KR101103397B1 - Plate of heat exchange - Google Patents

Abstract

The present invention relates to a heat exchange plate, and more particularly, to form a plurality of embossing protruding to the upper plate and the passage connecting each of the embossing, and by combining the lower plate of the plate, to generate vortex in the moving fresh water and waste water to foreign matter The present invention relates to a heat exchange plate capable of smoothly flowing and improving heat exchange efficiency without adsorption of scale or scale.

According to the heat exchange plate of the present invention as described above, the heat exchange efficiency is improved by the heat exchanger formed only on the upper plate, vortices are generated in the fresh water moving the heat exchanger and the waste water moving outside the heat exchanger, There is an advantage that the heat exchange path is prevented from being blocked, there is an excellent effect that the lower plate is not leaked by the water pressure of the fresh water because it is welded by seaming to wrap the upper plate.

Heat exchanger plate, embossing

Description

Heat exchanger plate {PLATE OF HEAT EXCHANGE}

The present invention relates to a heat exchange plate, and more particularly, to form a plurality of embossing protruding to the upper plate and the passage connecting each of the embossing, and by combining the lower plate of the plate, to generate vortex in the moving fresh water and waste water to foreign matter The present invention relates to a heat exchange plate capable of smoothly flowing and improving heat exchange efficiency without adsorption of scale or scale.

In general, wastewater is generated in the manufacturing plant due to the nature of the process. In particular, when a dyeing process is performed, high temperature wastewater is generated. When biological treatment is performed for the purification of such wastewater, biological treatment is impossible because sludge (microorganism) is killed due to the high temperature wastewater.

For the same reason as above, the wastewater of a high temperature is cooled to an appropriate temperature and then purified and discharged through biological water treatment.

In the past, when the wastewater is cooled, only the wastewater itself is cooled to process the water treatment step, but recently, a heat exchanger is installed and used to recycle the thermal energy of the wastewater.

In addition, the water of the bath is often changed for water quality management in large baths or jjimjilbangs, which are entering a lot in recent years, and at this time, a heat exchanger is required to recycle the thermal energy of the waste water that is disposed of.

A common heat exchanger is to install a plurality of heat exchange plates in which fresh water moves in a tank in which hot waste water is freshwater so that waste water moving between a plurality of heat exchange plates and fresh water moving inside each heat exchange plate are mutually heat exchanged. .

The present invention relates to a heat exchange plate that allows the fresh water to move to receive the thermal energy of the waste water.

1 is a schematic view showing a heat exchange plate of a conventional heat exchanger.

Referring to the drawings, in the tank where hot wastewater flows in and moves, the upper and lower plates 1 and 2 are coupled to each other, and the fresh water is transferred to the fresh water moving path 3 formed between the upper and lower plates 1 and 2. By installing a plurality of heat exchange plates 20 to be introduced, the heat exchange plate 20 is configured to perform heat exchange with waste water moving to the outside of the heat exchange plate 20.

 Looking at the conventional heat exchange plate 20, the upper plate (1) and the lower plate (2) to form the same or symmetrical irregularities, and is formed by combining both ends (4) to abut, upper, lower plate (1, 2) Since the whole is formed by the fresh water moving path (3), the efficiency of heat exchange is not high. That is, because the volume of the fresh water moving path (3) is large, a large amount of fresh water is exchanged with the waste water, the efficiency is reduced, there is a disadvantage that the flow of fresh water is not smooth.

In addition, since unevenness is also formed in the lower plate 2, foreign matters and scales included in the fresh water accumulate and the heat exchange efficiency is reduced, and furthermore, there is a problem of shortening the life of the heat exchanger plate itself by causing point corrosion.

In addition, since the lower plate 2 is bent to the upper plate 1 side, both ends 4 are welded or bonded in a state in which they are in contact with each other, and thus manufacturing is cumbersome, and the combined both ends 4 are connected to the fresh water moving path 3. There is a disadvantage that the water is easily broken by water pressure of the moving fresh water.

The present invention is to solve the problems of the prior art as described above, its purpose is to create a vortex in the heat exchanger to move the fresh water to prevent the adsorption of foreign matter or scale to smooth the flow of fresh water, and mutual heat exchange It is to provide a heat exchange plate to minimize the amount of fresh water to the amount of waste water to be maximized heat exchange efficiency.

One aspect of the present invention for achieving the above object,

A heat exchange plate is coupled to the upper plate and the lower plate to form a heat exchange path through which fresh water flows between the upper and lower plates to move and discharge fluid, thereby allowing heat exchange with the fluid moving to the outside of the upper and lower plates.

The heat exchange path relates to a heat exchange plate, characterized in that a plurality of embossing protruding in the upper plate is formed to protrude, the flow path for each of the embossing is interconnected with the adjacent embossing.

The upper plate and the lower plate may be coupled by seaming so that the lower plate surrounds the upper plate, and the end portions of the embossing and the flow path may be compressed and coupled to the lower plate.

The embossing of the heat exchange furnace may be formed in a polygonal shape and may be connected to adjacent embossings in a flow path.

According to the heat exchange plate of the present invention as described above, the heat exchange efficiency is improved by the heat exchanger formed only on the upper plate, vortices are generated in the fresh water moving the heat exchanger and the waste water moving outside the heat exchanger, There is an advantage that the heat exchange path is prevented from being blocked, there is an excellent effect that the lower plate is not leaked by the water pressure of the fresh water because it is welded by seaming to wrap the upper plate.

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

The heat exchanger plate of the present invention includes a heat exchanger for moving the upper plate, the lower plate, and the fresh water to exchange heat with waste water.

Figure 2 is a perspective view showing a heat exchange plate according to an embodiment of the present invention, Figure 3 is an enlarged perspective view of the 'A' portion of FIG.

Referring to FIGS. 2 and 3, the heat exchange plate 10 of the present invention includes a top plate 100, a bottom plate 200, a heat exchange path 300, a fresh water inlet pipe 400, and a fresh water outlet pipe 500. .

The heat exchange plate 10 of the present invention is formed by combining the upper plate 100 and the lower plate 200.

The upper plate 100 and the lower plate 200 are formed of a metal material having high thermal conductivity and strong corrosion resistance, and preferably made of stainless steel.

The upper plate 100 and the lower plate 200 is formed to a thickness of 0.6mm ~ 0.8mm to improve the heat exchange efficiency.

The upper plate 100 is formed with a heat exchange path 300 in which fresh water flows in and exchanges heat, and the lower plate 200 is combined with the upper plate 100 in the form of a plate without a separate molding.

Here, the lower plate 200 is coupled by seaming to surround the upper plate 100. After pressing the lower plate 200, Ar welding or spot welding is performed to apply an adhesive to maintain airtightness.

The heat exchange path 300 is to allow heat exchange between the upper and lower plates 100 and 200 while the fresh water is introduced into the upper and lower plates 100 and 200 so as to exchange heat with the wastewater outside the upper and lower plates 100 and 200. The configuration includes a plurality of embossing 310 and the flow path 320 for generating a vortex of.

The embossing 310 and the flow path 320 may protrude by compression molding the upper plate 100.

The embossing 310 is formed a plurality of vortices in the moving fresh water to smoothly move without clogging, the flow path 320 allows each of the embossing 310 is interconnected with the adjacent embossing 310.

Here, the end portions of the embossing 310 and the flow path 320, that is, the portions in which the embossing 310 and the flow path 320 and the lower plate 200 contact each other are welded to each other, and are preferably spot welded to exchange heat. The confidentiality of the furnace 300 is maintained.

Meanwhile, in one embodiment of the present invention, the embossing 310 is formed to protrude in a circular shape and arranged in a plurality of squares so that the flow path 320 is formed in all directions, but in some cases, the embossing 310 is formed into a polygon. A plurality of protrusions may be arranged and connected to each of the adjacent embossing 310 and the flow path 320.

For example, when the embossing 310 protrudes into a hexagon, the embossing 310 and the flow path 320 may be formed in a honeycomb shape.

The fresh water inlet pipe 400 is to supply fresh water at room temperature to the heat exchange path 300, is connected to the embossing 310 of one side.

The fresh water outlet pipe 500 is a pipe for discharging the fresh water heat-exchanged by moving the heat exchange path 300, the embossed in the opposite side of the inlet pipe 400, preferably in the diagonal direction of the fresh water inlet pipe 400 Connected to 310 is installed.

The heat exchanger plate 10 of the present invention including the above components is installed and used in a heat exchanger for transferring thermal energy of wastewater discarded in a factory or a large bathroom to fresh water.

4 is a perspective view showing a state of use of the heat exchange plate of the present invention.

As shown in FIG. 4, a plurality of heat exchange plates 10 are stacked at equal intervals and installed in a water tank or a tank (not shown) in which waste water moves, and the fresh water inflow pipe 400 provided in each heat exchange plate 10. ) Is connected to the connector (400a) to communicate with each other, and each outlet pipe (500) is connected to the connector (500a) to communicate with each other.

Wastewater is moved between the plurality of heat exchange plates 10 installed.

In the case of heat exchange, waste water of high temperature is transferred to a water tank or a water tank in which a plurality of heat exchange plates 10 are installed, and fresh water at room temperature is supplied to the heat exchange plate 10 through a fresh water inlet pipe 400 located at the bottom.

The supplied fresh water is connected to each of the heat exchange plates 10 while moving the heat exchange path 300 to recover the heat of the waste water moving to the outside of the heat exchange path 300 and discharged to the fresh water outlet pipe 500 to communicate with each heat exchange plate 10. The heat exchange is repeated by moving to the upper heat exchanger plate 10 through the pipes 400a and 500a.

At this time, the fresh water moving the heat exchange path 300 is caused by the vortex flow is moved by a plurality of embossing 310 is moved smoothly without clogging and heat exchange, each of the embossing 310 interconnected to the flow path 320 It is possible to efficiently obtain the thermal energy of the waste water by moving the).

The fresh water moved to the heat exchange plate 10 of the upper end is discharged through the fresh water outlet pipe 500 to complete the heat exchange.

Here, the fresh water introduced at room temperature may obtain a heat exchange efficiency of about 70 to 85%.

Fresh water is heat-exchanged will be used as hot water in factories and bathrooms.

While specific embodiments of the present invention have been described above by way of example, these are for illustrative purposes only and are not intended to limit the protection scope of the present invention. It will be apparent to those skilled in the art that various changes, substitutions, and alterations can be made therein without departing from the spirit of the invention.

1 is a schematic view showing a conventional heat exchange plate.

2 is a perspective view showing a heat exchange plate according to an embodiment of the present invention.

3 is a perspective view showing a main portion of a heat exchange plate according to an embodiment of the present invention.

4 is a perspective view showing a state of use of the heat exchange plate according to an embodiment of the present invention.

* Description of the main parts of the drawings *

10: heat exchange plate 100: top plate

200: lower plate 300: heat exchange furnace

310: embossing 320: euro

400: fresh water inflow pipe 500: fresh water inflow pipe

Claims (3)

A heat exchange plate is coupled to the upper plate and the lower plate to form a heat exchange path through which fresh water flows between the upper and lower plates to move and discharge fluid, thereby allowing heat exchange with the fluid moving to the outside of the upper and lower plates. The heat exchange path is formed by projecting a plurality of embossing causing vortex on the top plate, the flow path for each of the embossing is interconnected with the adjacent embossing, The upper plate and the lower plate is coupled by seaming so that the lower plate surrounds the upper plate, and an end portion of the embossing and flow path is compressed and coupled to the lower plate. delete The method according to claim 1, Embossing of the heat exchange path is formed of a polygonal heat exchange plate, characterized in that connected to each of the adjacent embossing passage.

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