KR19980083867A - Condenser Structure of Heat Exchanger - Google Patents

Abstract

The present invention uses the condensation medium of the condenser in contact with the surface of the high density liquid material (brine, antifreeze, constant) to the surface of the refrigerant pipe to maximize the condensation efficiency through the water-cooled heat dissipation state and also used in a small capacity heat exchanger Condensation Media of Condenser Condenser Medium The heat condensation medium in the upper part of the condenser and the condensation medium in the lower part which form room temperature utilize the natural convection phenomenon caused by the temperature difference between them. It is about the condenser structure of the heat exchanger device which achieves forced circulation through the circulation pump and exposes the heat dissipation part to the outside and has a long flow path like a condenser, so that its volume is reduced and efficient use of space can be achieved. A characteristic configuration is that in a conventional refrigeration cycle, the refrigerant pipe between the compressor and the capillary is centered. A condensation tube of a pretzel or screw type having a water outlet and an inlet formed through and coupled to each other; Coupled with the drain and inlet of the condensation tube, there are several heat dissipation fins that circulate the condensation medium (Brine, antifreeze, constant) absorbing heat by contacting the surface of the refrigerant pipe to cool the heat and widen the heat dissipation area to the outside. It has a feature consisting of an attached heat sink.

Description

Condenser Structure of Heat Exchanger

Generally, various heat exchangers such as refrigerators, showcases or freezers are provided for storing fish and meat or other foods stored at a temperature of about 2 to 5 ° C. or freezing them at a temperature below 0 ° C. The refrigeration cycle of such a heat exchanger is usually a compressor (1) for compressing the refrigerant at high temperature and high pressure, as shown in FIG. 1, a condenser (2) having a long flow path for dissipating and liquefying the refrigerant in the gas state flowing from the compressor, A capillary tube 3 for converting the liquid refrigerant introduced from the condenser into a gaseous liquid mixed refrigerant of low temperature and low pressure, and an evaporator which takes heat from the surroundings while the liquid refrigerant in the refrigerant introduced from the capillary evaporates (4) and an accumulator (5) for separating the refrigerant introduced from the evaporator into a gas refrigerant and a liquid refrigerant, wherein the accumulator is Inlet pipe to receive the refrigerant inlet and the outlet pipe emanating only vapor refrigerant to the compressor, it is composed of a housing that holds a liquid refrigerant.

In this series of refrigerant cycles, the refrigerant is cooled to high temperature and high pressure by the continuous pumping force of the compressor, which cools the refrigerant through a tube having a long flow path called a condenser, and the cooled refrigerant passes through a capillary tube having a narrow flow path. When the flow of the refrigerant is accelerated and sent to the evaporator, the refrigerant is vaporized as the pressure drops in the evaporator of the wide flow path, and the refrigerant performs a series of heat exchange cycles to absorb heat contained in the external fluid.

Referring to the configuration of the condenser according to the present invention in the series of refrigeration cycle described above is as follows.

That is, in the refrigerant pipe that connects the series of refrigeration cycle members, the refrigerant pipe between the compressor and the capillary tube is bent in a predetermined form to form a long flow path, thereby providing a condenser.

The condenser constructed as described above has a high temperature and high pressure refrigerant gas flowing from the compressor, which passes through a long flow path of the condenser, heats through external heat and natural heat, cools naturally, and drives a separate cooling fan when necessary to increase heat dissipation. After forced heat dissipation, it is introduced into a capillary tube which is converted into a gaseous liquid mixed refrigerant of low temperature and low pressure.

The performance of the condenser, for example, the efficiency of liquefaction is closely related to the heat dissipation.

However, the conventional condenser adopts a natural cooling method by contact with external air or an air cooling method of forced cooling method by driving a cooling fan. The heat dissipation efficiency of the condenser is extremely reduced in the hot summer season. It is difficult to obtain the best heat dissipation desired, and there are various problems that result in an increase in noise and power consumption due to excessive driving of the cooling fan.

Accordingly, the present invention has been made in order to solve the conventional problems, the object of the heat dissipation state of the water-cooled method by contacting the surface of the refrigerant pipe with a dense liquid material (Brine, antifreeze, constant) of the condensation medium of the condenser In order to maximize the condensation efficiency through the condensation medium, the condensation medium of the condenser used in the small-capacity heat exchanger. The circulating method of the condenser used in the large-capacity heat exchanger is forced circulation through the circulation pump, exposing the heat dissipation part to the outside, and the volume is reduced while having a long flow path like the condenser, so that the space can be efficiently used. To provide a condenser structure of a conventional heat exchanger.

1 is an illustration of a refrigeration cycle of a heat exchanger for explaining the prior art,

2 is a heat exchanger refrigeration cycle according to the present invention,

Figure 3 is an enlarged cross-sectional view of the main part according to an embodiment of the present invention,

Figure 4 is an enlarged cross-sectional view of the main part according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

10: compressor, 20: condenser,

21: condensation tube, 21a: drain port,

21b: inlet, 22: refrigerant pipe,

23: heat dissipation tube, 24, 24 ': extension tube,

25: circulation pump, 26: cooling fan,

30 capillary 40 evaporator

The present invention for achieving the above object in the conventional refrigeration cycle, the refrigerant pipe between the compressor and the capillary tube is penetrated to the center and the drain and inlet formed in the upper and lower condensate or screw type condensation tube; The heat dissipation fin is connected to the drain and inlet of the condensation tube and circulates the condensation medium (Brine, antifreeze, water, etc.) that absorbs heat by contacting the surface of the refrigerant pipe therein to cool the heat and expand the heat dissipation area to the outside. It is characterized by several attached heat sinks.

In addition, in the present invention, the length of the heat dissipation tube is extended to a long length and the volume is made in the form of a small condenser and is communicated with the condensation tube through a pair of extension tube is installed to be exposed to the outside of the wall and the condensation medium is forced circulation at a predetermined position There is another feature that is provided with a cooling fan for installing a circulation pump to force the heat radiating pipe to one side.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

Figure 2 shows a heat exchanger refrigeration cycle according to the present invention, Figure 3 shows an enlarged cross-sectional view of the main portion according to an embodiment of the present invention.

A represents a refrigeration cycle of the heat exchanger, the refrigeration cycle (A) constitutes a compressor (10) for compressing the refrigerant at high temperature and high pressure, and a long flow path for liquefying the heat of the refrigerant in the gas state flowing from the compressor Configure the condenser 20 having a.

And a capillary tube 30 for converting the liquid refrigerant introduced from the condenser into a gaseous liquid mixed refrigerant of low temperature and low pressure, and the refrigerant in the liquid state of the refrigerant introduced from the capillary evaporates to heat from the surroundings. While providing an evaporator 40 to take away, it consists of an accumulator 50 for separating the refrigerant flowing in the evaporator into a gas refrigerant and a liquid refrigerant, that is, the above shows a conventional heat exchanger refrigeration cycle, In the present invention, the refrigerant pipe (22) connecting the compressor (10) for generating a refrigerant gas of high temperature and high pressure and the capillary tube (30) for converting into a gas liquid mixed refrigerant of low temperature and low pressure passes through the center and has a drain hole in the upper part and the lower part. The condensation tube 21 in which 21a and the water inlet 21b were formed is formed.

The condensation tube 21 is represented as an upright tube in the drawing, but the actual product shape is manufactured to have a long flow path to increase the area of the pretzel type or screw type to increase the condensation efficiency of the condensation process.

And it forms a heat dissipation tube 23 in communication with the drain port 21a and the inlet port 21b of the condensation tube, which is composed of aluminum material having excellent heat dissipation and absorbs heat when the surface contact with the refrigerant tube therein Condensation medium, for example, calcium chloride solution, sodium chloride, magnesium chloride solution, etc., which is a medium for transferring heat between the refrigeration unit and the object to be cooled, brine, antifreeze or water It is obtained and several heat radiation fins 23a are attached to the outer surface.

Figure 4 shows an enlarged cross-sectional view of the main portion according to another embodiment of the present invention, which is to extend the length of the heat dissipation pipe 23 to increase the capacity of the condenser generated as the heat exchanger is increased and enlarged, The shape of the elongated flow path is made in the form of a cone sensor with a small volume, and is communicatively coupled to the outlet 21a and the inlet 21b of the condensation tube 21 described above through a pair of extension tubes 24 and 24 '. A circulation pump 25 for forcibly circulating the condensation medium is provided at a predetermined position of the heat dissipation tube, and a cooling fan 26 for increasing the amount of heat dissipation of the heat dissipation tube is installed on one side in response to a signal from the control means.

According to the present invention having the above configuration, the refrigerant forming the gaseous state of high temperature and high pressure by the pumping force of the compressor 10 passes through the body capillary 30 converted into the liquefied state through the condenser 20 and then the low temperature low pressure. After this, the liquid refrigerant evaporates as it enters the evaporator 40 again and undergoes a series of refrigeration cycles in which the hot heaters around the evaporator are heat-exchanged in a cool and cold state. In this cycle, the gaseous high-temperature refrigerant is condensed through the refrigerant pipe. The high heat of the refrigerant in the refrigerant pipe 22 having a temperature of about 80 ° C. or higher is a condensation medium (dense liquid) that maintains room temperature through the heat dissipation pipe 23 when passing through the center of the condensation pipe 21 of 20. By absorbing hot heat through heat exchange between the gas and the refrigerant, the refrigerant in the gaseous state is converted into the liquid state, thereby rapidly achieving the desired condensation process.

On the other hand, in the condensation medium having a high temperature by heat exchange with the refrigerant as described above, when the condenser 20 has a small capacity, natural convection occurs through a temperature difference between the condensation medium having a heat dissipation in the heat dissipation pipe 23 and the mutual temperature. The condensation medium generated and naturally heated through the upper portion of the condensation tube 21 is discharged to the heat dissipation tube, and the condensation medium at room temperature stayed in the heat dissipation tube flows into the lower inlet 21b of the condensation tube and continuously passes through the refrigerant tube. Absorbs heat from the refrigerant to condense the refrigerant in the gas state into the refrigerant in the liquid state.

On the other hand, when the capacity of the condenser 20 is large, the natural convection phenomenon due to the temperature difference is insufficient to operate the circulation pump 25 attached to a predetermined position of the heat dissipation pipe as shown in Figure 4 to achieve a smooth circulation of the condensation medium, Since the heat dissipation tube in the form of a condenser is exposed to the outside on the basis of the wall, a free piping form can be obtained, and the heat dissipation of the heat dissipation tube having a long flow path is driven by controlling the cooling fan 26 through the control means as necessary. Condensation medium is to maximize the heat radiation efficiency.

As described above, the present invention provides a water-cooling method using a high-density condensation medium (brine, antifreeze, and constant) in which a heat exchange medium of a condenser for condensing a gaseous refrigerant gas into a liquid state escapes normal air radiation. By maximizing the heat exchange efficiency of the condenser and suppressing the occurrence of loads of the members constituting the compressor and other refrigeration cycle, the power consumption or reduction, as well as the average life is further improved.

In addition, the circulation of the condensation medium in the small-capacity condenser uses natural convection, and in the large-capacity condenser, the circulation pump is separately installed to facilitate the circulation of the condensation medium, and the cooling fan is driven as needed to satisfy the heat dissipation tube. In addition to obtaining a large amount of heat dissipation, it is possible to obtain various effects to achieve efficient space utilization by exposing the heat dissipation tube in the form of a condenser to the outside of the wall in the form of free piping.

The above is only one embodiment of the present invention, the present invention is capable of various changes and modifications within the scope of the configuration.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an improved invention of a condenser for dissipating and liquefying a high-temperature, high-pressure compressor refrigerant in a heat exchanger for the purpose of refrigeration and refrigeration.

Claims (2)

In a typical refrigeration cycle, the refrigerant pipe 22 between the compressor 10 and the capillary tube 30 is penetrated into the center, and the upper and lower drain holes 21a and the inlet port 21b are formed in a pretzel or screw type condensation. Tube 21; The heat dissipation fin which is connected to the drain and inlet of the condensation tube and circulates the condensation medium (Brine, antifreeze, water, etc.) absorbing heat by contacting the surface of the refrigerant pipe therein to cool the heat and expand the heat dissipation area to the outside ( 23a) is a condenser structure of a heat exchanger, characterized in that composed of several heat dissipation pipes (23). The heat dissipation tube (23) according to claim 1, wherein the heat dissipation tube (23) is elongated and the volume is made in the form of a condenser, and the pair of communication pipes (21) communicate with the condensation tube (21) through a pair of extension tubes (24, 24 '). A) a condenser structure of a heat exchanger, characterized in that it is installed to be exposed to the outside and a circulation pump (25) for forcibly circulating the condensation medium is installed at a predetermined flow path and a cooling fan (26) for forcibly dissipating a heat dissipation tube to one side is installed.