KR20020002777A - Heat exchanger with over saturation coolant by pass function - Google Patents

Abstract

PURPOSE: A heat exchanger with supersaturated refrigerant bypass function is provided to reduce a thermal loss during heat exchange operation, improve heat exchange efficiency of the heat exchanger and prevent overload of the compressor. CONSTITUTION: A flow channel(2) is formed by laminating a plurality of plates(1), and a radiation fin(3) is installed between plates. A tank unit(6) connected to a refrigerant inlet port(4) and a refrigerant outlet port(5) is arranged onto the plates. A heat exchange operation is carried out by the radiation fin and an external air when the refrigerant circulates along the flow channel formed at the plate. The tank unit arranged onto the plates has a bypass hole(7), and the refrigerant at a gas state is by-passed to the refrigerant outlet port through the bypass hole.

Description

Heat exchanger with supersaturated refrigerant bypass function {HEAT EXCHANGER WITH OVER SATURATION COOLANT BY PASS FUNCTION}

The present invention provides a laminated type evaporator for use in a heat exchanger of a vehicle heat exchanger, and bypasses the supersaturated refrigerant gas completely evaporated by the evaporator without sending the refrigerant gas to a heat exchange zone and an effective liquid refrigerant in the heat exchange zone. The present invention relates to a heat exchanger having a supersaturated refrigerant bypass function, which allows to pass a bay, thereby reducing frictional resistance of fluid flowing into the heat exchanger and increasing heat exchange efficiency.

Generally, a heat radiator installed in a vehicle heat exchanger and performing heat dissipation and having a heat dissipation action has a coolant inlet and an outlet and a flow path through which the coolant is circulated and heat exchange is performed when the coolant is circulated through the flow path. It was configured to radiate heat from the radiator.

On the other hand, the heat exchanger of the conventional heat sink configured as described above, as shown in Figure 1 by stacking a plurality of plate-like plate 101 to form a flow path 102 and between the plates 101 to install a heat radiation fin 103 The upper portion of the plate 101 was formed by forming a tank 106 connected to the refrigerant inlet 104 and the outlet 105, the refrigerant introduced into the tank 106 through the inlet 104 It is provided on one side of the heat dissipation fin 103 and the heat exchanger when the refrigerant circulates along the flow path 102 and circulates along the pattern of the flow path 102 formed in each plate 101 through the tank part 106. The heat exchange action is performed by the wind power of the blower, and the refrigerant in the supersaturated gas state in which the heat exchange is performed is configured to be sent to the compressor through the outlet port 105.

However, in the conventional art, the liquid refrigerant circulates along the flow path and performs heat exchange, and the refrigerant circulating toward the outlet while performing the heat exchange action is a gas state in which no more evaporation or a state in which the cool air cannot be cooled. In the case of phosphorus supersaturated gas, a large amount of refrigerant in the supersaturated gas state is distributed in the effective area in which the heat exchange is performed. As a result, there was a closed end where the evaporation efficiency was significantly lowered.

In addition, as the refrigerant heat exchanges, a volume increase occurs due to the phase change of the liquid refrigerant into gas, and the internal flow resistance of the refrigerant increases due to the volume increase, thereby greatly reducing the efficiency of the heat exchanger. There was a problem.

The present invention has been made in view of the above-mentioned conventional problems, and the present invention provides a thin plate evaporator used for a heat radiator of a vehicle heat exchanger, and does not send the supersaturated refrigerant gas completely evaporated from the evaporator to a heat exchange area. It is to provide a heat exchanger having a supersaturated refrigerant bypass function to bypass and to allow only effective liquid refrigerant to pass through the heat exchange area, thereby reducing frictional resistance of the fluid flowing into the heat exchanger and increasing heat exchange efficiency. Inba, it will be described in detail based on the accompanying drawings and examples below.

1 is a perspective view showing the structure of a conventional heat exchanger

2 is a perspective view showing a heat exchanger configuration of an embodiment of the present invention

Figure 3 is a cross-sectional schematic diagram showing an operating state of the embodiment of the present invention

Explanation of symbols on the main parts of the drawing

1: thin plate

2: Euro

3: heat dissipation fin

4: refrigerant inlet

5: outlet

6: tank part

7: bypass ball

Laminating a plurality of plate-like plate (1) to form a flow path (2) and install a heat dissipation fin (3) between the plates (1) and the refrigerant inlet (4) and outlet (5) on the top of the plate (1) Forming a tank portion 6 to which the heat sink is connected to the heat dissipation fin 3 and the outside air when the refrigerant circulates along the pattern of the flow path 2 formed in the plate 1. In order to form a pattern of the flow path (2), a bypass hole (7) is formed in the tank part (6) formed on the upper part of the plates (1), and a gaseous refrigerant is formed through the bypass hole (7). It is configured to be bypassed to the outlet (5).

In addition, the upper portion of the tank portion 6 formed on the upper portion of the plate (1) is expanded and the liquid refrigerant flows to the lower portion of the tank portion 6, the gaseous refrigerant to the upper portion of the expanded portion is the outlet port It can be configured to bypass directly to (5).

According to the present invention configured as described above, a plurality of the plate-like plates 1 are stacked to form a flow path 2, and a heat dissipation fin 3 is installed between the plates 1, and a refrigerant inlet is formed on the plates 1. In forming the tank part 6 to which the 4 and the outlet port 5 are connected, in the state in which the bypass hole 7 which consists of a zigzag form is formed in the upper part of the said tank part 6, the said tank part 6 When the liquid refrigerant is introduced through the inlet 4 formed at one side of the), the liquid refrigerant is circulated along the pattern of the flow path 2 formed in the plate 1, and the liquid refrigerant is circulated while the heat dissipation fins 3 and Heat exchange is effected by external air, and the liquid refrigerant becomes a supersaturated gas refrigerant by the heat exchange.

When the supersaturated gaseous refrigerant is generated by heat exchange as described above, the gaseous refrigerant tries to vaporize upward by gravity, and the gaseous refrigerant in the gaseous state is formed in the tank part 6 by-pass. Bypassing the ball (7) while bypassing the outlet (5) and by the bypass action so that the supersaturated gas refrigerant is not introduced into the heat exchange effective area, only the liquid refrigerant is circulated at all times in the heat exchange effective area Since it is possible to reduce the resistance element of the heat exchange and to improve the heat exchange efficiency of the heat exchanger.

In addition, the upper portion of the tank portion 6 formed on the upper portion of the plate (1) is expanded and the liquid refrigerant flows to the lower portion of the tank portion 6, the gaseous refrigerant to the upper portion of the expanded portion is the outlet port If it is configured to bypass directly to (5), the above operation and effect can be obtained even if the bypass hole is not formed as described above.

The present invention as described above forms a configuration capable of bypassing the supersaturated gaseous refrigerant in the tank portion 6 of the heat exchanger as described above, and bypasses the gaseous supersaturated refrigerant with the bypass means. Since the refrigerant in the gaseous state does not enter the heat exchange effective area, and thus the flow path resistance of the refrigerant can be reduced, heat loss during heat exchange can be reduced, and at the same time, the heat exchange efficiency of the heat exchanger can be greatly improved. It is characterized by the fact that it can prevent overload.

Claims (2)

Laminating a plurality of plate-like plate (1) to form a flow path (2) and install a heat dissipation fin (3) between the plates (1) and the refrigerant inlet (4) and outlet (5) on the top of the plate (1) Forming a tank portion 6 to which the heat sink is connected to the heat dissipation fin 3 and the outside air when the refrigerant circulates along the pattern of the flow path 2 formed in the plate 1. In order to form a pattern of the flow path (2), a bypass hole (7) is formed in the tank part (6) formed on the upper part of the plates (1), and a gaseous refrigerant is formed through the bypass hole (7). Heat exchanger having a supersaturated refrigerant bypass function, characterized in that configured to be bypassed to the outlet (5). The method of claim 1, wherein the upper portion of the tank portion (6) formed on the upper portion of the plate (1) is expanded, the liquid refrigerant flows to the lower portion of the tank portion 6 and the gas state to the upper portion of the expanded portion Heat exchanger having a supersaturated refrigerant bypass function, characterized in that the refrigerant is configured to bypass directly to the outlet (5).