JP3113520U - Pump pressurized gas-liquid dissolution mixer - Google Patents

Abstract

Disclosed is a pump pressurized gas-liquid dissolution mixer that also has a sterilizing effect for improving aquaculture environment and clean detoxification.
A pump-pressurized gas-liquid dissolution mixer composed of a hollow main body 1 and a motor pump 4, in the hollow main body 1, one or a plurality of suction mixing chambers 111 in which gas and liquid communicate with each other. And a gas-liquid pressurized dissolution and mixing chamber 12 are installed. Near the upper side surface of the gas-liquid suction and mixing chamber 11, one or more gas-liquid suction ports 111 are installed. When the gas / liquid is sucked through the conduit 2, the gas and liquid are simultaneously drawn into the gas / liquid suction mixing chamber 11, and the bottom of the gas / liquid pressure-dissolution mixing chamber 12 is connected. One or more entrances and exits are installed near the side of the pipe, and the pressure regulating and constant pressure valve 91 is installed directly from the conduit.
[Selection] Figure 1

Description

  The present invention is a kind of pump pressurized gas-liquid dissolution mixer. In particular, when various liquids and gases are mixed and pressurized, the oxygen content and other gas contents in the liquid exceed the saturation state, and are also exported into various containers. ) Pumping gas-liquid dissolution with high sterilization effect, by increasing the oxygen (gas) content in it, or by making saturated gas bubbles under normal pressure to improve aquaculture environment and clean detoxification It relates to a mixer.

  Generally, when cultivating fish and other organisms, keep fish and other organisms in aquariums or farms, use an electric inflator, take outside air into the aquarium or farm, Allow oxygen to dissolve in the water and maintain a constant oxygen content in the water. At the same time, it is necessary to dissolve oxygen into the water so that living organisms such as fish in the water can obtain oxygen necessary for survival. However, even when using the above-mentioned electric inflator, just taking air into the water, the bubbles of air entering the water are very large, so not only the contact area of the bubbles and water is small, The speed at which the bubbles float on the surface of the water is no longer high, and the oxygen in the air taken into the water is less soluble in the water. And the oxygen content in water becomes comparatively small, and it also harms living organisms such as fish in the water.

  In addition, there has been a conventional vegetable detoxification instrument that has been combined with an ozone generator and a washing tank, and this is mainly due to the fact that the ozone generator generates ozone when energized. After that, the water enters the washing tank so that ozone is contained in the washing tank. As a result, people are able to eat fruits and vegetables with peace of mind by eliminating the pesticides that remain on the surface of vegetables due to the high oxidation ability of ozone in water. However, even if ozone itself can eliminate pesticides on the surface of fruits and vegetables, the size of the bubbles in the water of the ozone is very large, and as in the example given above, ozone is not easily dissolved in water. Its ozone content is low and its effect on agricultural chemicals is not so significant.

In order to solve the above-mentioned drawbacks, a large number of holes are made in the end of the conduit connecting the ozone generator, so that ozone can create many small fine bubbles in the water, and the content of ozone in the water is increased. . However, in such a method, even if ozone can increase the content in water, the fluidity of water in the washing tank is poor, and the bubbles created by the multi-hole structure of ozone are However, the water content of ozone is still insufficient. Moreover, the place where the content of ozone water is large is limited to the vicinity of the conduit that is the entrance and exit of ozone, and the content of ozone water is likely to be insufficient at a place away from the entrance and exit.
As explained, the conventional method has the above drawbacks and needs to be improved.

As described in claim 1, the pump pressurized gas-liquid dissolution mixer of the present invention comprises:
A pump pressurized gas-liquid dissolution mixer composed of a hollow body and a motor pump,
In the hollow body, one or a plurality of suction mixing chambers and gas-liquid pressure-dissolution mixing chambers in which gas and liquid communicate with each other are installed. There is a gas-liquid inlet,
The suction port is connected to one or more gas-liquid suction conduits, and when the gas-liquid is sucked through the conduits, gas and liquid are simultaneously guided into the gas-liquid suction mixing chamber,
Near the side of the bottom of the gas-liquid pressure-dissolution mixing chamber, one or more doorways are installed, exported directly from the conduit, and a pressure-regulating constant pressure valve is installed,
The motor pump is connected to the side surface of the hollow body, and its central axis is placed in the gas-liquid inhalation mixing chamber of the hollow main body, and one or more rotating blades are fixed on the central axis. Has saw-tooth slots that are lined up vertically and horizontally,
When the motor pump is turned on, its mandrel rotates with the rotating blade,
Gas and liquid are drawn into the gas-liquid suction mixing chamber through the gas-liquid suction conduit,
The gas and liquid are mixed by the rotation of the rotating blade, and the gas is evenly dissolved in the liquid to generate fine microbubbles. The gas enters the chamber, and at the same time, the gas is pressed by the pressure of the blade and subjected to the additional pressurization and time extension by the baffle plate, regenerates further microbubbles, dissolves in the solution, and contains the gas in the liquid Is oversaturated and is exported from the doorway into various containers.

Also, the motor pump, the hollow main body gas-liquid is combined, sucked into the stirring and mixing chamber, and the gas-liquid pressurizing and dissolving mixing chamber and the pressure regulating constant pressure valve are connected together to advance into the conduit, It is characterized by simplification.
Furthermore, the gas-liquid suction conduit is connected to one or more advancing pipes and launching pipes, and one or more suction pipes are installed, and at the same time, a multi-tube, an ozone generator and other devices capable of generating different liquids. It is characterized by introducing various gases and liquids into the gas-liquid suction mixing chamber and mixing them in the mixing chamber.

When a liquid such as water and a gas such as oxygen or ozone are injected into the mixer of the present invention, the gas naturally reaches a supersaturated content due to atmospheric pressure, and the gas becomes extremely fine bubbles, vegetables, Removes dirt from objects to be cleaned, such as fruits, food, and medical instruments, by the impact of bubbles.
When the gas is ozone, it is possible to sterilize agricultural chemical residues such as vegetables and detoxify other chemical substances by the oxidizing action of ozone in water. Thereby, prevention of infection of a disease poison and securing of food safety hygiene can be improved.
Such a method can be used in aquariums, fish ponds, farms and pools, etc., increasing the oxygen content in the water and cleaning tank disinfection and sterilization efficacy, preventing the generation of pathogenic bacteria, improving the growth environment of underwater aquaculture, Reduce disease.

  The pump pressurized gas-liquid dissolution mixer of the present invention includes a hollow body and a motor pump. In the hollow main body, an inhalation mixing chamber and a gas-liquid pressurization dissolution mixing chamber in which one or more gases and liquids communicate in order from the top to the bottom are installed. Near the upper side surface of the gas-liquid suction mixing chamber, one or more gas-liquid suction ports are provided. The gas-liquid suction port is connected to one or more gas-liquid suction conduits. When the gas-liquid is sucked through the conduits, gas and water are simultaneously introduced into the gas-liquid suction mixing chamber. The above suction pipe is connected to an ozone generator and other different gas appliances, and the advancing pipe and the launching pipe simultaneously introduce water and gas into the gas-liquid inhalation mixing chamber through the pipe. There is at least one baffle in the gas-liquid pressure-dissolution mixing chamber, and one or more water outlets are installed near the bottom side of the gas-liquid pressure-dissolution mixing chamber. Export directly from the conduit and install a pressure regulation valve.

  The motor pump is connected to the upper side surface of the hollow body, and the motor shaft enters the gas-liquid inhalation mixing chamber by the top end of the body, and one rotating blade is fixed on the shaft. ing. On the rotating blade, there are sawtooth slots arranged crossing each other in the vertical and horizontal directions. In addition, the postponing rotating blade corresponds to the gas-liquid suction conduit in the gas-liquid suction mixing chamber, and is linked with the motor pump, so that the rotating blade rotates together at high speed. As a result, a liquid or gas is sucked into the gas-liquid suction mixing chamber, and at the same time, the rotating blade rotates at a high speed, thereby producing an effect of mixing the gas and liquid. Thereby, a gas-liquid can melt | dissolve uniformly in a liquid and can generate | occur | produce a fine micro bubble. The microbubbles and liquid are pressurized by the motor pump and enter the gas-liquid pressurization and dissolution mixing chamber through the communication port. In response to the extension, further microbubbles are regenerated, dissolved in the solution body (water), the state of oxygen in the liquid (water) exceeds the saturated state, and is exported again from the water entrance to various containers. . (For example, detoxification dishes, water tanks, farms, etc.)

1 and 2 relate to a pump pressurized gas-liquid dissolution mixer of the present invention. This will be described in detail below.
A waterproof joint hole (not shown) is installed on the top surface of the hollow body (1), and the gas-liquid suction mixing chamber (11) and the gas-liquid pressurizing and dissolving mixing chamber (12) are arranged in order from the top to the bottom. Installed. The coupling hole and the gas / liquid suction / mixing chamber (11) communicate with each other, and the gas / liquid suction / mixing chamber (11) and the gas / liquid pressure-dissolution / mixing chamber (12) have one or more communication ports (13). Near the upper side surface of the gas-liquid suction mixing chamber (11), one or more gas-liquid suction ports (111) are provided. The gas-liquid suction port (111) is connected to one or more gas-liquid suction conduits (2).

When the gas-liquid is sucked through the conduit (2), the gas-liquid includes a launch pipe (22) and at least one or more advance pipes (21), and the launch pipe (22) and the advance pipe (21) are at least one. That is all. The conduit (2) can be connected to an ozone generator (211) (see FIG. 4) and other devices capable of generating different liquids. The launch pipe (22) can be made together with the advance pipe (21).
As a result, the gas-liquid suction conduit (2) passes through the launch pipe (22) and the launch pipe (21), and separately sends the gas (31) and water (32) from the gas-liquid suction port (111) to the gas-liquid suction mixing chamber. (11) and at least one baffle plate (121) is also installed in the gas-liquid pressure-dissolution mixing chamber (12). A water inlet / outlet (122) at the bottom side nearby is provided once, and an export conduit is connected to create a pressure regulating constant pressure valve (91). The pressure regulating constant pressure valve (91) is mainly used for water outlet. Control the condition.
The shaft (41) of the motor pump (4) enters the gas-liquid suction mixing chamber (11) through the coupling hole of the hollow body (1), and the shaft (41) and the coupling hole are completely sealed, There are no gaps. There is a rotating blade (5) on the mandrel (41), which corresponds to the rotating blade (5) and the gas-liquid inlet (111) on one side of the gas-liquid inlet / outlet chamber (11). On the rotating blade (5), there are saw-tooth slots (51) arranged so as to intersect vertically and horizontally. A lid (42) is provided outside the motor pump (4) to protect the motor pump (4).

  When the motor pump (4) is turned on, its mandrel (41) rotates along with the rotating blade (5) and rotates together at a high speed, so Gas (31) and water (32) are separately sucked into the gas-liquid suction port (11) through the water pipe (22), and sucked into the gas-liquid suction mixing chamber (11). At the same time, the rotating blade (5) and the sawtooth slot (51) are rotated at high speed, whereby the gas-liquid (31) is dissolved in the liquid (32), and fine microbubbles (71) can be generated. The microbubble (71) and liquid (32) are pressurized by the motor pump (4) and enter the gas-liquid pressurization and dissolution mixing chamber (12) through the communication port (13), and simultaneously the gas-liquid pressurization and dissolution. The baffle plate (121) installed in the mixing chamber (12) prevents the flow of current, increases the space and area where the gas and liquid are dissolved, creates more time for the foam (71), and withstands pressure. To be able to. Thereby, as for the liquid (32), oxygen content exceeds a saturated state and the bubble (71) is exported into various containers again by the water entrance / exit (122). (For example, an aquarium / culture farm (61), various detoxifiers (62) (as shown in FIGS. 4, 5, and 6), a pool (63), etc.)

As shown in FIGS. 4, 5 and 6, when the fine microbubbles (71) are injected into the container described above, the liquid (32) naturally contains supersaturated oxygen under normal pressure. The amount of oxygen is generated into very fine bubbles (71), and these bubbles (71) are distributed on average by gas and liquid, serving as dishes and dishes (81) vegetables (83), fruits, food, medical The instrument (82) can be washed off by impact, and the ozone high oxidation action in water can prevent the sterilization of the pesticide residue and other chemical substances, detoxification, and the like. Thereby, prevention of infection of a disease poison and securing of food safety hygiene can be improved. Among them, a spiral blade (92) can be provided in the detoxification dish (62), which is moved by a motor (93) at the bottom of the container, and the liquid in the container is rotated by movement by the spiral blade (92), Microbubbles can be stimulated by the rotational force of the liquid. With such power, the vegetables, fruits, food, medical instruments, etc. in the container can be washed away by impact, and the effects of detoxification and sterilization can be achieved.
Next, as shown in FIGS. 3 and 7, the present invention can be used in aquarium (61), fish pond, farm and pool (63), etc. to increase the high oxygen content in water and the sterilization and sterilization effect of washing tank. It can reach the goal of preventing pathogenic germs, improving the growth environment of underwater aquaculture, and reducing disease.

It is a section explanatory view of a pump pressurization gas liquid dissolution mixer of the present invention. It is operation | movement explanatory drawing of the pump pressurization gas-liquid melt | dissolution mixer of this invention. It is 1st application explanatory drawing of the pump pressurization gas-liquid melt | dissolution mixer of this invention. It is a 2nd application explanatory drawing of the pump pressurization gas-liquid dissolution mixer of this invention. It is a 3rd application explanatory view of the pump pressurization gas liquid dissolution mixer of the present invention. It is a 4th application explanatory view of the pump pressurization gas liquid dissolution mixer of the present invention. It is a 5th application explanatory view of the pump pressurization gas liquid dissolution mixer of the present invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Hollow main body 11 Gas-liquid suction | inhalation mixing chamber 111 Gas-liquid suction inlet 12 Gas-liquid pressurization melt | dissolution mixing chamber 121 Baffle plate 122 Water inlet / outlet 13 Connecting port 2 Gas-liquid suction conduit 21 Gas advance pipe 211 Ozone maker 22 Launch pipe 31 Gas 32 Water 4 Motor pump 41 Axle 42 Lid 5 Rotating blade 51 Sawtooth slot 61 Aquarium / culture farm 62 Detoxification dish 63 Pool 71 Microbubbles 81 Vessels and dishes 82 Medical instruments 83 Vegetables 91 Pressure control and constant pressure valve 92 Spiral blade 93 Motor

Claims (3)

A pump pressurized gas-liquid dissolution mixer composed of a hollow body and a motor pump,
In the hollow main body, one or a plurality of gas-liquid suction mixing chambers and gas-liquid pressurization / dissolution mixing chambers in which gas and liquid communicate with each other are installed, and there is one near the upper side of the gas-liquid suction mixing chamber. The above gas-liquid inlet is installed,
The suction port is connected to one or more gas-liquid suction conduits, and when the gas-liquid is sucked through the conduits, gas and liquid are simultaneously guided into the gas-liquid suction mixing chamber,
Near the side of the bottom of the gas-liquid pressure-dissolution mixing chamber, one or more doorways are installed, exported directly from the conduit, and a pressure-regulating constant pressure valve is installed,
The motor pump is connected to the side surface of the hollow body, and its central axis is placed in the gas-liquid inhalation mixing chamber of the hollow main body, and one or more rotating blades are fixed on the central axis. Has saw-tooth slots that are lined up vertically and horizontally,
When the motor pump is turned on, its mandrel rotates with the rotating blade,
Gas and liquid are drawn into the gas-liquid suction mixing chamber through the gas-liquid suction conduit,
The gas and liquid are mixed by the rotation of the rotating blade, and the gas is evenly dissolved in the liquid to generate fine microbubbles. The gas enters the chamber, and at the same time, the gas is pressed by the pressure of the blade and subjected to the additional pressurization and time extension by the baffle plate, regenerates further microbubbles, dissolves in the solution, and contains the gas in the liquid The pump pressurized gas-liquid dissolution mixer is characterized in that is oversaturated and is exported again from the doorway into various containers.   Combining the motor pump and hollow body gas-liquid, sucking them into the stirring and mixing chamber, and connecting the integrated combination structure of the gas-liquid pressurizing and dissolving mixing chamber and pressure regulating constant pressure valve, advance to the conduit and simplify The pump pressurized gas-liquid dissolution mixer according to claim 1, wherein:   The gas-liquid intake conduit is connected to one or more intake pipes and launch pipes, and one or more intake pipes are installed, and at the same time connected to multiple pipes, ozone generators and other devices capable of generating different liquids. 2. The pump pressurized gas-liquid dissolution mixer according to claim 1, wherein various gases and liquids are introduced into the gas-liquid suction mixing chamber and mixed in the mixing chamber.

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