KR101482056B1 - A Ventilating System for Energy Recovery and White Smoke Removal - Google Patents

Abstract

The present invention relates to an energy recovery type ventilation system having a white smoke condensing and removing function. According to the present invention, a pair of distributors (20, 20′) is combined with the right and left of a heat storage material (10) densely having a plurality of through holes. Indoor exhaust gas containing white smoke is injected by a ventilator (205) through an inlet (201) and passing through a heat storage material (10), and the white smoke is condensed and removed. Moreover, gas wherein white smoke is removed is discharged through an outlet (202) to an outside. Outdoor air is passing through the heat storage material (10) in the opposite direction of exhaust gas by a ventilator (206) through an inlet (203), and thereby air heated at the appropriate temperature by heat exchanging flows into an inside through an outlet (204). According to the present invention, distributors (20, 20′) respectively consist of a distributing device (21) and a lower distributing part (23), and the distributing device (21) rotates at a constant speed around a vertical shaft (not illustrated) while a ventilation system is operated. Moreover, inflow gas and exhaust gas are appropriately distributed while the distributing device (21) rotates at a constant speed.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an energy recovery type ventilation system,

The present invention relates to a ventilation system for removing white smoke contained in exhaust gas. More specifically, the present invention relates to a ventilation system capable of condensing and removing white smoke contained in exhaust gas and recovering energy through heat exchange.

White smoke (white smoke) is the result of saturated water vapor (relative humidity 98 to 100%) discharged from a cooling tower of an industrial facility such as a factory, in the process of diluting with cool air below the dew point of the cooling tower. Condensed and looks like white smoke. The white smoke is pure water vapor and not a pollutant, but it can be misinterpreted as a visual pollutant generated in the manufacturing process when viewed from the outside of the plant, and condensed water drops on the road around the cooling tower, causing a safety accident by freezing the road in winter do. The white smoke phenomenon does not occur throughout the year, but it occurs mainly in the high relative humidity, with the temperature around the cooling tower being as low as about 18 ~ 20 ℃, and the atmospheric condition of the white smoke changes depending on the cooling condition.

Atmospheric conditions in which white smoke occurs are closely related to relative humidity. If the relative humidity of the air discharged from the cooling tower is reduced as much as possible and discharged into the atmosphere in the unsaturated air state, it is possible to significantly reduce the temperature of the air below the dew point in the process of dilution with the air to prevent the condensation of the water vapor in the exhaust air It is possible to prevent the white smoke phenomenon.

Cooling tower In order to cool the cooling water, which is the main purpose of the cooling tower, to prevent condensation of water vapor in the cooling tower exhaust air and to reduce the white smoke phenomenon, cooling water should be passed through the filler material. By reducing the relative humidity by increasing the temperature by heating the saturated air passing through the filler, or by lowering the discharge temperature and the relative humidity by mixing saturated air passing through the filler and air of very low relative humidity, the white smoke can be reduced.

When the air passing through the filling material is heated by using an external heat source, it is referred to as a series air flow (air flow course). This format requires a separate heat source, so additional heat source equipment is needed unless there is available waste heat.

The present invention provides a new ventilation system that can reduce energy by collecting and removing white smoke contained in exhaust gas and recovering energy through heat exchange during the condensing process.

In the present invention, exhaust gas from a room containing white smoke is passed through a heat storage material to condense and remove white smoke, exhaust gas from which white smoke has been removed to the outside, and allow outside air to pass through the heat storage material The present invention provides a new ventilation system capable of introducing air heated to an appropriate temperature through heat exchange into a room.

SUMMARY OF THE INVENTION An object of the present invention is to provide a new ventilation system that can reduce energy by collecting and removing white smoke contained in exhaust gas and recovering energy through heat exchange during the condensing process.

Another object of the present invention is to provide an exhaust gas purifying apparatus and an exhaust gas purifying apparatus that exhaust gas from a room containing white smoke is passed through a heat storage material to condense and remove white smoke, And the air heated to an appropriate temperature through the heat exchange can be introduced into the room.

It is still another object of the present invention to provide a conventional regenerative thermal oxidizer (RTO) type combustion method for burning a pollutant gas containing various kinds of harmful substances such as volatile organic compounds (VOC) In an oxidation system, it is intended to provide a new ventilation system for removing white smoke by cooling and condensing white smoke using a cooler instead of combustion oxidation.

The above and other objects of the present invention can be achieved by the present invention described in detail below.

The energy recovery type ventilation system having the function of removing white condensate according to the present invention is configured such that a pair of distributing devices 20 and 20 'are coupled to the left and right of the heat storage material 10 in which a plurality of through holes are densely formed, The exhaust gas from the room is injected by the blower 205 through the injection port 201 and passed through the heat storage material 10 to condense and remove the white smoke, And external air is passed through the injection port 203 by the blower 206 in the direction opposite to the exhaust gas to the heat storage material 10 to heat the air heated to a proper temperature through the outlet 204 So as to be introduced into the room.

The dispenser 20, 20 'of the present invention comprises a dispenser 21 and a lower dispenser 23, respectively, while the ventilator system of the present invention is in operation, the dispenser 21 has a longitudinal axis (not shown) As shown in FIG. The distributor 21 appropriately distributes the inflow gas and the exhaust gas while rotating at a constant speed.

The distributor 21 is composed of an upper plate 211, a partition member 212 and a lower plate 213. A passage 211a is formed in the upper plate 211 to allow inflow gas to pass therethrough and passages 211b A passage 212c is formed in the partition member 212 so that the inflow gas is allowed to pass therethrough and a passage 212b is formed so that the purge gas is allowed to pass therethrough, A passageway 213c is formed in the lower plate 213 so that the inflow gas is allowed to pass therethrough and a passageway 213b is formed so that the purge gas is allowed to pass therethrough and a passageway 213c is formed do. The upper plate 211, the partition member 212, and the lower plate 213 are assembled as partitioned, and integrally rotated to pass inflow gas, exhaust gas, and purge gas.

In order for the inflow gas, the exhaust gas and the purge gas to pass through separately in the lower portion 23, the injection port 201 or 203 through which the inflow gas flows is passed only through the passageway 213a of the lower plate 213, The discharge port 202 or 204 is discharged only through the passage 213c of the lower plate 213 and the purge pipe 207 into which the purge gas is introduced passes only through the passage 213b of the lower plate 213. [

An upper portion distributing portion 23 may be further provided between the distributor 21 and the heat storage material 10 if necessary. The upper portion distributing portion 23 is assembled while being concentric with the distributor 21, but is fixed instead of rotating as the distributor 21.

In another embodiment of the present invention, a gear wheel 32 is formed on a cylindrical heat storage material 10 so as to fix the distributor 21 and rotate the heat storage material 10 at a constant speed, and the gear motor 30 and the chain 31) are also possible.

According to another embodiment of the present invention, in a conventional regenerative burning (RTO) combustion oxidation system for burning a pollutant gas containing various kinds of harmful substances such as volatile organic compounds (VOC) to remove harmful components, A fresh ventilation system for removing white smoke by cooling and condensing white smoke using a cooler (50).

A plurality of ventilation systems having a unit structure in which a pair of distributing devices 20 and 20 'are coupled to the left and right of the heat storage material 10 can be arranged in a modular fashion according to the capacity of the processing gas.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings.

The present invention provides a new ventilation system capable of reducing energy by collecting and removing white smoke contained in the exhaust gas and recovering energy through heat exchange during the condensation process. The present invention provides various kinds of harmful substances such as volatile organic compounds (VOC) A new ventilation system for removing white smoke by cooling and condensing white smoke using a cooler instead of combustion oxidation in a conventional regenerative burning (RTO) combustion oxidation system that burns contaminant gases containing material to remove harmful components The present invention provides the effect of the present invention.

FIG. 1 is a schematic exploded perspective view of an energy recovery type ventilation system having a function of removing white condensate according to an embodiment of the present invention.
FIG. 2 is an exploded perspective view for explaining the structure of the distributor 21 of FIG. 1.
3 is an exploded perspective view for explaining the structure of the distributor 21, the lower portion distributing portion 23, and the upper portion distributing portion 25.
4 shows another embodiment of the present invention in which a gear wheel 32 is formed in a cylindrical heat storage material 10 so as to fix the distributor 21 and rotate the heat storage material 10 at a constant speed, And a chain (31). The ventilation system shown in FIG.
FIG. 5 is a schematic view of a conventional combustion regenerative burning (RTO) combustion oxidation system for burning a pollutant gas containing various kinds of harmful substances such as volatile organic compounds (VOC) And is a schematic illustration of a ventilation system for removing white smoke by cooling and condensing white smoke using a cooler 50 instead of combustion oxidation.

The present invention relates to a ventilation system for removing white smoke contained in an exhaust gas, and more particularly, to a ventilation system capable of condensing and removing white smoke contained in an exhaust gas and recovering energy through heat exchange.

The energy recovery type ventilation system having the function of removing white condensate according to the present invention has a structure in which a pair of distributing devices 20 and 20 'are coupled to the left and right of the heat storage material 10 in which a plurality of through holes are densely formed. FIG. 1 is a schematic exploded perspective view of an energy recovery type ventilation system having a function of removing white condensate according to an embodiment of the present invention.

The distributing apparatuses 20 and 20 'are roughly divided into a distributor 21 and a lower distributing unit 23 and are assembled concentrically by a vertical axis (not shown). During operation of the ventilation system of the present invention, the distributor 21 rotates at a constant rate about a vertical axis (not shown). The distributor 21 appropriately distributes the inflow gas and the exhaust gas while rotating at a constant speed.

As shown in FIG. The ventilation system of the present invention is divided into two spaces around the wall, one of which is indoor and the other is outdoor. And is located in the middle of the heat storage material (10).

The lower portion 23 of the distribution apparatus 20 is provided with an injection port 201 for injecting the exhaust gas from the room containing the white smoke and air outside the room through the heat storage material 10, And an air blower 205 is installed at one position of the injection port 201 so as to allow the exhaust gas to pass through the heat storage material 10. [ The blower 205 may be installed inside the lower portion portion 23 as shown in FIG. 1, or may be installed outside.

The lower portion 23 of the distribution apparatus 20 'is provided with an inlet 203 for injecting outside air and an outlet 202 for discharging exhaust gas from which white smoke has been removed to the outside, The blower 206 is installed at one position of the injection port 203 to pass through the injection port 10. The blower 206 may be installed inside the lower portion portion 23 as shown in FIG. 1 or may be installed outside.

The heat storage material 10 is preferably a ceramic heat storage material usually used in a conventional combustion oxidation system. The heat storage material 10 has a cylindrical shape or a rectangular parallelepiped shape and a through hole is formed at regular intervals like a net in the longitudinal direction. For example, a rectangular parallelepiped thermal storage material having a length of 150 mm and a length of 300 mm may be used, but the present invention is not limited thereto and the size can be changed according to the capacity.

The energy recovery type ventilation system having the function of removing white condensate according to the present invention is configured such that a pair of distributing devices 20 and 20 'are coupled to the left and right of the heat storage material 10 in which a plurality of through holes are densely formed, The exhaust gas from the room is injected by the blower 205 through the injection port 201 and passed through the heat storage material 10 to condense and remove the white smoke, And external air is passed through the injection port 203 by the blower 206 in the direction opposite to the exhaust gas to the heat storage material 10 to heat the air heated to a proper temperature through the outlet 204 So as to be introduced into the room.

The dispenser 20, 20 'of the present invention comprises a dispenser 21 and a lower dispenser 23, respectively, while the ventilator system of the present invention is in operation, the dispenser 21 has a longitudinal axis (not shown) As shown in FIG. The distributor 21 appropriately distributes the inflow gas and the exhaust gas while rotating at a constant speed.

FIG. 2 is an exploded perspective view for explaining the structure of the distributor 21 of FIG. 1.

The distributor 21 is composed of an upper plate 211, a partition member 212 and a lower plate 213. A passage 211a is formed in the upper plate 211 to allow inflow gas to pass therethrough and passages 211b A passage 212c is formed in the partition member 212 so that the inflow gas is allowed to pass therethrough and a passage 212b is formed so that the purge gas is allowed to pass therethrough, A passageway 213c is formed in the lower plate 213 so that the inflow gas is allowed to pass therethrough and a passageway 213b is formed so that the purge gas is allowed to pass therethrough and a passageway 213c is formed do. The upper plate 211, the partition member 212, and the lower plate 213 are assembled as partitioned, and integrally rotated to pass inflow gas, exhaust gas, and purge gas. Numeral 212i shown in FIG. 2 represents the position of a partition or partition.

3 is an exploded perspective view for explaining the structure of the distributor 21, the lower portion distributing portion 23, and the upper portion distributing portion 25.

In order for the inflow gas, the exhaust gas and the purge gas to pass through separately in the lower portion 23, the injection port 201 or 203 through which the inflow gas flows is passed only through the passageway 213a of the lower plate 213, The discharge port 202 or 204 is discharged only through the passage 213c of the lower plate 213 and the purge pipe 207 into which the purge gas is introduced passes only through the passage 213b of the lower plate 213. [

An upper portion distributing portion 23 may be further provided between the distributor 21 and the heat storage material 10 if necessary. The upper portion distributing portion 23 is assembled while being concentric with the distributor 21, but is fixed instead of rotating as the distributor 21.

The principle of the distributor 21 as well as the structure of the lower portion distributor 23 and the upper portion distributor 25 are the same as those of the conventional distributor 21 for burning the pollutant gas containing harmful substances such as volatile organic compounds (VOC) The structure adopted in the combustion oxidation system of the regenerative burning (RTO) type is described in detail in the other patents of the present applicants, patents 1011361 and 1029867.

In another embodiment of the present invention, a gear wheel 32 is formed on a cylindrical heat storage material 10 so as to fix the distributor 21 and rotate the heat storage material 10 at a constant speed, and the gear motor 30 and the chain 31) are also possible. A diagram of this embodiment is schematically shown in FIG.

The ventilation system of FIG. 4 can achieve the same effect as a system for rotating the distributor 21 by rotating the regenerator 10 at a constant speed by fixing the distributor 21. Since the heat storage material 10, the distributor 21 and the lower portion 23 are all assembled on the same axis, it is necessary to fix the distributor 21 and the lower portion 23 and rotate the heat storage material 10 only in a structural .

FIG. 5 is a schematic view of a conventional combustion regenerative burning (RTO) combustion oxidation system for burning a pollutant gas containing various kinds of harmful substances such as volatile organic compounds (VOC) And is a schematic illustration of a ventilation system for removing white smoke by cooling and condensing white smoke using a cooler 50 instead of combustion oxidation.

Referring to FIG. 5, a purge pipe 208 for introducing purge gas into the chamber is installed at the front end of the purge pipe 207, and a purge pipe 208 for introducing the inflow gas into the combustion chamber An air blower 205 is installed. The gaseous white gasses are transferred to the distributor 21 along the injection port 201 by the blower 205. The white smoke passing through the distributor is cooled and condensed by the upper cooler 50 while passing through the heat storage material. The gas from which the white smoke has been removed descends along the heat storage material 10 and is discharged to the chimney 300 along the discharge port 202 via the distributor 21. A cooler (50) is provided to condense the white smoke by cooling the gas at the top of the chamber, and the condensed water vapor is collected and discharged downward.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It should be understood that the invention is included in the scope of the invention.

10. (Ceramic) Heat storage material 203: (Outside gas)
20: inner dispensing device 204: outlet
20 ': Outside distributor 205, 206: Blower
20, 20 ': distribution device 207: purge pipe
21. Distributor 208: Fuzzy fan
23: lower distributor 211: upper plate
25: upper distributor 212: partition member (middle plate)
30: geared motor 212i: partition
31: chain 213: bottom plate
32: Cogs 213a, 212a, 211a: Inlet gas passage
50: cooler 213b, 212b, 211b: purge gas passage
213c, 212c, 211c: exhaust gas passage 201: (white gas) inlet
300: chimney 202: outlet

Claims (5)

And a pair of distributing devices 20 and 20 'are coupled to the left and right of the heat storage material 10 in which a plurality of through holes are densely formed. The exhaust gas from the room containing the white smoke is supplied to the blower 205 to condense and remove the white smoke passing through the heat storage material 10 so that the gas from which white smoke has been removed is discharged to the outside through the discharge port 202 and the outside air is blown through the blower 206) through the heat storage material (10) in a direction opposite to the discharge gas to exchange heat, and the air heated to a suitable temperature is introduced into the room through the discharge port (204) Type ventilation system.
The apparatus according to claim 1, wherein the distributor (20, 20 ') comprises a distributor (21) and a lower distributor (23)
The distributor 21 is composed of an upper plate 211, a partitioning member 212 and a lower plate 213 rotating at a constant speed around a vertical axis,
A passageway 211a is formed in the upper plate 211 to allow the inflow gas to pass therethrough and a passageway 211b is formed so that the purge gas passes therethrough.
A passage 212a is formed in the partition member 212 so that the inflow gas is allowed to pass therethrough and a passage 212b is formed to allow the purge gas to pass therethrough,
A passage 213a is formed in the lower plate 213 so that the inflow gas is allowed to pass therethrough and a passage 213b is formed so that the purge gas is passed therethrough,
The lower portion 23 has an inlet 201 or 203 through which only the inflow gas is introduced to pass through the passage 213a of the lower plate 213 so that the inflow gas, And the purge pipe 207 into which the purge gas is introduced passes only through the passageway 213b of the lower plate 213. In this case,
Wherein the energy recovery type ventilation system has a function of removing white smoke condensate.
The energy recovery type ventilating system according to claim 2, further comprising an upper portion distributing portion (23) between the distributor (21) and the heat storage material (10).
The distribution apparatuses 20 and 20 'have a structure in which a pair of distribution apparatuses 20 and 20' are coupled to the right and left of the heat storage material 10 in which a plurality of through holes are densely formed. A gear 32 is formed on the cylindrical heat storage material 10 so as to rotate the heat storage material 10 at a constant speed while the distributor 21 is fixed and the gear motor 30 And a chain (31)
The exhaust gas from the room containing the white smoke is injected by the blower 205 through the injection port 201 and passed through the heat storage material 10 to condense and remove the white smoke and to remove the white smoke from the exhaust port 202 And the outside air is passed through the injection hole 203 by the blower 206 and the heat storage material 10 in the direction opposite to the exhaust gas so as to heat the air heated to the proper temperature through the outlet 204 And the air is introduced into the room through the ventilation duct.
A purge pipe (208) for introducing purge gas into the chamber at a front end of the purge pipe (207);
A blower 205 for introducing the inflow gas into the combustion chamber at the front end of the inflow pipe 201;
A distributor (21) for transferring the gaseous offgas by the blower (205) along the inlet (201);
A cooler (50) for cooling the white smoke passing through the distributor and the heat storage material (10); And
A chimney 300 that descends along the heat storage material 10 and is discharged along the discharge port 202 through the distributor 21;
And an energy recovery type ventilation system having a function of removing white smoke condensate.

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