KR102140908B1 - Vortex Mix Deodorizing Device Advanced Oxidation Process - Google Patents

Abstract

The present invention relates to a vortex-mixing deodorization apparatus using an advanced oxidation process to increase deodorization efficiency. According to the present invention, the vortex-mixing deodorization apparatus comprises: a treatment water supply unit producing and selectively supplying treatment water which includes bubbles, oxidants, and catalysts to promote absorption while oxidizing and removing odor components from odorous gas including odor; a blowing deodorization unit disposed on one side of the treatment water supply unit, receiving and moving the odorous gas in one direction, where deodorization is performed, while increasing blowing pressure, spraying the treatment water when receiving the odorous gas to absorb the odorous components of the odorous gas to the treatment water while the odorous gas passes through the environment, and separating the treatment water having the gas adsorbed thereon to purify the treatment water; a gas deodorization unit disposed in the blowing deodorization unit and having a plurality of spaces divided in one direction to generate a vortex of the odorous gas in each space in an environment in which the treatment water supplied from the treatment water supply unit is sprayed, thereby discharging the odorous gas in a vortex type while the gas and liquid are primarily separated; a gas-liquid separation deodorization unit disposed in the blowing deodorization unit, placed at one side of the gas deodorization unit to generate a vortex when the odorous gas supplied in the vortex type is upwardly rotated and supplied, and separating the gas and the liquid to discharge purified gas; and an absorption water treatment unit disposed in the blowing deodorization unit, placed on the lower part of the gas deodorization unit, and oxidizing the separated treatment water during circulation to purify and circulate the treatment water to the treatment water supply unit.

Description

Vortex Mix Deodorizing Device Advanced Oxidation Process}

The present invention relates to a vortex mix deodorizer using an advanced oxidation process, and more specifically, to improve the structure of a deodorizer that deodorizes malodorous components from contaminated air generated in a wastewater treatment plant, while moving to one side by blowing air. , By separating the gas and liquid in the state of oxidation treatment by spraying the liquid containing the catalyst, and the oxidizing agent, and filtering and discharging the gas in a vortex form, the deodorization efficiency is improved by secondary oxidation of the separated liquid phase It relates to a vortex mix deodorizer using an advanced oxidation process.

Due to the rapid development of the industry, deodorizers are used to remove harmful gases such as ammonia, hydrogen sulfide, trimethylamine, and methyl sulfide generated from various wastewater treatment plants and food composting and feed facilities, but due to deterioration in efficiency and careless management It has become a serious social problem with civil complaints.

Soil deodorization method, adsorption method, microbial treatment method, bio-filter method, general cleaning method, etc. are used as measures to reduce the emissions of odors, which are harmful gases.However, installation and maintenance costs are excessive, and management difficulties and deodorization efficiency after installation Due to this decline, many complaints have been generated. In particular, in the general cleaning method, a problem in management of spray nozzles and fillers and a serious problem in which odor removal efficiency is reduced due to the discharge of the washed water particles into the atmosphere are pointed out.

Accordingly, recently, a technique of spraying washing water onto a gas containing odor and adsorbing it to discharge it to the outside has been developed and used.

In the deodorizing apparatus using the washing water of the prior art, when the gas containing the malodor component is supplied, the adsorption efficiency is reduced by simply supplying the washing water by spraying the washing water and dropping the malodor component by adsorption. There was a problem.

In addition, when various chemicals for removing odors are mixed with the cleaning solution, odors due to chemical reaction of the chemicals of the remaining cleaning solution are generated due to continuous purification, and maintenance costs are excessive due to regular cleaning. There was a problem.

The present invention has been devised to solve the above-mentioned problems, and the object of the present invention is to spray a liquid containing bubbles, catalysts, and oxidizing agents on one side by blowing in deodorizing contaminated air generated in a wastewater treatment plant. It is to provide a vortex mix deodorizer using an advanced oxidation process that improves deodorization efficiency by separating gas and liquid in an oxidized state, filtering and discharging the gas in a vortex form, and performing secondary oxidation of the separated liquid phase. .

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood from the following description.

In order to achieve the above object, the present invention, the vortex mix deodorization apparatus using a high-level oxidation process according to an embodiment includes a bubble, an oxidizing agent, and a catalyst to promote adsorption while oxidatively removing malodorous components from malodorous gases including malodors A treated water supply unit that generates and selectively supplies the treated water; It is disposed on one side of the treated water supply unit, and moves in one direction to be deodorized while receiving the odor gas and pressurizes the pressure to be blown. When malodorous gas flows in, the treated water is sprayed and passes through the environment. A blower deodorizing unit to which the malodorous component is adsorbed and to separate and purify the gas and adsorbed treated water; It is disposed inside the blowing deodorization unit, and is divided into a plurality of spaces in one direction to generate odor gas as a vortex in an environment in which the treatment water supplied from the treatment water supply unit is sprayed in each space to primarily separate gas and liquid. A gas deodorizer that discharges in a vortex form in one state; A gas-liquid separation and deodorization unit disposed inside the blowing deodorization unit and located on one side of the gas deodorization unit to rotate and supply the odor gas supplied in the form of a vortex while rotating to generate vortex to separate the gas and discharge purified gas; And an adsorption water treatment unit disposed inside the blowing deodorization unit and located under the gas deodorization unit to oxidize and purify the separated treatment water while circulating to supply it to circulate the treatment water supply unit.

In addition, the treated water supply unit, a bubble catalyst water generating device for generating a treated water containing a catalyst in the bubble water; A bubble catalyst water supply pipe connected to the plurality of zones from the center to the other of the plurality of zones partitioned by the gas deodorant inside the blowing deodorizer; A bubble oxidizing water generator that generates treated water containing oxidizing agent in the bubble water; A bubble oxidized water supply pipe connected to a plurality of zones from the center to one of the plurality of zones partitioned by the gas deodorant inside the blowing deodorizer; A bubble water generator for generating treated water containing bubbles; And a bubble water supply pipe connected to one end of the plurality of zones partitioned by the gas deodorant inside the blowing deodorant.

And, the blowing deodorizing unit, is disposed on one side of the processing water supply unit, a blowing pump that provides the air pressure to be blown; A blower mixing body disposed on the upper portion of the blower pump and connected to the portion to which the odor gas is supplied and the blower pump to mix to increase the blowing pressure of the odor gas; A mixing supply pipe disposed on one side of the blowing mixing body and supplying an odor gas having an increased pressure; And a vortex in a space partitioned by the gas deodorant in the center, which is arranged on one side of the blow mixing body and is connected to the mixing supply pipe to divide odor gas in an environment in which treated water is supplied to the treated water supply inside. It has a separating partition wall having a deodorizing movement space, respectively, in the position where the odor gas supplied to the upper portion of the separation partition wall has a deodorizing space to be purified while moving a plurality of locations partitioned in the gas deodorizing section, the separation partition wall It has an adsorption water treatment space in which treated water adsorbed with odor components is treated at a lower portion of the pipe, and a partition wall treated water in the form of a tube to recover the treated water falling in a space partitioned from the gas deodorization section to the adsorption water treatment section below the separation partition wall. It may include a deodorant body provided with a discharge pipe.

In addition, it is arranged in an upper position on one side of the deodorizing body, the movable monitoring window provided with a transparent material for observing the deodorizing operation state from the outside of the deodorizing body partitioned by the gas deodorizing unit; And a water level monitoring window disposed in a central position on one side of the deodorizing body, and provided with a transparent material for observing the water level of the treated water outside the deodorizing body partitioned at the separation partition location. .

In addition, the gas deodorizing unit is connected to the treatment water supply unit in the upper part of the other side where the odor gas is supplied from the space partitioned into the portion where the odor gas to be blown out of the blowing deodorizing unit is supplied. A first spraying nozzle sprayed on; Arranged inside the blowing deodorizing unit, the first deodorant space is partitioned while the first spraying nozzle is sprayed. A first deodorant bulkhead generated by vortex and discharged to one side; It is disposed on the other lower portion of the first deodorization partition wall, is installed in an open position on the upper portion of the adsorption water treatment unit and has a distribution space through which the treated water passes through the communication with the adsorption water treatment unit on the other side. A first induction partition having a first inflow space to which the treated water stored in the adsorption water treatment section is supplied to the lower portion of the adsorption water treatment section, and having a first induction space closed to guide the treated water from one side to the other; A second injection nozzle disposed in a pair on one side of the first deodorization partition wall and connected to the treatment water supply unit to inject bubble catalyst water through the first vortex generating unit to a vortexed odorous gas; It is disposed on one side of the first deodorization partition wall, and is divided into sections so that a second deodorization space is formed to secondaryly deodorize the malodor gas supplied from the second jet nozzle and deodorized through the first vortex generator and supplied to the vortex. A second deodorizing bulkhead that is generated as a vortex in a second vortex generating unit located at one lower portion and discharged to one side in a state in which the odor gas supplied from the lower portion is absorbed with treated water in the form of a partition wall; The second inflow space is disposed at the other lower portion of the second deodorization partition wall and is installed in an open position on the upper portion of the adsorption water treatment unit to one side to which the treated water stored in the adsorption water treatment unit is supplied to the lower portion of the second deodorization partition wall. A second guide bulkhead having a second guide space in which a lower portion is closed so that the treated water guides in one direction from the other side; A third injection nozzle disposed in a pair on one side of the second deodorization partition wall and connected to the treatment water supply unit to inject bubble oxidized water through the second vortex generating unit to a vortexed odor gas; A third deodorization space and the gas-liquid separation and deodorization unit disposed on one side of the second deodorization partition wall and secondaryly deodorizing the malodor gas supplied through the second deodorization partition wall and deodorized through the second deodorization partition wall In the form of a partition wall that divides the compartment so that the installed gas-liquid separation space is formed, the odor gas supplied from the bottom rises and is adsorbed with treated water. A third deodorant bulkhead; And a third inflow space disposed at the other lower portion of the third deodorization partition wall and installed in an open position on the upper portion of the adsorption water treatment unit to supply the treated water stored in the adsorption water treatment unit to the lower side of the third deodorization partition wall. It may include a; a third guide bulkhead having a third guide space, the bottom of which is closed so that the treated water guides from one side to the other.

In addition, the first vortex generating unit is disposed to be inclined in one direction below the first deodorizing partition wall, and is provided to reduce the cross-sectional area in which the malodorous gas is introduced by inclining in one direction in the lower portion, and stench from one side to the other in the upper direction. It has a first guide distribution space, which is a space in which the gas flows, and protrudes to maintain a predetermined interval with a cross-sectional area reduced to one side, and a process supplied from the first inflow space and the odor gas guided in the first induction space. A first guide bulkhead provided with a first incorporating body having a first inflow channel through which pressure is reduced due to an increase in speed due to a decrease in cross-sectional area due to mixing of water; It is disposed in the lower part of the first mixing body, and is provided in a tube shape in which the first mixing passage and the adsorption water treatment unit communicate, so that the treated water of the absorption water treatment unit is sucked by the low pressure of the first mixing passage. 1 A first suction pipe supplied to the mixing passage; A first ascending bulkhead protruding upward from a position away from one direction of the first incorporating body, and causing the malodorous gas mixed in the inside of the first incorporating body to rise by collision; And a first vortex generating space that protrudes in one direction from one side of the first deodorizing bulkhead and extends in one direction to an upper portion away from the first rising bulkhead to generate vortex while colliding with the raised air. , Supplying the other side so that the odor gas of the vortex is circulated to the first circulation passage space formed at an upper position in communication with the first vortex generation space of the first deodorization partition wall, closed off to the other side of the first circulation passage space A first discharge guide space that is closed to one side of the first circulating guide body while colliding with the first circulation guide body and is moved to one side after the odor gas rises apart at a predetermined interval in one direction of the first ascending bulkhead. A first vortex is generated through the first discharge passage space and discharges the malodorous gas guided to the second deodorization space with one side blocked by the first discharge guide bulkhead so as to guide the lower part of the first discharge guide space. It may include; a partition wall.

In addition, the second vortex generating unit is disposed inclined in one direction below the second deodorizing partition wall, and is provided to reduce a cross-sectional area in which malodorous gas is introduced by inclining in one direction in the lower portion, and malodor from one side to the other in the upper direction. It has a second guide distribution space, which is a space in which gas is distributed, and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the second induction space and the processing supplied from the second inflow space A second guide bulkhead provided with a second mixing body having a second mixing flow path through which the pressure decreases and the pressure increases due to the increase in speed due to the decrease in cross-sectional area due to mixing of water; It is disposed in the lower portion of the second mixing body, and is provided in a tube shape in which the second mixing passage and the adsorption water treatment unit communicate, so that the treated water of the absorption water treatment unit is sucked by the low pressure of the second mixing passage. 2 A second suction pipe to supply to the mixing passage; A second ascending bulkhead protruding upward from a position away from one direction of the second mixed body, and causing the malodorous gas mixed inside the second mixed body to rise by collision; And a second vortex generating space that protrudes in one direction from one side of the second deodorizing bulkhead, extends in one direction to an upper portion away from the second rising bulkhead, and generates vortex while colliding with the raised air. , To the second circulation passage space formed at an upper position in communication with the second vortex generation space of the second deodorization partition wall so as to be supplied to the other side so that the odor gas of the vortex is circulated, and closed off to the other side of the second circulation passage space A second discharge guiding space closed on one side so as to collide with the second circulation guide body and face downward, and the odor gas risen apart at a predetermined interval in one direction of the second rising bulkhead moves in one direction and moves downward. A second vortex generation that discharges the odor gas guided to the third deodorization space through the second discharge passage space while one side is blocked by the second discharge guide bulkhead so as to guide it to the lower portion of the second discharge guide space. It may include; a partition wall.

In addition, the third vortex generating unit is disposed inclined in one direction to the lower portion of the third deodorization partition wall, and is provided to reduce the cross-sectional area in which the malodorous gas is inclined in one direction in the lower portion, and the malodor from one side to the other in the upper direction. It has a third guiding circulation space, which is a space in which gas is distributed, and protrudes to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the third guiding space and the processing supplied from the third inflow space A third guide bulkhead provided with a third mixing body having a third mixing flow path through which the pressure decreases and the pressure increases due to the increase in speed due to the decrease in cross-sectional area due to mixing of water; Is disposed in the lower portion of the third mixing body, the third mixing flow path and the adsorption water treatment section is provided in a tube shape to be communicated with the treated water of the adsorption water treatment section is sucked by the low pressure of the third mixing flow path 3 A third suction pipe supplied to the mixing passage; A third ascending bulkhead protruding upward from a position away from one direction of the third mixed body, and causing the malodorous gas mixed in the third mixed body to rise by collision; And a third vortex generating space that protrudes in one direction from one surface of the third deodorant bulkhead, extends in one direction to an upper portion away from the third rising bulkhead, and generates vortices as air rises inside and collides. , The third circulation passage space formed at an upper position in communication with the third vortex generation space of the third deodorization partition wall is supplied to the other side to circulate the odor gas of the vortex, and closed off to the other side of the third circulation passage space A third discharge guiding space closed on one side so as to collide with the third circulation guide body and face downward, and the odor gas risen apart at a predetermined interval in one direction of the third rising bulkhead moves in one direction and moves downward. A third vortex generating bulkhead that discharges odor gas guided to the gas-liquid separation and deodorization unit through a third discharge passage space in a state where one side is blocked by a third discharge guide bulkhead so as to guide the lower portion of the third discharge guide space. ; May include.

In addition, the first vortex generating unit is arranged to be inclined in one direction below the first deodorizing partition wall, and is provided to reduce a cross-sectional area in which malodorous gas is introduced by inclining in one direction in the lower portion, and stench from one side to the other in the upper direction. It has a first guide distribution space, which is a space in which the gas flows, and protrudes to maintain a predetermined interval with a cross-sectional area reduced to one side, and a process supplied from the first inflow space and the odor gas guided in the first induction space. A first guide bulkhead provided with a first incorporating body having a first inflow channel through which pressure is reduced due to an increase in speed due to a decrease in cross-sectional area due to mixing of water; It is disposed in the lower part of the first mixing body, and is provided in a tube shape in which the first mixing passage and the adsorption water treatment unit communicate, so that the treated water of the absorption water treatment unit is sucked by the low pressure of the first mixing passage. 1 A first suction pipe supplied to the mixing passage; A first ascending bulkhead protruding upward from a position away from one direction of the first incorporating body, and causing the malodorous gas mixed in the inside of the first incorporating body to rise by collision; It has a first vortex generating space that protrudes in one direction from one side of the first deodorizing bulkhead, extends in one direction to an upper portion away from the first rising bulkhead, and generates vortices while the air rising into the interior collides, A first circulation passage space 0 formed at an upper position communicating with the first vortex generation space of the first deodorization partition wall is supplied to the other side so that the odor gas of the vortex is circulated, and is closed off from the other side of the first circulation passage space. 1 While colliding with the circulating guide body, it is directed downward, and the first discharge guide space is closed on one side so that the odor gas risen at a predetermined interval in one direction of the first ascending bulkhead moves to one upper direction and then moves downward. A first vortex generating bulkhead passing through the first discharge passage space and being discharged while one side is blocked by the first discharge guide bulkhead so as to guide the lower portion of the first discharge guide space; It is provided in the form of a partition wall that protrudes to one side of the first deodorant partition wall, and extends in one direction while enclosing the upper portion of the first vortex generation partition wall, and forms a first double discharge guide partition wall partially closed in one direction at one end. 1 double vortex generating bulkhead; It is provided in the form of a partition wall protruding downward to the center of the first double vortex generating partition wall, and has a first double circulation space, which is a space with the first discharge guide partition wall on the other side, and moves from one bottom to the other in a vortex. A first double deodorant bulkhead formed with a first double guide bulkhead protruding from the center to the bottom so as to have a first double vortex generating space in which a part of the bottom is inclined in one direction to reduce the cross-sectional area; It is disposed under the first double deodorant bulkhead, and has a first double guided bulkhead extending from the bottom of the first raised bulkhead to close the bottom of the first double circulation space, and the first double guided bulkhead A first double mixture having a first double mixing flow path extending upward and downward from the first double inducing bulkhead and having a first double mixing flow path through which the odor gas supplied to the first double circulation space decreases pressure through an increased speed; Inserted and disposed under the first double mixing body, the first double mixing flow passage and the adsorption water treatment part are provided in a pipe shape to communicate with the suction water treatment part by the low pressure of the first double mixing flow passage A first double suction pipe which is supplied to the first double mixing channel; And protruding upward from a position away from one direction of the first double mixing body, while decomposing the first double vortex generating space, falling below the first double vortex generating partition wall and discharging the malodorous gas raised to one side to the top. It may include a; passing through the first double discharge space formed between the first double discharge guide bulkhead and discharged.

In addition, the second vortex generating unit is disposed inclined in one direction on the lower portion of the second deodorization partition wall, and is provided to reduce the cross-sectional area in which the malodorous gas is inclined in one direction in the lower portion, and the odor from one side to the other in the upper direction. It has a second guide distribution space, which is a space in which gas is distributed, and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the second induction space and the processing supplied from the second inflow space A second guide bulkhead provided with a second mixing body having a second mixing flow path through which the pressure decreases and the pressure increases due to the increase in speed due to the decrease in cross-sectional area due to mixing of water; It is disposed in the lower portion of the second mixing body, and is provided in a tube shape in which the second mixing passage and the adsorption water treatment unit communicate, so that the treated water of the absorption water treatment unit is sucked by the low pressure of the second mixing passage. 2 A second suction pipe to supply to the mixing passage; A second ascending bulkhead protruding upward from a position away from one direction of the second mixed body, and causing the malodorous gas mixed inside the second mixed body to rise by collision; It has a second vortex generating space that protrudes in one direction from one side of the second deodorizing bulkhead and extends in one direction to an upper part away from the second rising bulkhead, where vortex is generated while air is raised into the interior and collides. A second circulation passage space formed at an upper position communicating with the second vortex generation space of the second deodorization partition wall, and supplied to the other side so that the odor gas of the vortex is circulated, and closed to the other side of the second circulation passage space 2 A second discharge guiding space closed on one side so as to collide with the circulation guide body and face downward, and the odor gas risen at a predetermined interval in one direction of the second ascending bulkhead moves to one upper direction and then moves downward. A second vortex generating partition wall that discharges through the second discharge passage space in a state where one side is blocked by the second discharge guide partition wall to guide the lower part of the second discharge guide space; It is provided in the form of a partition wall that protrudes to one side of the second deodorant partition wall, and extends in one direction while enclosing the upper portion of the second vortex generating partition wall, and forms a second double discharge guide partition wall partially closed in one direction at one end. 2 double vortex generating bulkheads; It is provided in the form of a partition wall protruding downward from the center of the second double vortex generating partition wall, and has a second double circulation space, which is a space with the second discharge guide partition wall, on the other side, while moving from one bottom to the top. A second double deodorant bulkhead formed with a second double guide bulkhead protruding from the center to the bottom so as to have a second double vortex generating space in which a part of the bottom is inclined in one direction to reduce the cross-sectional area; It is disposed under the second double deodorant bulkhead, and has a second double guided bulkhead extending from the bottom of the second raised bulkhead to close the bottom of the second double circulation space, and the second double guide bulkhead A second double mixing body having a second double mixing flow path extending upward and downward from the second double inducing bulkhead and reducing the pressure by passing the malodor gas supplied to the second double circulation space at an increased speed as the cross-sectional area is reduced; Is disposed in the lower portion of the second double mixing body, the second double mixing flow path and the adsorption water treatment unit is provided in a tube shape in communication with the second double mixing flow path by the low pressure of the absorption water treatment unit suction A second double suction pipe which is supplied to the second double mixing channel; And protruding upward from a position away from one direction of the second double-mixture, while separating the second double-vortex-generating space, falling below the second double-vortex-generating partition wall, and increasing the malodorous gas raised to one side to the top. It may include a; passing through the second double discharge space formed between the second double discharge guide bulkhead and discharged.

In addition, the third vortex generating unit is disposed inclined in one direction on the lower portion of the third deodorizing partition wall, and is provided to reduce the cross-sectional area in which the malodorous gas is introduced by inclining in one direction in the lower portion, and malodor from one side to the other in the upper direction. It has a third guiding circulation space, which is a space in which gas is distributed, and protrudes to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the third guiding space and the processing supplied from the third inflow space A third guide bulkhead provided with a third mixing body having a third mixing flow path through which the pressure decreases and the pressure increases due to the increase in speed due to the decrease in cross-sectional area due to mixing of water; Is disposed in the lower portion of the third mixing body, the third mixing flow path and the adsorption water treatment section is provided in a tube shape to be communicated with the treated water of the adsorption water treatment section is sucked by the low pressure of the third mixing flow path 3 A third suction pipe supplied to the mixing passage; A third ascending bulkhead protruding upward from a position away from one direction of the third mixed body, and causing the malodorous gas mixed in the third mixed body to rise by collision; It has a third vortex generating space that protrudes in one direction from one side of the third deodorizing bulkhead and extends in one direction to an upper part away from the third rising bulkhead, where vortices are generated while air rising therein collides. The third circulation passage space 164b formed at an upper position communicating with the third vortex generation space of the third deodorization partition wall is supplied to the other side so as to circulate the odor gas of the vortex, and is closed off to the other side of the third circulation passage space. The third discharge guide is closed so that the odor gas rises to one side of the third ascending bulkhead and moves to the bottom after being moved to one upper direction. A third vortex generating partition wall having a space and passing through the third discharge passage space in a state where one side is blocked by a third discharge guide partition wall to guide the lower part of the third discharge guide space; It is provided in the form of a partition wall that protrudes to one side of the third deodorant partition wall, and extends in one direction while enclosing the upper portion of the third vortex generation partition wall and forms a third double discharge guide partition wall partially closed in one direction toward the lower end. 3 double vortex generating bulkheads; It is provided in the form of a partition wall protruding downward from the center of the third double vortex generating partition wall, and has a third double circulation space, which is a space with the third discharge guide partition wall, on the other side, while moving from one bottom to the top. A third double deodorant bulkhead formed with a third double guide bulkhead projecting from the center to the bottom to have a third double vortex generating space where a part of the lower portion is inclined in one direction to reduce the cross-sectional area; It is disposed under the third double deodorant bulkhead, and has a third double guided bulkhead extending from the bottom of the third raised bulkhead to close the bottom of the third double circulation space, and the third double guided bulkhead A third double mixing body having a third double mixing flow path extending upward and downward from the third double inducing bulkhead and reducing the pressure by passing the malodorous gas supplied to the third double circulation space at an increased speed; Is disposed in the lower portion of the third double mixing body, the third double mixing flow path and the adsorption water treatment unit is provided in a tube shape to communicate with the suction pressure of the treated water by the low pressure of the third double mixing flow path A third double suction pipe which is supplied to the third double mixing channel; And protruding upward from a position away from one direction of the third double-mixture, and separating the third double-vortex-generating space to the lower part of the third double-vortex-generating partition wall, and the upper side of the malodorous gas rising to one side. It may include; a third double rising bulkhead passing through the third double discharge space formed between the third double discharge guide partition wall and discharged.

In addition, it is disposed inside the blowing deodorization unit, is installed in an optional space in a plurality of compartments separated from the gas deodorization unit, the odorous gas vortexed in the gas deodorization unit, the lower portion is closed at the lower center upper portion It may further include a contact gas-liquid separating unit provided to separate the liquid primarily by contact while moving in the direction, and to separate the liquid secondaryly while moving from the upper center to one lower portion.

In addition, the contact gas-liquid separating part is disposed inside the blowing deodorizing part, and is provided at a plurality of optional positions among a plurality of compartments partitioned by the gas deodorizing part, and both ends of one and the other are located at the top of each compartment. A gas-liquid separating support provided to maintain an inclined angle so that the center is located at the lower portion, and having a shape in contact with each other when moving to one lower portion after the odor gas supplied to the other lower portion passes and rises to the center; A lower closing bulkhead disposed at a lower center portion of the gas-liquid separation support and positioned at an upper portion of the separated portion so that the malodor gas and the treated water of the blowing deodorization unit are received; The gas-liquid separation support is inserted and disposed in a plurality of spaced apart at predetermined intervals so as to have a contact space penetrating up and down in one direction from the other. A contact blade having at least one curved contact portion in one and the other direction so as to be separated; And it is disposed in the gas-liquid separation support, it is located between the contact blades are installed to maintain the gap of the contact space contact gap holder; may include.

In addition, the gas-liquid separation and deodorization unit is disposed inside the blowing deodorization unit and is provided in a pair at one end position where purified malodorous gas is supplied from the lower part of the space partitioned by the gas deodorization unit and supplied from the treatment water supply unit. A gas-liquid separation deodorizing nozzle installed to spray bubble water; It is disposed between the gas-liquid separation and deodorizing nozzles, and has a gas-liquid separation and deodorization space in which adsorbed particles in which the supplied gas is rotated fall in the form of treated water. A gas-liquid separating deodorizing body having a separating deodorizing water discharge pipe discharging into the space; The gas-liquid separation and deodorizing body is arranged to protrude from a plurality of locations in a radial position on the outer periphery, and the suction body has a suction space that is sucked toward one direction in a round form so that the malodorous gas that has passed through the environment in which the bubble water is sprayed rotates in one direction. ; A diffusion body disposed above the gas-liquid separation and deodorization body and provided in a cylindrical shape at an upper center position of the gas-liquid separation and deodorization space; A diffusion blade disposed in a plurality of radially protruding outward directions on the outer periphery of the diffusion body, and having a round blade curved in one direction so that the gas rotated inside the gas-liquid separation and deodorization space diffuses in the same rotational direction; It is disposed on the upper portion of the diffusion body, is provided in the form of a plate that blocks the space divided by the partition wall of the gas-liquid separation deodorizing body, a jet plate having a plurality of through-holes through which the gas passes to filter impurities inside ; The gas-liquid separation and deodorizing nozzle is disposed at the bottom, and the treated water discharged from the separation and deodorization water discharge pipe is separated under the partition portion separating the gas deodorization unit and the adsorption water treatment unit. discharge pipe; A gas-liquid separator disposed on an upper portion of the injection plate and filtering while purified gas passes through the gas-liquid separation and deodorizing body; And it is disposed protruding on one upper portion of the blowing deodorant, the gas passing through the gas-liquid separator is discharged to the outside of the pipe type gas discharge pipe; may include.

In addition, the adsorption water treatment unit is disposed inside the blower deodorization unit, and the adsorbed treatment water is located in a separated lower portion and is divided into a plurality of treated water discharged from the gas deodorization unit and the gas deodorization unit. A processing body in the form of a water tank for storing the discharged treated water located at the vortex generating portion; It is disposed inside the processing body, and a plurality of compartments are partitioned inside the processing body so that the treated water discharged from one side to the other moves from one side to the other so that the malodorous components are purified by reaction with the oxidizing agent and the catalyst. A treated water flow partition wall provided in the form of a flowing partition wall; And a treatment water discharge pipe disposed on one side of the treatment body and installed to discharge the recycled treatment water to the outside.

In addition, it is disposed on one side of the treatment body, and connects the treatment water discharge pipe and the treatment water supply, and supplies the purified water in the treatment body to the treatment water supply to provide supply pressure to be circulated. Treated water circulation pump; A water level sensing sensor disposed inside the blowing deodorizing unit and positioned between the gas deodorizing unit and the processing body to detect the level of the treated water; And disposed on one side of the treatment body, connected to each of the treatment water circulation pump and the water level sensor to maintain the water level to the lower position of the gas deodorization unit before the blowing deodorization unit operates, and when the blowing deodorization unit operates It may include a; water level control unit for controlling the operation of the treatment water circulation pump by the measurement of the water level sensor so that the odor gas generated by the vortex of the gas deodorization unit to contact the treatment water by increasing the water level of the treatment water; have.

Specific details for achieving the above object will be clarified with reference to the embodiments described below in detail together with the accompanying drawings.

However, the present invention is not limited to the embodiments disclosed below, but may be configured in various different forms, and the present embodiments allow the disclosure of the present invention to be complete and to obtain common knowledge in the technical field to which the present invention pertains. It is provided to fully inform the possessor of the scope of the invention.

According to one of the above-described problem solving means of the present invention, in deodorizing contaminated air generated in a wastewater treatment plant, gas is oxidized while spraying a liquid containing a bubble, a catalyst, and an oxidizing agent to one side by blowing air. By separating the and liquid to discharge the gas while filtering in the form of a vortex, it provides an effect of improving the deodorization efficiency by performing secondary oxidation of the separated liquid phase.

In addition, according to an embodiment of the present invention, the air is polluted to one side through a pump, and deodorization is performed while passing through a plurality of partition walls, and the height of the device can be checked from the outside through a window of transparent material. It is possible to reduce the operation status and to check the operation status, thereby providing an effect of increasing management efficiency.

1 is a partial cross-sectional installation state diagram showing a vortex mix deodorizing apparatus using an advanced oxidation process according to an embodiment of the present invention.
FIG. 2 is a partially omitted installation state diagram showing a vortex mix deodorizer using the advanced oxidation process of FIG. 1.
FIG. 3 is a configuration diagram showing a state in which the first vortex generating unit, which is a main component, is operated in the vortex mix deodorizing apparatus using the advanced oxidation process of FIG. 1.
FIG. 4 is a configuration diagram showing a state in which the second vortex generating unit, which is a main component, is operated in the vortex mix deodorizing apparatus using the advanced oxidation process of FIG. 1.
FIG. 5 is a configuration diagram showing a state in which a third vortex generation unit and a gas-liquid separation and deodorization unit, which are main components of the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 1, are operated.
FIG. 6 is a configuration diagram showing a contact gas-liquid separation unit, which is a main component of the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 1.
7 is a cross-sectional view showing a gas-liquid separation and deodorization unit, which is a main component of the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 1.
8 is an operation diagram showing a state in which the gas-liquid separation and deodorization unit is sucked into the vortex mix deodorization device using the advanced oxidation process of FIG. 6.
9 is an operation diagram showing a diffusion state of the gas-liquid separation and deodorization unit in the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 6.
FIG. 10 is a plan view showing a separation deodorizing spray plate that is sprayed after diffusion of a gas-liquid separation deodorization unit in a vortex mix deodorization apparatus using the advanced oxidation process of FIG. 6.
11 is an operation diagram showing an adsorption water treatment unit that is a main component of the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 1.
12 is a block diagram showing a state in which the first vortex generating unit, which is a main component, is operated in a vortex mix deodorizing apparatus using an advanced oxidation process according to another embodiment of the present invention.
FIG. 13 is a configuration diagram showing a state in which the first vortex generating unit, which is a main component, is operated in the vortex mix deodorizing apparatus using the advanced oxidation process of FIG. 12.
FIG. 14 is a configuration diagram showing a state in which the first vortex generator, which is a main component, is operated in the vortex mix deodorizer using the advanced oxidation process of FIG. 12.

The present invention can be applied to various changes and can have various embodiments, and specific embodiments will be illustrated in the drawings and described in detail through detailed description. However, this is not intended to limit the present invention to specific embodiments, and should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention.

In describing the present invention, when it is determined that detailed descriptions of related known technologies may unnecessarily obscure the subject matter of the present invention, detailed descriptions thereof will be omitted. In addition, the numbers (for example, first, second, etc.) used in the description process of the present specification are only identification symbols for distinguishing one component from other components.

In addition, in the present specification, when one component is referred to as “connected” or “connected” with another component, the one component may be directly connected to the other component, or may be directly connected. It should be understood that, as long as there is no objection to the contrary, it may or may be connected via another component in the middle.

The suffixes "modules" and "parts" for components used in the following description are given or mixed only considering the ease of writing the specification, and do not have meanings or roles distinguished from each other in themselves. In addition, in order to clearly describe the present invention, parts not related to the description are omitted in the drawings, and in the drawings, the width, length, and thickness of components may be exaggerated for convenience. Throughout the specification, the same reference numerals denote the same components.

Hereinafter, with reference to the accompanying drawings will be described in detail for the practice of the present invention.

1 is a partial cross-sectional installation state diagram showing a vortex mix deodorizing device using a high-level oxidation process according to an embodiment of the present invention, Figure 2 is a partially omitted installation state diagram showing a vortex mix deodorizing device using a high-level oxidation process of Figure 1 to be.

1 and 2, the vortex mix deodorization apparatus 100 using a high-level oxidation process according to an embodiment of the present invention adds blowing pressure to a malodorous gas including malodor, moves to one side, and causes bubbles, oxidizers, And a device for vortexing in an atmosphere in which the treated water containing the catalyst is sprayed, adsorbing, purifying and discharging, and collecting and adsorbing the treated water to the bottom, whereby the treated water and the malodorous components react with each other to purify and circulate. will be.

The vortex mix deodorization apparatus 100 using the advanced oxidation process includes a treated water supply unit 110, a blower deodorization unit 120, a gas deodorization unit 130, a gas-liquid separation deodorization unit 180, and an adsorption water processing unit 190 It includes.

The treated water supply unit 110 is provided to selectively generate and supply treated water containing bubbles, oxidizing agents, and catalysts to promote adsorption while oxidatively removing odor components from gases containing odor.

The treated water supply unit 110 includes a bubble catalyst water generator 111, a bubble catalyst water supply pipe 112, a bubble oxidized water generator 113, a bubble oxidized water supply pipe 114, a bubble water generator 119, and It includes a bubble water supply pipe 116.

The bubble catalyst water generator 111 is provided to generate treated water containing a catalyst in the bubble water.

Here, the bubble water contains micro- and nano-type air particles in the form of bubbles, and the removal efficiency of removing the pollutants while adsorbing the polluted gas can be improved.

In addition, the catalyst acts as a catalyst to trigger coagulation to remove the malodorous components contained in the gas phase by adsorption.

The bubble catalyst water supply pipe 112 is connected so that the bubble catalyst water is supplied to a plurality of zones from the center to the other among a plurality of zones partitioned by the gas deodorization unit 130 inside the blowing deodorization unit 120.

That is, the bubble catalyst water supply pipe 112 is connected to the gas deodorization unit 130 so as to be supplied to a location where the malodorous gas blown from the blowing deodorization unit 120 is firstly deodorized and purified from the other side to the center.

The bubble oxidized water generating device 113 is provided to generate treated water containing an oxidizing agent in the bubble water.

Here, the bubble water contains micro- and nano-type air particles in the form of bubbles, and the removal efficiency of removing the pollutants while adsorbing the polluted gas can be improved.

In addition, the oxidizing agent can be purified by oxidizing the solidified malodor component by acting with the catalyst.

The bubble oxidized water supply pipe 114 is connected so that the bubble oxidized water is supplied to a plurality of zones from the center to one of a plurality of zones partitioned by the gas deodorizer 130 inside the blowing deodorizer 120.

That is, the bubble oxidized water supply pipe 114 is supplied to the gas deodorizing unit 130 so as to be supplied to a location for deodorizing and purifying the malodorous gas in which the bubble catalyst water is injected from the center to which the blown malodorous gas of the blowing deodorizing unit 120 flows. Connected.

The bubble water generator 119 is provided to generate bubble water containing bubbles.

Here, the bubble water contains micro- and nano-type air particles in the form of bubbles, and the removal efficiency of removing the pollutants while adsorbing the polluted gas can be improved.

The bubble water supply pipe 116 is connected so that the bubble water is supplied to one end of the plurality of zones partitioned by the gas deodorization unit 130 inside the blowing deodorization unit 120.

That is, the bubble water supply pipe 116 is provided to adsorb and remove the malodor component purified by being coagulated with bubble catalyst water and oxidized with bubble oxidation water.

The blowing deodorization unit 120 is disposed on one side of the treatment water supply unit 110, and is moved in one direction to be deodorized while receiving the odor gas and pressurizes the pressure to be blown. The odor component of the treated water and gas is adsorbed while passing through the environment, and is provided to separate and purify the gas and the adsorbed treated water.

Such, the blower deodorizing unit 120 includes a blower pump 121, a blower mixing body 122, a mixing supply pipe 123, a deodorizing body 124, a movable monitoring window 126, and a water level monitoring window 127 do.

The blowing pump 121 is disposed on one side of the treated water supply unit 110 and is provided to provide air pressure to be blown.

The blowing mixing body 122 is disposed on the upper portion of the blowing pump 121, and is connected to the portion where the odor gas is supplied and the blowing pump 121 to be mixed to increase the blowing pressure of the odor gas.

The mixing supply pipe 123 is disposed on one side of the blowing mixing body 122 and is provided to supply the odor gas with increased pressure.

The deodorizing body 124 is disposed on one side of the blow mixing body 122 and is connected to the mixing supply pipe 123 to be divided up and down to treat odor gas in an environment in which processing water is supplied to the treatment water supply unit 110 therein. The separation partition wall 125 is provided at the center, and the odor gas supplied to the upper part of the separation partition wall 125 has a deodorization space 124a that is purified while moving a plurality of positions partitioned by the gas deodorization unit 130, and the separation partition wall It is provided to have an adsorption water treatment space (124b) in which the treated water to which the malodorous component has been adsorbed is treated.

The deodorizing body 124 is disposed on one side of the blow mixing body 122 and is connected to the mixing supply pipe 123 to be divided up and down to treat odor gas in an environment in which processing water is supplied to the treatment water supply unit 110 therein. Separation partition walls 125 each having a deodorization moving space 125c are provided at positions where vortices in the space partitioned by the gas deodorization unit 130 are generated in the center.

Such, the odor gas supplied to the upper portion of the separation partition 125 has a deodorization space 125a that is purified while moving a plurality of positions partitioned by the gas deodorization unit 130, and the odor component is located at the lower part of the separation partition 125. It has an adsorption water treatment space (125b) in which the adsorbed treated water is treated, and in the form of a tube to recover the treated water falling into the space partitioned from the gas deodorization unit (130) at the lower part of the partition wall (125) to the adsorption water treatment unit (190). Bulkhead treated water discharge pipe (125d) is provided.

The operation monitoring window 126 is disposed at an upper position on one side of the deodorizing body 124, and is a transparent material that observes the deodorizing operation state from the outside of the deodorizing body 124 partitioned by the gas deodorizing unit 130. It is provided.

The water level monitoring window 127 is disposed at a central position on one side of the deodorizing body 124, and is provided with a transparent material for observing the water level of the treated water from the outside of the deodorizing body 124 partitioned at the partition wall position. .

The gas deodorization unit 130 includes a first injection nozzle 131, a first deodorization partition wall 132, a first induction partition wall 133, a second injection nozzle 134, a second deodorization partition wall 135, and a second induction The partition wall 136, the third injection nozzle 137, the third deodorization partition wall 138, the third guided partition wall 139, the first vortex generation unit 140, the second vortex generation unit 150, and the third It includes a vortex generating unit 160.

The first injection nozzle 131 is connected to the bubble catalyst water supply pipe 112 from the other upper portion where the malodor gas is supplied from the deodorization space 124a of the deodorization body 124 where the malodor gas blown from the mixing supply pipe 123 is It is provided to spray the bubble catalyst water to the supplied odor gas.

The first deodorizing partition wall 132 is disposed inside the deodorizing body 124, and the first vortex generating unit located in the lower portion partitioned while partitioning the first deodorizing space 132a in which the first spraying nozzle 131 is injected It is provided to be discharged to one side by generating a malodorous gas that is supplied from the mixed supply pipe 123 at 140 and moves to one side as a vortex.

The first induction partition wall 133 is disposed at the other lower portion of the first deodorizing partition wall 132, and is installed in an open position on the upper portion of the adsorption water treatment unit 190 to communicate with the adsorption water treatment unit 190 to the other side so that the treated water It has a distribution space (133a) to be passed through, and has a first inflow space (133c) to which treated water stored in the adsorption water treatment unit (190) is supplied to the lower portion of the first deodorization partition wall (132) to one side, and the treated water flows from one side to the other. It is provided to have a first guide space (133b) that is closed to guide the lower portion.

The second spray nozzle 134 is arranged in a pair on one upper portion of the first deodorization partition wall 132 and is connected to the bubble catalyst water supply pipe 112 to pass the bubble catalyst water through the first vortex generator 140. It is provided to spray the vortexed odor gas.

The second deodorizing partition wall 135 is disposed on one side of the first deodorizing partition wall 132, and is deodorized by the second jet nozzle 134 and deodorized through the first vortex generating unit 140 and supplied to the odor gas. A second vortex generating unit 150 located at one lower portion in a state in which the malodorous gas supplied from the lower side is adsorbed with the treated water in the form of a partition wall dividing the partition so that the second deodorizing space 135a for secondary deodorization is formed. ) To be discharged to one side by generating it as a vortex.

The second induction partition wall 136 is disposed at the other lower portion of the second deodorization partition wall 135 and is installed at an open position on the upper portion of the adsorption water treatment unit 190 to one side to the lower portion of the second deodorization partition wall 135. It has a second inlet space (136b) to which the treated water stored in the adsorption water treatment unit (190) is supplied, and has a second induction space (136a), the lower portion of which is closed to guide the treated water from one side to the other.

The third spray nozzle 137 is arranged in a pair on one upper portion of the second deodorization partition wall 135 and is connected to the bubble oxidized water supply pipe 114 to vortex the bubble oxidized water through the second vortex generator 150. It is provided to spray the odor gas.

The third deodorizing partition wall 138 is disposed on one side of the second deodorizing partition wall 135, and is ejected from the third spray nozzle 137 to deodorize through the second deodorizing partition wall 135 to supply the malodorous gas supplied to the vortex. The odor gas supplied from the bottom rises to the treated water in the form of a partition wall that divides the compartment so that the third deodorization space 138a for secondary deodorization and the gas-liquid separation space 138b in which the gas-liquid separation and deodorization unit 180 is installed are formed. In the adsorbed state, the third vortex generator 160 located at one lower portion is generated as a vortex and is discharged to one side.

The third induction partition wall 139 is disposed at the other lower portion of the third deodorization partition wall 138 and is installed at an open position on the upper portion of the adsorption water treatment unit 190 to one side to the lower side of the third deodorization partition wall 138. It has a third inlet space (139b) to which the treated water stored in the adsorption water treatment unit (190) is supplied, and has a third induction space (139a) that is closed at the bottom to guide the treated water from one side to the other.

FIG. 3 is a configuration diagram showing a state in which the first vortex generating unit, which is a main component, is operated in the vortex mix deodorizing apparatus using the advanced oxidation process of FIG. 1.

Referring to FIG. 3, the above-described first vortex generating unit 140 includes a first guide bulkhead 141, a first suction pipe 142, a first rising bulkhead 143, and a first vortex generating bulkhead 144. Includes.

The first guide partition wall 141 is disposed inclined in one direction below the first deodorant partition wall 132, and is provided to reduce the cross-sectional area inclined in one direction toward the lower side and inflows the malodorous gas, from one side to the other in the upper direction. It has a first guide distribution space (141a), which is a space in which odor gas is distributed, and protrudes so as to maintain a predetermined gap with a cross-sectional area reduced to one side and a first inflow of the odor gas guided in the first guide space (133b). A first mixing body 141b having a first mixing flow path 141c, which is mixed by mixing the water supplied from the space 133c and decreasing the pressure due to an increase in speed according to a reduction in the cross-sectional area, is provided.

The first suction pipe 142 is inserted and disposed under the first mixing body 141b, and is provided in the form of a pipe through which the first mixing flow path 141c and the adsorption water treatment unit 190 communicate with each other, and the first mixing flow path 141c. It is provided so that the treated water of the adsorption water treatment unit 190 is sucked by the low pressure of to be supplied to the first mixing passage (141c).

The first rising bulkhead 143 protrudes upward from a position away from one direction of the first mixing body 141b, and is provided so that the malodorous gas mixed inside the first mixing body 141b is raised by collision. do.

The first vortex generating partition wall 144 protrudes in one direction from one surface of the first deodorizing partition wall 132, and extends in one direction above the first rising partition wall 143 to collide with the raised air. While having a first vortex generation space (144a) where vortices are generated, the vortex flows to the first circulation passage space (144b) formed at an upper position communicating with the first vortex generation space (144a) of the first deodorization partition wall (132). The odor gas is supplied to the other side so as to be circulated, and collides with the first circulation guide body 144c which is closed off to the other side of the first circulation passage space and faces downward, and moves in one direction of the first ascending bulkhead 143 The first discharge guide is guided to the lower portion of the first discharge guide space 144e with the first discharge guide space 144e closed on one side so that the odor gas raised at a predetermined interval moves in one direction and then moves downward. It is provided to discharge the odor gas guided to the second deodorization space (135a) in a state where one side is blocked by the partition wall (144d) through the first discharge passage space (144f).

FIG. 4 is a configuration diagram showing a state in which the second vortex generating unit, which is a main component, is operated in the vortex mix deodorizing apparatus using the advanced oxidation process of FIG. 1.

Referring to FIG. 4, the second vortex generating unit 150 includes a second guide bulkhead 151, a second suction pipe 152, a second rising bulkhead 153, and a second vortex generating bulkhead 154. .

The second guide bulkhead 151 is disposed inclined in one direction at the bottom of the second deodorant partition wall 135, and is provided to reduce the cross-sectional area in which the malodorous gas is inclined in one direction in the lower direction, and from one side to the other in the upper direction. It has a second guide distribution space (151a), which is a space in which the odor gas is distributed, and protrudes so as to maintain a predetermined gap with a cross-sectional area reduced to one side and a second inflow of the odor gas guided in the second guide space (136a). A second mixing body 151b having a second mixing flow path 151c in which pressure is reduced due to an increase in speed according to a decrease in cross-sectional area due to mixing of the water supplied from the space 136b is provided.

The second suction pipe 152 is inserted and disposed under the second mixing body 151b, and is provided in the form of a pipe through which the second mixing flow path 151c and the adsorption water treatment unit 190 communicate, and the second mixing flow path 151c. It is provided so that the treated water of the adsorption water treatment unit 190 is sucked by the low pressure of to be supplied to the second mixing passage (151c).

The second rising bulkhead 153 protrudes upward from a position away from one direction of the second mixing body 151b, and is provided so that the malodorous gas mixed inside the second mixing body 151b is raised by collision. do.

The second vortex generating partition wall 154 protrudes in one direction from one surface of the second deodorizing partition wall 135, and extends in one direction to the upper part away from the second rising partition wall 153, so that the raised air collides inside. While having a second vortex generation space (154a) in which vortex is generated, the vortex flows into the second circulation passage space (154b) formed at an upper position communicating with the second vortex generation space (154a) of the second deodorization partition wall (135). The odor gas is supplied to the other side so as to be circulated, and is directed downward while colliding with the second circulation guide body 154c, which is closed off to the other side of the second circulation passage space 154b, and directed to the lower side of the second ascending bulkhead 153 With a second discharge guide space 154e closed on one side so that the odor gas risen at a predetermined interval and moves in one direction to the bottom, the second discharge guide space 154e is guided to the bottom. It is provided to discharge the odor gas guided to the third deodorization space 138a through the second discharge passage space 154f in a state where one side is blocked by the discharge guide partition wall 154d.

FIG. 5 is a configuration diagram showing a state in which a third vortex generation unit and a gas-liquid separation and deodorization unit, which are main components of the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 1, are operated.

Referring to FIG. 5, the third vortex generating unit 160 includes a third guide bulkhead 161, a third suction pipe 162, a third rising bulkhead 163, and a third vortex generating bulkhead 164. .

The third guide partition wall 161 is disposed inclined in one direction below the third deodorant partition wall 138, and is provided to reduce a cross-sectional area inclined in one direction toward the lower side, and reduces the cross-sectional area through which the malodorous gas flows, from one side to the other in the upper direction. It has a third guide distribution space 161a, which is a space in which odor gas is distributed, and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas and the third inflow guided in the third guide space 139a. A third mixing body 161b having a third mixing flow path 161c in which pressure is reduced due to an increase in speed according to a reduction in cross-sectional area due to mixing of the water supplied from the space 139b is provided.

The third suction pipe 162 is inserted and disposed under the third mixing body 161b, and is provided in the form of a pipe through which the third mixing flow path 161c and the adsorption water treatment unit 190 communicate with each other, and the third mixing flow path 161c. It is provided so that the treated water of the adsorption water treatment unit 190 is sucked by the low pressure of to be supplied to the third mixing passage (161c).

The third rising bulkhead 163 protrudes upward from a position away from one direction of the third mixing body 161b, and is provided so that the malodorous gas mixed inside the third mixing body 161b is raised by collision. do.

The third vortex generating partition wall 164 protrudes in one direction from one surface of the third deodorant partition wall 138, and extends in one direction to an upper portion away from the third rising partition wall 163, so that the raised air collides inside. While having a third vortex generation space (164a) where vortices are generated, the odorous gas of the vortex flows into the third circulation passage space (164b) formed at an upper position communicating with the third vortex generation space (164a) of the third deodorization partition wall. It is supplied to the other side to be circulated, collides with the third circulation guide body 164c that is closed off to the other side of the third circulation passage space 164b, faces downward, and is preset in one direction of the third rising bulkhead 163 A third discharge guide bulkhead having one closed third discharge guide space 164e so that the odor gas raised at intervals and moved in one direction and then moved downwards, and guided to the bottom of the third discharge guide space 164e It is provided to discharge the malodorous gas guided to the gas-liquid separation and deodorization unit 180 in a state where one side is blocked (164d) through the third discharge passage space (164f).

FIG. 6 is a configuration diagram showing a contact gas-liquid separation unit, which is a main component of the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 1.

Referring to FIG. 6, the contact gas-liquid separation unit 170 is disposed in the second deodorization space 135a and the third deodorization space 138a, and the odor gas passing through the first vortex generation unit 140 is different. It is provided so that the liquid is primarily separated by contact while moving from the lower portion toward the central upper portion where the lower portion is closed, and the liquid is secondarily separated while moving from the upper portion to one lower portion.

The contact gas-liquid separation unit 170 includes a gas-liquid separation support 171, a lower closed bulkhead 172, a contact blade 173, and a contact spacing holder 174.

The gas-liquid separation support 171 is disposed inside the second deodorization space 135a and the third deodorization space 138a, respectively, and both ends of one side and the other are positioned at the top, and the angle is inclined so that the center is located at the bottom. It is provided to maintain the odor gas supplied to the lower portion of the other side is passed through the center and is provided in a shape that is in contact with each other when moving to one lower portion.

The lower closed bulkhead 172 is disposed at the lower center of the gas-liquid separation support 171, and is located at the upper portion of the separation bulkhead and is installed to close the lower center of the gas-liquid separation support 171.

The contact blades 173 are arranged to be inserted into the gas-liquid separation support 171, and are disposed in plural spaces apart at predetermined intervals to have a contact space 173b penetrating up and down in one direction from the other, and the contact space 173b. In order to separate the gas and the liquid by the collision, the malodorous gas that is moved in is provided with at least one curved contact portion 173a in one or the other direction.

The contact spacing holder 174 is inserted and disposed in the gas-liquid separation support 171, and is positioned between the contact blades 173 to maintain the spacing of the contact space 173b.

FIG. 7 is a cross-sectional view showing a gas-liquid separation and deodorization unit which is a main component of the vortex mix deodorization device using the advanced oxidation process of FIG. 1, and FIG. 8 is a state in which the gas-liquid separation deodorization unit is sucked into the vortex mix deodorization device using the advanced oxidation process of FIG. 9 is an operation diagram showing the diffusion state of the gas-liquid separation and deodorization unit in the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 6, and FIG. 10 is a vortex mix deodorization apparatus using the advanced oxidation process of FIG. It is a plan view showing a separating deodorizing spray plate to be sprayed after diffusion of the gas-liquid separating and deodorizing portion.

7 to 10, the gas-liquid separation and deodorization unit 180 includes a gas-liquid separation and deodorizing nozzle 181, a gas-liquid separation and deodorizing body 182, a suction body 183, a diffusion body 184, and a diffusion blade 185. , An injection plate 186, a separation treatment water discharge pipe 187, a gas-liquid separator 188, and a gas discharge pipe 189.

The gas-liquid separation and deodorizing nozzle 181 is disposed inside the deodorizing body 124, and is provided in a pair at the top of the gas-liquid separation space 138b to be installed to spray bubble water supplied from the bubble water supply pipe 116.

The gas-liquid separation and deodorization body 182 is disposed between the gas-liquid separation and deodorization nozzle 181, and has a gas-liquid separation and deodorization space 182a in which adsorbed particles, in which the gas supplied therein is rotated, fall in the form of treated water, and the lower part. It is provided to have a separate deodorizing water discharge pipe (182b) for discharging the treated water dropped into the gas-liquid separation space (138b).

The suction body 183 is disposed protruding from a plurality of positions in a radial position around the outer periphery of the gas-liquid separation and deodorizing body 182, and toward the one direction in a round form so that the odor gas passing through the environment in which the bubble water is sprayed rotates in one direction. It is provided to have a suction space (183a) to be sucked.

The diffusion body 184 is disposed above the gas-liquid separation and deodorization body 182, and is provided in a cylindrical shape at an upper center position of the gas-liquid separation and deodorization space 182a.

The diffusion blade 185 is disposed to protrude outward in a plurality in a radial position around the outer periphery of the diffusion body 184, and a round bent in one direction so that the gas rotated inside the gas-liquid separation and deodorization space 182a diffuses in the same rotational direction. It is provided in the form of a blade.

The injection plate 186 is disposed on the upper portion of the diffusion body 184, and is provided in a plate shape that blocks a space divided by a partition wall of the gas-liquid separation and deodorization body 182, through which gas passes through to filter impurities therein. It is provided to have a plurality of injection holes 186a in the form.

The separation treatment water discharge pipe 187 has a gas-liquid separation deodorizing nozzle 181 disposed at the bottom, and discharges the treatment water discharged from the separation deodorization water discharge pipe 182b to the bottom of the separation partition wall 125 to the adsorption water treatment unit 190. It is provided in the form of a tube.

The gas-liquid separator 188 is disposed on the upper portion of the injection plate 186, and is provided in a screen form for filtering as the purified gas passes through the gas-liquid separation and deodorizing body 182.

The gas discharge pipe 189 is disposed to protrude on one upper portion of the deodorizing body 124, and is provided in the form of a pipe through which gas passing through the gas-liquid separator 188 is discharged to the outside.

11 is an operation diagram showing an adsorption water treatment unit that is a main component of the vortex mix deodorization apparatus using the advanced oxidation process of FIG. 1.

Referring to FIG. 11, the adsorption water treatment unit 190 is disposed inside the blowing deodorization unit 120 and is located at the lower portion of the gas deodorization unit 130 to oxidize and purify the separated treatment water while circulating to purify it. It is provided to circulate supply to (110).

The adsorption water treatment unit 190 includes a treatment body 191, a treatment water flow partition 192, a treatment water discharge pipe 193, a treatment water circulation pump 194, a water level sensor 195, and a water level controller 196. It includes.

The treatment body 191 is disposed inside the deodorizing body 124 and is located at the bottom of the separating partition wall 125 to process the water discharged from the partitioning treatment water discharge pipe 125d and the separating deodorizing water discharge pipe 182b. It is equipped to store.

The treated water flow partition wall 192 is disposed inside the treatment body 191, and divides a plurality of compartments inside the treatment body 191, so that the treated water discharged from one side to the other moves from one side to the other and stinks inside. It is provided in the form of a partition that flows so that the components are purified by reaction with an oxidizing agent and a catalyst.

The treatment water discharge pipe 193 is disposed on one side of the treatment body 191 and is installed to discharge the recycled treatment water to the outside.

The treatment water circulation pump 194 is disposed on one side of the treatment body 191, connects the treatment water discharge pipe 193 and the treatment water supply unit 110, and treats the purified water in the treatment body 191. It is provided to supply the pressure to be supplied to the treated water supply unit 110 to be circulated.

The water level sensor 195 is disposed inside the deodorizing body 124, and is installed at a position of the separation partition 124 dividing the deodorizing space 124a and the adsorption water treatment space 124b to detect the water level.

The water level control unit 196 is disposed on one side of the treatment body 191, and is connected to the treatment water circulation pump 194 and the water level sensor 195, respectively, and the lower portion of the gas deodorization unit prior to the operation of the blowing deodorization unit 120. Maintain the water level to the position, and increase the water level of the treated water when the blower pump 121 is operated to control the operation of the treated water circulation pump 194 by the measurement value of the water level sensor 195 so that the malodorous gas comes into contact with the treated water. It is provided to.

FIG. 12 is a configuration diagram showing a state in which a first vortex generating unit, which is a main component, is operated in a vortex mix deodorizing apparatus using an advanced oxidation process according to another embodiment of the present invention, and FIG. 13 is a vortex using the advanced oxidation process of FIG. 12. A configuration diagram showing a state in which the first vortex generation unit, which is the main component of the mix deodorizing device, is operated, and FIG. 14 shows a state in which the first vortex generation unit, which is the main component in the vortex mix deodorizing device, using the advanced oxidation process of FIG. 12 is operated. It is a block diagram.

12 to 14, the vortex mix deodorizing apparatus 100 using a high-level oxidation process according to another embodiment of the present invention includes a treated water supply unit 110, a blowing deodorizing unit 120, and a gas deodorizing unit 130 , A gas-liquid separation and deodorization unit 180, and an adsorption water treatment unit 190. Here, the components of the treated water supply unit, the blowing deodorant unit, the gas-liquid separation deodorant unit, and the adsorption water treatment unit and some components of the gas deodorant unit are the same as the vortex mix deodorizer 100 using the advanced oxidation process shown in FIGS. Accordingly, some configurations of the gas deodorization unit having differences are as follows.

In addition, the gas deodorizing unit 130 includes a first injection nozzle 131, a first deodorization partition wall 132, a first induction partition wall 133, a second injection nozzle 134, a second induction partition wall 136, a first 3 includes a deodorizing partition wall 138, a third induction partition wall 139, a first vortex generation unit 140, a second vortex generation unit 150, and a third vortex generation unit 160.

Here, the first injection nozzle 131, the first deodorizing partition wall 132, the first induction partition wall 133, the second injection nozzle 134, the second induction partition wall 136, the third deodorizing partition wall 138, And the third induction barrier 139 is the same as the vortex mix deodorizing apparatus 100 using the advanced oxidation process shown in Figures 1 to?? The first vortex generator 140, the second vortex generator The 150 and the third vortex generator 160 will be described as follows.

The above-described first vortex generating unit 140 includes a first guide partition wall 141, a first suction pipe 142, a first rising partition wall 143, a first vortex generation partition wall 144, and a first double vortex generation partition wall ( 145), a first double deodorant bulkhead 146, a first double mixed body 147, a first double suction pipe 148, and a first double raised bulkhead 149.

The first guide partition wall 141 is disposed inclined in one direction below the first deodorant partition wall 132, and is provided to reduce the cross-sectional area inclined in one direction toward the lower side and inflows the malodorous gas, from one side to the other in the upper direction. It has a first guide distribution space (141a), which is a space in which odor gas is distributed, and protrudes so as to maintain a predetermined gap with a cross-sectional area reduced to one side and a first inflow of the odor gas guided in the first guide space (133b). A first mixing body 141b having a first mixing flow path 141c, which is mixed by mixing the water supplied from the space 133c and decreasing the pressure due to an increase in speed according to a reduction in the cross-sectional area, is provided.

The first suction pipe 142 is inserted and disposed under the first mixing body 141b, and is provided in the form of a pipe through which the first mixing flow path 141c and the adsorption water treatment unit 190 communicate with each other, and the first mixing flow path 141c. It is provided so that the treated water of the adsorption water treatment unit 190 is sucked by the low pressure of to be supplied to the first mixing passage (141c).

The first rising bulkhead 143 protrudes upward from a position away from one direction of the first mixing body 141b, and is provided so that the malodorous gas mixed inside the first mixing body 141b is raised by collision. do.

The first vortex generating partition wall 144 protrudes in one direction from one side of the first deodorizing partition wall 132, and extends in one direction above the first rising partition wall 143 to collide with the raised air inside. While having a first vortex generating space (144a) in which vortex is generated, the vortex flows to the first circulation passage space (144b) formed at an upper position communicating with the first vortex generating space (144a) of the first deodorization partition wall (132). The odor gas is supplied to the other side so as to be circulated, and is directed downward while colliding with the first circulation guide body 144c that is closed off to the other side of the first circulation passage space 144b, and is directed in one direction of the first ascending bulkhead 143 With the first discharge guide space 144e closed on one side so that the odor gas risen at a predetermined interval and moves to the bottom after moving to one upper direction, it is provided to guide the lower part of the first discharge guide space 144e. 1 is provided to discharge through the first discharge passage space 144f in a state where one side is blocked by the discharge guide partition wall 144d.

The first double vortex generating partition wall 145 is provided in the form of a partition wall protruding to one side of the first deodorizing partition wall 132 and extends in one direction while enclosing the upper portion of the first vortex generating partition wall 144 and is lowered at one end. The first double discharge guide partition wall 145a partially closed in the direction is provided to be formed.

The first double deodorant partition wall 146 is provided in the form of a partition wall protruding downward to the center of the first double vortex generating partition wall 145, and the first double circulation which is a space with the first discharge guide partition wall 144d to the other side. It has a space 146a and protrudes from the center to the bottom so as to have a first double vortex generating space 146b where vortices are generated while moving from bottom to top on one side, and a part of the bottom is inclined in one direction to reduce the cross-sectional area. 1 Double guide bulkhead (146c) is provided to be formed.

The first double mixing body 147 is disposed under the first double deodorization partition wall 146 and extends from the bottom of the first rising partition wall 143 to close the bottom of the first double circulation space 146a. 1 The odor gas supplied to the first double circulation space (146a) is provided with a double induction bulkhead (147a) and extends vertically from the first double guide bulkhead (146c) and the first double guided bulkhead (147a) to reduce the cross-sectional area. It is provided to have a first double mixing flow path (147b) that passes through at an increased speed and decreases the pressure.

The first double suction pipe 148 is inserted and disposed under the first double mixing body 147, and is provided in the form of a pipe through which the first double mixing flow path 147b and the adsorption water treatment unit 190 communicate with each other. It is provided so that the treated water of the adsorption water treatment unit 190 is sucked by the low pressure of the flow path 147b and supplied to the first double mixing flow path 147b.

The first double rising bulkhead 149 protrudes upward from a position away from one direction of the first double mixing body 147, and partitions the first double vortex generating space 146b, while the first double vortex generating bulkhead 145 It is provided to pass through the first double discharge space (149a) formed between the first double discharge guide bulkhead (145a) passing through the upper portion of the odor gas risen to one side away from the lower portion.

In addition, the second vortex generating unit 150 includes a second guide partition wall 151, a second suction pipe 152, a second rising partition wall 153, a second vortex generation partition wall 154, and a second double vortex generation partition wall ( 155), a second double deodorant bulkhead 156, a second double mixed body 157, a second double suction pipe 158, and a second double rising bulkhead 159.

The second guide bulkhead 151 is disposed inclined in one direction at the bottom of the second deodorant partition wall 135, and is provided to reduce the cross-sectional area in which the malodorous gas is inclined in one direction in the lower direction, and from one side to the other in the upper direction. It has a second guide distribution space (151a), which is a space in which the odor gas is distributed, and protrudes so as to maintain a predetermined gap with a cross-sectional area reduced to one side and a second inflow of the odor gas guided in the second guide space (136a). A second mixing body 151b having a second mixing flow path 151c in which pressure is reduced due to an increase in speed according to a decrease in cross-sectional area due to mixing of the water supplied from the space 136b is provided.

The second suction pipe 152 is inserted and disposed under the second mixing body 151b, and is provided in the form of a pipe through which the second mixing flow path 151c and the adsorption water treatment unit 190 communicate, and the second mixing flow path 151c. It is provided so that the treated water of the adsorption water treatment unit 190 is sucked by the low pressure of to be supplied to the second mixing passage (151c).

The second rising bulkhead 153 protrudes upward from a position away from one direction of the second mixing body 151b, and is provided so that the malodorous gas mixed inside the second mixing body 151b is raised by collision. do.

The second vortex generating partition wall 154 protrudes in one direction from one surface of the second deodorizing partition wall 135, and extends in one direction to the upper part away from the second rising partition wall 153, so that the raised air collides inside. While having a second vortex generation space (154a) in which vortex is generated, the vortex flows into the second circulation passage space (154b) formed at an upper position communicating with the second vortex generation space (154a) of the second deodorization partition wall (135). The odor gas is supplied to the other side so as to be circulated, and is directed downward while colliding with the second circulation guide body 154c, which is closed off to the other side of the second circulation passage space 154b, and directed to the lower side of the second ascending bulkhead 153 With the second discharge guide space 154e closed on one side so that the odor gas risen at a predetermined interval and moves to the bottom after being moved at a predetermined interval, the second discharge guide space 154e is guided to the lower portion. 2 It is provided to discharge through the second discharge passage space (154f) in a state where one side is blocked by the discharge guide partition wall (154d).

The second double vortex generating partition wall 155 is provided in the form of a partition wall protruding to one side of the second deodorizing partition wall 135 and extends in one direction while enclosing the upper portion of the second vortex generating partition wall 154 and is lowered at one end. A second double discharge guide partition wall 155a partially closed in the direction is provided to be formed.

The second double deodorization partition wall 156 is provided in the form of a partition wall protruding downward to the center of the second double vortex generation partition wall 155, and the second double circulation which is a space with the second discharge guide partition wall 154d to the other side. It has a space 156a and protrudes from the center to the bottom so as to have a second double vortex generating space 156b where vortices are generated while moving from bottom to top on one side, and a part of the bottom is inclined in one direction to reduce the cross-sectional area. 2 Double guide bulkhead (156c) is provided to be formed.

The second double mixing body 157 is disposed under the second double deodorant partition wall 156 and extends from the bottom of the second rising bulkhead 153 to close the bottom of the second double circulation space 156a. 2 Equipped with a double induction bulkhead (157a), the odor gas supplied to the second double circulation space (156a) as the cross section is reduced by extending up and down from the second double guided bulkhead (156c) and the second double guided bulkhead (157a) It is provided to have a second double mixing flow path (157b) that passes through at an increased speed and decreases the pressure.

The second double suction pipe 158 is disposed in the lower portion of the second double mixing body 157, and is provided in the form of a pipe through which the second double mixing flow path 157b and the adsorption water treatment unit 190 communicate with each other. It is provided so that the treated water of the adsorption water treatment unit 190 is sucked by the low pressure of the flow passage 157b and supplied to the second double mixing flow passage 157b.

The second double rising bulkhead 159 protrudes upward from a position away from one direction of the second double mixing body 157, and partitions the second double vortex generating space 156b, thereby separating the second double vortex generating bulkhead 155 It is provided to pass through the second double discharge space (159a) formed between the second double discharge guide bulkhead (155a) passing through the upper portion of the odor gas risen to one side away from the lower portion.

In addition, the third vortex generating unit 160 includes a third guide partition wall 161, a third suction pipe 162, a third rising partition wall 163, a third vortex generation partition wall 164, and a third double vortex generation partition wall ( 165), a third double deodorant bulkhead 166, a third double mixed body 167, a third double suction pipe 168, and a third double rising bulkhead 169.

The third guide partition wall 161 is disposed inclined in one direction below the third deodorant partition wall 138, and is provided to reduce a cross-sectional area inclined in one direction toward the lower side, and reduces the cross-sectional area through which the malodorous gas flows, from one side to the other in the upper direction. It has a third guide distribution space 161a, which is a space in which odor gas is distributed, and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas and the third inflow guided in the third guide space 139a. A third mixing body 161b having a third mixing flow path 161c in which pressure is reduced due to an increase in speed according to a reduction in cross-sectional area due to mixing of the water supplied from the space 139b is provided.

The third suction pipe 162 is inserted and disposed under the third mixing body 161b, and is provided in the form of a pipe through which the third mixing flow path 161c and the adsorption water treatment unit communicate, thereby lowering the pressure of the third mixing flow path 161c. It is provided so that the treated water of the adsorption water treatment unit 190 is sucked and supplied to the third mixing passage 161c.

The third rising bulkhead 163 protrudes upward from a position away from one direction of the third mixing body 161b, and is provided so that the malodorous gas mixed inside the third mixing body 161b is raised by collision. do.

The third vortex generating partition wall 164 protrudes in one direction from one surface of the third deodorant partition wall 138, and extends in one direction to an upper portion away from the third rising partition wall 163, so that the raised air collides inside. While having a third vortex generation space (164a) where vortex is generated, the vortex flows to the third circulation passage space (164b) formed at an upper position communicating with the second vortex generation space (154a) of the third deodorization partition wall (138). The odor gas is supplied to the other side so as to be circulated, and it is directed downward while colliding with the third circulation guide body 164c that is closed off to the other side of the third circulation passage space 164b, and is directed in one direction of the third ascending bulkhead 163 With the third discharge guide space 164e closed on one side so that the odor gas risen at a predetermined interval and moves to the bottom after being moved to one upper direction, it is provided to guide the lower part of the third discharge guide space 164e. 3 is provided to discharge through the third discharge passage space (164f) in a state where one side is blocked by the discharge guide partition wall (164d).

The third double vortex generating partition wall 165 is provided in the form of a partition wall protruding to one side of the third deodorizing partition wall 138 and extends in one direction while surrounding the upper portion of the third vortex generating partition wall 164 and is lowered at one end. A third double discharge guide partition wall 165a, which is partially closed in the direction, is provided.

The third double deodorization partition wall 166 is provided in the form of a partition wall protruding downward to the center of the third double vortex generation partition wall 165, and to the other side is a third double circulation which is a space with the third discharge guide partition wall 164d. It has a space 166a and protrudes from the center to the bottom so as to have a third double vortex generating space 166b where vortices are generated while moving from bottom to top on one side, and a part of the bottom is inclined in one direction to reduce the cross-sectional area. 3 Double guide bulkhead 166c is provided to be formed.

The third double mixing body 167 is disposed under the third double deodorant partition wall 166 and extends from the bottom of the third rising bulkhead 163 to close the bottom of the third double circulation space 166a. 3 Equipped with a double induction bulkhead (167a), the odor gas supplied to the third double circulation space (166a) as the cross section is reduced by extending up and down from the third double guide bulkhead (166c) and the third double guided bulkhead (167a) It is provided to have a third double mixing flow path (167b) to decrease the pressure by passing through at an increased speed.

The third double suction pipe 168 is inserted and disposed under the third double mixing body 167, and is provided in the form of a pipe through which the third double mixing channel 167b and the adsorption water treatment unit communicate, thereby providing a third double mixing channel 167b. It is provided so that the treated water of the adsorption water treatment unit is sucked by the low pressure of) and supplied to the third double mixing passage 167b.

The third double rising bulkhead 169 protrudes upward from a position away from one direction of the third double mixing body 167, and partitions the third double vortex generating space 166b, thereby releasing the third double vortex generating bulkhead 165 It is provided to pass through the third double discharge space (169a) formed between the third double discharge guide bulkhead (165a) passing through the upper portion of the odor gas risen to one side off the lower portion.

The above description is merely illustrative of the technical spirit of the present invention, and those of ordinary skill in the art to which the present invention pertains will be capable of various modifications and variations without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention, but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted by the claims below, and all technical spirits within the scope equivalent thereto should be interpreted as being included in the scope of the present invention.

<Explanation of reference numerals for main parts of drawings>
100: deodorizer 110: treated water supply
111: bubble catalyst water generating device 112: bubble catalyst water supply pipe
113: bubble oxidized water generator 114: bubble oxidized water supply pipe
115: bubble water generator 116: bubble water supply pipe
120: blowing deodorization section 121: blowing pump
122: ventilation mixing body 123: mixing supply pipe
124: deodorizing body 125: separating bulkhead
125a: Deodorization space 125b: Adsorption water treatment space
125c: Deodorization movement space 125d: Bulkhead treated water discharge pipe
126: Operation monitoring window 127: Water level monitoring window
130: gas deodorizing unit 131: the first injection nozzle
132: first deodorant bulkhead 132a: first deodorant space
133: first guided bulkhead 133a: distribution space
133b: first induction space 133c: first inflow space
134: second spray nozzle 135: second deodorant bulkhead
135a: second deodorant space 136: second guided bulkhead
136a: second induction space 136b: second inflow space
137: the third spray nozzle 138: the third deodorant bulkhead
138a: 3rd deodorization space 138b: gas-liquid separation space
139: 3rd guide bulkhead 139a: 3rd guide space
139b: third inflow space 140: first vortex generation unit
141: 1st guide bulkhead 141a: 1st guide distribution space
141b: first mixed body 141c: first mixed flow path
142: first suction pipe 143: first rising bulkhead
144: first vortex generating partition 144a: first vortex generating space
144b: first circulation passage space 144c: first circulation guide
144d: First discharge guide bulkhead 144e: First discharge guide space
144f: First discharge passage space 145: First double vortex generating bulkhead
145a: 1st double discharge guide bulkhead 146: 1st double deodorant bulkhead
146a: first double circulation space 146b: first double vortex generation space
146c: first double guide bulkhead 147: first double mixture
147a: 1st double induction bulkhead 147b: 1st double mixing channel
148: first double suction pipe 149: first double rising bulkhead
149a: 1st double discharge space 150: 2nd vortex generation part
151: 2nd guide bulkhead 151a: 2nd guide distribution space
151b: second mixed body 151c: second mixed flow path
152: second suction pipe 153: second rising bulkhead
154: second vortex generation partition 154a: second vortex generation space
154b: second circulation passage space 154c: second circulation guide
154d: Second discharge guide bulkhead 154e: Second discharge guide space
154f: Second discharge passage space 155: Second double vortex generating bulkhead
155a: second double discharge guide bulkhead 156: second double deodorant bulkhead
156a: second double circulation space 156b: second double vortex generation space
156c: second double guide bulkhead 157: second double mixture
157a: second double induction bulkhead 157b: second double mixing channel
158: second double suction pipe 159: second double rising bulkhead
159a: second double discharge space 160: third vortex generation unit
161: 3rd guide bulkhead 161a: 3rd guide distribution space
161b: third mixed body 161c: third mixed flow path
162: 3rd suction pipe 163: 3rd rising bulkhead
164: third vortex generation partition 164a: third vortex generation space
164b: 3rd circulation passage space 164c: 3rd circulation guide
164d: 3rd discharge guide bulkhead 164e: 3rd discharge guide space
164f: 3rd discharge passage space 165: 3rd double vortex generation bulkhead
165a: 3rd double discharge guide bulkhead 166: 3rd double deodorant bulkhead
166a: Third double circulation space 166b: Third double vortex generation space
166c: Third double guide bulkhead 167: Third double mixed body
167a: 3rd double induction bulkhead 167b: 3rd double mixing channel
168: 3rd double suction pipe 169: 3rd double rising bulkhead
169a: third double discharge space 170: contact gas-liquid separator
171: gas-liquid separation support 172: lower closed bulkhead
173: contact blade 173a: contact bend
173b: contact space 174: contact spacing retainer
180: gas-liquid separation deodorizing unit 181: gas-liquid separation deodorizing nozzle
182: gas-liquid separation and deodorization body 182a: gas-liquid separation and deodorization space
182b: separating deodorant discharge pipe 183: suction body
183a: suction space 184: diffusion body
185: diffusion blade 186: spray plate
186a: Injection hole 187: Separated water discharge pipe
188: gas-liquid separator 189: gas discharge pipe
190: adsorption water treatment unit 191: treatment body
192: treated water flow bulkhead 193: treated water discharge pipe
194: Treatment water circulation pump 195: Water level sensor
196: Water level control body

Claims (16)

A treatment water supply unit which selectively generates and supplies treated water containing bubbles, oxidizers, and catalysts to promote adsorption while oxidatively removing odor components from odor gases including odors;
It is disposed on one side of the treated water supply unit, and moves in one direction to be deodorized while receiving the odor gas and pressurizes the pressure to be blown. When malodorous gas flows in, the treated water is sprayed and passes through the environment. A blower deodorizing unit to which the malodorous component is adsorbed and to separate and purify the gas and adsorbed treated water;
It is disposed inside the blowing deodorization unit, and is divided into a plurality of spaces in one direction to generate odor gas as a vortex in an environment in which the treatment water supplied from the treatment water supply unit is sprayed in each space to primarily separate gas and liquid. A gas deodorizer that discharges in a vortex form in one state;
A gas-liquid separation and deodorization unit disposed inside the blowing deodorization unit and located on one side of the gas deodorization unit to rotate and supply the odor gas supplied in the form of a vortex while rotating to generate vortex to separate the gas and discharge purified gas; And
It is disposed inside the blowing deodorizing unit, located in the lower portion of the gas deodorizing unit, adsorbed water treatment unit for supplying the separated treatment water to circulate while oxidizing and purifying and circulating the treated water supply unit.
Vortex mix deodorizer using advanced oxidation process.
According to claim 1,
The treated water supply unit,
Bubble catalyst water generating device for generating a treated water containing a catalyst in the bubble water;
A bubble catalyst water supply pipe connected to the plurality of zones from the center to the other among a plurality of zones partitioned by the gas deodorant inside the blowing deodorizer;
A bubble oxidizing water generator that generates treated water containing oxidizing agent in the bubble water;
A bubble oxidized water supply pipe connected to a plurality of zones from the center to one of the plurality of zones partitioned by the gas deodorant inside the blowing deodorizer;
A bubble water generator for generating treated water containing bubbles; And
Including the bubble water supply pipe which is connected so that the bubble water is supplied to one end of the plurality of zones partitioned by the gas deodorant inside the blowing deodorization unit;
Vortex mix deodorizer using advanced oxidation process.
According to claim 1,
The blowing deodorant,
A blower pump disposed on one side of the treated water supply unit and providing air pressure to be blown;
A blowing mixing body disposed on the upper portion of the blower pump and connected to a portion to which the odor gas is supplied and the blower pump to mix and increase the blowing pressure of the odor gas;
A mixing supply pipe disposed on one side of the blowing mixing body and supplying an odor gas having an increased pressure; And
The vortex of the space partitioned by the gas deodorant in the center, which is disposed on one side of the blow mixing body and is connected to the mixing supply pipe to process the malodorous gas in an environment in which treated water is supplied to the treated water supply unit therein. It is provided with a separating partition wall having a deodorizing movement space in each of the generated positions, and the odor gas supplied to the upper part of the separating partition wall has a deodorizing space that is purified while moving a plurality of positions partitioned in the gas deodorizing section, It has an adsorption water treatment space in which treated water adsorbed with odor components is treated at the bottom, and a partition wall treated water discharge pipe in the form of a tube to recover the treated water falling in the space partitioned from the gas deodorization section to the adsorption water treatment section at the bottom of the separation partition wall. Deodorizing body equipped with; containing
Vortex mix deodorizer using advanced oxidation process.
The method of claim 3,
An operation monitoring window disposed at an upper position on one side of the deodorization body and provided with a transparent material for observing the deodorization operation state from the outside of the deodorization body partitioned by the gas deodorization unit; And
It includes a water level monitoring window which is arranged in a central position on one side of the deodorizing body, and is made of a transparent material for observing the water level of the treated water from the outside of the deodorizing body partitioned at the separation partition location.
Vortex mix deodorizer using advanced oxidation process.
According to claim 1,
The gas deodorant,
A first injection nozzle that is connected to the treatment water supply unit from the upper part of the other side where the odor gas is supplied in a space partitioned into the inside of the portion where the odor gas blown by the blowing deodorant is deodorized, and is injected into the odor gas supplied with bubble catalyst water. ;
Arranged inside the blowing deodorizing unit, the first deodorant space is partitioned while the first spraying nozzle is sprayed. A first deodorant bulkhead generated by vortex and discharged to one side;
It is disposed on the other lower portion of the first deodorization partition wall, is installed in an open position on the upper portion of the adsorption water treatment unit and has a distribution space through which the treated water passes through the communication with the adsorption water treatment unit on the other side. A first induction partition having a first inflow space through which the treated water stored in the adsorption water treatment section is supplied, and a first induction space with a bottom closed to guide the treated water from one side to the other;
A second injection nozzle disposed in a pair on one side of the first deodorization partition wall and connected to the treatment water supply unit to inject bubble catalyst water through the first vortex generating unit to a vortexed odorous gas;
It is disposed on one side of the first deodorization partition wall, and is divided into sections so that a second deodorization space is formed to secondaryly deodorize the malodor gas supplied from the second jet nozzle and deodorized through the first vortex generator and supplied to the vortex. A second deodorizing bulkhead that is generated as a vortex in a second vortex generating unit located at one lower portion and discharged to one side in a state in which the odor gas supplied from the lower portion in the form of a partition wall rises and is adsorbed with treated water;
The second inflow space is disposed at the other lower portion of the second deodorization partition wall and is installed in an open position on the upper portion of the adsorption water treatment unit to one side to which the treated water stored in the adsorption water treatment unit is supplied to the lower portion of the second deodorization partition wall. A second guide bulkhead having a second guide space in which a lower portion is closed so that the treated water guides in one direction from the other side;
A third injection nozzle disposed in a pair on one side of the second deodorization partition wall and connected to the treatment water supply unit to inject bubble oxidized water through the second vortex generation unit to a vortexed odor gas;
A third deodorization space and the gas-liquid separation and deodorization unit disposed on one side of the second deodorization partition wall and secondaryly deodorizing the malodor gas supplied through the second deodorization partition wall and deodorized through the second deodorization partition wall In the form of a partition wall that divides the compartment so that the installed gas-liquid separation space is formed, the odor gas supplied from the bottom rises and is adsorbed with treated water. A third deodorant bulkhead; And
The third inflow space is disposed at the other lower portion of the third deodorization partition wall and is installed in an open position on the upper portion of the adsorption water treatment unit to one side to which the treated water stored in the adsorption water treatment unit is supplied to the third deodorization partition wall. Having, a third guiding barrier having a third guiding space whose bottom is closed so that the treated water guides in one direction from the other side; including
Vortex mix deodorizer using advanced oxidation process.
The method of claim 5,
The first vortex generating unit,
The first guide, which is disposed inclined in one direction at the lower portion of the first deodorizing partition wall, is provided to reduce the cross-sectional area in which the malodorous gas is introduced by inclining in one direction in the lower portion, and the space where the malodorous gas flows from one side to the other in the upper direction. It has a distribution space and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the first induction space and the treatment water supplied from the first inflow space are mixed to increase the speed due to the reduction in cross-sectional area. A first guide bulkhead provided with a first mixing body having a first mixing flow path through which the furnace pressure is lowered and mixed;
It is disposed in the lower part of the first mixing body, and is provided in a tube shape in which the first mixing passage and the adsorption water treatment unit communicate, so that the treated water of the absorption water treatment unit is sucked by the low pressure of the first mixing passage. 1 A first suction pipe supplied to the mixing passage;
A first ascending bulkhead protruding upward from a position away from one direction of the first incorporating body, and causing the malodorous gas mixed in the inside of the first incorporating body to rise by collision; And
It has a first vortex generating space that protrudes in one direction from one side of the first deodorizing bulkhead, extends in one direction to an upper portion away from the first rising bulkhead, and generates vortices while the air rising into the interior collides, A first circulation passage space formed at an upper position in communication with the first vortex generation space of the first deodorization partition wall, supplied to the other side to circulate the odorous gas of the vortex, and closed to the other side of the first circulation passage space 1 facing the lower portion while colliding with the circulation guide body, the first discharge guide space closed on one side so that the malodorous gas which has risen at a predetermined interval in one direction of the first ascending bulkhead moves in one direction and moves downward. A first vortex generating bulkhead that discharges the odor gas guided to the second deodorization space through the first discharge passage space in a state where one side is blocked by the first discharge guide bulkhead to guide the lower part of the first discharge guide space. Containing
Vortex mix deodorizer using advanced oxidation process.
The method of claim 5,
The second vortex generating unit,
The second guide, which is disposed inclined in one direction at the lower portion of the second deodorizing partition wall, is provided to reduce the cross-sectional area in which the malodorous gas is introduced by inclining in one direction in the lower portion, and in which the malodorous gas is distributed from one side to the other in the upper direction. It has a distribution space and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the second induction space and the treatment water supplied from the second inflow space are mixed to increase the speed due to the reduction in cross-sectional area. A second guide bulkhead provided with a second mixing body having a second mixing flow path through which the furnace pressure is lowered and mixed;
It is disposed in the lower portion of the second mixing body, and is provided in a tube shape in which the second mixing passage and the adsorption water treatment unit communicate, so that the treated water of the absorption water treatment unit is sucked by the low pressure of the second mixing passage. 2 A second suction pipe to supply to the mixing passage;
A second ascending bulkhead protruding upward from a position away from one direction of the second mixed body, and causing the malodorous gas mixed inside the second mixed body to rise by collision; And
It has a second vortex generating space that protrudes in one direction from one side of the second deodorizing bulkhead and extends in one direction to an upper part away from the second rising bulkhead, where vortex is generated while air is raised into the interior and collides. A second circulation passage space formed at an upper position communicating with the second vortex generation space of the second deodorization partition wall, and supplied to the other side so that the odor gas of the vortex is circulated, and closed to the other side of the second circulation passage space 2 While colliding with the circulation guide body, it is directed to the lower portion, and the second discharge guide space is closed on one side so that the malodorous gas which has risen at a predetermined interval in one direction of the second rising bulkhead moves in one direction and moves downward. A second vortex generating bulkhead that discharges the odor gas guided to the third deodorization space through the second discharge passage space with one side blocked by the second discharge guide bulkhead so as to guide it to the lower portion of the second discharge guide space. Containing
Vortex mix deodorizer using advanced oxidation process.
The method of claim 5,
The third vortex generating unit,
The third guide, which is disposed inclined in one direction at the lower portion of the third deodorization partition wall, is provided to reduce the cross-sectional area in which the malodorous gas is introduced by inclining in one direction in the lower portion, and the space where the malodorous gas flows from one side to the other in the upper direction. It has a distribution space and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the third induction space and the treatment water supplied from the third inflow space are mixed to increase the speed due to the reduction in cross-sectional area. A third guide bulkhead provided with a third mixing body having a third mixing flow path through which the furnace pressure is lowered and mixed;
Is disposed in the lower portion of the third mixing body, the third mixing flow path and the adsorption water treatment section is provided in a tube shape to be communicated with the treated water of the adsorption water treatment section is sucked by the low pressure of the third mixing flow path 3 A third suction pipe supplied to the mixing passage;
A third ascending bulkhead protruding upward from a position away from one direction of the third mixed body, and causing the malodorous gas mixed in the third mixed body to rise by collision; And
It has a third vortex generating space that protrudes in one direction from one side of the third deodorizing bulkhead and extends in one direction to an upper part away from the third rising bulkhead, where vortices are generated while air rising therein collides. A third circulation passage space formed at an upper position in communication with the third vortex generation space of the third deodorization partition wall, supplied to the other side so that the odor gas of the vortex is circulated, and closed to the other side of the third circulation passage space 3 Conflict with the circulation guide body and face downward, and the third discharge guide space closed on one side so that the odor gas risen at a predetermined interval in one direction of the third rising bulkhead moves in one direction and moves downward. A third vortex generating bulkhead that discharges odor gas guided to the gas-liquid separation and deodorization unit through a third discharge passage space in a state where one side is blocked by a third discharge guide bulkhead so as to guide to a lower portion of the third discharge guide space; Containing
Vortex mix deodorizer using advanced oxidation process.
The method of claim 5,
The first vortex generating unit,
The first guide, which is disposed inclined in one direction at the lower portion of the first deodorizing partition wall, is provided to reduce the cross-sectional area in which the malodorous gas is introduced by inclining in one direction in the lower portion, and the space where the malodorous gas flows from one side to the other in the upper direction. It has a distribution space and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the first induction space and the treatment water supplied from the first inflow space are mixed to increase the speed due to the reduction in cross-sectional area. A first guide bulkhead provided with a first mixing body having a first mixing flow path through which the furnace pressure is lowered and mixed;
It is disposed in the lower part of the first mixing body, and is provided in a tube shape in which the first mixing passage and the adsorption water treatment unit communicate, so that the treated water of the absorption water treatment unit is sucked by the low pressure of the first mixing passage. 1 A first suction pipe supplied to the mixing passage;
A first ascending bulkhead protruding upward from a position away from one direction of the first incorporating body, and causing the malodorous gas mixed in the inside of the first incorporating body to rise by collision;
It has a first vortex generating space that protrudes in one direction from one side of the first deodorizing bulkhead, extends in one direction to an upper portion away from the first rising bulkhead, and generates vortices while the air rising into the interior collides, A first circulation passage space 0 formed at an upper position communicating with the first vortex generation space of the first deodorization partition wall is supplied to the other side so that the odor gas of the vortex is circulated, and is closed off from the other side of the first circulation passage space. 1 While colliding with the circulating guide body, it is directed downward, and the first discharge guide space is closed on one side so that the odor gas risen at a predetermined interval in one direction of the first ascending bulkhead moves to one upper direction and then moves downward. A first vortex generating bulkhead passing through the first discharge passage space and being discharged while one side is blocked by the first discharge guide bulkhead so as to guide the lower portion of the first discharge guide space;
It is provided in the form of a partition wall that protrudes to one side of the first deodorant partition wall, and extends in one direction while enclosing the upper portion of the first vortex generation partition wall, and forms a first double discharge guide partition wall partially closed in one direction at one end. 1 double vortex generating bulkhead;
It is provided in the form of a partition wall protruding downward to the center of the first double vortex generating partition wall, and has a first double circulation space, which is a space with the first discharge guide partition wall on the other side, and moves from one bottom to the other in a vortex. A first double deodorant bulkhead formed with a first double guide bulkhead protruding from the center to the bottom so as to have a first double vortex generating space in which a part of the bottom is inclined in one direction to reduce the cross-sectional area;
It is disposed under the first double deodorant bulkhead, and has a first double guided bulkhead extending from the bottom of the first raised bulkhead to close the bottom of the first double circulation space, and the first double guided bulkhead A first double mixture having a first double mixing flow path extending upward and downward from the first double inducing bulkhead and having a first double mixing flow path through which the odor gas supplied to the first double circulation space decreases pressure through an increased speed;
Inserted and disposed under the first double mixing body, the first double mixing flow passage and the adsorption water treatment part are provided in a pipe shape to communicate with the suction water treatment part by the low pressure of the first double mixing flow passage A first double suction pipe which is supplied to the first double mixing channel; And
It protrudes upward from a position away from one direction of the first double mixture, and while partitioning the first double vortex generating space, falls to the lower portion of the first double vortex generating partition wall and passes the odor gas raised to one side through the upper part. Including the first double upward bulkhead to discharge through the first double discharge space formed between the first double discharge guide bulkhead
Vortex mix deodorizer using advanced oxidation process.
The method of claim 5,
The second vortex generating unit,
The second guide, which is disposed inclined in one direction at the lower portion of the second deodorizing partition wall, is provided to reduce the cross-sectional area in which the malodorous gas is introduced by inclining in one direction in the lower portion, and in which the malodorous gas is distributed from one side to the other in the upper direction. It has a distribution space and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the second induction space and the treatment water supplied from the second inflow space are mixed to increase the speed due to the reduction in cross-sectional area. A second guide bulkhead provided with a second mixing body having a second mixing flow path through which the furnace pressure is lowered and mixed;
It is disposed in the lower portion of the second mixing body, and is provided in a tube shape in which the second mixing passage and the adsorption water treatment unit communicate, so that the treated water of the absorption water treatment unit is sucked by the low pressure of the second mixing passage. 2 A second suction pipe to supply to the mixing passage;
A second ascending bulkhead protruding upward from a position away from one direction of the second mixed body, and causing the malodorous gas mixed inside the second mixed body to rise by collision;
It has a second vortex generating space that protrudes in one direction from one side of the second deodorizing bulkhead and extends in one direction to an upper part away from the second rising bulkhead, where vortex is generated while air is raised into the interior and collides. A second circulation passage space formed at an upper position communicating with the second vortex generation space of the second deodorization partition wall, and supplied to the other side so that the odor gas of the vortex is circulated, and closed to the other side of the second circulation passage space 2 A second discharge guiding space closed on one side so as to collide with the circulation guide body and face downward, and the odor gas risen at a predetermined interval in one direction of the second ascending bulkhead moves to one upper direction and then moves downward. A second vortex generating partition wall that discharges through the second discharge passage space in a state where one side is blocked by the second discharge guide partition wall to guide the lower part of the second discharge guide space;
It is provided in the form of a partition wall that protrudes to one side of the second deodorant partition wall, and extends in one direction while enclosing the upper portion of the second vortex generating partition wall, and forms a second double discharge guide partition wall partially closed in one direction at one end. 2 double vortex generating bulkheads;
It is provided in the form of a partition wall protruding downward from the center of the second double vortex generating partition wall, and has a second double circulation space, which is a space with the second discharge guide partition wall, on the other side, while moving from one bottom to the top. A second double deodorant bulkhead formed with a second double guide bulkhead protruding from the center to the bottom so as to have a second double vortex generating space in which a part of the bottom is inclined in one direction to reduce the cross-sectional area;
It is disposed under the second double deodorant bulkhead, and has a second double guided bulkhead extending from the bottom of the second raised bulkhead to close the bottom of the second double circulation space, and the second double guide bulkhead A second double mixing body having a second double mixing flow path extending upward and downward from the second double inducing bulkhead and reducing the pressure by passing the malodor gas supplied to the second double circulation space at an increased speed as the cross-sectional area is reduced;
Is disposed in the lower portion of the second double mixing body, the second double mixing flow path and the adsorption water treatment unit is provided in a tube shape in communication with the second double mixing flow path by the low pressure of the absorption water treatment unit suction A second double suction pipe which is supplied to the second double mixing channel; And
It protrudes upward from a position away from one direction of the second double-mixture, and while partitioning the second double vortex generating space, falls below the second double vortex-generating partition wall and passes the odor gas raised to one side through the top. Including the second double rising bulkhead to discharge through the second double discharge space formed between the second double discharge guide bulkhead
Vortex mix deodorizer using advanced oxidation process.
The method of claim 5,
The third vortex generating unit,
The third guide, which is disposed inclined in one direction at the lower portion of the third deodorization partition wall, is provided to reduce the cross-sectional area in which the malodorous gas is introduced by inclining in one direction in the lower portion, and the space where the malodorous gas flows from one side to the other in the upper direction. It has a distribution space and protrudes so as to maintain a predetermined interval up and down in which the cross-sectional area is reduced to one side, and the odor gas guided in the third induction space and the treatment water supplied from the third inflow space are mixed to increase the speed due to the reduction in cross-sectional area. A third guide bulkhead provided with a third mixing body having a third mixing flow path through which the furnace pressure is lowered and mixed;
Is disposed in the lower portion of the third mixing body, the third mixing flow path and the adsorption water treatment section is provided in a tube shape to be communicated with the treated water of the adsorption water treatment section is sucked by the low pressure of the third mixing flow path 3 A third suction pipe supplied to the mixing passage;
A third ascending bulkhead protruding upward from a position away from one direction of the third mixed body, and causing the malodorous gas mixed in the third mixed body to rise by collision;
It has a third vortex generating space that protrudes in one direction from one side of the third deodorizing bulkhead and extends in one direction to an upper part away from the third rising bulkhead, where vortices are generated while air rising therein collides. The third circulation passage space 164b formed at an upper position communicating with the third vortex generation space of the third deodorization partition wall is supplied to the other side so as to circulate the odor gas of the vortex, and is closed off to the other side of the third circulation passage space. The third discharge guide is closed so that the odor gas rises to one side of the third ascending bulkhead and moves to the bottom after being moved to one upper direction. A third vortex generating partition wall having a space and passing through the third discharge passage space in a state where one side is blocked by a third discharge guide partition wall to guide the lower part of the third discharge guide space;
It is provided in the form of a partition wall that protrudes to one side of the third deodorant partition wall, and extends in one direction while enclosing the upper portion of the third vortex generation partition wall and forms a third double discharge guide partition wall partially closed in one direction toward the lower end. 3 double vortex generating bulkheads;
It is provided in the form of a partition wall protruding downward from the center of the third double vortex generating partition wall, and has a third double circulation space, which is a space with the third discharge guide partition wall, on the other side, while moving from one bottom to the top. A third double deodorant bulkhead formed with a third double guide bulkhead projecting from the center to the bottom to have a third double vortex generating space where a part of the lower portion is inclined in one direction to reduce the cross-sectional area;
It is disposed under the third double deodorant bulkhead, and has a third double guided bulkhead extending from the bottom of the third raised bulkhead to close the bottom of the third double circulation space, and the third double guided bulkhead A third double mixing body having a third double mixing flow path extending upward and downward from the third double inducing bulkhead and reducing the pressure by passing the malodorous gas supplied to the third double circulation space at an increased speed;
Is disposed in the lower portion of the third double mixing body, the third double mixing flow path and the adsorption water treatment unit is provided in a tube shape to communicate with the suction pressure of the treated water by the low pressure of the third double mixing flow path A third double suction pipe which is supplied to the third double mixing channel; And
It protrudes upward from a position away from one direction of the third double-mixture, and while partitioning the third double vortex generating space, falls below the third double vortex-generating partition wall and passes through the upper side of the malodorous gas raised to one side. Including a third double rising bulkhead to discharge through the third double discharge space formed between the third double discharge guide bulkhead
Vortex mix deodorizer using advanced oxidation process.
According to claim 1,
It is disposed inside the blowing deodorization unit, and is installed in a selective space in a plurality of compartments separated from the gas deodorization unit, and the malodor gas vortexed in the gas deodorization unit is directed toward the central upper portion where the lower portion is closed from the other lower portion. Further comprising a contact gas-liquid separating unit provided to separate the liquid primarily by contact while moving, and to separate the liquid secondary while moving from the upper center to one lower portion.
Vortex mix deodorizer using advanced oxidation process.
The method of claim 12,
The contact gas liquid separation unit,
It is disposed inside the blowing deodorization unit, and is provided at an optional plurality of locations among a plurality of divisions partitioned by the gas deodorization unit, so that both ends of one side and the other are located at the top of each section and inclined so that the center is located at the bottom. A gas-liquid separation support provided in such a manner that the odor gas supplied to the other lower portion passes through the odor gas and is raised to the center to move to one lower portion after being moved to one lower portion;
A lower closing bulkhead disposed at a lower center portion of the gas-liquid separation support and positioned at an upper portion of the separated portion so that the malodor gas and the treated water of the blowing deodorization unit are received;
The gas-liquid separation support is inserted and disposed in a plurality of spaced apart at predetermined intervals so as to have a contact space penetrating up and down in one direction from the other. A contact blade having at least one curved contact portion in one and the other direction so as to be separated; And
It is inserted into the gas-liquid separation support, and is located between the contact blades to maintain a gap of the contact space contact gap holding member; including
Vortex mix deodorizer using advanced oxidation process.
According to claim 1,
The gas-liquid separation and deodorization unit,
The gas-liquid separation which is disposed inside the blowing deodorization unit and is provided in a pair at one end position where purified malodor gas is supplied from the lower part of the space partitioned by the gas deodorization unit and is installed to spray bubble water supplied from the treatment water supply unit Deodorizing nozzles;
It is disposed between the gas-liquid separation and deodorizing nozzles, and has a gas-liquid separation and deodorization space in which adsorbed particles in which the supplied gas is rotated fall in the form of treated water. A gas-liquid separating deodorizing body having a separating deodorizing water discharge pipe discharging into the space;
The gas-liquid separation and deodorizing body is arranged to protrude from a plurality of positions in a radial position on the outer periphery, and the suction body has a suction space that is sucked toward one direction in a round shape so that the malodorous gas passing through the environment in which the bubble water is sprayed rotates in one direction ;
A diffusion body disposed above the gas-liquid separation and deodorization body and provided in a cylindrical shape at an upper center position of the gas-liquid separation and deodorization space;
A diffusion blade disposed in a plurality of radially protruding outward directions on the outer periphery of the diffusion body, and having a round blade curved in one direction so that the gas rotated inside the gas-liquid separation and deodorization space diffuses in the same rotational direction;
It is disposed on the upper portion of the diffusion body, is provided in the form of a plate that blocks the space divided by the partition wall of the gas-liquid separation deodorizing body, a jet plate having a plurality of through-holes through which the gas passes to filter impurities inside ;
The gas-liquid separation and deodorizing nozzle is disposed at the bottom, and the treated water discharged from the separation and deodorization water discharge pipe is separated under the partition portion separating the gas deodorization unit and the adsorption water treatment unit. discharge pipe;
A gas-liquid separator disposed on an upper portion of the injection plate and filtering while purified gas passes through the gas-liquid separation and deodorizing body; And
It is disposed protruding on one upper portion of the blowing deodorant, the gas discharge pipe in the form of a pipe through which the gas passing through the gas-liquid separator is discharged to the outside
Vortex mix deodorizer using advanced oxidation process.
According to claim 1,
The adsorption water treatment unit,
It is disposed inside the blowing deodorization unit, and the adsorbed treated water is located at the lower part of the separation and is located in a portion where the odorous gas is purified and discharged from the gas deodorization unit and the gas deodorization unit is divided into a plurality. A processing body in the form of a water tank that stores the treated water discharged from the blowing deodorizer;
It is disposed inside the processing body, and a plurality of compartments are partitioned inside the processing body so that the treated water discharged from one side to the other moves from one side to the other so that the malodorous components are purified by reaction with the oxidizing agent and the catalyst. A treated water flow partition wall provided in the form of a flowing partition wall; And
It is disposed on one side of the treatment body, the treatment water discharge pipe installed to discharge the circulated treatment water to the outside
Vortex mix deodorizer using advanced oxidation process.
The method of claim 15,
It is disposed on one side of the treatment body, connects the treatment water discharge pipe and the treatment water supply, and supplies purified water in the treatment body to the treatment water supply to provide supply pressure to be circulated. Circulation pump;
A water level sensing sensor disposed inside the blowing deodorizing unit and positioned between the gas deodorizing unit and the processing body to detect the level of the treated water; And
It is arranged on one side of the treatment body, and is connected to the treatment water circulation pump and the water level sensor, respectively, maintaining the water level to the lower position of the gas deodorizing unit before the blowing deodorizing unit is operated, and processing when the blowing deodorizing unit is operated Containing a water level control unit for controlling the operation of the treatment water circulation pump by the measurement value of the water level sensor so that the odor gas generated in the vortex of the gas deodorization unit to contact the treated water by increasing the water level
Vortex mix deodorizer using advanced oxidation process.

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