KR101597503B1 - Fin tube type heat exchanger for cooling the high-temperature exhaust gas of high concentration and high viscosity - Google Patents

Abstract

The present invention relates to a fin tube type heat exchanger for cooling high-temperature, high-concentration, and high-viscosity exhaust gas. The fin tube type heat exchanger for cooling high-temperature, high-concentration, and high-viscosity exhaust gas comprises: a case which is formed in a box shape to have an inner receiving space, and has multiple doors in the front and multiple coupling holes formed in the top and bottom of the rear surface; multiple heat exchange modules which are detachably installed and received in the receiving space of the case and cool cooling high-temperature, high-concentration, and high-viscosity exhaust gas flowing into the case; multiple rollers which are formed on the inner bottom end of the receiving space of the case to support the heat exchange modules and guide the movement of the heat exchange modules; a cooling water supply pipe which supplies cooling water to the heat exchange modules; and a cooling water discharge pipe which discharges the cooling water discharged from the heat exchange modules to the outside.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a fin-tube type heat exchanger for cooling high-temperature high-concentration and high-

The present invention relates to a fin-tube type heat exchanger for cooling a high-concentration high-concentration and high-viscous exhaust gas, and more particularly, to a heat exchanger having a plurality of heat- A fin tube for cooling a high-temperature high-concentration and high-viscosity exhaust gas which can quickly re-start the heat exchanger by joining a heat exchange module that is previously washed or repaired in advance, Type heat exchanger.

In general, exhaust gases from industrial facilities such as textile dyeing, food processing, paper processing, food waste treatment, sewage treatment, metal processing, paint and paint manufacturing, and lubricant manufacturing include organic solvents such as oil mist and VOCs This causes air pollution such as odor.

In order to remove atmospheric pollutants generated in the tentering process of textile and dyeing facilities among the industrial facilities, most companies use absorption towers using activated carbon or absorption towers for cleaning with water. However, it is technically difficult to effectively remove organic solvents such as fine oil mist and VOCs.

In order to solve these problems, the present applicant has already proposed "Oil mist and organic solvent recovery device included in industrial exhaust gas, and an oil mist and an organic solvent recovery method using the same", by the registered patent No. 10-1489190. The present invention is an improvement on the registered patent of the present applicant.

However, since the heat exchanger in the structure of the recovery device is cooled exhaust gas contaminated with high concentration and high viscosity, the heat transfer pipe inside the heat exchanger is easily contaminated as shown in FIG. 1, and contaminants of oil component stick to the heat transfer pipe and accumulate The heat exchange rate is lowered and the differential pressure is increased due to clogging.

Further, in order to clean the contaminants adhered to the heat transfer tube of the heat exchanger, the heat transfer tube fixed inside the heat exchanger must be disassembled and cleaned to increase the working time. In order to reduce the working time, only a part of the heat exchanger is disassembled, There was a problem.

Also, since the entire recovery device must be stopped for a long time before the cleaning operation and the assembling of the disassembled heat exchanger are completed, there is a problem that the oil mist and organic solvents contained in the exhaust gas are not recovered but are discharged as they are.

Korean Registered Patent No. 10-1489190 (2015.01.28)

SUMMARY OF THE INVENTION The present invention has been made to overcome the above problems of the prior art, and it is an object of the present invention to provide a heat exchange module in which a plurality of heat exchange modules installed inside a case can be individually separated and separated, A fin-tube type heat exchanger for cooling a high-temperature high-concentration and high-viscosity exhaust gas which can quickly restart the heat exchanger by joining a heat exchange module preliminarily cleaned or repaired in place, There is a purpose.

In order to achieve the above-mentioned object, the present invention can be applied to an industrial facility such as textile, dyeing, food processing, paper processing, food waste treatment, sewage treatment, metal processing, And an electrostatic precipitator for recovering organic solvents such as oil mist and VOCs contained in the exhaust gas by an electric dust collecting method by corona discharge. The high-temperature and high- A fin-tube type heat exchanger for cooling high-concentration and high-viscosity exhaust gas, wherein one side is opened to allow the high-temperature high-concentration and high-viscous exhaust gas to flow from the inlet pipe, and the high- A receiving space is formed in a box shape in which the other side is opened so as to be cooled and moved to the electrostatic precipitator, The case is provided, and, a plurality of holes coupled to the rear side of the upper and the lower part are formed; A heat exchange module for cooling a high-temperature high-concentration and high-viscous exhaust gas, which is accommodated and installed in a receiving space of the case so as to be coupled and separated, A plurality of heat exchange modules disposed along the moving direction of the heat exchange module inside the lower end of the housing space of the case to support and move the heat exchange module, A cooling water supply pipe located outside the coupling hole formed at the lower side of the rear side of the case and supplying cooling water to the heat exchange module; And a cooling water discharge pipe located outside the coupling hole formed in the upper portion of the rear side of the case for discharging the cooling water discharged from the heat exchange module to the outside, A first cooling water movement space in which cooling water is supplied and moved inside one frame of the rectangular frame is formed by the first and second partition plates, The second cooling water movement space in which the cooling water is supplied and moved to the inside of the other frame of the frame is formed by the third cupboard and is passed through the first and second inner surfaces of the frame, A plurality of holes are formed in the vertical zigzag direction, and one side of the rectangular frame and the other side of the frame The cooling water flowing from the first and second cooling water moving spaces is inserted into the respective through holes formed in each corner so that both ends of the tube formed in the tube shape passing through the inside are connected to each other, And a heat transfer fin is wound around the periphery of the heat transfer fin in a coil shape. The heat transfer fin passes through a coupling hole formed in a lower portion of a rear side of the case at a lower outer side of one frame of a rectangular frame, A cooling water supply unit for supplying cooling water to the space is protruded and is coupled to a cooling water discharge pipe through a coupling hole formed in an upper portion of a rear side surface of a case at an upper portion of one side frame of a rectangular frame in which a first cooling water movement space is formed, Characterized in that a cooling water discharge portion for causing the cooling water supplied to the space to move and be discharged is protruded A fin-tube type heat exchanger for cooling a high-temperature high-concentration and high-viscosity exhaust gas is provided.

In the fin-tube type heat exchanger for cooling high-temperature high-concentration and high-viscous exhaust gas according to the present invention, a number of heat exchange modules installed inside the case can be separately detachably connected, It is possible to easily separate and clean or repair only the heat exchange module in that part.

In addition, the heat exchange module, which has been previously cleaned or repaired, can be coupled to the place of the separated heat exchange module for cleaning or repairing, and the heat exchange device can be quickly restarted.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a photograph showing the state of a heat exchange pattern contaminated by a conventional high concentration and high viscosity exhaust gas,
FIG. 2 and FIG. 3 are a side view showing the installation state of a fin-tube type heat exchanger for cooling a high-temperature high-concentration and high-viscous exhaust gas according to the present invention,
FIG. 4 is a sectional view of a fin-tube type heat exchanger for cooling a high-temperature high-concentration and high-viscosity exhaust gas according to the present invention,
5 is an exploded perspective view of the heat exchange module according to the present invention,
6 is a perspective view of a heat exchange module according to the present invention,
FIG. 7 and FIG. 8 are diagrams showing the state of use of the heat exchange module according to the present invention,
FIG. 9 is a side view showing the installation state of the cooling water supply pipe and the cooling water discharge pipe according to the present invention,
Fig. 10 is a side sectional view showing part A of Fig. 9,
11 is a side cross-sectional view showing another embodiment of a fin-tube type heat exchanger for cooling a high-temperature high-concentration and high-viscous exhaust gas according to the present invention.

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

2 to 11, the fin-tube type heat exchanger for cooling high-concentration high-concentration and high-viscous exhaust gas of the present invention includes a fiber-finishing type heat exchanger for finishing a fiber, dyeing, food processing, papermaking, food waste treatment, An inlet pipe 1 into which a high-temperature high-concentration and high-viscosity exhaust gas, which is collected in a hood installed in an industrial facility such as paint, paint manufacturing, and lubricant production, is introduced into a duct, and oil mist and VOCs contained in the exhaust gas A heat exchanging module 20, a roller 30, a cooling water supply pipe 40, a cooling water discharge pipe 50 (hereinafter, referred to as " cooling water discharge pipe " ).

As shown in FIGS. 2 to 4, the case 10 is opened at one side to introduce high-temperature high-concentration and high-viscous exhaust gas from the inlet pipe 1, and the high- And the receiving space 11 is formed in a box shape in which the other side is opened to be moved to the electrostatic precipitator 5.

A plurality of doors 12 are provided on the front side of the case 10 so as to allow the heat exchange module 20 to be easily accommodated in the accommodation space 11 or to be separated from the case 10, A plurality of coupling holes 13 are formed in each of the lower portions.

A plurality of heat exchange modules 20 for cooling high-temperature high-concentration and high-viscous exhaust gases flowing into the case 10 are accommodated and dismounted in the housing space 11 of the case 10 .

As shown in FIGS. 4 and 5, the heat exchange module 20 is formed with a rectangular frame 21 that is received and installed so as to be detachably coupled to the accommodation space 11 of the case 10.

In consideration of durability and corrosion resistance, the square frame 21 is preferably made of one material selected from the group consisting of stainless steel, carbon steel, aluminum, aluminum alloy, copper and copper alloy.

Meanwhile, the first cooling water movement space 22 in which the cooling water is supplied and moved into one frame of the rectangular frame 21 is divided by the first and second partition plates 22a and 22b, The second cooling water movement space 23 in which the cooling water is supplied and moved to the inside of the other side frame of the rectangular frame 21 facing one side frame is formed by the third feeding plate 23a.

A plurality of through holes 24 are formed in the vertical zigzag direction through the first and second cooling water movement spaces 22 and 23 on one side of the rectangular frame 21 and on the inner side of the other frame, And the cooling water flowing from the first and second cooling water moving spaces 22 and 23 is passed through the through holes 24 formed at one side of the inner side of the first frame and the inner side face of the other frame, The heat conductive fins 26 are wound in a coil shape along the outer periphery in the longitudinal direction of the tube 25,

The high temperature high concentration and high viscous exhaust gas flowing into the case 10 due to the tube 25 provided with the heat conductive fins 26 in the vertical zigzag direction on the rectangular frame 21 moves into the case 10, And passes through the tubes 25 provided with the heat conductive fins 26 so as to be bent upward and downward to be cooled.

The heat conductive fins 26 of the heat exchange module 20 may be formed in a sawtooth shape.

Since the high-temperature high-concentration and high-viscosity exhaust gas pass through the tube 25 provided in the zigzag direction so as to bend upwardly and downwardly, and the heat conductive fins 26 are formed in a sawtooth shape, So that the heat transfer area is increased and the cooling is performed more quickly.

On the other hand, as shown in FIGS. 4 and 5, a coupling hole 13 formed at the lower side of the rear side of the case 10 is formed at a lower outer side of one side frame of the rectangular frame 21 where the first cooling water movement space 22 is formed And a cooling water supply portion 27 protruding to pass therethrough is formed.

A cooling water discharging portion 28 protruding through an engaging hole 13 formed in an upper portion of the rear side of the case 10 at an upper portion of one side frame of the rectangular frame 21 on which the first cooling water moving space 22 is formed, .

A plurality of rollers 30 are provided along the moving direction of the heat exchange module 20 inside the lower end of the receiving space 11 of the case 10. The roller 30 supports and moves the heat exchange module 20 which is moved when the heat exchange module 20 is coupled or separated to the accommodation space 11 of the case 10. [

9, a cooling water supply pipe 40 located outside by a coupling hole 13 formed at the lower side of the rear side of the case 10 is inserted into a coupling hole 13 formed in the lower side of the rear side of the case 10, The cooling water supply unit 27 of the heat exchange module 20 protruding outwardly is supplied with cooling water to the heat exchange module 20.

A cooling water discharge pipe 50 located on the outer side by a coupling hole 13 formed on the upper side of the rear side of the case 10 is connected to a heat exchange module 20 The cooling water discharged from the heat exchange module 20 is discharged to the outside.

The cooling water supplied to the cooling water supply pipe 40 is transferred to the cooling water supply unit 27 of the heat exchange module 20 coupled to the cooling water supply pipe 40 and is moved to the first cooling water transfer space 22 of the heat exchange module 20 .

4, the cooling water moved to the first cooling water movement space 22 flows into the second cooling water movement space 23 along the inner diameter of the tube 25 in the process of reaching the first partition plate 22a The cooling water moved to the second cooling water movement space 23 moves along the inner diameter of the tube 25 in the process of reaching the third partition plate 23a and the cooling water moves to the first partition plate 22a, And moves to the cooling water moving space (23).

The cooling water moved to the first cooling water moving space 23 formed on the first partition plate 22a is heated up to the second partition plate 22b, 25 and moves to the second cooling water moving space 23 formed on the third partition plate 23a.

The cooling water moved to the second cooling water moving space 23 formed on the third partition plate 23a then enters the second cooling water moving space 23 formed on the third partition plate 23a, The first cooling water moving space 23 formed on the upper surface of the second partition plate 22b moves along the inner diameter of the tube 25 in the course of the cooling water flowing into the second cooling water moving space 23 formed on the upper part of the three partition plate 23a, And moves to the first cooling water movement space 23 formed on the upper portion of the second partition plate 22b to be discharged to the cooling water discharge pipe 40 coupled with the cooling water discharge portion 28. [ As a result, the cooling water is uniformly distributed throughout the heat exchange module 20.

9 and 10, an extension pipe 80 is formed between the cooling water discharge portion 28 of the heat exchange module 20 and the cooling water discharge pipe 50 so as to be bent in the upward direction.

The cooling water discharge pipe 50 is installed higher than the upper position of the heat exchange module 20 due to the extension pipe 80 and the cooling water is completely discharged without the air layer inside the heat exchange module 20, (50).

11, the roller 30 provided inside the lower end of the receiving space 11 of the case 10 can be installed at the lower end of the rectangular frame 21 of the heat exchange module 20. [

The heat exchange module 20 separated from the case 10 by the roller 30 installed at the lower end portion of the square frame 21 of the heat exchange module 20 can be moved easily when moved for washing.

A handle 100 may further be formed on one side of the square frame 21 of the heat exchange module 20 to facilitate coupling or separation of the heat exchange module 20 with the case 10.

According to the present invention configured as described above, when a number of heat exchange modules 20 installed inside the case 10 can be individually coupled and separated, and when washing or repair due to contamination is required, only the heat exchange module 20 So that it can be cleaned or repaired.

In addition, the heat exchange module 20 previously cleaned or repaired can be coupled to the separated heat exchange module 20 for washing or repairing, and the heat exchange device can be quickly restarted.

10: Case 20: Heat exchange module
30: roller 40: cooling water supply pipe
50: Cooling water discharge pipe

Claims (5)

High-temperature, high-viscosity and high-viscosity exhaust gases are collected in the hoods installed in industrial facilities such as textile and dyeing, food processing, paper processing, food waste treatment, sewage treatment, metal processing, paint and paint manufacturing, And an electrostatic precipitator (5) for recovering organic solvents such as oil mist and VOCs contained in the exhaust gas by an electric dust collection method by corona discharge. The high concentration and high viscosity exhaust gas A fin-tube type heat exchanger for cooling gas, comprising:
A box type in which one side is opened to allow high-concentration high-concentration and high-viscosity exhaust gas to flow from the inflow pipe 1 and the other side is opened so that the high-temperature high-concentration and high-viscosity exhaust gas is cooled and moved to the electrostatic precipitator 5 A case 10 having a receiving space 11 formed therein, a plurality of doors 12 provided at a front side thereof, and a plurality of engaging holes 13 formed at each of upper and lower sides of the rear side thereof;
A heat exchange module 20 for accommodating and accommodating a plurality of high-density high-concentration and high-viscous exhaust gases introduced into and moving into the case 10 so as to be detachably coupled to the accommodating space 11 of the case 10;
A plurality of heat exchange modules 20 are provided inside the lower end of the accommodation space 11 of the case 10 along the moving direction of the heat exchange module 20 to move the heat exchange module 20 to the accommodation space 11 of the case 10 A roller (30) for supporting and moving the heat exchange module (20);
A cooling water supply pipe (40) located outside the coupling hole (13) formed at the lower side of the rear side of the case (10) and supplying cooling water to the heat exchange module (20);
And a cooling water discharge pipe (50) located outside the coupling hole (13) formed on the upper side of the rear side of the case (10) to move and discharge the cooling water discharged from the heat exchange module (20) to the outside,
The heat exchange module 20 is provided with a rectangular frame 21 that is received and installed so as to be detachably coupled to the accommodation space 11 of the case 10 and cooling water is supplied into one frame of the rectangular frame 21, The first cooling water movement space 22 is divided by the first and second partition plates 22a and 22b and the cooling water is supplied to the inside of the other frame of the rectangular frame 21 facing the one frame of the rectangular frame 21. [ The second cooling water movement space 23 is formed by the third partition plate 23a and the first and second cooling water movement spaces 22 and 22 are formed on one side of the rectangular frame 21 and on the inner side of the other frame, respectively. A plurality of through holes 24 passing through the rectangular frames 21 and 23 are formed in the vertical zigzag direction so that the first and second cooling water movements So that the cooling water, which is moved from the spaces 22 and 23, The heat transfer fins 26 are wound in the form of a coil along the outer periphery of the tube 25 in the longitudinal direction of the tube 25, Passes through the coupling hole 13 formed in the lower side of the rear side of the case 10 at the lower outer side of the frame at one side of the rectangular frame 21 in which the first cooling water movement space 22 And a cooling water supply unit 27 for supplying cooling water to the cooling water supply unit 27. The cooling water supply unit 27 protrudes from the cooling water supply unit 27 for supplying the cooling water to the first cooling water moving space 22, And a cooling water discharging part (28) which is connected to the cooling water discharging pipe (40) through the first cooling water discharging pipe (13) to move and discharge the cooling water supplied to the first cooling water moving space (22) For cooling the viscous exhaust gas The heat exchanger of the tube type delete The method according to claim 1,
Characterized in that the square frame (21) of the heat exchange module (20) is made of one material selected from the group consisting of stainless steel, carbon steel, aluminum, aluminum alloy, copper and copper alloy. A heat exchanger of a fin tube type. The method according to claim 1,
Wherein the heat transfer fin (26) of the heat exchange module (20) is formed in a sawtooth shape. The fin-tube type heat exchanger for cooling exhaust gas of high temperature and high viscosity. The method according to claim 1,
An extension pipe 80 is formed between the cooling water supply unit 27 and the cooling water supply pipe 40 of the heat exchange module 20 and between the cooling water discharge unit 28 of the heat exchange module 20 and the cooling water discharge pipe 50, Wherein the high-temperature high-viscosity and high-viscosity exhaust gas is cooled by a high-temperature heat exchanger.

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