KR101159532B1 - double typic heat exchanger - Google Patents

Abstract

The present invention is to arrange the double tube having a plurality of rows and a plurality of columns with an inner tube which is a fruit conveying tube which extends in the X-axis direction and an outer tube which is a tube for conveying the liquid to be treated which is to be heat-exchanged which extends in the X-axis direction as a double tube. The inner pipes of the plurality of double pipes are distributed to each other by a curved pipe which is a bent pipe bent in the Z-axis direction, and the plurality of straight first header pipes extending in the Y-axis direction between the outer surfaces of the plurality of double pipes and the straight first line. A plurality of straight second header tubes having an inner space larger than the inner space of the header tube allow each other to flow therebetween, and Z between the first header tubes except for the first header tube disposed at the inlet side and the outlet side of the liquid to be treated. It is distributed to each other by the curved tube bent in the axial direction, and the fruit supply to the inner tube of the plurality of customs pipes is passed through the branch pipes of the plurality of customs branches branched from the supply header tube The fruit discharge of the inner tube, which is a plurality of tubules, is carried out via a branch tube, which is a branch of the fruit discharge header tube, so that the thermal contact area is kept in a predetermined space without increasing the capacity of the pump. It can be increased than before.

Description

Double typic heat exchanger

The present invention relates to a double tube type heat exchanger.

The conventional double tube type heat exchanger is composed of an inner tube and an outer tube, and the inner tube has a double tube made of an inner and outer tube in a zigzag pipe in which the fruit, which is a refrigerant, flows from the inlet to the outlet and the liquid to be exchanged flows from the inlet to the outlet. It is.

However, the conventional double tube type heat exchanger has a limit in arranging pipes in a zigzag by bending the double tube in a predetermined space because the appearance of the double tube type heat pipe is enlarged and the curvature of the double tube is increased. Where the space is limited, there is a problem that the heat transfer contact area that can be provided is small, and inefficient in terms of heat exchange efficiency.

In addition, the conventional double tube heat exchanger is good for the use of water when applied to the condenser, it is difficult to clean and has a problem that there is not enough space for separation of gas and liquid.

In addition, the conventional double tube heat exchanger can obtain a supercooled refrigerant because the amount of cooling water is at least, there is a problem that one large capacity is not applicable.

The present invention has a problem in solving the above problems.

The present invention is to arrange the double tube having a plurality of rows and a plurality of columns with an inner tube which is a fruit conveying tube which extends in the X-axis direction and an outer tube which is a tube for conveying the liquid to be treated which is to be heat-exchanged which extends in the X-axis direction as a double tube. The inner pipes of the plurality of double pipes are distributed to each other by a curved pipe which is a bent pipe bent in the Z-axis direction, and the plurality of straight first header pipes extending in the Y-axis direction between the outer surfaces of the plurality of double pipes and the straight first line. A plurality of straight second header tubes having an inner space larger than the inner space of the header tube allow each other to flow therebetween, and Z between the first header tubes except for the first header tube disposed at the inlet side and the outlet side of the liquid to be treated. It is distributed to each other by the curved tube bent in the axial direction, and the fruit supply to the inner tube of the plurality of customs pipes is passed through the branch pipes of the plurality of customs branches branched from the supply header tube It is to be carried out by, and the fruit discharge to the inner tube which is a plurality of customs can be carried out via a branch pipe which is a plurality of customs branched from the fruit discharge header tube, it is possible to solve the problem.

The present invention, by the means for solving the above problems, it is possible to apply a large capacity of the disadvantages of the existing double tube heat exchanger, and also by applying a plurality of pipes (2-3) of the inner tube of the double tube heat exchanger to the appearance in a twisted shape By inserting, it is possible to promote heat transfer and reduce pressure intensification, and also to allow the header of the double tube heat exchanger to secure sufficient space for separation of gas and liquid.

1 is a perspective view showing a heat exchanger of the present embodiment,
Fig. 2 is a front view of Fig. 1,
3 is a left side view of FIG. 2, and
4 is a detailed view of the double tube of FIG.

Hereinafter, the heat exchanger according to the present embodiment will be described in detail with reference to FIGS. 1 to 4.

In Fig. 1, the heat exchanger of this embodiment is indicated by reference numeral 100.

As illustrated in FIGS. 1 to 3, the heat exchanger 100 includes a plurality of double tubes 10 extending in the X-axis direction with a plurality of rows and a plurality of columns in the Y-axis and Z-axis directions.

The double tube 10 has the same center as the center of the inner tube 11 and the inner tube 11 which is a fruit transfer tube extending in the X-axis direction in the state in which the inner tube 11 is inserted to be exposed at both ends. It includes an appearance (12) which is a customs for transporting the liquid to be processed heat exchanged to.

One end of the outer appearances 12 of the plurality of double pipes 10 are connected to the plurality of straight first header pipes 21 extending in the Y-axis direction spaced apart from each other in the Z-axis direction and distributed to each other, one The first header tube 21 is connected to one end of the group of facades 12 spaced apart from each other in the Y-axis direction and at the same position in the Z-axis direction.

The other ends of the outer surfaces 12 of the plurality of double tubes 10 have an inner space larger than that of the straight first header tube 21 and are spaced apart from each other in the Z axis direction by a predetermined interval and extend in the Y axis direction. It is connected to two linear second header pipes 22, and is mutually distributed.

The plurality of second header pipes 22 are spaced apart at regular intervals in the Z-axis direction, but the number of the second header pipes 22 is half of the number of the first header pipes 21. Thus, each of the plurality of second header pipes 22 is spaced apart at regular intervals in the Y-axis direction and at the other end of the group of facades 12 at the same position in the Z-direction and of the group of facades 12. The other end is connected to the other ends of another group of facades 12 immediately adjacent in the Z-axis direction.

Both ends of the inner tube 11 are exposed through the first header tube 21 and the second header tube 22 in the X-axis direction.

The ends of the plurality of inner tubes 11 except for the ends of the plurality of inner tubes to be connected to the fruit inlet side and the ends of the plurality of inner tubes to be connected to the fruit outlet side among the inner tubes 11 of the plurality of double tubes 10 are The outlet end and the inlet end of the inner tube 11 immediately adjacent in the Z-axis direction are connected by the curved tubes 13, which are fine pipes bent in the Z-axis direction, to be distributed to each other.

The first header tube arranged on one side in the Z-axis direction and the first header tube to be directly connected to the inflow side of the liquid to be heat-treated, and the heat-treated solution as the first header tube disposed on the other side in the Z-axis direction. The first header tubes disposed between one side and the other side in the Z-axis direction except for the first header tube to be directly connected to the side immediately adjacent to the outlet side of the outlet end and the inlet of the first header tube immediately adjacent in the Z-axis direction The side ends are connected to each other by a curved header pipe 23 bent in the Z-axis direction and are circulated to each other.

The other end of the plurality of branch pipes 31, one end of which is connected to the convergence chamber 30, is connected to the inner pipes 11 exposed to the first header pipe 21 arranged on one side in the Z-axis direction. .

The inner tubes 11 exposed to the first header tube 21 disposed on the other side in the Z-axis direction are connected to the fruit discharge header tube 40 extending in the Y-axis direction.

The convergence chamber 30 is connected to a fruit supply header tube 50 connected to a fruit supply source.

The first header tube 21 disposed on one side in the Z-axis direction is connected to a source of unshown feature liquid, and the first header tube 21 disposed on the other side in the Z-axis direction is to be treated. It is connected to the discharge pipe which is not shown which discharge | releases.

As shown in Fig. 4, the inner tube 11 is preferably composed of two tubules 11a and 11b twisted in a two-line twisted manner. The reason is because the outer surface of the inner tube due to the twist of the two tubules (11a, 11b) constituting the inner tube to move the liquid to be treated spirally, the tubules (11a, 11b) itself also extends in a spiral, The fruit in the tubules 11a and 11b also moves helically, so that the refrigerant and the liquid to be treated can be uniformly distributed radially in the double tube 10 and the refrigerant and the refrigerant by their own weight. This is because the to-be-processed liquid can increase the heat transfer efficiency than the conventional heat exchanger which is concentrated at the lower end in the double pipe.

In the description of the embodiment, the inner tube is described as being twisted in a three-line twisted manner by two tubules, the present invention constitutes the inner tube with three or more tubules and twisted the plurality of tubules in a plurality of twisted manners It may be true.

The heat exchanger 100 configured as described above is capable of applying a large capacity among the disadvantages of the conventional double tube heat exchanger, and also inserts a plurality of inner tubes of the double tube heat exchanger (2-3) into the exterior in a twisted shape. This makes it possible to promote heat transfer and to reduce pressure intensification, and also to enable the header of the double tube heat exchanger to secure sufficient space for separation of gas and liquid.

10; Double tube, 11; Inner tube, 11a; Customs, 11b; Customs, 12; Appearance 13; Curved tube, 21; First header tube, 22; Second header tube, 23; Curved header pipe, 30; Converging chamber, 31; Branch pipe, 40; fruit discharge header pipe, 50; Fruit Feed Header Tube, 100 ;, Heat Exchanger

Claims (5)

A heat exchanger (100) comprising a plurality of double tubes (10) extending in the X-axis direction with a plurality of rows and a plurality of columns in the Y-axis and Z-axis directions,
The double tube 10 has the same center as the center of the inner tube 11 and the inner tube 11 which is a fruit transfer tube extending in the X-axis direction in the state in which the inner tube 11 is inserted to be exposed at both ends. And an exterior 12 which is a customs for transferring the liquid to be treated which is to be heat-exchanged to
One end of the outer appearances 12 of the plurality of double pipes 10 are connected to the plurality of straight first header pipes 21 extending in the Y-axis direction spaced apart from each other in the Z-axis direction and distributed to each other, one The first header pipe 21 of the is to be connected to one end of the group of facades 12 which are spaced apart at regular intervals in the Y-axis direction and in the same position in the Z-axis direction,
The other ends of the outer surfaces 12 of the plurality of double tubes 10 have an inner space larger than that of the straight first header tube 21 and are spaced apart from each other in the Z axis direction by a predetermined interval and extend in the Y axis direction. Connected to two straight second header pipes 22,
The plurality of second header pipes 22 are spaced apart at regular intervals in the Z-axis direction, and are half of the number of the first header pipes 21, so that the plurality of second header pipes 22 Each of the other ends of the group of facades 12 spaced apart from each other in the Y-axis direction and in the same position in the Z direction, and the other group of facades immediately adjacent to the other end of the group of facades 12 in the Z-axis direction ( To be connected to the other ends of 12),
Both ends of the inner tube 11 are exposed through the first header tube 21 and the second header tube 22 in the X-axis direction,
The ends of the plurality of inner tubes 11 except for the ends of the plurality of inner tubes to be connected to the fruit inlet side and the ends of the plurality of inner tubes to be connected to the fruit outlet side among the inner tubes 11 of the plurality of double tubes 10 are The outlet end and the inlet end of the inner tube 11 immediately adjacent in the Z-axis direction are connected to each other by the curved tubes 13 which are the bent tubulars bent in the Z-axis direction, and are circulated to each other.
The first header tube arranged on one side in the Z-axis direction and the first header tube to be directly connected to the inflow side of the liquid to be heat-treated, and the heat-treated solution as the first header tube disposed on the other side in the Z-axis direction. The first header tubes disposed between one side and the other side in the Z-axis direction except for the first header tube to be directly connected to the side immediately adjacent to the outlet side of the outlet end and the inlet of the first header tube immediately adjacent in the Z-axis direction The side ends are connected to each other by the curved header pipe 23 bent in the Z-axis direction and are circulated to each other,
The inner tube is a double-pipe type heat exchanger, characterized in that the plurality of tubular twisted in a plurality of twisted manner. The method of claim 1,
The other end of the plurality of branch pipes 31, one end of which is connected to the converging chamber 30, is connected to the inner pipes 11 exposed to the first header pipe 21 arranged at one side in the Z-axis direction. ,
The inner tube 11 exposed to the first header tube 21 disposed on the other side in the Z-axis direction is connected to the fruit discharge header tube 40 extending in the Y-axis direction. group. The method of claim 2,
The convergence chamber 30 is connected to a fruit supply header tube 50 connected to a fruit supply source,
The first header pipe 21 disposed on one side in the Z-axis direction is connected to a source of feature liquid, and the first header tube 21 disposed on the other side in the Z-axis direction allows the liquid to be treated to be discharged. A double tube type heat exchanger, connected to the discharge pipe. The inner tube which is a fruit conveying tube which extends in the X-axis direction and the outer tube which is a tube for conveying the to-be-processed liquid to be heat-exchanged which extends in the X-axis direction become double tubes, and are arranged with a plurality of rows and a plurality of columns,
The inner tubes of the plurality of double tubes are circulated with each other by a curved tube which is a bent tube bent in the Z-axis direction,
Between the external appearances of the plurality of double pipes are circulated with each other by a plurality of straight first header pipes extending in the Y-axis direction and a plurality of straight second header pipes having an inner space larger than that of the straight first header pipes. ,
Between the first header tubes except for the first header tube disposed on the inlet side and the outlet side of the liquid to be treated, they are circulated with each other by a curved tube bent in the Z-axis direction, and
Fruit is supplied to the inner tube which is the plurality of customs via a branch pipe which is a plurality of customs branches branched from a supply header tube, and the fruit discharged from the inner tube which is the plurality of customs tubes is a plurality of customs branched from the fruit discharge header tube. Discharge through the organs,
The inner tube is a double-pipe type heat exchanger, characterized in that the plurality of tubular twisted in a plurality of twisted manner. delete

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