KR20190024121A - A plate type heat exchanger having a drain space portion for removing impurities - Google Patents

Abstract

The present invention relates to a plate type heat exchanger, and more particularly, to a plate type heat exchanger having a drain space portion for removing impurities, which removes impurities by forming the drain space portion in the plate type heat exchanger to maintain the heat exchange performance. To this end, a plate type heat exchanger according to the present invention includes: an inlet through which gas flows into an upper side; a first flow path formed with a plurality of flow paths formed to correspond to the inlet; a second flow path formed with a plurality of flow paths and separated from the first flow path; an outlet through which the gas flows out through the second flow path to the lower opposite side; a plate having a drain space portion of a predetermined size between the first flow path and the second flow path, and overlapping in a horizontal direction; and a drain screw passing through the plate stacked at a lower end of the drain space portion. Each of the inlet and outlet of the stacked plate has a header and has a drain space portion for removing impurities.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plate type heat exchanger having a drain space for removing impurities,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a plate type heat exchanger, and more particularly, to a plate type heat exchanger having a drain space portion for removing impurities by removing impurities to form a drain space portion in a plate type heat exchanger to maintain heat exchange performance.

Generally, a heat exchanger refers to a device that exchanges heat from a high-temperature fluid to a low-temperature fluid without mixing the two fluids having different temperatures. Heat exchangers are widely used in a wide range of fields ranging from domestic air conditioning systems such as air conditioners to chemical processes and power generation in large factories.

Such a heat exchanger can be roughly divided into a shell-and-tube heat exchanger and a plate heat exchanger. The plate heat exchanger includes a gasket type, a brazed type, a plate-pin type, and a printing plate type.

A plate heat exchanger generally forms a flow path by extruding a plate. In a PCHE (Printed Circuit Heat Exchanger), a surface of a metal plate is etched to form a flow path.

As a prior art of a printing plate type heat exchanger, Korean Patent Registration No. 10-1233346 'Micro heat exchanger using a bonded metal and a manufacturing method thereof' is introduced.

In other words, the plate-type heat exchanger of the printing plate is a heat exchanger having a structure in which channels are formed by using an optical etching technique such as etching on a plate, and welding between plates of the heat exchanger is eliminated by using a diffusion bonding technique. In addition, unlike other plate type heat exchangers that extrude and form a flow path, a plate-type heat exchanger of a printing plate can form a small flow path of a millimeter scale in a micrometer, and has a large heat transfer area, Can be effectively reduced. In addition, it has a strong durability against high-temperature and high-pressure environment, and has an advantage of high integration and excellent heat exchange efficiency.

However, impurities contained in the heat transfer medium or droplets or ice particles generated in the heat exchange process block the flow path or form a film, thereby deteriorating heat exchange performance. Particularly, in a plate-type heat exchanger having a plurality of micro-flow channels, clogging may easily occur in some micro-flow passages even with fine impurities. In addition, there is a problem that the efficiency of the heat exchanger may be drastically reduced due to an increase in pressure loss due to the clogging of the flow path.

Also, in order to maintain the desired performance, it is necessary to disassemble the plate of the plate heat exchanger or to block the flow path by using the water jet, which is expensive and time-consuming to maintain and manage the performance of the plate heat exchanger.

KR 10-1233346 B1

The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a plate type heat exchanger having a drain space part for removing impurities which removes impurities blocking the flow path through the drain space part provided in the plate type heat exchanger, The purpose is to provide.

According to an aspect of the present invention, there is provided an exhaust gas purifying apparatus, comprising: an inlet having an inlet for introducing gas into an upper portion thereof; a first flow path including a plurality of flow paths formed so as to correspond to the inlet; An outlet for discharging the gas through the second flow path to the other side of the lower portion, a plate having a drain space portion having a predetermined size between the first flow path and the second flow path and overlapping in the horizontal direction, The plate type heat exchanger is provided with a drain screw passing through the stacked plate, and each of the inlet and outlet of the stacked plate is further provided with a header to have a drain space for removing impurities.

The drain space portion may include a first storage portion in which impurities of the gas generated in the first flow path are temporarily stored, the first storage portion having a width decreasing toward the lower side, and a second storage portion communicating with the first storage portion, And can be provided as a storage unit.

The first storage unit may include a first inclined surface inclined downward from the first flow path toward the second flow path, the outlet of the first flow path and the inlet of the second flow path being located on the same line, May be provided as a second inclined surface inclined downward from the second flow path toward the first flow path.

In addition, the first flow path may be provided with a guide pin inclined downward at an outlet of the first flow path.

A first flow path formed of a plurality of flow paths formed so as to correspond to the inlet port, a second flow path formed of a plurality of flow paths separated from the first flow path, a second flow path formed of a plurality of flow paths formed separately from the first flow path, An outlet through which the gas flows out through the flow path, a plate which passes through the first flow path and the second flow path downward and overlaps in the horizontal direction, an outlet of the first flow path of the overlapped plate and an inlet of the second flow path, And a drain space for removing the impurities is provided in the inlet and the outlet of the laminated plate. The plate type heat exchanger according to the present invention includes:

In addition, the drain space part is provided with a hemispherical header in which impurities of the gas generated in the first flow path are temporarily stored.

According to the present invention, there is provided a plate type heat exchanger having a drain space for removing impurities according to the present invention, which is capable of discharging impurities temporarily stored in a drain space through a drain screw, And the efficiency of the heat exchanger can be prevented from being lowered.

In addition, impurities blocking the flow path can be removed, and the maintenance and repairing period of the plate heat exchanger can be prolonged, which saves cost and time.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view of a plate type heat exchanger having a drain space for removing impurities according to an embodiment of the present invention. FIG.
FIG. 2 is a view showing the structure of a plate having a drain space outside the plate in a plate-type heat exchanger having a drain space for impurity removal according to the present invention.

Hereinafter, a plate type heat exchanger having a drain space for removing impurities according to an embodiment of the present invention will be described in detail.

FIG. 1 is a view of a plate having a drain space inside a plate in a plate type heat exchanger having a drain space part for removing impurities according to the present invention, FIG. 3 is a view illustrating a plate having a drain space part for removing impurities according to the present invention, Type heat exchanger is provided with a drain space portion outside the plate.

1, a plate type heat exchanger having a drain space part according to the present invention includes an inlet 100, a first flow path 200, a second flow path 300, an outlet port 400, a drain space part 500, (600), a drain screw (700), and a header (800).

The inlet 100 is formed at an upper end of one side of the plate 600 to be described later and includes an inlet 210 of a first flow path which is a passage through which gas as a heat transfer medium flows. Here, the inlet 210 of the first flow path is formed with grooves having a predetermined depth while maintaining a plurality of flow paths at a predetermined interval.

The first flow path 200 includes a plurality of flow paths formed in the inlet 100 and a flow path of a horizontal line corresponding to the inlet 100 is formed. The flow path of the horizontal line is bent to a vertical line so as to be separated from the second flow path 300 at a predetermined interval, thereby forming the first flow path 200. The outlets 230 of the first flow path are formed on the same line so that gas and impurities are discharged at the same height.

The second flow path 300 is spaced apart from the first flow path 200 by a predetermined distance, and the inlet 310 of the second flow path is formed on the same line. At the inlet 310 of the second flow path, the flow path is formed as a vertical line and is again bent to a horizontal line. Then, in the horizontal line, the vertical line and the horizontal line are continuously formed, and the vertical line and the horizontal line can be made longer, if necessary, with a refracted shape at the connection.

The first flow path 200 and the second flow path 300 are formed as a horizontal line and a vertical line, thereby increasing the heat exchange area and maximizing heat exchange efficiency.

The outlet (400) is formed at the other end of the plate (600) in a direction opposite to the inlet (100) and includes an outlet (330) of the second flow path. The outflow port (400) receives the gas from which impurities have been removed through the inlet (310) of the second flow path formed on the same line, and is discharged after heat exchange.

The drain space part 500 is provided at a predetermined size at the outlet 230 of the first flow path and the lower end of the inlet 310 of the second flow path. The impurities generated through heat transfer in the first flow path 200 are temporarily stored in the drain space part 500 through the inlet port 100. The drain space 500 may be formed to be inclined toward the discharge port so that the stored impurities can be easily discharged.

More specifically, the drain space part 500 can be divided into a first storage part 510 and a second storage part 530.

The first inclined surface 511 may be formed in a shape such that the width of the first storage portion 510 decreases toward the lower portion of the gravity direction. The first inclined surface 511 is inclined downwardly from the first flow path 200 toward the second flow path 300 and the guide vents 513 are provided at the outlet 230 of the first flow path, . The vanes 513 may be inclined downward at the outlet 230 of the first flow path in the same direction as the first inclined surface 511. The gas and impurities discharged through the guide vanes 513 are guided, and the discharged impurities move to the first inclined surface 511 inclined downward, and the gas again flows into the inlet 310 of the second flow path. The formation of the first inclined surface 511 increases the contact area that can withstand pressure.

The second storage unit 530 includes a second inclined surface 531 communicating with the first storage unit 510 and formed in a horizontal direction and inclined downward from the second flow path 300 toward the first flow path 200, Respectively. The impurities introduced from the first storage part 510 are temporarily stored in the second storage part 530 and the second inclined surface 531 formed in the lower part of the second storage part 530, Impurities stored by the screw 700 can be easily discharged.

The plate 600 includes an inlet 100, a first flow path 200, a second flow path 300, an outlet 400, and a drain space 500. In addition, each of the plates 600 through which different heat transfer media flow is continuously overlapped with each other so that two heat transfer media are not mixed with each other.

The drain screw 700 is formed through the lower end of the drain space 500 of the laminated plate 600. The drain screw 700 is periodically discharged from the drain space part 500 provided in each of the plates 600 through the drain screw 700 to discharge stored impurities to thereby cause clogging of the flow path And the efficiency of the heat exchanger can be prevented from being lowered. Also, the maintenance and management cycle of the heat exchanger is prolonged, which saves cost and time.

FIG. 2 is a view showing the structure of a plate having a drain space outside the plate in a plate-type heat exchanger having a drain space for removing impurities according to the present invention.

The inlet 100 and the outlet 400 are the same as those in FIG. 2 and will not be described in detail.

Referring to FIG. 2, the inlet 210 of the first flow path is provided in the inlet 100, and a flow path is formed as a horizontal line. The vertical line is connected to the lower end of the plate 600 so that the outlet 230 of the first flow path is provided at the end.

The second flow path 300 is spaced apart from the first flow path 200 by a predetermined distance and the inlet 310 of the second flow path is formed as a vertical line at the lower end of the plate 600, . In the horizontal line, the vertical line and the horizontal line are continuously formed, and the vertical line and the horizontal line can be made longer as necessary.

1, the plate 600 includes an inlet 100, a first flow path 200, a second flow path 300, and an outlet 400 except for the drain space 500.

The drain space 500 is formed at the lower end of the plate 600 which surrounds the outlet 230 of the first flow path and the inlet 310 of the second flow path, Impurities are temporarily stored and the gas flows into the second flow path 300. The drain space 500 may be formed as a semicylindrical header 800, and impurities may be gathered at the gravity direction end of the header 800 to be easily discharged.

The drain screw 700 is configured to be perpendicular to the gravity direction at the lower end of the drain space 500 and periodically drains the drain screw 700 to discharge impurities stored in the drain space 500, It is possible to prevent the pressure loss and the efficiency deterioration of the heat exchanger. Also, the maintenance and management cycle of the heat exchanger is prolonged, which saves cost and time.

The impurity removal process by the plate heat exchanger having the drain space portion for removing impurities according to an embodiment having the above structure will be described.

First, a process of removing impurities by a plate type heat exchanger having a drain space portion for removing impurities shown in FIG. 1 will be described.

A gas as a heat transfer medium flows into the inlet 210 of the first flow path from the inlet 100 and flows to the vertical line from the horizontal line of the first flow path 200. As the temperature of the gas is lowered due to heat transfer, Or the droplet freezes to generate impurities.

The generated impurities are guided through the guide feathers 513 provided at the same height of the outlet 230 of the first flow path so that the gas flows into the inlet 310 of the second flow path again and the droplets, The impurities are flown to the drain space part (500) and stored.

The gas flowing into the second flow path 300 flows through the continuous horizontal line and the vertical line and the gas is discharged through the outlet 400. [

The impurities stored in the drain space part 500 formed in each of the plates 600 are discharged through the drain screw 700.

A process of removing impurities by a plate type heat exchanger having a drain space portion for removing impurities of FIG. 2 will be described.

A gas as a heat transfer medium flows into the inlet 210 of the first flow path from the inlet 100 and flows into the vertical line from the horizontal line of the first flow path 200. As the temperature of the gas drops due to heat transfer, The liquid is liquefied or the droplet freezes to generate impurities.

The generated impurities are discharged through the outlet 230 of the first flow path, the gas flows into the inlet 310 of the second flow path again, and impurities such as droplets or ice particles flow into the drain space portion 500 .

The gas flowing into the second flow path 300 flows through the continuous horizontal line and the vertical line and the gas is discharged through the outlet 400. [

The impurities stored in the drain space part 500 provided under the laminated plate 600 are discharged through the drain screw 700.

As described above, the basic technical idea of the present invention is to provide a plate-type heat exchanger having a drain space portion for removing impurities that removes impurities blocking the flow path through the drain space portion provided in the plate type heat exchanger, thereby increasing the efficiency of the plate heat exchanger. Able to know.

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. will be.

100: inlet
200: First Euro
210: entrance of the first euro
230: exit of the first euro
300: second euro
310: entrance of the second euro
330: exit of the second euro
400: outlet
500: drain space part
510: first storage unit
511: First inclined surface
513:
530: Second storage unit
531: second inclined surface
600: Plate
700: drain screw
800: Header

Claims (6)

An inlet through which the gas flows into the upper side,
A first flow path including a plurality of flow paths formed corresponding to the inlet,
A second flow path formed of a plurality of flow paths separated from the first flow path,
An outlet through which the gas flows out through the second flow path,
A plate having a drain space of a predetermined size formed between the first and second flow paths and overlapping in the horizontal direction; And
And a drain screw penetrating the stacked plate at a lower end of the drain space part,
Wherein the inlet and outlet of the laminated plate are further provided with a header, respectively. The method according to claim 1,
The drain-
And a second storage part communicating with the first storage part and being formed in a horizontal direction, characterized in that the first storage part is formed by temporarily storing impurities of the gas generated in the first flow path, And a drain space for removing the impurities. 3. The method of claim 2,
In the first storage section,
Wherein the first inclined surface is inclined downwardly from the first flow path to the second flow path,
In the second storage unit,
And a second inclined surface inclined downward from the second flow path toward the first flow path. The plate type heat exchanger of claim 1, wherein the second inclined surface is inclined downward from the second flow path toward the first flow path. The method according to claim 1,
Wherein the first flow path includes:
And a guide vane inclined downward at an outlet of the first flow path. 2. The plate type heat exchanger of claim 1, An inlet through which the gas flows into the upper side,
A first flow path including a plurality of flow paths formed corresponding to the inlet,
A second flow path formed of a plurality of flow paths separated from the first flow path,
An outlet through which the gas flows out through the second flow path,
A plate having a first passage and a second passage,
A drain space portion interconnecting an outlet of the first flow path of the overlapped plate and an inlet of the second flow path; And
A drain screw is provided at a lower end of the drain space,
Wherein the inlet and outlet of the laminated plate are further provided with a header, respectively. 6. The method of claim 5,
The drain-
Wherein the impurity of the gas generated in the first flow path is temporarily stored, and is provided with a hemispherical header.

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