KR20120016834A - Structure of condensation module for solvent recovering and dehumidifying deodorize - Google Patents

Abstract

PURPOSE: The structure of a coagulating module for collecting organic solvent and dehumidifying deodorization is provided to improve the using efficiency of the module by closely attaching a plurality of heat pipes and coagulating pipes on a stacked thermal conductive plate. CONSTITUTION: A plurality of thermal conductive plates(10) is stacked by forming a plurality of first through holes(11) and second through holes(12). A pair of frames(20) is installed on both sides of the stacked thermal conductive plate and is connected by a lateral side panel(25) which is in contact with the lateral side of the stacked thermal conductive plate. The outer circumferences of a plurality of heat pipes(30) is closed attached to respective thermal conductive plates by passing through the first through hole of the thermal conductive plates and the first inserting hole of the frames. The outer circumferences of a serial of coagulating pipes is closed attached to respective thermal conductive plates by passing through the second through hole of the thermal conductive plates and the second inserting hole of the frames.

Description

Structure of condensation module for organic solvent recovery and dehumidification deodorization {STRUCTURE OF CONDENSATION MODULE FOR SOLVENT RECOVERING AND DEHUMIDIFYING DEODORIZE}

The present invention relates to a structure of a condensation module, in particular, is installed in the organic solvent recovery apparatus to condensate and recover the organic solvent contained in the air, or installed in the deodorizer dryer to remove the odor causing substances by agglomeration with the moisture contained in the air The condensation module is designed to be able to do this, but by providing a structure that can be integrated by integrating a plurality of heat pipes and condensation pipes more easily on the laminated heat conduction plate, it maximizes condensation efficiency and is easy to manufacture organic solvent. It relates to the structure of the condensation module for recovery and dehumidification deodorization.

In general, condensation is a phenomenon in which a gas is converted into a liquid. When condensation occurs when a gas of a certain pressure is cooled to a temperature below a certain temperature or a pressure is applied at a certain temperature to exceed the saturated vapor pressure of the substance, the condensation phenomenon occurs. It is usually applied in various forms throughout the industry such as air conditioners, freezers, dryers, dehumidifiers.

On the other hand, looking at an example of the organic solvent recovery apparatus for washing among the various devices using the above condensation principle, dry cleaning using the organic solvent for washing is frequently performed in the laundry that is commonly encountered around the living, the dry-cleaned clothes are usually a dryer Drying the organic solvent permeated into the garment by using, in this case carcinogens such as benzene and toluene contained in the laundry organic solvent is discharged to the atmosphere, by introducing the exhaust gas discharged from the dryer into the organic solvent recovery apparatus, The organic solvent contained in the gaseous state in the exhaust gas is condensed and recovered.

However, in the case of the organic solvent recovery apparatus for laundry as described above, in view of the necessity of dissemination, such as used to recover the organic solvent containing carcinogens in the laundry that is commonly encountered around the living area, as a simple structure Not only should it be easy to manufacture, but it must also have a more efficient structure for effective flocculation of carcinogens such as benzene and toluene. However, as a conventional heat pump system, a conventional organic solvent recovery device comprising a compressor, a condenser, an expansion valve, and an evaporator The structure and the effect of the problem did not meet the above requirements.

On the other hand, in the case of the conventional organic solvent recovery apparatus as described above there was also another problem that can not be used in other dehumidifier / deodorizer or dryer.

The present invention is to solve the problems as described above, made of a concise structure compared to the prior art to facilitate the condensation and more efficient condensation, a plurality of heat pipes and condensation pipes are integrated in a stacked heat conduction plate in close contact. The object of the present invention is to provide a condensation module that is suitable for application to an organic solvent recovery device for washing, and is compatible with dehumidification / deodorization and other uses by providing a condensation module configuration. There is this.

The structure of the condensation module for organic solvent recovery and dehumidification deodorization according to the present invention for achieving the above object, a plurality of heat conduction plate and a plurality of heat conduction plates stacked at regular intervals to form a plurality of first through holes and the second, A pair of frames formed by forming a plurality of first insertion holes and second insertion holes respectively corresponding to the first and second through holes and installed on both sides of the stacked heat conducting plates, and interconnected by side panels contacting the side ends of the heat conducting plates. And a plurality of heat pipes penetrating the first through holes of the heat conduction plate and the first insertion holes of the frame, and the outer circumferential surfaces of the heat conduction plates are in close contact with each other through the expansion pipe, and the second through holes of the heat conduction plate and the second insertion of the frame. A series of condensation pipes which penetrate the ball and the outer circumferential surface of each heat conduction plate is brought into close contact with each other through a pipe, and an inlet and an exhaust port are formed on the frame and the side panel of the side where the heat pipe is disposed. Good adhesion to the panel and the intake and exhaust, side frames and the side panel of the condensing pipe is formed, but has a feature in the structure of the lower panel a condensation module for use in an organic solvent recovery and dehumidification deodorant form a provided with a drain pipe on the bottom surface.

In another aspect, the present invention, the structure of the organic solvent recovery and dehumidification decondensation condensation module and the heat of the heat conductive plate so that the protrusions are formed on one side of the first and second through holes formed in the heat conduction plate to be laminated at regular intervals, and the heat There is an additional feature in the structure of the condensation module for organic solvent recovery and dehumidification deodorization integrating a pair of heat pipes by forming connecting pipes at both ends of the pipe.

According to the present invention of the configuration as described above, by inserting a plurality of heat pipes and condensation pipes in the laminated heat conduction plate to form a condensation module, the condensation module can be configured not only easier than conventional, but also laminated Since the heat conduction plate, the heat pipe and the condensation pipe are in close contact with each other, more efficient condensation is possible, thereby maximizing the condensation efficiency. In addition, as an independent structure, it is compatible with other dehumidifying / deodorizing apparatuses or dryers such as food waste drying apparatuses in addition to the organic solvent recovery apparatus for washing, and thus can be used universally.

1 is a perspective view showing a heat conduction plate of the condensation module according to the present invention.
Figure 2 is a perspective view showing a frame and a side panel of the condensation module according to the present invention
3 to 5 are perspective views showing a heat pipe and a condensation pipe of the condensation module according to the present invention.
6 is a perspective view showing an intake and exhaust panel and a lower panel of the condensation module according to the present invention.
7 is a cross-sectional view showing an operating state of the condensation module according to the present invention.

Hereinafter, an embodiment of the structure of the condensation module for organic solvent recovery and dehumidification deodorization according to the present invention will be described in detail with reference to FIGS. 1 to 7.

The condensation module 1 according to the present invention has a structure in which a plurality of heat pipes 30 and a condensation pipe 40 are integrated into a stacked heat conducting plate 10 and a frame 20 so as to be integrated with each other. 10 shows a plurality of first through holes 11 and second through holes 12 to be stacked at regular intervals, as shown in Figure 1, but as shown in the enlarged cross-sectional view of FIG. The protrusions 15 are formed on one side of the formed first through holes 11 and the second through holes 12, respectively, so that an air passage having a predetermined gap is formed between the stacked thermal conductive plates 10. This is preferred. Meanwhile, although not shown, a gap may be formed between the thermal conductive plates 10 by providing a separate spacer (not shown).

And the frame 20 is installed on both sides of the heat conductive plate 10 stacked as shown in Figures 1 and 2, respectively, a plurality of first corresponding to the first and second through holes 11 and 12, respectively The first insertion hole 21 and the second insertion hole 22 are formed in the frame 20, and the pair of frames 20 are connected to each other by the side panel 25, and the side panel 25 In order to keep the airtight in contact with the side ends of the laminated heat conductive plates 10, the pair of frames 20 and the side panels 25 are combined to form a duct.

3 to 5, the structure of the plurality of heat pipes 30 and the condensation pipe 40 integrated with the heat conductive plate 10 and the frame 20 by being inserted / expanded into the heat pipe 30 will be described. Looking at the configuration of the first, the heat pipe 30 is inserted through the first through hole 11 of the heat conducting plate 10 and the first insertion hole 21 of the frame 20, but the inserted heat pipe The outer peripheral surface of the heat pipe 30 is brought into close contact with and integrated with the first through hole 11 of each heat conductive plate 10 and the first insertion hole 21 of the frame 20 by expanding the 30.

In the above, the integrated structure of the heat conduction plate 10 and the frame 20 and the heat pipe 30 will be described in detail. First, the first through hole 11 and the first insertion hole of the frame 20 of the heat conduction plate 10 will be described. The heat pipe 30 is inserted into the through hole 21, and preferably, a "U" shaped heat pipe connector 31 is attached to one end of the pair of heat pipes 30 to attach a pair of heat pipes ( 30 is simultaneously inserted into the first through hole 11 and the first insertion hole 21, and the expansion pipe A is pushed into the other open end of the inserted heat pipe 30 to press the heat pipe 30. By expanding, the outer circumferential surface of the heat pipe 30 is brought into close contact with and integrated with the inner circumferential surfaces of the first through hole 11 and the first insertion hole 21 (see FIG. 3).

Thereafter, the wick 35 is inserted into one open end of each heat pipe 30, and then the other end of the pair of heat pipes 30 is connected using another “U” shaped heat pipe connector 32. It is sealed (refer FIG. 4), and the injection hole 33 is formed in the connection pipe 31 of either side, and working oil can be injected simultaneously into the inside of a pair of heat pipes 30, and working efficiency can be improved (FIG. 5). Reference).

Next, referring to the structure of the plurality of condensation pipes 40 integrated into the heat conduction plate 10 and the frame 20 and integrated into the heat conduction plate 10 and the frame 20, the condensation pipe 40 has a second through hole of the heat conduction plate 10. Inserted into the second insertion hole 22 of the 12 and the frame 20, and penetrates, and the "U" shaped condensation pipe connecting pipe at one end of the pair of condensation pipes 40 so as to improve work efficiency. 41) attaching a pair of condensation pipe 40 into the second through-hole 12 and the second insertion hole 22 at the same time, after which the expansion pipe (A) as in the case of the heat pipe 30 described above Presses into the condensation pipe 40 and expands it so that the outer circumferential surface of the condensation pipe 40 is intimately integrated with the inner circumferential surfaces of the second through hole 12 and the second insertion hole 22 (see FIG. 3). Then, the other end of the expanded condensation pipe 40 is opened using another "U" shaped condensation pipe connecting pipe 42 (see Fig. 4). At this time, the condensation pipe 40, as shown in Figure 7, unlike the heat pipe 30 so as to continue from one end to the other end of the condensation pipe 40, the series of each condensation pipe 40 Dispensing pipe 45 is preferably formed at the front end and the end to communicate with each other.

On the other hand, the condensation pipe 40 is a portion corresponding to the evaporator in a conventional heat pump system is filled with a refrigerant therein, as shown in Figure 7 refrigerant filled in the condensation pipe 40 Absorbs heat from an external gas and vaporizes it. At this time, the solvent and water contained in the external gas deprived of heat condense to the outside of the condensation pipe 40, and the vaporized refrigerant flows into the compressor 110 and is compressed. After releasing the absorbed heat into the condenser 120, the liquid is liquefied, and then flows back into the condensation pipe 40 through the expansion valve 130.

As described above, in the condensation module 1 in which the plurality of heat pipes 30 and the condensation pipe 40 are integrated with respect to the heat conductive plate 10 and the frame 20, the intake and exhaust panel 50 is illustrated in FIGS. 6 and 7. ) And the lower panel 60, the intake and exhaust panel 50 forms the intake port 51 and the exhaust port 52 to form the frame 20 and the side panel 25 on the side where the heat pipe 30 is disposed. ) In addition, the lower panel 60 is attached to the frame 20 and the side panel 25 on the side where the condensation pipe 40 is formed, and has a drain pipe 65 at the bottom thereof to condense outside the condensation pipe 40. Allow spilled solvent or moisture to run off.

Hereinafter, referring to the operation and effect of the condensation module 1 according to the present invention, when the exhaust gas discharged from the dryer or the like of the laundry flows into the intake port 51 of the intake and exhaust panel 50, the heat energy of the exhaust gas is heat pipe 30. The first cooling is absorbed to one end of the), the first cooled exhaust gas is secondary cooled through the condensation pipe 40, the organic solvent and moisture contained in the exhaust gas is condensed pipe according to the secondary cooling Condensed on the outside of the 40 is discharged to the outside through the drain pipe 65 formed in the lower panel 60, wherein each heat pipe 30 and the condensation pipe 40 to a number of heat conducting plate 10 The close and high thermal conductivity enables fast and efficient cooling of the exhaust gas. As a result, efficient solvent recovery and dehumidification are possible, and the gap between each heat conduction plate 10 serves as a circulation passage of the exhaust gas.It is not necessary and the structure can be simplified.

Thereafter, the exhaust gas from which the solvent and the water have been recovered is discharged to the outside through the exhaust port 52 through the other end of the heat pipe 30 or flows into the dryer again. At this time, the exhaust gas is absorbed at one end of the heat pipe 30. The heat energy is returned to the exhaust gas through the other end of the heat pipe 30, and additionally, the condenser 120 of the heat pump system is disposed on the exhaust port 52 side as illustrated in FIG. 7 to be absorbed by the condensation pipe 40. Up to a row of exhaust gases can be returned. Meanwhile, the refrigerant of the condensation pipe 40 circulates to the condensation pipe 40 of the condensation module 1 via the compressor 110, the condenser 120, and the expansion valve 130 of the heat pump system.

Finally, the condensation module 1 of the present invention having the above-described configuration and working effect can be used interchangeably in various heat pump systems in place of an evaporator, as well as being applicable to an organic solvent recovery apparatus for washing. In addition, it can be used for dehumidification and deodorization by condensing and removing odor-causing substances by condensation with water by using a food waste drying apparatus, and can be used in other dryers, etc. The present invention is applicable to the application of the condensation module 1. It is not limited.

1: condensation module 10: heat conduction plate 11: first through hole
12: second opening 15: protrusion 20: frame
21: first insertion hole 22: second insertion hole 25: side panel
30: heat pipe 31, 32: heat pipe connector 40: condensation pipe
41, 42: condensation pipe connector 50: intake and exhaust panel 51: intake port
52 exhaust port 60 lower panel 65 drain pipe
110: compressor 120: condenser 130: expansion valve

Claims (3)

A plurality of heat conductive plates 10 formed with a plurality of first through holes 11 and second through holes 12 and stacked at a predetermined interval; A plurality of first insertion holes 21 and second insertion holes 22 respectively corresponding to the first and second through holes 11 and 12 are formed to be installed at both sides of the stacked thermal conductive plates 10. A pair of frames 20 interconnected by side panels 25 in contact with side ends of the heat conduction plates 10; A plurality of heat pipes 30 penetrating the first through hole 11 of the heat conductive plate 10 and the first insertion hole 21 of the frame 20 to be in close contact with the outer circumferential surface of each heat conductive plate 10 through expansion. )Wow; A plurality of condensed pipes that pass through the second through hole 12 of the heat conduction plate 10 and the second insertion hole 22 of the frame 20, and the outer circumferential surface is in close contact with each heat conduction plate 10 through expansion. 40; An intake and exhaust panel 50 which forms an intake port 51 and an exhaust port 52 and is attached to the frame 20 and the side panel 25 on the side where the heat pipe 30 is disposed; Organic solvent recovery and dehumidification, characterized in that attached to the frame 20 and the side panel 25 of the side on which the condensation pipe 40 is formed, the lower panel 60 having a drain pipe 65 on the bottom surface thereof. Structure of deodorizing condensation module.
The method of claim 1;
The protrusions 15 are formed at one side of the first through holes 11 and the second through holes 12 formed in the heat conductive plate 10 so that each of the heat conductive plates 10 is stacked at a predetermined interval. Structure of condensation module for organic solvent recovery and dehumidification deodorization.
The method of claim 1;
The heat pipe 30 is a structure of the organic solvent recovery and dehumidification deodorizing condensation module, characterized in that a pair of heat pipes (30) are integrated by the connection pipes (31) (32) formed at both ends.

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