KR100512116B1 - A refrigerator unit - Google Patents

Abstract

The present invention relates to a chiller comprising an evaporator having an evaporator tube, a condenser tube and an inlet and outlet, wherein the inlet of the evaporator is at the bottom of the evaporator and the outlet of the evaporator is at the top of the evaporator and the condensation tube is a Bending pipes connected to both sides are connected to each other to form a heat exchange pipe layer, one side of the evaporator tube is connected to the outlet of the evaporator, one side of the condenser tube is connected to the inlet of the evaporator, and the other side of the evaporator tube is It is connected to the other side of the condenser tube. In another cooler according to the present invention comprising an evaporator having a condenser tube and an inlet and outlet, the inlet and outlet of the evaporator are located at the top of the evaporator and the condensation tube is composed of several straight pipes and banding pipes connected to both sides of the straight pipes connected to each other. It forms a heat exchange pipe layer and one side of the condenser tube is connected to the inlet and outlet of the evaporator and the other side is connected to the other inlet and outlet of the evaporator. The present invention increases the number of layers of the heat exchange pipe layer and greatly increases the heat of evaporation by using the space in the vertical direction efficiently under a constant cooling plane.

Description

Refrigerator {A refrigerator unit}

TECHNICAL FIELD The present invention relates to a chiller, and more particularly to a multi-layer net type heat pipe cooler.

As heat pipe technology advances, the cooling capacity of the chillers is increasing. Although heat pipe technology has greatly improved the heat conduction efficiency, whether or not the conducted heat can be exchanged on time depends on the heat exchange area and heat exchange conditions of the cooler. The current technology is to increase the diameter of the heat transfer pipe so that energy can be transferred smoothly, and at the same time, the heat exchange area is increased by increasing the heat exchange area using the space allowed by the cooling plane, and the heat exchange conditions of the net cooler are advantageous. To increase the evaporative heat of the cooler. Therefore, the coolers currently used are 1 ~ 2 layer net coolers. However, when the heat transfer pipe is smoothly heated (no bottleneck in heat transfer) and the heat exchange method is constant, the heat exchange area of the cooler can determine the amount of heat of evaporation and when the space of the cooling plane is limited, that is, the size of the heat exchange area of the plane. If the constant is a single- or two-layer net type cooler alone can not implement a large heat of evaporation.

An object of the present invention is to improve the evaporation heat of the cooler in a condition where the space of the cooling plane is constant.

In order to achieve the above object, the present invention provides a cooler as follows. The cooler includes an evaporator having an evaporator tube, a condenser tube and an inlet and outlet, the inlet of the evaporator is at the bottom of the evaporator, the outlet of the evaporator is at the top of the evaporator, and the condensation tube is on both of the straight pipe and the straight pipe. Connected bending pipes are connected to each other to form a heat exchange pipe layer, one side of the evaporator tube is connected to the outlet of the evaporator, one side of the condensation tube is connected to the inlet of the evaporator and the other side of the evaporator tube Are connected to the other side of the condensation tube.

The angle between the straight pipe of the condenser tube and the ground (horizontal plane) is 20 degrees to -20 degrees so that the refrigerant condensed by gravity is returned to the evaporator well. The inner diameter of the evaporation tube and the condensation tube is preferably 2 mm to 10 mm. This is because, in order to move the refrigerant condensed in the condenser tube to the evaporator by the capillary phenomenon, the inner diameter of the condenser tube must be small (since the capillary phenomenon is inversely proportional to the inner diameter of the pipe), and the flow rate must be taken into account to increase the cooling efficiency.

The evaporation tube is composed of several evaporation tubes, the condensation tube is composed of several condensation tubes, the several condensation tubes are connected one-to-one with the several evaporation tubes, and the heat exchange pipe layer forms one or more layers. The evaporator has one outlet and the several evaporation tubes are all connected to the outlet. Or the evaporator has one or more outlets and the several evaporator tubes are connected one-to-one with one or more outlets of the evaporator. The evaporator has one inlet and the several condensation tubes are all connected to the inlet. Or the evaporator has at least one inlet and the several condensation tubes are connected one-to-one with at least one inlet of the evaporator.

The condensation tube is connected to one or more cooling fins. The evaporator may further be connected with a tailpipe used for repair while forming a vacuum state.

The present invention provides another cooler comprising an evaporator having a condenser tube and an inlet and outlet. The inlet and outlet of the evaporator is located on the upper part of the evaporator, and the condensation pipe is composed of a plurality of straight pipes and banding pipes connected to both of the straight pipes to form a heat exchange pipe layer and one side of the condensation pipe. It is connected to the inlet and outlet of the evaporator and the other side is connected to the other inlet and outlet of the evaporator.

Here, the inner diameter of the condensation tube is preferably 2mm ~ 10mm in consideration of the capillary phenomenon and the cooling efficiency. The condensation tube is composed of a plurality of condensation tube and the heat exchange pipe layer is composed of one or more layers. One side of the several condensation tubes is all connected to one inlet and outlet of the evaporator. Or the evaporator has one or more outlets and one side of the multiple evaporator tubes is connected one-to-one with the inlet and the outlet respectively. The condensation tube is connected to one or more cooling fins. Tail evaporator may be further attached to the evaporator to be able to form a vacuum state and to be easily used for repair.

 Therefore, the present invention has the advantage of greatly improving the evaporation heat of the cooler in a state where the space of the cooling plane is constant.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the technical solution of the present invention will be described in detail as follows:

Example 1:

1 to 3 are front, bottom and side views of the preferred embodiment 1 of the present invention. At the top of the evaporator 1 of the cooler there are three outlets 10 and at the bottom there is one inlet 11 and one tail pipe 12. Three outlets 10 are each connected to three evaporation tubes 2 and three evaporation tubes 2 are also connected to three condensation tubes 3 respectively. The other side of the three condensation tubes 3 is connected to the inlet 11 via a four-way connector 5. The condensation pipe (3) is composed of three pipes for heat exchange pipe layer (9) consisting of three layers and all of the heat exchange pipe (39) connected to both of the straight pipe 38 and the straight pipe (38) are connected to each other. Ten cooling fins 4 were welded to the piping layer 9 for welding. The uppermost and lowermost straight pipe 38 is in a horizontal shape, and the remaining straight pipe 38 maintains an angle of 20 degrees to -20 degrees with respect to the ground (horizontal plane) and is set to 20 degrees or -20 degrees in this embodiment. The inner diameters of the condensation tube 3 and the evaporation tube 2 are both 2 mm.

Before use, the evaporator (1), the evaporator tube (2) and the condensation tube (3) are evacuated via a tail pipe (12) and then a working fluid (e.g. isobutane, municipal) No.), and the height of the working fluid is lower than the height of the outlet (10). After the evaporator 1 is in contact with a heat source, the heat exchanger performs heat exchange to increase the temperature of the working fluid to become a gaseous state, and passes through the evaporator tube 2 and the condensation tube 3 sequentially to continue the heat exchange. When the temperature becomes lower than the boiling point and becomes a liquid, it is refluxed to the evaporator 1 by gravity or capillary action through the condensation tube 3.

Example 2:

4 to 6 are front, bottom and side views of the preferred embodiment 2 of the present invention. At the top of the evaporator 1 of the cooler there are two outlets 10 and at the bottom there is one inlet 11 and one tail pipe 12. The two outlets 10 are each connected to two evaporation tubes 2, the first evaporation tube 21 is connected to the first condensation tube 31, and the second evaporation tube 22 is a three-way connector 6. It is connected to the second condensation tube 32 and the third condensation tube 33 through. The other side of the three condensation tubes 3 is connected with the inlet 11 via a four-way connector 5. Condensation pipe (3) is composed of a plurality of straight pipes (38) and a bending pipe (39) connected to both sides of the straight pipes (38) are composed of three layers of heat exchange pipe layer (9) and for heat exchange Ten cooling fins 4 were welded to the piping layer 9. The top and bottom straight pipes 38 are horizontal, the angles of the other straight pipes 38 are 16 degrees or -16 degrees, and the inner diameters of the condensation tube 3 and the evaporation tube 2 are 4 mm.

Since the principle of operation is the same as in Example 1, the description is not repeated here.

Example 3:

7 to 9 are front, plan and side views of the preferred embodiment 3 of the present invention. At the top of the evaporator 1 of the cooler there are two outlets 10 and at the bottom there are two inlets 11 and one tail pipe 12. The two outlets 10 are respectively connected to two evaporation tubes 21 and 22, the first evaporation tube 21 is connected to the first condensation tube 31, and the first condensation tube 31 is the inlet 111. The second evaporation tube 22 is connected to the second condensation tube 32 and the third condensation tube 33 through the three-way connector 6. The other side of the second condensation tube 32 and the third condensation tube 33 is connected to the inlet 112 via a three-way connector 6. Condensation pipe (3) is composed of a plurality of straight pipes (38) and a bending pipe (39) connected to both sides of the straight pipes (38) are composed of three layers of heat exchange pipe layer (9) and for heat exchange 17 cooling fins 4 were welded to the piping layer 9. The uppermost and lowermost straight pipe 38 is horizontal, the angle of the other straight pipe 38 is 12 degrees or -12 degrees, and the inner diameters of the condensation tube 3 and the evaporation tube 2 are both 6 mm.

Since the principle of operation is the same as in Example 1, the description is not repeated here.

Example 4:

10 to 12 are front, bottom and side views of the preferred embodiment 4 of the present invention. At the top of the evaporator 1 of the cooler there are three outlets 10 and at the bottom there are three inlets 11 and one tail pipe 12. Three outlets (10) are each connected to three evaporation tubes (2), three evaporation tubes (2) are connected to three condensation tubes (3) each, and three condensation tubes (3) are each connected to three inlets ( 11) and one-to-one connection. Condensation pipe (3) is composed of a plurality of straight pipes (38) and a bending pipe (39) connected to both sides of the straight pipes (38) are composed of three layers of heat exchange pipe layer (9) and for heat exchange Eight cooling fins 4 were welded to the piping layer 9. The top and bottom straight pipes 38 are horizontal, the angles of the other straight pipes 38 are 8 degrees or -8 degrees, and the inner diameters of both the condensation tube 3 and the evaporation tube 2 are 8 mm.

Since the principle of operation is the same as in Example 1, the description is not repeated here.

Example 5:

13 to 15 are front, bottom and side views of the preferred embodiment 5 of the present invention. At the top of the evaporator 1 of the cooler there are two outlets 10 and at the bottom there is one inlet 11 and one tail pipe 12. The two outlets 10 are connected to two evaporation tubes 2, respectively, wherein the first evaporation tube 21 is connected to the first condensation tube 31 and the second condensation tube 32 through the three-way connector 6. The second evaporation tube 22 is connected to the third condensation tube 33 and the fourth condensation tube 34 through the three-way connector 6. The other side of the four condensation tubes 3 is connected to the inlet 11 via a five-way connector 7. Condensation pipe (3) is composed of a plurality of pipe pipes (9) for heat exchange and the heat exchange for the heat exchange pipe (39) and the bending pipe (39) connected to both sides of the straight pipe (38) are all composed of Ten cooling fins 4 were welded to the piping layer 9. The top and bottom straight pipes 38 have a horizontal shape, the angle between the other straight pipes 38 and the horizontal plane is 4 degrees or -4 degrees, and the inner diameters of the condensation tube 3 and the evaporation tube 2 are both 10 mm.

Since the principle of operation is the same as in Example 1, the description is not repeated here.

Example 6:

16 to 18 are front, plan and side views of the preferred embodiment 6 of the present invention. At the top of the evaporator 1 of the cooler there are two inlets and outlets 13 and at the bottom there is one tail pipe 12. One side of the two condensation tubes 3 is connected to the inlet and outlet 131 via a four-way connector 5, and the other side of the two condensation tubes 3 is connected to the other inlet and outlet 132 via a four-way connector 5. Connected. Condensation pipe (3) is composed of a plurality of straight pipes (38) and a bending pipe (39) connected to both sides of the straight pipes (38) are composed of three layers of heat exchange pipe layer (9) and for heat exchange Eight cooling fins 4 were welded to the piping layer 9. The inner diameter range of the condensation tube 3 and the evaporation tube 2 is 2 to 10 mm, and in this embodiment, all are 5 mm.

Before use, the evaporator (1), the evaporator tube (2) and the condensation tube (3) are evacuated via a tail pipe (12) and then a working fluid (e.g. isobutane, municipal) No.), and the height of the working fluid is lower than the height of the inlet and outlet (13). After the evaporator 1 comes into contact with the heat source, it exchanges heat and the temperature of the working fluid becomes high to become gaseous and enters the condensation tube 3 to continue heat exchange, and the temperature of the working fluid is lower than the boiling point. When it is returned to the evaporator 1 by gravity or capillary action through the condensation tube (3).

Although the preferred embodiments of the present invention have been described in detail above, the present invention is not limited thereto, and various modifications can be made by those skilled in the art. For example, the numerical limitation (gravity type) of the straight pipe slope of the condensation tube for refluxing the condensed refrigerant to the evaporator, or the numerical limitation of the inner diameter of the condensation tube and the evaporation tube for causing the capillary phenomenon is limited to the above embodiment. Not surprisingly.

As described in the above description, the cooler of the present invention can significantly increase the number of layers of the cooler pipe net by efficiently using the longitudinal space in a state where the space of the cooling plane is constant, thereby greatly increasing the heat of evaporation of the cooler.

1 is a front view of a preferred embodiment 1 of a cooler according to the present invention,

2 is a bottom view of a preferred embodiment 1 of a cooler according to the present invention;

3 is a side view of a preferred embodiment 1 of a cooler according to the present invention;

4 is a front view of a preferred embodiment 2 of a cooler according to the present invention,

5 is a bottom view of a preferred embodiment 2 of a cooler according to the invention,

6 is a side view of a preferred embodiment 2 of a cooler according to the present invention;

7 is a front view of a preferred embodiment 3 of a cooler according to the present invention,

8 is a plan view of a preferred embodiment 3 of a cooler according to the present invention;

9 is a side view of a preferred embodiment 3 of a cooler according to the present invention,

10 is a front view of a preferred embodiment 4 of a cooler according to the present invention,

11 is a bottom view of a preferred embodiment 4 of a cooler according to the present invention;

12 is a side view of a preferred embodiment 4 of a cooler according to the present invention,

13 is a front view of a preferred embodiment 5 of the cooler according to the present invention;

14 is a bottom view of a preferred embodiment 5 of a cooler according to the present invention;

15 is a side view of a preferred embodiment 5 of a cooler according to the present invention;

16 is a front view of a preferred embodiment 6 of the cooler according to the present invention;

17 is a plan view of a preferred embodiment 6 of a cooler according to the present invention;

18 is a side view of a preferred embodiment 6 of a cooler according to the present invention.

<Explanation of symbols for the main parts of the drawings>

DESCRIPTION OF REFERENCE NUMERALS 1 evaporator 2 evaporation tube 21, 22 first and second evaporation tube 3 condensation tube 31 to 34 first to fourth condensation tube 4 cooling fin 5 four way connector 6 three way connector 7 five way connector 9 heat exchange pipe layer 10 outlet 11, 111, 112 inlet 12 tail pipe 13, 131, 132 inlet and outlet 38 straight pipe 39 bending pipe

Claims (17)

delete delete delete delete delete In a chiller comprising an evaporator having an evaporator tube, a condensation tube and an inlet and outlet, The inlet of the evaporator is at the bottom of the evaporator, the outlet of the evaporator is at the top of the evaporator, The condensation tube is composed of a plurality of straight pipes, the bending pipes are connected to each other on both sides of the straight pipe to form a heat exchange pipe layer, One side of the evaporator tube is connected to the outlet of the evaporator, one side of the condenser tube is connected to the inlet of the evaporator, the other side of the evaporator tube is connected to the other side of the condensation tube, Each of the evaporation tube and the condensation tube is composed of a plurality, each evaporation tube is connected to one of the condensation tube one-to-one, the heat exchange pipe layer is one or more layers, And the evaporator has one or more outlets, each outlet being one-to-one connected with one of the evaporator tubes. delete In a chiller comprising an evaporator having an evaporator tube, a condensation tube and an inlet and outlet, The inlet of the evaporator is at the bottom of the evaporator, the outlet of the evaporator is at the top of the evaporator, The condensation tube is composed of a plurality of straight pipes, the bending pipes are connected to each other on both sides of the straight pipe to form a heat exchange pipe layer, One side of the evaporator tube is connected to the outlet of the evaporator, one side of the condenser tube is connected to the inlet of the evaporator, the other side of the evaporator tube is connected to the other side of the condensation tube, Each of the evaporation tube and the condensation tube is composed of a plurality, each evaporation tube is connected to one of the condensation tube one-to-one, the heat exchange pipe layer is one or more layers, And the evaporator has one or more inlets, each inlet connected one to one of the condensation tubes. delete delete A chiller comprising an evaporator having a condenser tube and an inlet and outlet, The inlet and outlet of the evaporator is located at the top of the evaporator, The condensation tube is composed of a plurality of straight pipes, the bending pipes are connected to each other on both sides of the straight pipe to form a heat exchange pipe layer, One side of the condenser tube is connected to the inlet and outlet of the evaporator, and the other side of the condenser tube is connected to the other inlet and outlet of the evaporator. The method of claim 11, The inner diameter of the condensation tube is a cooler, characterized in that 2mm ~ 10mm. The method according to claim 11 or 12, The condenser tube is composed of a plurality, the heat exchange pipe layer is a cooler, characterized in that more than one layer. The method of claim 13, Wherein one side of the plurality of condensation tubes is all connected to one inlet and outlet of the evaporator, and the other side of the plurality of condensation tubes is all connected to the other inlet and outlet of the evaporator. The method of claim 13, And the evaporator has one or more inlets and outlets, and one side and the other side of the plurality of condensation tubes are connected one-to-one with one of the inlet and outlet respectively. The method of claim 11, The condenser tube is characterized in that at least one cooling fin is connected. The method of claim 11, Cooler, characterized in that the evaporator is further connected to the tail pipe used for repair while forming a vacuum state.