water while the water jetted into the second mixing case travels along the side wall of the second mixing case and when the water is reversed from the upward flow to the downward flow. The air separated from the water moves to the upper air layer in the tank. For this reason, the amount of undissolved air contained in the water flowing out from the outlet of the tank can be reduced. Then, air is taken into the water in the first mixing case from the upper air layer in the tank through the communication air path. Therefore, the air in the gas-liquid mixing device can be used efficiently.

  The diameter of the inner peripheral wall of the stirring unit may be reduced as it approaches the spout.

  According to said structure, the turning speed of the water in the stirring part of a 1st mixing case can be accelerated. The amount of air dissolved in water (hereinafter referred to as “dissolved air amount”) depends on the swirling speed of water. Therefore, the amount of dissolved air in the gas-liquid mixing device can be increased.

  The tank may include a water outflow path that protrudes upward from the bottom of the tank and includes an outlet. The gas-liquid mixing device may further include a shielding member that surrounds the upper side and the side of the water outflow path, and the lower end of the shielding member may be located below the upper end of the water outflow path.

  While the water jetted in the second mixing case rises in the second mixing case and when the water is reversed from the upward flow to the downward flow, a part of the undissolved air may not be separated from the water. The water that flows into the lower part of the tank from the inside of the second mixing case including undissolved air cannot be directly flowed into the water outflow path by being blocked by the shielding member. For this reason, the water flowing out to the lower part of the tank flows around the lower end of the shielding member and flows upward, and flows out to the outside of the tank through the upper end of the water outflow path and the outlet. After the water flowing out to the lower part of the tank becomes an upward flow, it reverses and becomes a downward flow, and while reaching the upper end of the water outflow path, the undissolved air is separated from the water and becomes a layer of air in the tank. Can move. For this reason, the amount of undissolved air contained in the water flowing out from the outlet of the tank can be further reduced, and the air in the gas-liquid mixing device can be utilized more efficiently.

  The gas-liquid mixing device may further include a collision wall that is provided above the side wall of the second mixing case and changes the direction of the flow path of the water that flows upward from the second mixing case.

  When the water rising along the side wall of the second mixing case reaches the upper end of the side wall, the direction of the upward flow is changed from the downward flow to the downward flow, and the upward flow is maintained. And water flowing upward from the second mixing case. The water flowing upward from the second mixing case while maintaining the upward flow can reach the upper air layer in the tank. In this case, the water that flows upward from the second mixing case and reaches the air layer passes through the communication air path. By passing the water through the communication air path, the amount of air taken into the stirring unit through the communication air path is reduced. According to said structure, the water which flows out upward from a 2nd mixing case in the state which maintained the flow of the upward flow collides with a collision wall, and changes its direction from an upward flow to a downward flow. Therefore, it is possible to prevent the water flowing upward from the second mixing case while maintaining the upward flow from reaching the air layer. As a result, it is possible to prevent a reduction in the amount of air taken into the stirring unit from the air layer through the communication air path.

  Moreover, in this specification, the gas-liquid mixing apparatus which dissolves gas in water is disclosed. The gas-liquid mixing apparatus includes a tank having an inlet and an outlet, a first mixing case accommodated in the tank, an agitation part having an inner peripheral wall having a rotating surface shape, and a downstream side of the agitation part A first mixing case provided with a jet port provided in the water and a water introduction path that opens along a tangential direction of the inner peripheral wall of the stirring unit, and water provided between the outlet and the jet port A second mixing case comprising: a receiving portion; and a cylindrical side wall connected to the water receiving portion and extending upward from the water receiving portion; a layer of gas accumulated in the tank; A continuous air passage connecting the inside of the stirring unit of one mixing case, and water flowing into the tank is introduced into the stirring unit from the inlet through the water introduction path of the first mixing case. .

  According to said structure, the water which flows in into a tank flows out into the lower part of a tank through a 1st mixing case (specifically stirring part) and a 2nd mixing case, turning, entraining gas. . A swirl flow is formed in the first mixing case and the second mixing case. The water ejected from the outlet of the first mixing case into the second mixing case collides with the water receiving part of the second mixing case, and then rises along the side wall of the second mixing case, and the upper end of the side wall is Through the bottom of the tank. In this case, while the water jetted into the second mixing case is traveling along the side wall of the second mixing case and when reversing from the upward flow to the downward flow, the gas that has not dissolved in the water (hereinafter, Called “undissolved gas”) is separated from the water. The gas separated from the water moves to the upper gas layer in the tank. For this reason, the amount of undissolved gas contained in the water flowing out from the outlet of the tank can be reduced. And gas is taken in into the water in a 1st mixing case from the upper gas layer in a tank via a continuous ventilation path. Therefore, the gas in the gas-liquid mixing device can be used efficiently.

It is a perspective view of the gas-liquid mixing apparatus 2 which concerns on 1st Embodiment. It is an exploded view of the gas-liquid mixing apparatus 2 which concerns on 1st Embodiment. It is a top view of the gas-liquid mixing apparatus 2 which concerns on 1st Embodiment. It is sectional drawing of the gas-liquid mixing apparatus 2 along the IV-IV line of FIG. It is sectional drawing of the gas-liquid mixing apparatus 2 along the VV line of FIG. It is sectional drawing of the gas-liquid mixing apparatus 2 along the VI-VI line of FIG. It is a figure which shows the structure of the 1st mixing case 60 which concerns on 1st Embodiment. It is a figure which shows the structure of the 2nd mixing case 90 which concerns on 1st Embodiment. It is a figure which shows the structure of the case cover 40 which concerns on 1st Embodiment. It is a figure which shows the structure of the water supply system 202 which concerns on 1st Example. It is a figure which shows the structure of the water supply system 502 which concerns on 2nd Example. It is sectional drawing of the gas-liquid mixing apparatus 2 which concerns on a 1st modification. It is sectional drawing of the gas-liquid mixing apparatus 802 which concerns on 2nd Embodiment. It is a figure which shows the structure of the 1st mixing case 860 which concerns on 2nd Embodiment. It is a figure which shows the structure of the 2nd mixing case 890 which concerns on 2nd Embodiment. It is a figure which shows the structure of the case cover 840 which concerns on 2nd Embodiment.

(First embodiment)
(Configuration of gas-liquid mixing device 2)
With reference to FIGS. 1-9, the gas-liquid mixing apparatus 2 of 1st Embodiment is demonstrated. FIG. 1 is a perspective view showing an external appearance of the gas-liquid mixing device 2, FIG. 2 is an exploded view of the gas-liquid mixing device 2, and FIG. 3 is a top view of the gas-liquid mixing device 2. FIG. 4 is a cross-sectional view of the gas-liquid mixing device 2 taken along line IV-IV in FIG. 5 and 6 are cross-sectional views of the gas-liquid mixing apparatus 2 taken along lines VV and VI-VI in FIG. 3, respectively. As shown in FIG. 2, the gas-liquid mixing device 2 includes a tank 10, a case cover 40, a first mixing case 60, a second mixing case 90, and a connection path 120. The tank 10, the case cover 40, the first mixing case 60, and the second mixing case 90 are arranged so that the central axis of each device coincides with the central axis C1.

  As shown in FIGS. 5 and 6, the case cover 40, the first mixing case 60, the second mixing case 90, and the connection path 120 are accommodated in the tank 10. The second mixing case 90 is attached to the tank 10. The case cover 40 and the first mixing case 60 are connected to the second mixing case 90.

(Configuration of tank 10)
The configuration of the tank 10 will be described with reference to FIGS. 1 to 4, the Z axis is an axis parallel to the central axis C <b> 1 (see FIG. 2). The X axis is an axis orthogonal to the Z axis. The Y axis is an axis orthogonal to the X axis and the Z axis. As shown in FIG. 1, the tank 10 includes a tank upper portion 12 and a tank lower portion 26. The tank upper portion 12 includes a cylindrical portion 14, an upper bottom portion 16, and a water inflow path 18. The cylindrical portion 14 has a cylindrical shape. A flange portion 22 extending outward is provided at the lower portion of the cylindrical portion 14. The flange portion 22 is provided with four mounting holes B1. The mounting hole B1 of the flange portion 22 is a hole for screwing the tank upper portion 12 and the tank lower portion 26 with screws. The upper bottom portion 16 has a dome shape protruding upward. The diameter of the upper bottom portion 16 matches the outer diameter of the cylindrical portion 14. The upper bottom portion 16 is provided with an air introduction portion 20 having a screw hole B2 and an introduction hole 20a. An air outflow path (not shown) of the air control valve is connected to the introduction hole 20a. The screw hole B <b> 2 is a hole for screwing an air control valve (not shown) to the tank upper part 12. The water inflow channel 18 has a cylindrical shape. The water inflow path 18 extends from the outer periphery of the cylindrical portion 14 along the X-axis direction (see FIG. 3). The water inflow channel 18 includes an inflow port 18a (see FIG. 6).

  As shown in FIG. 5, a high water level electrode 34 a and a low water level electrode 34 b for detecting the water level of water stored in the tank 10 are installed at the lower end of the upper bottom portion 16 of the tank upper portion 12. The first water level detected by the high water level electrode 34a is higher than the second water level detected by the low water level electrode 34b. In addition, the lower end of the high water level electrode 34a is located below the lower end of the notch part 96d of the 2nd mixing case 90 through which the water introduction path 70 of the 1st mixing case 60 mentioned later passes. In the modification, the lower end of the high water level electrode 34a may be located above the lower end of the notch 96d.

  As shown in FIG. 1, the tank lower portion 26 includes a cylindrical portion 28, a lower bottom portion 30, and a water outflow path 32. The cylindrical portion 28 has a cylindrical shape. The outer diameter of the cylindrical portion 28 is slightly smaller than the inner diameter of the cylindrical portion 14 of the tank upper portion 12 but substantially matches (see FIGS. 5 and 6). A flange portion 34 extending outward is provided at the upper portion of the cylindrical portion 28. The flange portion 34 is provided with four screw holes B3 (see FIG. 2). The screw hole B3 of the flange portion 34 is provided at a position corresponding to the mounting hole B1 provided in the flange portion 22 of the tank upper portion 12, and is used for screwing the tank upper portion 12 and the tank lower portion 26. By inserting a screw member (not shown) into the mounting hole B1 of the flange portion 22 and screwing the screw member into the screw hole B3 of the flange portion 34, the tank upper portion 12 and the tank lower portion 26 are connected. The lower bottom part 30 has a dome shape protruding downward. The diameter of the lower bottom portion 30 matches the outer diameter of the cylindrical portion 28. The water outflow passage 32 passes through the center of the lower bottom portion 30 and is provided integrally with the lower bottom portion 30. The water outflow path 32 includes an outflow port 32a (see FIG. 5).

(Configuration of the first mixing case 60)
The first mixing case 60 will be described with reference to FIGS. FIG. 7A is a perspective view of the first mixing case 60, and FIG. 7B is a top view of the first mixing case 60 as viewed from above. As shown in FIG. 7A, the first mixing case 60 includes a stirring part 62, a lower bottom part 64, and a water introduction path 70. The stirring unit 62 has a cylindrical shape. The outer diameter and inner diameter of the stirring unit 62 are smaller than the inner diameter of the cylindrical portion 14 of the tank upper portion 12 and the inner diameter of the cylindrical portion 28 of the tank lower portion 26 (see FIGS. 5 and 6). A flange portion 66 extending toward the outside is provided on the upper portion of the stirring portion 62. Two protrusions 66 a for aligning the case cover 40 are provided on the upper surface of the flange portion 66.

  As shown in FIG. 4, the water introduction path 70 is provided along the tangential direction of the inner peripheral wall of the stirring unit 62. The water introduction path 70 includes an opening 70a.

  As shown in FIG. 7A, the lower bottom portion 64 has a disk shape. The outer diameter of the lower bottom portion 64 matches the outer diameter of the stirring portion 62. A jet port 64a is provided at the center of the lower bottom portion 64 (see FIGS. 5 and 7B).

(Configuration of the second mixing case 90)
The second mixing case 90 will be described with reference to FIGS. 4 to 6 and FIG. FIG. 8A is a perspective view of the second mixing case 90, and FIG. 8B is a top view of the second mixing case 90 as viewed from above. As shown in FIG. 8A, the second mixing case 90 includes a cylindrical portion 92, four annular pieces 94, and a water receiving portion 100 (see FIG. 5).

  As shown in FIG. 5, the water receiving part 100 is provided in the inside of the cylindrical part 92, and has a disk shape in which a center part protrudes upwards. A small communication hole 100 a is formed at the center of the water receiving portion 100. The cylindrical portion 92 includes a first cylindrical portion 92 a above the water receiving portion 100 and a second cylindrical portion 92 b below the water receiving portion 100. The inner diameter of the cylindrical portion 92 is larger than the outer diameter of the stirring portion 62 of the first mixing case 60. That is, a gap is provided between the first cylindrical portion 92 a and the stirring portion 62 of the first mixing case 60. Further, the inner diameter of the annular piece 94 is larger than the outer diameter of the flange portion 66 of the first mixing case 60. The lower end of the second cylindrical portion 92 b is provided below the upper end of the water outflow path 32 of the tank lower portion 26. The communication hole 100a also functions as a water outflow hole for allowing the water in the first cylindrical portion 92a above the water receiving portion 100 to flow downward during the air introduction operation described later, It also functions as an air escape hole for introducing the air accumulated in the second cylindrical portion 92b below the water receiving portion 100 during the first water supply operation for dissolving the water into the first cylindrical portion 92a.

  As shown in FIG. 8A, a single flange portion 98 extending outward is provided on the upper portion of the first cylindrical portion 92a. The flange portion 98 is provided with a screw hole B4. The screw hole B4 is a screw hole for screwing the tank upper part 12 and the second mixing case 90 together. The second mixing case 90 is attached to the tank upper portion 12 by aligning the screw hole B4 of the flange portion 98 with the mounting hole (not shown) inside the tank upper portion 12 and screwing a screw member (not shown). be able to.

  Between the annular pieces 94, four notches 96a to 96d are formed. The inner diameter of the annular piece 94 is slightly larger than the outer diameter of the flange portion 66 of the first mixing case 60 (see FIGS. 5 and 6). The inner diameter of the annular piece 94 is larger than the inner diameter of the cylindrical portion 92, and a step is formed (see FIGS. 5 and 6). The notches 96a to 96d are provided at equal intervals in the circumferential direction. The lower end of the notch 96d is formed below the lower ends of the notches 96a to 96c. Moreover, the circumferential length of the notch 96d is larger than the circumferential length of the notches 96a to 96c (see FIG. 8B) so that the water introduction path 70 of the first mixing case 60 can pass through. It is formed (see FIG. 5). The two annular pieces 94 located between the notch 96a and the notch 96b and between the notch 96c and the notch 96d are provided with fitting holes 94a.

(Configuration of case cover 40)
The case cover 40 will be described with reference to FIGS. 4 to 6 and 9. FIG. 9A is a perspective view of the case cover 40, and FIG. 9B is a top view of the case cover 40 as viewed from above. As shown in FIG. 9A, the case cover 40 includes an annular portion 42, a disc portion 46, a cylindrical portion 48, and a communication air path 50. The outer diameter of the annular portion 42 is slightly smaller than the inner diameter of the annular piece 94 of the second mixing case 90 (see FIGS. 5 and 6). The annular portion 42 is provided with notches 42 a to 42 d at positions corresponding to the notches 96 a to 96 d of the second mixing case 90. In the annular portion 42, protruding portions 44 are provided between the cutout portion 42a and the cutout portion 42b, and between the cutout portion 42a and the cutout portion 42b, respectively. The two protruding portions 44 correspond to the two fitting holes 94 a of the second mixing case 90. After placing the first mixing case 60 on the step at the upper end of the cylindrical portion 92 of the second mixing case 90, the protruding portion 44 of the case cover 40 is fitted into the fitting hole 94 a of the second mixing case 90, thereby The first mixing case 60 and the case cover 40 are connected to the second mixing case 90.

  The cylindrical portion 48 has a cylindrical shape. The outermost diameter of the cylindrical portion 48 substantially matches the inner diameter of the stirring portion 62 of the first mixing case 60 (see FIGS. 5 and 6). The cylindrical portion 48 is inserted into the stirring portion 62 in a state where a seal member (not shown) is attached (see FIGS. 5 and 6).

  The communication air passage 50 passes through the central portion of the disc portion 46 and is provided integrally with the disc portion 46. The communication air path 50 includes a communication hole 50a. The upper end 50b of the communication air passage 50 is located above the annular portion 42, and is located in the air layer 52 above the tank 10 (see FIG. 5). The lower end 50c of the communication air path 50 protrudes slightly above the upper end of the water introduction path 70 of the first mixing case 60 (see FIG. 5).

(Configuration of connecting path 120)
The connecting path 120 will be described with reference to FIGS. As shown in FIG. 4, the connection path 120 connects the water inflow path 18 of the tank upper part 12 and the water introduction path 70 of the first mixing case 60. The connection path 120 has a cylindrical shape. The outer diameter of the connection path 120 substantially matches the inner diameter of the water inflow path 18 and the water introduction path 70. The connection path 120 is inserted into the water inflow path 18 and the water introduction path 70 with a seal member (not shown) attached. In addition, the central axis of the water inflow path 18 of the tank 10, the connection path 120, and the water introduction path 70 of the 1st mixing case 60 corresponds to the central axis C2 (refer FIG. 4).

  Next, with reference to FIG. 5 and FIG. 6, a situation where air is dissolved in water in the gas-liquid mixing apparatus 2 will be described. The solid line arrows in FIGS. 5 and 6 indicate water flow paths, and the broken line arrows indicate air paths. Water pressurized by a pump (not shown) (or water in which water and air are mixed) passes through the water inflow path 18 of the tank 10, the connection path 120, and the water introduction path 70 of the first mixing case 60. Then, it is introduced into the stirring unit 62 of the first mixing case 60. The water introduced into the stirring unit 62 flows downward while turning spirally in the stirring unit 62. When water turns in the stirring unit 62, a large negative pressure is generated near the center of the stirring unit 62. For this reason, the air accumulated in the air layer 52 at the upper part of the tank 10 passes through the communication air passage 50 and is taken into the stirring unit 62. The air taken into the stirring unit 62 is caught in the water swirling in the stirring unit 62. Thereby, air melt | dissolves in water and air melt | dissolution pressurization water is produced | generated. Water ejected from the ejection port 64a of the first mixing case 60 is discharged to the second mixing case 90 while maintaining a swirling flow. The discharged swirling water is mixed with air not dissolved in water (undissolved air). Then, when the water discharged | emitted to the 2nd mixing case 90 collides with the water on the water receiving part 100 of the 2nd mixing case 90 and the water receiving part 100, a part of undissolved air will melt | dissolve in water. That is, the amount of air dissolved in water (dissolved air amount) increases. The air-dissolved pressurized water that collides with the water receiving unit 100 and changes its direction flows upward through the gap between the first cylindrical portion 92a of the second mixing case 90 and the stirring unit 62 of the first mixing case 60, The second mixing case 90 flows out of the second mixing case 90 from the notches 96a to 96d. The air-dissolved pressurized water that has flowed to the outside of the second mixing case 90 flows downward in the gap between the second mixing case 90 and the inner surface of the tank 10. When the air-dissolved pressurized water flows out of the second mixing case 90, the undissolved air is separated from the water by the upward flow and the deceleration during the direction change. The air separated from the water passes through the notches 42 a to 42 d of the case cover 40, moves to the upper portion of the tank 10 located above the case cover 40, and returns to the air layer 52.

  Further, the air-dissolved pressurized water that has flowed out from the second mixing case 90 to the lower part of the tank 10 flows around the lower end of the second cylindrical portion 92b of the second mixing case 90 and flows upward. It flows out of the tank 10 through the outlet 32a. The undissolved air is separated from the water while the air-dissolved pressurized water flows around the lower end of the second cylindrical portion 92b and flows upward, and by the deceleration during the change of direction from the upward flow to the downward flow. . The air separated from the water remains in the second cylindrical portion 92 b of the second mixing case 90, that is, below the water receiving portion 100. Thereafter, the air remaining below the water receiver 100 can rise through the communication hole 100 a and return to the air layer 52.

  As described above, the water discharged from the first mixing case 60 to the second mixing case 90 rises in the gap between the first cylindrical portion 92a of the second mixing case 90 and the stirring portion 62 of the first mixing case 60. The undissolved air is separated from the water during the process and by deceleration during the turn from upward to downward flow. The air separated from the water is returned to the air layer 52 in the tank 10. For this reason, while being able to reduce the quantity of the undissolved air contained in the water which flows out from the outflow port 32a of the tank 10, the air in the gas-liquid mixing apparatus 2 can be utilized efficiently.

  Further, the water flowing out from the second mixing case 90 to the lower part of the tank 10 cannot directly flow from the upper side toward the water outflow path 32 by the second cylindrical portion 92b of the second mixing case 90, and is directed from the downward flow to the upward flow. After the conversion, the direction again changes from the upward flow to the downward flow and flows into the water outflow path 32. Undissolved air is separated from the water during the upward flow and by deceleration during the turn from upward to downward flow. The air separated from the water stays below the water receiver 100 and then moves to the air layer 52 above the tank 10 through the communication hole 100a. For this reason, the amount of undissolved air contained in the water flowing out from the outlet 32a of the tank 10 can be further reduced, and the air in the gas-liquid mixing device 2 can be utilized more efficiently.

(Correspondence)
The first cylindrical portion 92a is an example of “a cylindrical side wall of the second mixing case”. The second cylindrical portion 92b and the water receiving portion 100 are examples of the “shielding member”. In the present embodiment, the water receiver 100 is an example of a “water receiver” and also an example of a part of a “shielding member”.

(Second Embodiment)
Subsequently, the gas-liquid mixing device 802 of the second embodiment will be described with reference to FIGS. In the gas-liquid mixing device 802 of the present embodiment, the structures (case cover 840, first mixing case 860, and second mixing case 890) housed in the tank 10 are the same as those in the first embodiment. It is different from the structure (case cover 40, first mixing case 60, second mixing case 90) housed in the tank 10 of the liquid mixing apparatus. Below, about the structure (tank 10, connection path 120) common between embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted.

(Configuration of first mixing case 860)
The first mixing case 860 will be described with reference to FIGS. 13 and 14. FIG. 14A is a perspective view of the first mixing case 860, and FIG. 14B is a top view of the first mixing case 860 as viewed from above. As shown in FIG. 14A, the first mixing case 860 includes a stirring portion 862, a lower bottom portion 864, a cylindrical portion 868, and a water introduction path 870. The outer diameter and inner diameter of the stirring unit 862 are smaller than the inner diameter of the cylindrical portion 14 of the tank upper portion 12 and the inner diameter of the cylindrical portion 28 of the tank lower portion 26 (see FIG. 13). The cylindrical portion 868 has a cylindrical shape. The outermost diameter of the cylindrical portion 868 is slightly larger than the outer diameter of the stirring portion 862. A flange portion 866 extending outward is provided at a connection portion between the stirring portion 862 and the cylindrical portion 868. The flange portion 866 is provided with two projecting portions 866a for aligning the case cover 840. The water introduction path 870 is provided along the tangential direction of the inner peripheral wall of the stirring unit 862. The water introduction path 870 includes an opening 870a.

(Configuration of second mixing case 890)
The second mixing case 890 will be described with reference to FIGS. 13 and 15. FIG. 15A is a perspective view of the second mixing case 890, and FIG. 15B is a top view of the second mixing case 890 viewed from above. As illustrated in FIG. 15A, the second mixing case 890 includes a cylindrical portion 892, four annular pieces 894, and a water receiving portion 900. The inner diameter of the cylindrical portion 892 is larger than the outer diameter of the stirring portion 862 of the first mixing case 860 (see FIG. 13). That is, a gap is provided between the cylindrical portion 892 and the stirring portion 862. Moreover, the outer diameter of the cylindrical part 892 is smaller than the outer diameter of the flange part 866 of the 1st mixing case 860 (refer FIG. 13). The inner diameter and outer diameter of the annular piece 894 coincide with the inner diameter and outer diameter of the cylindrical portion 892 (see FIG. 13). Four notches 896a to 896d are formed between the four annular pieces 894a to 894d. The lower end of the notch 896d is formed below the lower ends of the notches 896a to 896c. Further, as shown in FIG. 15B, the circumferential length of the notch 896d is larger than the circumferential length of the notches 896a to 896c, and the water introduction path 870 of the first mixing case 860 can pass through. It is formed as follows. The annular pieces 894a and 894c are provided with protruding portions 898a and 898c.

  The water receiver 900 has a disk shape. As shown in FIG. 15 (b), a small communication hole 900 a is formed at the center of the water receiving portion 900. The outer diameter of the water receiving portion 900 matches the outer diameter of the cylindrical portion 892 (see FIG. 13).

  As shown in FIGS. 15A and 15B, four placement portions 902 a to 902 d extending outward are provided at the lower portion of the cylindrical portion 892. The outermost diameter of the mounting portion 902 is larger than the inner diameter of the cylindrical portion 28 of the tank lower portion 26. In a state where the tank 10 and the second mixing case 890 are connected, the placement unit 902 is placed on the tank lower portion 26.

(Configuration of case cover 840)
The case cover 840 will be described with reference to FIGS. 13 and 16. 16A is a perspective view of the case cover 840, and FIG. 16B is a top view of the case cover 840 as viewed from above. As shown in FIG. 16A, the case cover 840 includes an annular portion 842, an inclined portion 844, an upper bottom portion 846, and a communication air path 850. The outer diameter of the annular portion 842 is larger than the outer diameter of the cylindrical portion 892 of the second mixing case 890 and smaller than the inner diameter of the cylindrical portion 14 of the tank upper portion 12 (see FIG. 13). As shown in FIG. 16B, the annular portion 842 is provided with fitting portions 842 a and 842 c at positions corresponding to the protruding portions 898 a and 898 c of the second mixing case 890. The upper bottom portion 846 has a disc shape. The outer diameter of the upper bottom portion 846 substantially matches the outer diameter of the cylindrical portion 892 of the second mixing case 890 (see FIG. 13). The upper bottom portion 846 is provided with two projecting portions 848 for aligning the tank upper portion 10. The inclined portion 844 connects the annular portion 842 and the upper bottom portion 846. The inclined portion 844 is inclined so that the lower portion is inclined outward. The lower end of the inclined portion 844 is located above the upper end of the second mixing case 890.

  The communication air passage 850 passes through the center portion of the upper bottom portion 846 and is provided integrally with the upper bottom portion 846. The communication air path 850 includes a communication hole 850a. The upper end 850b of the communication air path 850 is located in the air layer 852 at the upper part of the tank 10 (see FIG. 13). The lower end 850c of the communication air path 850 is located in the upper part in the stirring part 862 of the 1st mixing case 860 (refer FIG. 13).

(Configuration of water level electrodes 834a and 834b)
As shown in FIG. 13, a high water level electrode 834 a and a low water level electrode 834 b for detecting the water level of water stored in the tank 10 are installed at the lower end of the upper bottom portion 16 of the tank upper portion 12. The first water level detected by the high water level electrode 834a is higher than the second water level detected by the low water level electrode 834b. The lower end of the high water level electrode 834 a is located in the air layer 852 at the upper part of the tank 10, and the lower end of the low water level electrode 834 b is located below the lower end of the second mixing case 890.

  The gas-liquid mixing device 802 of the present embodiment is characterized by the movement of air-dissolved pressurized water that flows out from the second mixing case 890 with respect to the gas-liquid mixing device 2 of the first embodiment. For this reason, with reference to FIG. 13, the movement of the air dissolution pressurized water which flows out from the 2nd mixing case 890 is mainly demonstrated. A solid line arrow in FIG. 13 indicates a water flow path, and a broken line arrow indicates an air path. The air-dissolved pressurized water discharged from the jet port 864a of the first mixing case 860 to the second mixing case 890 collides with the water receiving portion 900 and changes direction, and the cylindrical portion 892 of the second mixing case 890 and the first mixing case. The gap between the stirring portions 862 of 860 flows upward. The air-dissolved pressurized water flows out of the second mixing case 890 from the notches 896a to 896d of the second mixing case 890. The air-dissolved pressurized water flowing out from the second mixing case 890 maintained the upward flow with the air-dissolved pressurized water (see arrow A1) that diverts from the upward flow to the downward flow and flows downward from the second mixing case 890. In this state, it is separated into air-dissolved pressurized water (see arrow A2) that flows upward from the second mixing case. And in the water which flows out in the direction of arrow A1, undissolved air isolate | separates from water by the deceleration at the time of the direction change from an upward flow to a downward flow. The air separated from the water passes between the cylindrical portion 14 of the tank upper portion 12 and the case cover 840, moves to the upper portion of the tank 10 located above the case cover 840, and returns to the air layer 852. Also, the air-dissolved pressurized water that flows out in the direction of the arrow A2 changes direction by colliding with the inclined portion 844 of the case cover 840 and flows downward (see arrow A3).

  Even with such a configuration, the amount of undissolved air contained in the water flowing out from the outlet 32a of the tank 10 can be reduced, and the air in the gas-liquid mixing device 802 can be efficiently utilized. .

  Further, the air-dissolved pressurized water (see arrow A2 in FIG. 13) that flows upward from the second mixing case 890 while maintaining the upward flow is changed in direction by colliding with the inclined portion 844 of the case cover 840, and downward. (See arrow A3). For this reason, it is possible to prevent the air-dissolved pressurized water from reaching the air layer 852 in the upper part of the tank 10. Accordingly, it is possible to prevent the air-dissolved pressurized water flowing upward from the second mixing case 890 from reaching the air layer 852. As a result, it is possible to prevent the amount of air taken into the stirring unit 862 from the air layer 852 through the communication air path 850 from being reduced.

  Further, the air-dissolved pressurized water (see arrow A2 in FIG. 13) that flows upward from the second mixing case while maintaining the upward flow is in contact with the high water level electrode 834a provided in the upper part of the tank 10. Can be prevented.

(Correspondence)
The cylindrical portion 892 of the second mixing case 890 is an example of “a cylindrical side wall of the second mixing case”. The inclined portion 844 of the case cover 840 is an example of a “collision wall”.

(1st Example of the water supply system using the gas-liquid mixing apparatus 2)
With reference to FIG. 10, the 1st Example of the water supply system using the gas-liquid mixing apparatus 2 of 1st Embodiment is demonstrated. The water supply system 202 is a system that supplies air-dissolved pressurized water generated by the gas-liquid mixing device 2 to the bathtub 330 and generates fine bubbles in the bathtub 330.

(Configuration of water supply system 202)
As shown in FIG. 10, the water supply system 202 includes a heat source unit 210, a fine bubble generation unit 250, a bathtub 330, and a control device 350. The heat source unit 210 is connected to the water supply source 400, the hot water outlet 402, and the fine bubble generating unit 250. The fine bubble generating unit 250 is connected to the heat source unit 210 and the bathtub 330. In the following, a case where water flows in the direction of the arrow shown in FIG. 10 will be described as an example.

(Configuration of heat source unit 210)
The heat source unit 210 is a unit for heating the water supplied from the water supply source 400 and supplying the heated water to the hot water outlet 402 and the bathtub 330. The heat source unit 210 includes a first heat source unit 212, a second heat source unit 214, a water supply channel 220, a tapping channel 222, a branch channel 226, a first return channel 228, and a first forward channel 230. .

  The upstream end of the water supply channel 220 is connected to a water supply source 400 such as a city water supply, and the downstream end of the water supply channel 220 is connected to the first heat source machine 212. The first heat source unit 212 is a gas heat source unit that heats water passing through the first heat source unit 212.

  The upstream end of the hot water outlet 222 is connected to the first heat source machine 212. The downstream end of the hot water outlet 222 is connected to a hot water outlet 402 such as a currant. A branch water passage 226 connected to the first return water passage 228 is connected to the hot water supply passage 222. A hot water filling valve 232 is provided in the branch water channel 226. The hot water filling valve 232 is a valve that controls the flow of water from the tap water passage 222 to the first return water passage 228.

  The upstream end of the first return water channel 228 is connected to the fine bubble generating unit 250 (specifically, the second return water channel 260), and the downstream end is connected to the second heat source unit 214. In the first return water channel 228, a first pump 234 and a water flow switch 236 are provided between the connection between the first return water channel 228 and the branch water channel 226 and the second heat source unit 214. The first pump 234 is provided on the upstream side of the water flow switch 236 and sends the water in the first return water channel 228 to the downstream side. The water flow switch 236 detects that water is passing through the first return water channel 228. The second heat source unit 214 is a gas heat source unit that heats water passing through the second heat source unit 214.

  The upstream end of the first outgoing water channel 230 is connected to the second heat source unit 214, and the downstream end is connected to the fine bubble generating unit 250 (specifically, the second outgoing water channel 268).

(Configuration of the fine bubble generating unit 250)
The fine bubble generating unit 250 includes the gas-liquid mixing device 2, the second return water channel 260, the second forward water channel 268, the water supply channel 274, and the air introduction channel 300.

  The upstream end of the second return water channel 260 is connected to the first three-way valve 280, and the downstream end is connected to the heat source unit 210 via the first return water channel 228. The second return water channel 260 is connected to the downstream end of the communication passage 266 whose upstream end is connected to the second three-way valve 282. One end of the third return water channel 262 is connected to the first three-way valve 280, and the other end is connected to the bathtub 330. The upstream end of the ejection water channel 264 is connected to the gas-liquid mixing device 2 (specifically, the water outflow channel 32 of the tank 10), and the downstream end is connected to the first three-way valve 280. A water supply control valve 284 is provided in the ejection water channel 264. As described above, the second return water channel 260, the third return water channel 262, and the ejection water channel 264 are connected to the first three-way valve 280. The first three-way valve 280 can switch between a fine bubble supply state in which water flows from the ejection channel 264 to the third return channel 262 and a recirculation state in which water flows from the third return channel 262 to the second return channel 260. . Note that a decompression nozzle 332 is provided at a connection portion between the third return water channel 262 and the bathtub 330. Although not shown, the decompression nozzle 332 is provided with a water suction port for sucking water in the bathtub 330 and a pressurized water discharge port for discharging air-dissolved pressurized water into the bathtub 330. A check valve body and the like corresponding to each of the water suction port and the pressurized water discharge port are provided. In the fine bubble supply state, only the check valve body corresponding to the pressurized water discharge port is opened.

  The upstream end of the second outgoing water channel 268 is connected to the heat source unit 210 via the first outgoing water channel 230, and the downstream end is connected to the second three-way valve 282. One end of the third forward water channel 270 is connected to the bathtub 330, and the other end is connected to the second three-way valve 282. That is, the second three-way valve 282 is connected to the communication path 266, the second forward water path 268, and the third forward water path 270. The second three-way valve 282 can switch between a fine bubble supply state in which water flows from the third forward water passage 270 to the communication passage 266 and a recirculation state in which water flows from the second forward water passage 268 to the third forward water passage 270. .

  The upstream end of the water supply path 274 is connected to the second forward water path 268, and the downstream end of the water supply path 274 is connected to the gas-liquid mixing device 2 (specifically, the water inflow path 18 of the tank 10). ing. A second pump 286 is provided in the water supply path 274.

  An air introduction path 300 is connected to the gas-liquid mixing device 2 (specifically, the air introduction unit 20 of the tank 10). The air introduction path 300 is provided with an air pump 302 and a check valve 304. When the air pump 302 is driven, air is introduced into the gas-liquid mixing device 2.

(Configuration of control device 350)
The control device 350 controls the operation of each component of the heat source unit 210 and the fine bubble generating unit 250. The control device 350 is configured to be able to communicate with a remote controller (not shown) that can be operated by the user. The control device 350 can execute a fine bubble supply operation, a chasing operation, and a hot water operation in accordance with an operation on the remote controller by the user. The water supply system 202 is characterized by a fine bubble supply operation. The control device 350 receives an ON signal when the water level electrodes 34 a and 34 b (see FIG. 5) contact the water surface of the water stored in the tank 10. Hereinafter, the state in which the control device 350 receives the ON signal from the water level electrodes 34a and 34b is expressed as the water level electrodes 34a and 34b being ON, and the control device 350 receives the ON signal from the water level electrodes 34a and 34b. A state in which the water level electrodes 34a and 34b are OFF is expressed as a state where the water level electrodes 34a and 34b are OFF.

(Operation of the water supply system 202)
Subsequently, the operation of the water supply system 202 will be described. Hereinafter, a hot water filling operation, a reheating operation, and a fine bubble supply operation performed by the water supply system 202 will be described in order. At the time when each operation is started, the first three-way valve 280 and the second three-way valve 282 are in a recirculation state. Moreover, the drive of the 1st pump 234 and the 2nd pump 286 is stopped, and the hot water filling valve 232 and the water supply control valve 284 are closed.

(Hot water operation)
The hot water filling operation is an operation in which water supplied from the water supply source 400 is heated and supplied to the bathtub 330. When an operation for instructing execution of the hot water filling operation is performed by the user on the remote controller, the control device 350 switches the hot water filling valve 232 from the closed state to the open state, and drives the first heat source device 212. Thereby, the water supplied from the water supply source 400 is supplied to the water supply channel 220, the first heat source device 212, the hot water supply channel 222, the branch water channel 226, the first return water channel 228, the second heat source device 214, the first forward water channel 230, and the first. The water is supplied to the bathtub 330 through the second outgoing water channel 268 and the third outgoing water channel 270. That is, the water heated by the first heat source device 212 is supplied to the bathtub 330. When the integrated flow rate of the water supplied to the bathtub 330 reaches a predetermined amount of water, the control device 350 switches the hot water filling valve 232 from the open state to the closed state, and stops the driving of the first heat source device 212. As a result, the hot water filling operation ends.

(Reaping driving)
The chasing operation is an operation in which the water stored in the bathtub 330 is heated by the second heat source unit 214. When an operation for instructing execution of the chasing operation is performed on the remote controller by the user, the control device 350 drives the first pump 234. Thereby, the water in the bathtub 330 is supplied to the second heat source unit 214 through the third return water channel 262, the second return water channel 260, and the first return water channel 228. Then, the water heated by the second heat source device 214 is supplied to the bathtub 330 through the first outgoing water channel 230, the second outgoing water channel 268, and the third outgoing water channel 270. The control device 350 stops the driving of the second heat source unit 214 and the first pump 234 when the temperature in the bathtub 330 reaches the set temperature or when a predetermined time elapses. This ends the chasing operation.

(Microbubble supply operation)
The fine bubble supply operation is an operation for generating air-dissolved pressurized water in the gas-liquid mixing apparatus 2 and supplying the generated air-dissolved pressurized water to the bathtub 330. When an operation for instructing execution of the fine bubble supply operation is performed on the remote controller by the user, the control device 350 starts the fine bubble supply operation. The fine bubble supply operation includes an air introduction operation and a first water supply operation.

(Air introduction operation)
The air introduction operation is an operation started when the water level in the gas-liquid mixing apparatus 2 is equal to or higher than the first water level at which the high water level electrode 34a is ON. In addition, after the control device 350 starts the fine bubble supply operation, when the water level of the gas in the gas-liquid mixing device 2 is changed from the state below the first water level to the state above the first water level, The water supply control valve 284 is switched from the closed state to the open state. The control device 350 keeps the water supply control valve 284 in the open state until an operation for instructing the user to stop the fine bubble supply operation is performed on the remote controller.

  In the air introduction operation, the control device 350 stops driving the first pump 234 and the second pump 286 and drives the air pump 302. As a result, air is introduced into the gas-liquid mixing device 2, and water in the gas-liquid mixing device 2 flows out from the outlet 32a, so that the water level in the gas-liquid mixing device 2 decreases. During the air introduction operation, the water in the first cylindrical portion 92a of the second mixing case 90 flows out to the lower part of the tank 10 through the communication hole 100a. The control device 350 determines that the water level in the gas-liquid mixing device 2 is equal to or higher than the first water level, and then the water level in the gas-liquid mixing device 2 is the second level in which the low water level electrode 34b is OFF. The air introduction operation is executed until it is determined that the water level is lower than the water level. In the air introduction operation, air-dissolved pressurized water is not generated.

(First water supply operation)
The first water supply operation is an operation started when the water level in the gas-liquid mixing device 2 is lower than the second water level at which the low water level electrode 34b is OFF. The control device 350 stops driving the air pump 302 while driving the first pump 234 and the second pump 286.

  In the first water supply operation, the water that has flowed into the gas-liquid mixing device 2 spirally swirls within the stirring unit 62 while entraining air taken into the stirring unit 62 of the first mixing case 60 from the air layer 52. And when the water which flowed into the gas-liquid mixing apparatus 2 passes the 1st mixing case 60, and when it collides with the water receiving part 100 of the 2nd mixing case 90, air melt | dissolves in water. That is, air-dissolved pressurized water is generated in the tank 10. The air-dissolved pressurized water generated in the tank 10 is supplied to the bathtub 330 through the ejection water channel 264, the third return water channel 262, and the decompression nozzle 332. The air-dissolved pressurized water released into the bathtub 330 is rapidly depressurized at the moment when it passes through the depressurizing nozzle 332. In this case, air dissolved in water becomes fine bubbles having a diameter of about 20 μm. That is, a large amount of fine bubbles are generated in the bathtub 330 and the water becomes cloudy. The control device 350 determines that the water level in the gas-liquid mixing device 2 is lower than the second water level, and then determines that the water level in the gas-liquid mixing device 2 is equal to or higher than the first water level. Until the first water supply operation is executed.

  As described above, the control device 350 repeatedly performs the air introduction operation and the first water supply operation according to the water level in the gas-liquid mixing device 2.

  Note that the control device 350 stops driving the first pump 234 and the second pump 286 and opens the water supply control valve 284 when an operation for instructing the user to stop the fine bubble supply operation is performed on the remote controller. The state is switched from the closed state to the closed state, and the driving of the air pump 302 is stopped. Furthermore, the control device 350 switches the first three-way valve 280 and the second three-way valve 282 from the fine bubble supply state to the recirculation circulation. Thereby, supply of fine bubbles is completed.

  As described above, the air in the tank 10 can be efficiently used in the gas-liquid mixing device 2. Therefore, by using the gas-liquid mixing device 2 of the present embodiment, it is possible to reduce the proportion of time during which the air introduction operation is performed during the fine bubble supply operation.

(Second embodiment of a water supply system using the gas-liquid mixing device 2)
With reference to FIG. 11, the 2nd Example of the water supply system using the gas-liquid mixing apparatus 2 of 1st Embodiment is demonstrated. In the water supply system 502 of the present embodiment, the second outgoing water channel 268 and the gas-liquid mixing device 2 are connected by a water supply channel 574 (first water supply channel 574a and second water supply channel 574b), and the gas-liquid mixing device. 2 has the same configuration as that of the water supply system 202 of the first embodiment except that the air introduction path 300 is not connected to 2. In the case of the present embodiment, the air introduction part 20 is not provided in the upper bottom part 16 of the tank upper part 12. In the following, components common to the embodiments are denoted by the same reference numerals and description thereof is omitted.

  As shown in FIG. 11, the water supply path 574 is provided with a second pump 286. The upstream side of the second pump 286 of the water supply path 574 is branched in parallel with the first water supply path 574a and the second water supply path 574b, and the first water supply path 574a and the second water supply path 574b merge. Is configured to do. The water supply path 574 sends the water of the first water supply path 574a and the second water supply path 574b to the downstream side.

  A constant flow valve 590 and a venturi 592 are provided in the second water supply path 574b. The constant flow valve 590 is a valve for adjusting the ratio of the amount of water flowing through the second water supply path 574b. The venturi 592 is provided on the downstream side of the constant flow valve 590. An air introduction path 600 is connected to the venturi 592.

  The upstream end side of the air introduction path 600 is open to the atmosphere, and the downstream end is connected to the second water supply path 574b. The air introduction path 600 introduces air into the second water supply path 574b. The air introduction path 600 is provided with a check valve 602 and an air valve 604. The check valve 602 is provided on the upstream side of the air valve 604 and prevents water from being discharged through the air introduction path 600. The air valve 604 opens and closes the air introduction path 600.

(Microbubble supply operation)
In the present embodiment, the control device 350 performs the second water supply operation instead of the air introduction operation. That is, the control device 350 repeatedly executes the first water supply operation and the second water supply operation according to the water level in the gas-liquid mixing device 2. The control device 350 starts the first water supply operation when the water level in the gas-liquid mixing device 2 is lower than the second water level, and the water level in the gas-liquid mixing device 2 becomes equal to or higher than the first water level. Until the first water supply operation is executed. In the first water supply operation, the control device 350 controls the air valve 604 to be closed while the first pump 234 and the second pump 286 are being driven.

(Second water supply operation)
The control device 350 starts the second water supply operation when the water level in the gas-liquid mixing device 2 is equal to or higher than the first water level, and the water level in the gas-liquid mixing device 2 becomes less than the second water level. Until the second water supply operation. In the second water supply operation, the air valve 604 is controlled to be opened while the first pump 234 and the second pump 286 are driven. Since the air valve 604 is in the open state, air is introduced into the second water supply passage 574b through the air introduction passage 600. The air supplied to the second water supply path 574b is introduced into the gas-liquid mixing device 2. That is, the gas-liquid mixed water in which water and air are mixed flows into the gas-liquid mixing device 2 (specifically, the tank 10). In the second water supply operation, air-dissolved pressurized water can be generated using air contained in the gas-liquid mixed water and air accumulated in the air layer 52.

  Note that the pressurization capacity of the second pump 286 when the air valve 604 is open is lower than the pressurization capacity of the second pump 286 when the air valve 604 is closed. In this case, the amount of water flowing out from the gas-liquid mixing device 2 to the ejection water channel 264 is larger than the amount of water flowing into the gas-liquid mixing device 2 through the water supply channel 574, and the gas-liquid mixing device 2 The water level inside falls.

  The control device 350 performs the first water supply operation and the second water supply operation according to the water level in the gas-liquid mixing device 2, and supplies air-dissolved pressurized water to the bathtub 330.

  As described above, air-dissolved pressurized water in which a relatively large amount of air is dissolved is generated in the gas-liquid mixing device 2. Therefore, by using the gas-liquid mixing apparatus 2 of this embodiment, many fine bubbles can be generated in the bathtub 330, and the cloudiness in the bathtub 330 can be improved.

  In the first and second examples described above, the configuration in which the gas-liquid mixing device 2 of the first embodiment is employed has been described. However, the gas-liquid mixing device 802 of the second embodiment is used instead of the gas-liquid mixing device 2. May be adopted.

  Each embodiment has been described in detail above, but these are merely examples and do not limit the scope of the claims. The technology described in the claims includes various modifications and changes of the specific examples illustrated above.

(First Modification) As shown in FIG. 12, in the first mixing case 60, the stirring unit 62 may include an inclined portion 762a. The outer diameter and inner diameter of the inclined portion 762a become smaller as the nozzle 64a approaches. That is, the outer diameter and inner diameter of the inclined portion 762a are reduced from the upper side to the lower side. In this modification, the swirl speed of water in the stirring unit 62 of the first mixing case 60 can be increased. The amount of dissolved air depends on the swirling speed of water. Therefore, in this modification, the amount of dissolved air in the gas-liquid mixing device 2 can be increased.

(Second Modification) The cylindrical portion 92 of the second mixing case 90 may be configured not to include the second cylindrical portion 92b but to include only the first cylindrical portion 92a. In the present modification, the gas-liquid mixing apparatus 2 includes a lid portion as a shielding member that is separate from the second mixing case 90 between the second mixing case 90 and the lower bottom portion 30 of the tank lower portion 26. The lid portion includes a top plate portion having a disk shape, and a side wall portion extending downward from the outer peripheral end of the top plate portion. The top plate portion is provided between the water receiving portion 100 of the second mixing case 90 and the upper end of the water outflow path 32. The lower end of the side wall portion is located below the upper end of the water outflow path 32. Also in this modification, the same effect as each above-mentioned example can be produced. That is, the amount of undissolved air contained in the water flowing out from the outlet 32a of the tank 10 can be further reduced, and the air in the gas-liquid mixing device 2 can be utilized more efficiently.

(Third Modification) The “collision wall” may not be inclined. The “collision wall” may be perpendicular to the center axis C1, for example. Generally speaking, the “collision wall” only needs to prevent air-dissolved pressurized water that flows upward from the second mixing case while maintaining the upward flow from reaching the air layer 852 in the upper part of the tank 10. .

(Fourth Modification) In each of the above embodiments and examples, water mixed with water flows into the gas-liquid mixing devices 2 and 802. In a modification, instead of water mixed with water and air, water mixed with water and gas may flow into the gas-liquid mixing devices 2 and 802. For example, in the modification of the gas-liquid mixing device 2 of the first embodiment, a gas layer is formed in the upper part of the tank 10 instead of the air layer 52. Further, the case cover 40 includes a communication vent path instead of the communication air path 50. According to such a structure, the gas in the gas-liquid mixing apparatus 2 can be utilized efficiently. For example, in the modification of the first embodiment, the water supply system 202 includes a gas introduction path and a gas pump instead of the air introduction path 300 and the air pump 302. In this modification, the upstream end of the gas introduction path is connected to a tank filled with gas, and the downstream end of the gas introduction path is connected to the gas-liquid mixing device 2. In this modification, the control device 350 controls the operation of the gas pump instead of the operation of the air pump 302. Further, for example, in the modification of the second embodiment, the water supply system 502 includes a gas introduction path and a gas valve instead of the air introduction path 600 and the air valve 604. In this modification, the upstream end of the gas introduction path is connected to a tank filled with gas, and the downstream end of the gas introduction path is connected to the second water supply path 574b. In this modification, the control device 350 controls the operation of the gas valve instead of the operation of the air valve 604. “Gas” is, for example, carbon dioxide, oxygen, hydrogen or the like.

  The technical elements described in this specification or the drawings exhibit technical usefulness alone or in various combinations, and are not limited to the combinations described in the claims at the time of filing. In addition, the technology exemplified in this specification or the drawings can achieve a plurality of objects at the same time, and has technical usefulness by achieving one of the objects.

2: Gas-liquid mixing device 10: Tank 12: Tank upper part 14: Cylindrical part 16: Upper bottom part 18: Water inflow path 20: Air introduction part 20a: Introduction hole 22: Flange part 26: Lower tank part 28: Cylindrical part 30: Lower Bottom 32: Water outflow path 32a: Outlet 34: Flange 34a: High water level electrode 34b: Low water level electrode 40: Case cover 42: Annular part 42a-42d: Notch part 44: Projection part 46: Disk part 48: Cylindrical part 50: Communication air passage 50a: Communication hole 50b: Upper end 50c: Lower end 52: Air layer 60: First mixing case 62: Stirring portion 64: Lower bottom portion 64a: Jet port 66: Flange portion 66a: Protrusion 70: Water introduction passage 70a : Opening 90: Second mixing case 92: Cylindrical portion 92a: First cylindrical portion 92b: Second cylindrical portion 94: Annular piece 94a: Fitting hole 96: Notch portion 98: Flange portion 00: Water receiving part 120: Connection path 802: Gas-liquid mixing device 834a: High water level electrode 834b: Low water level electrode 840: Case cover 842: Annular part 844: Inclined part 846: Upper bottom part 850: Communication air path 850a: Communication hole 852: Air layer 860: First mixing case 862: Stirring portion 864: Lower bottom portion 864a: Jet port 866: Flange portion 866a: Protruding portion 868: Cylindrical portion 870: Water introduction path 870a: Opening 890: Second mixing case 892: Cylindrical portion 894: annular piece 896: notch portion 898: protrusion 900: water receiving portion 900a: communication hole 902: mounting portion

Claims (5)

A gas-liquid mixing device for dissolving air in water,
A tank having an inlet and an outlet;
1st mixing case accommodated in the said tank, Comprising: The stirring part which an inner peripheral wall has a rotation surface shape, the jet nozzle provided in the downstream from the said stirring part, and the tangential direction of the inner peripheral wall of the said stirring part A water introduction path that opens along the first mixing case, and
A second mixing case comprising: a water receiving portion provided between the outlet and the jet outlet; and a cylindrical side wall connected to the water receiving portion and extending upward from the water receiving portion. ,
A communication air path connecting the layer of air accumulated in the tank and the inside of the stirring portion of the first mixing case;
With
The water flowing into the tank is introduced into the agitation unit from the inlet through the water introduction path of the first mixing case.
Gas-liquid mixing device.   The gas-liquid mixing apparatus according to claim 1, wherein a diameter of an inner peripheral wall of the stirring unit is reduced as the diameter approaches the jet port. The tank
A water outflow path that protrudes upward from the lower surface of the tank and includes the outlet;
The gas-liquid mixing device further includes:
A shielding member that surrounds the upper and side of the water outflow path;
The gas-liquid mixing apparatus according to claim 1 or 2, wherein a lower end of the shielding member is positioned below an upper end of the water outflow path. The gas-liquid mixing device further includes:
4. The apparatus according to claim 1, further comprising a collision wall that is provided above a side wall of the second mixing case and changes a direction of a flow path of water that flows upward from the second mixing case. The gas-liquid mixing device described. A gas-liquid mixing device for dissolving a gas in water,
A tank having an inlet and an outlet;
1st mixing case accommodated in the said tank, Comprising: The stirring part which an inner peripheral wall has a rotation surface shape, the jet nozzle provided in the downstream from the said stirring part, and the tangential direction of the inner peripheral wall of the said stirring part A water introduction path that opens along the first mixing case, and
A second mixing case comprising: a water receiving portion provided between the outlet and the jet outlet; and a cylindrical side wall connected to the water receiving portion and extending upward from the water receiving portion; ,
A continuous air passage connecting the gas layer accumulated above in the tank and the agitation part of the first mixing case;
With
The water flowing into the tank is introduced into the agitation unit from the inlet through the water introduction path of the first mixing case.
Gas-liquid mixing device.

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