KR102144583B1 - Air supply cabinet for wastewater institution - Google Patents

Abstract

Disclosed is an air supply device for a wastewater treatment facility, which can prevent overheating of a machine room and supplying clean air to the wastewater treatment facility by allowing air introduced into an air intake room at an upper end to be suctioned into an air blower at a lower end by installaing the air intake room at the upper end and the machine room to which the blower is installed at the lower end.

Description

Air supply system for wastewater treatment facility {AIR SUPPLY CABINET FOR WASTEWATER INSTITUTION}

The present invention relates to an air supply device for a wastewater treatment facility, and more particularly, a machine room in which a blower is installed is installed at the bottom and an air suction room is installed at the top so that the air introduced into the air suction room at the top is sucked by the blower at the bottom. By doing so, it is possible to supply clean air to the wastewater treatment facility, and to an air supply device for wastewater treatment facilities that can prevent overheating of the machine room.

The air supply device of the wastewater treatment facility is a device that inhales air in the atmosphere and supplies air to the aeration tank of the wastewater treatment facility to help activate microorganisms in the aeration tank.

1 shows an air supply device of a conventional wastewater treatment facility. Referring to this, in the air supply device of a conventional wastewater treatment facility, a blower 12 for sucking air is installed inside the cabinet 11. The cabinet 11 has an inlet hole 12 through which outside air is introduced, and the ceiling is covered with a finishing panel 13. Then, the blower is connected to the supply pipe 22 for supplying air to the wastewater treatment facility.

Therefore, when the blower is operated, external air is introduced into the cabinet and then supplied to the wastewater treatment apparatus through the blower.

However, the air treatment device of the wastewater treatment facility as described above is supplied to the wastewater treatment device by supplying clean air to the wastewater treatment device when external air is introduced by the blower operation. It cannot be supplied, and there are various problems such as a reduction in the life of the blower.

In addition, since it is formed in a single-layer structure, there is a problem that the inside of the cabinet is overheated due to the radiation heat of the sun and its own heat caused by the operation of the blower, so that there is a problem in that the blower's remaining breakdown and lifespan are also reduced.

The present invention has been conceived to solve the above problems, and its object is to provide an air supply device for a wastewater treatment facility capable of supplying clean air to a wastewater treatment facility and preventing overheating of a machine room.

An object of the present invention is that a diaphragm is installed horizontally in the interior so that the machine room at the bottom and the air suction room at the top are formed in a multi-layered structure, and the upper surface of the air suction room is supplied with external air and the introduced air sucks air. A cabinet finished with a ceiling having an air inflow passage for input into the room; A blower installed in the machine room, which sucks outside air so that the outside air flows into the machine room through the air intake room and then supplies it to the aeration tank of the wastewater treatment facility through an air supply pipe; A cyclone installed in the air suction chamber and having an inlet pipe through which air from the air suction chamber is introduced at one side thereof; A transfer pipe that transfers the air inside the cyclone to the machine room, but at one end of which a water separator is installed; A foreign matter discharge pipe branched from the air supply pipe and drawn out of the machine room, and having a first solenoid valve and a second solenoid valve formed therebetween; One end is connected to the lower part of the cyclone, and the other end is connected between the first solenoid valve and the second solenoid valve of the foreign substance discharge pipe. It is achieved by providing an air supply device for a wastewater treatment facility as characterized.

The air supply device for a wastewater treatment facility according to the present invention is a multi-layered structure in which a machine room is formed at the bottom and an air suction room is formed at the top, so that the blower is directly avoided from the direct sunlight of the sun through the air suction room. Since it is possible to lower the temperature of the machine room by cooling the air intake chamber through the flow, there is an effect that it is possible to delay the blower's remaining breakdown and lifespan.

In addition, since the air from which moisture has been removed by the water separator is sucked into the blower, there is an effect that it is possible to prevent the blower from being damaged by moisture.

And, above all, there is an effect of improving water quality and increasing wastewater treatment efficiency by supplying clean air from which foreign matter has been removed by a cyclone to the aeration tank.

1 is a schematic diagram of an air supply device of a conventional wastewater treatment facility,
2 is a cross-sectional view of an air supply device of a wastewater treatment facility according to the present invention.

Hereinafter, an air supply device for a wastewater treatment facility according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view of an air supply device of a wastewater treatment facility according to the present invention.

Referring to the above drawings, the air supply device for a wastewater treatment facility according to the present invention includes a cabinet 110, a blower 120, a cyclone 130, a transfer pipe 140, a foreign substance discharge pipe 150, and a connection pipe 160. It consists of including.

The cabinet 110 has a diaphragm 111 installed horizontally therein, so that the machine room 112 at the lower end and the air intake room 113 at the upper end are formed in a multilayer structure. In addition, a controller room 114 for controlling an electric facility is formed on the side of the air intake room 113 at the top.

And, the upper surface of the air intake chamber 113 is closed with a ceiling 115, the ceiling has an air inlet passage through which external air is introduced and the introduced air is introduced into the air intake chamber due to suction of a blower described later. do. That is, air holes are formed at both sides and lower ends of the ceiling, and air is sucked into the air suction chamber 113 through the air holes 115-1 and 115-2.

The blower 120 is installed in the machine room 112 at the bottom of the cabinet 110, and external air is introduced into the machine room 112 through the air suction room 113 by inhaling external air. The air introduced into the machine room 112 is sucked into the blower 120 and then supplied to the aeration tank of the wastewater treatment facility through the air supply pipe 121 at a predetermined pressure.

The cyclone 130 is installed in the air suction chamber 113 and has an inlet pipe 131 through which air from the air suction chamber is introduced at one side thereof. In addition, a transfer pipe 140 is inserted into the cyclone, and the transfer pipe 140 is connected to the machine room 112. In addition, a water separator 141 is installed at the end of the transfer pipe.

Therefore, the air sucked into the air intake chamber 113 flows into the cyclone 130 through the inlet pipe 131 and then rotates inside the cyclone. During rotation, heavy foreign substances fall to the bottom of the cyclone and the foreign substances The removed air is transferred to the machine room through the transfer pipe 140.

At this time, moisture from the air from which foreign substances have been removed is separated by the water separator 141 and then the dry air from which the moisture has been removed is transferred to the machine room 112.

The foreign matter discharge pipe 150 is branched from the air supply pipe 121 and is drawn out of the machine room, and a first solenoid valve 151 and a second solenoid valve 152 are formed in the middle.

The connection pipe 160 has one end connected to the lower portion of the cyclone 130, and the other end connected between the first solenoid valve 151 and the second solenoid valve 152 of the foreign matter discharge pipe, so that air inside the cyclone 130 The foreign matters dropped by the rotation of are transferred to the foreign matter discharge pipe 150 through the connection pipe 160.

Therefore, when a foreign substance enters the foreign substance discharge pipe 150 through the connection pipe 160, the first solenoid valve 151 and the second solenoid valve 152 are opened by a signal, and accordingly, some of the air supplied from the blower is As the air flows to the foreign material discharge pipe 150, the foreign matter introduced into the foreign matter discharge pipe is discharged to the outside.

The operation and effect of the air supply device for a wastewater treatment facility according to the present invention configured as described above will be described.

The air supply device for a wastewater treatment facility according to the present invention has a multi-layered structure in which a machine room 112 is formed at the bottom and an air intake room 113 is formed at the top, and the blower 120 is installed in the machine room 112.

Therefore, it is possible to reduce the temperature of the machine room by directly avoiding the blower 120 from the direct sunlight of the sun through the air intake chamber 113 and cooling the air intake chamber 113 through the flow of air. It has the advantage of delaying the failure of the product and its lifespan.

In addition, since the air from which moisture has been removed by the water separator 141 is sucked into the blower, it is possible to prevent the blower from being damaged by moisture.

And, above all, by supplying clean air from which foreign substances have been removed by a cyclone to the aeration tank, it is possible to improve water quality and increase wastewater treatment efficiency.

Meanwhile, in the present invention, a heat dissipating material may be coated on the inner surface of the air supply pipe 121 in order to suppress an increase in temperature of the supply air passing through the air supply pipe 121.

In addition, the same heat dissipation material for suppressing the increase in temperature of the dry air filtered through the cyclone 130 may be further coated on the inner wall of the machine room 112.

The heat dissipation material is glacial acetic acid (Glacial Acetic Acide) 20% by weight, boron trifluoride amine complex salt 10% by weight, lithium bromide (LiBr) 10% by weight, acetum 2.5% by weight, silicon dioxide 3.5% by weight, polyisocyanate 3.0% by weight and Mix composition with the remaining water-soluble acrylic resin.

Here, glacial acetic acid has a certain point of 14.5°C or higher, which increases cooling characteristics even at room temperature to increase heat dissipation.

In addition, boron trifluoride amine complex salt is added to maintain stable adhesive strength and chemical resistance.

In addition, lithium bromide has a very high hygroscopicity and is used as an additive to increase cooling characteristics while attracting moisture from the surroundings to increase heat dissipation.

In addition, Acetum is a vegetable anti-static agent and implements antistatic properties.

In addition, silicon dioxide is added to enhance the adhesion to the coated surface to increase the peeling inhibiting function, thereby providing a solid fixing force.

In addition, the polyisocyanate is added to improve hardness, moist heat durability, and impact resistance by reaction between compositions.

In addition, water-soluble acrylic resins are added to maintain excellent binding properties and increase adhesion during application.

On the other hand, when the air discharged through the transfer pipe 140 is sucked into the blower 120, moisture is first removed during the separation of the cyclone 130, but if a trace amount of moisture remains, it remains inside the blower 120. In order to completely block this, it may cause the proliferation of bacteria, etc., which has a bad effect upon aeration, and also may cause damage to the blower 120 by moisture. The material can be further coated.

In this case, preferred hygroscopic substances include silica gel 30% by weight, noble stone powder 15% by weight, fluorine alkylsilane 7.5% by weight, water-soluble silicic acid 5% by weight, vinegar 2.5% by weight, calcium hydroxide 1.0% by weight, glyceryl monostearate 4.5 % By weight, and the rest of the water-soluble acrylic resin.

At this time, silica gel is a representative desiccant, and the precious stone powder has a three-dimensional network structure and has a humidity control function, so it can absorb and hold moisture, and is added to increase the moisture removal function.

In addition, the bolsoalkylsilane maintains smoothness by microstructure, but reduces contact angle hysteresis, so that it can provide excellent sliding properties so that contaminants do not adhere.

In addition, water-soluble silicic acid reacts with vinegar and calcium hydroxide to form an insoluble C-S-H gel, which is added to inhibit cracking, improve strong adhesion, and protect silica gel.

In addition, glyceryl monostearate is usually used as a food emulsifier, but in the present invention, it is added to implement antistatic properties according to a surfactant function.

Accordingly, since minute moisture contained in the dry air transferred through the transfer pipe 140 is completely removed and supplied to the blower 120, the blower 120 can be driven and maintained in a clean state.

In the state coated with such a heat dissipating material, it was confirmed whether there was a heat dissipation characteristic, that is, a cooling characteristic.

Two plastic plate samples were coated with the same thickness, but one was coated with the heat dissipating material according to the present invention, and the other was not coated for comparison.

The two samples were put into a humidity chamber maintained at 15°C, and hot air was applied to keep the inside of the humidity chamber at 30°C for 10 minutes. Then, an infrared thermometer was irradiated on the surfaces of the two samples to check whether there was heat loss.

As a result of the test, after 1 hour, the surface temperature of the sample coated with the moisture-proof material according to the present invention was 21.2°C, and the comparative sample was 26.5°C. Through this, it was confirmed that a heat dissipation effect can be obtained due to the cooling characteristic as the temperature rapidly drops after a certain period of time.

In addition, a coating solution consisting of 15% by weight of silicon metal gel, 5% by weight of ferric chloride (FeCl ₃ ), 5% by weight of decarburization powder, and the rest of water may be spray coated on the inner wall of the ceiling 115.

At this time, the metal silicon gel is a material made by processing silicon metal, and is added to increase antibacterial deodorant power and improve affinity with oxygen.

Such metal silicon is made into powder by crushing the reduced metal silicon rough with a crusher and then pulverizing it again in a rolling grinder, putting it in a nano grinder and pulverizing it to make nano powder, and then adding metal silicon nano powder, inorganic binder, and water to 4 Mix in a weight ratio of 1:1:5 and use a gel.

In addition, ferric chloride (FeCl ₃ ) is a trivalent iron salt, which is a transition metal having oxidizing power and is added to increase the sterilization power to increase the cleanliness of the air supplied to the aeration tank.

In addition, since the ferric chloride has a strong oxidizing power, tantalum is added and mixed together to prevent the inner wall of the ceiling from being corroded. This is because it has acid resistance.

By doing so, it is possible to cleanly process the introduced air, thereby further increasing the aeration efficiency.

110: cabinet 120: blower
130: cyclone 140: conveying pipe
150: foreign matter discharge pipe 160: connector

Claims (2)

Inside, a diaphragm is installed horizontally so that the machine room at the bottom and the air intake room at the top are formed in a multi-layered structure, and the air inflow allows external air to flow in and the inflow air into the air intake room. A cabinet finished with a ceiling having a passage;
A blower installed in the machine room, which sucks outside air so that the outside air flows into the machine room through the air intake room and then supplies it to the aeration tank of the wastewater treatment facility through an air supply pipe;
A cyclone installed in the air suction chamber and having an inlet pipe through which air from the air suction chamber is introduced at one side thereof;
A transfer pipe that transfers the air inside the cyclone to the machine room, but at one end of which a water separator is installed;
A foreign matter discharge pipe branched from the air supply pipe and drawn out of the machine room, and having a first solenoid valve and a second solenoid valve formed therebetween;
One end is connected to the lower part of the cyclone, and the other end is connected between the first solenoid valve and the second solenoid valve of the foreign substance discharge pipe, and comprises a discharge pipe for discharging foreign substances dropped by the rotation of air inside the cyclone to the foreign substance discharge pipe,
The inner surface of the air supply pipe and the inner wall of the machine room are coated with a heat radiation material, and the heat radiation material is 20% by weight of glacial acetic acid, 10% by weight of boron trifluoride amine complex salt, and 10% by weight of lithium bromide (LiBr). , 2.5% by weight of acetum, 3.5% by weight of silicon dioxide, 3.0% by weight of polyisocyanate, and the remaining water-soluble acrylic resin;
The inner surface of the transfer pipe 140 is coated with a moisture-absorbing material, the moisture-absorbing material is silica gel 30% by weight, noble stone powder 15% by weight, fluorine alkylsilane 7.5% by weight, water-soluble silicic acid 5% by weight, vinegar 2.5% by weight , Calcium hydroxide 1.0% by weight, glyceryl monostearate 4.5% by weight, and the air supply device for wastewater treatment facilities, characterized in that consisting of the remaining water-soluble acrylic resin. delete

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