KR20020054176A - Roof type condenser - Google Patents

Abstract

PURPOSE: A roof type condenser is provided to be easily installed and separated by reducing number, weight and volume of parts thereof. CONSTITUTION: A condenser(19) includes a refrigerant inflow line(21) supplying gaseous refrigerant and liquefied refrigerant; a heat radiator(23) rotated by a motor(33) to convert refrigerant supplied through the refrigerant inflow line into liquefied refrigerant; a refrigerant collecting pipe(25) installed closely to an inside of the heat radiator to collect liquefied refrigerant cooled down by the heat radiator; and a pump(27) supplying low-temperature liquefied refrigerant collected in the refrigerant collecting pipe to an evaporator.

Description

Loop Capacitors {ROOF TYPE CONDENSER}

The present invention relates to a loop type capacitor, and more particularly, to a loop type air conditioner system having a heat sink and a heat sink.

In general, an air conditioning system used for a bus comprises a compressor 1, a condenser 3, an evaporator 5, and a refrigerant hose 7, 9 connecting thereto, as shown in FIG.

The compressor 1 is driven by a separate dedicated engine to compress the high temperature gas refrigerant into a high temperature and high pressure gas refrigerant to supply it to the capacitor 3. The capacitor 3 cools the compressed high temperature and high pressure gas refrigerant to condense it into a low temperature liquid refrigerant. The evaporator 5 lowers the temperature of the compartment to absorb ambient heat while vaporizing the low temperature liquid refrigerant into the high temperature gas refrigerant. Refrigerant hoses 7 and 9 enable flow of such refrigerant.

On the other hand, the capacitor 3 is mounted to the loop 11 of the bus together with the evaporator 5. As shown in Fig. 2, the capacitor 3 separately constitutes a heat dissipation fan 13 and fin or tubular heat dissipation plates 15 and 17 provided on both sides of the heat dissipation fan 13, respectively.

As the loop type condenser is configured to separate the heat dissipation fan and the heat dissipation plate to condense the high temperature and high pressure refrigerant into the low temperature liquid refrigerant, the number of components increases, making the installation and removal work difficult as the weight and volume increase. There are disadvantages.

Therefore, the present invention has been invented to solve the above disadvantages, an object of the present invention is to configure the heat sink and the heat dissipation fan as one to reduce the number, weight and volume of the components to facilitate the installation and removal operation loop Is to provide a type capacitor.

1 is a block diagram of a bus air conditioner system to which a loop type capacitor is applied.

2 is a block diagram of a loop type capacitor according to the prior art.

3 is a block diagram of a loop type capacitor according to the present invention.

4 is an operational state diagram of a loop type capacitor according to the present invention.

In order to realize this, the loop type capacitor according to the present invention,

The compressed high temperature and high pressure gas and liquid refrigerant supplied from the compressor is condensed into a low temperature liquid refrigerant and supplied to the evaporator,

a) refrigerant inlet line for supplying the gas and liquid refrigerant,

b) a heat dissipation port rotating by the rotating means to convert the refrigerant supplied to the refrigerant inlet line into a liquid refrigerant,

c) a refrigerant collection pipe installed near the inner surface of the heat dissipation hole to collect the liquid refrigerant cooled by the heat dissipation hole,

d) a pump for supplying a low temperature liquid refrigerant collected in the refrigerant collection tube to the evaporator,

It includes.

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

3 is a configuration diagram of a loop type capacitor according to the present invention, in which the capacitor 19 condenses the compressed high temperature and high pressure gas and liquid refrigerant supplied from the compressor 1 into the low temperature liquid refrigerant and supplies it to the evaporator 3. It is configured to.

As shown in FIG. 4, the capacitor 19 includes a refrigerant inflow line 21, a heat dissipation port 23, a refrigerant collection pipe 25, and a pump 27.

The refrigerant inlet line 21 is supplied with a refrigerant of high temperature and high pressure gas and liquid from the compressor 1. Therefore, the refrigerant inlet line 21 is configured to supply the refrigerant of the gas and liquid thus supplied to the heat dissipation port 23.

That is, the refrigerant inlet line 21 is composed of a gas line 29 and a liquid line 31. The gas line 29 is formed toward the upper end of the heat dissipation port 23 to supply a gaseous refrigerant to the upper side of the heat dissipation port 23. The liquid line 31 is configured to supply a liquid refrigerant supplied to the gas line 29 to the lower side of the heat dissipation port 23. This liquid line 31 is formed to be inclined downward from the lower side of the gas line 27.

The heat dissipation port 23 is configured to convert the coolant supplied to the gas line 29 via the coolant inflow line 21 into a liquid coolant.

That is, the heat dissipation port 23 converts the gaseous refrigerant flowing into the gas line 29 into a liquid, and collects the liquid refrigerant flowing into the liquid line 31 and the liquid refrigerant flowing into the liquid line 31 together. It is formed into a sphere.

In this way, in order to more smoothly the action of collecting the refrigerant in the liquid state is installed to the rotational movement by the rotation means in the heat dissipation port (23). This rotating means is possible in a variety of configurations, but the present embodiment illustrates that the motor 33 is included. The motor 33 and the heat dissipation port 23 are provided with respective gears 35 and 37 capable of transmitting power.

In addition, the heat dissipation port 23 is formed with a refrigerant collecting groove 39 so that the collection pipe 25 collects the liquid refrigerant. The refrigerant collecting groove 39 is formed in the radial direction of the rotating heat dissipation port 23.

On the other hand, the coolant collection pipe 25 is installed to approach the inner surface of the heat dissipation port 23 to collect the liquid refrigerant cooled by the heat dissipation port (23).

That is, the coolant collection pipe 25 is installed to be inclined upward on both sides of the coolant inflow line 21. The refrigerant collecting pipe 25 is provided with a collecting hole 41. This collection hole 41 is formed in the upper end of the refrigerant collection pipe 25 so as to approach the refrigerant collection groove 39 of the heat dissipation port 23.

A pump 43 is provided at one side of the refrigerant collection pipe 25, and the pump 43 is connected to supply the low temperature liquid refrigerant collected in the refrigerant collection pipe 25 to the evaporator 5.

The operation of the loop type capacitor 19 as described above will be described.

The high temperature, high pressure gas and liquid refrigerant supplied by the compressor 1 flow into the refrigerant inflow line 21 of the capacitor 19.

Among the refrigerant flowing into the refrigerant inflow line 21, the gaseous refrigerant is injected toward the inner surface above the heat dissipation port 23 through the gas line 29, and the liquid refrigerant is discharged through the liquid line 31. 23 is directed towards the downward inner surface.

In this state, the motor 33 is driven to rotate the heat dissipation opening 19 through the gears 35 and 37. Therefore, the wide surface of the heat dissipation port 19 is cooled by the outside air.

By the rotation of the heat dissipation port 19, the gaseous refrigerant present in the heat dissipation port 23 is converted into a low temperature liquid refrigerant by the cooling action of the heat dissipation port 19.

The low-temperature liquid state refrigerant and the liquid state state refrigerant guided to the liquid line 31 are guided to the refrigerant collection groove 39 by the centrifugal force of the rotating heat dissipation port 19.

The coolant in the low temperature liquid state guided to the coolant collection groove 39 is supplied to the evaporator 5 by the action of the pump 29.

As described above, the loop-type capacitor according to the present invention constitutes a heat sink and a heat sink as one heat sink, thereby enabling reduction of the number, weight, and volume of components.

The looped capacitor according to the invention thus enables easy mounting and dismounting operations.

Claims (4)

In a loop type condenser for supplying a compressed high temperature and high pressure gas and liquid refrigerant supplied from a compressor to a low temperature liquid refrigerant to the evaporator, a) refrigerant inlet line for supplying the gas and liquid refrigerant, b) a heat dissipation port rotating by the rotating means to convert the refrigerant supplied to the refrigerant inlet line into a liquid refrigerant, c) a refrigerant collection pipe installed near the inner surface of the heat dissipation hole to collect the liquid refrigerant cooled by the heat dissipation hole, d) a pump for supplying a low temperature liquid refrigerant collected in the refrigerant collection tube to the evaporator, Loop type condenser comprising a. The method according to claim 1, wherein the a) refrigerant inlet line, e) a gas line formed toward an upper end of the heat dissipation port to supply the gaseous refrigerant to an upper side of the heat dissipation port, f) a liquid line formed to be inclined downward from the lower side of the gas line to supply the liquid refrigerant supplied to the gas line to the lower side of the heat dissipation port; Loop type condenser comprising a. The method according to claim 1, wherein b) the heat sink, g) a refrigerant collecting groove formed in the radial direction in which the collecting pipe rotates to collect the liquid refrigerant, Loop type condenser comprising a. The method of claim 1, wherein the c) refrigerant collection pipe is installed inclined upward on both sides of the refrigerant inlet line, h) a collecting hole formed at an upper end thereof so as to approach the refrigerant collecting groove of the heat sink; Loop type condenser comprising a.