KR20020046345A - Evaporative condensing unit - Google Patents

Abstract

PURPOSE: An evaporative integral condensing unit is provided to improve cooling efficiency and to reduce power consumption. CONSTITUTION: A condenser comprises a casing(49); an exhaust fan(41) installed on a ceiling of the casing; a water drop removing plate(42) installed under the exhaust fan to prevent discharge of water drop by the exhaust fan; a sprinkler(43) installed under the water drop removing plate to spray water downward; a refrigerant coil(47) installed under the sprinkler and having one end, fluidically connected with a side of the casing for high-temperature high-pressure refrigerant gas, compressed in a refrigerant compressor(10) to flow in, and the other end through which low-temperature high-pressure refrigerant fluid is discharged; a water tank(44) installed under the refrigerant coil; a supplementary water supply device(48) installed on the water tank; and a coolant circulation device(45) circulating coolant by connecting the sprinkler and the water tank.

Description

Evaporative condensing unit

The present invention relates to a condensing unit, and more particularly, to an evaporative integrated condensing unit including an evaporative condenser using the heat of evaporation of air.

Condensing unit is a device used in refrigeration or freezing equipment. Compresses the refrigerant changed into a low temperature and low pressure gas state through the evaporator to make a refrigerant gas of high temperature and high pressure, and then condenses it into a refrigerant liquid of low temperature and high pressure in the condenser and sends it back to the evaporator. Device.

In general, the condensing unit is an integrated unit composed of a refrigerant compressor 10, an oil separator 12, a condenser, a receiver 27, a filter dryer 29 and the like. Here, the refrigerant compressor 10 is a device for making the refrigerant gas of low temperature and low pressure at a high temperature and high pressure, and the oil separator 12 is a device that separates the oil mixed in the refrigerant gas. The receiver 27 is a device for storing the refrigerant liquid converted from the condenser to the liquid, and the filter dry 29 filters the impurities in the refrigerant liquid and removes moisture. The condenser is a device for making a refrigerant gas compressed at high temperature and high pressure from the refrigerant compressor 10 to a refrigerant of low temperature and high pressure. The condenser is a water-cooled condenser 30 and an air-cooled condenser according to a method of converting a refrigerant gas of high temperature into a refrigerant of low temperature. 20). The water-cooled condenser 30 converts the refrigerant gas into the refrigerant liquid by heat exchange with the cooling water flowing around the refrigerant coil in which the refrigerant is circulated, and the air-cooled condenser 20 forcibly vents the outside air to the outside of the refrigerant coil. The refrigerant gas is converted into the refrigerant liquid by heat exchange with.

With reference to the accompanying Figures 1 and 2 will be described the operation of the conventional air-cooled and water-cooled condensing unit.

First, referring to the air-cooled condensing unit, the low-temperature low-pressure refrigerant gas enters the inlet pipe 1 from the evaporator (not shown) and passes through the compressor 10. The refrigerant gas passing through the compressor 10 becomes a refrigerant gas of high temperature and high pressure and is introduced into the condenser 20. In addition, it is common to pass the oil separator 12 for separating the oil component contained in the refrigerant gas before the refrigerant gas from the compressor 10 is introduced into the condenser 20. The high temperature and high pressure refrigerant gas introduced into the condenser 20 undergoes heat exchange with external air passing through the refrigerant coil while passing through the refrigerant coil, and the refrigerant gas becomes a liquid state, and the cold external air absorbs the heat of the high temperature refrigerant. It becomes hot air and is discharged to the outside. Here, the outside air is forcibly blown into the refrigerant coil by the blower (22). The refrigerant liquid converted into the liquid of low temperature and high pressure in the condenser 20 is stored in the receiver 27 and discharged through the discharge pipe 3 to the evaporator (not shown) through the filter dryer 29.

In addition, when the operation of the water-cooled condensing unit is explained, it is the air-cooled type described above that the low-temperature low-pressure refrigerant gas is introduced into the inlet pipe (1), and the low-pressure high-pressure refrigerant liquid through the condenser 30 to exit the discharge pipe (3) Same as the condensing unit. However, the heat exchange methods in the condenser 30 are different from each other. That is, the refrigerant gas in the water-cooled type is converted into the refrigerant liquid by exchanging heat with the circulating cooling water around the refrigerant coil, and the cooling water absorbing the high temperature of the refrigerant gas is circulated to the cooling tower (not shown) to exchange with external air. The heat absorbed by the heat exchanger is released, cooled to the original temperature, and circulated back to the condenser 30. Here, reference numerals which are not described here are the coolant inlet pipe 32 and the coolant discharge pipe 31 which form an inlet and an outlet of the coolant supplied to the water-cooled condenser.

However, such a conventional condensing unit has a problem that the cooling efficiency is low, the power consumption is very large. In particular, in the case of a water-cooled condensing unit, a cooling water circulation pump, a cooling tower, and related auxiliary equipment are required, and thus, the apparatus cost is high and power consumption is further increased.

The present invention has been made to improve the above problems, the cooling efficiency is high, the power consumption is less than the conventional condensing unit, in particular, to provide an evaporative integrated condensing unit that does not require additional equipment such as cooling towers. There is this.

1 is a system diagram of an air-cooled condensing unit according to the prior art,

2 is a system diagram of a water-cooled condensing unit according to the prior art,

3 is a system diagram of an evaporative integrated condensing unit according to the present invention;

Figure 4 is a schematic view showing the arrangement of each component of the evaporative integrated condensing unit according to the present invention.

* Description of the symbols for the main parts of the drawings *

10; Compressor 12; Oil separator

20; Air cooled condenser 30; Water cooled condenser

40; Evaporative condenser 41; Exhaust fan

42; Droplet removal plate 43; Sprinkler

45; Cooling water circulator 47; Refrigerant Coil

48; Make-up water supply 49; Casing

Evaporative integrated condensing unit according to the present invention for achieving the above object, a refrigerant compressor for compressing the expanded refrigerant gas, an oil separator for separating the oil contained in the compressed refrigerant gas, refrigerant gas as a liquid And a condenser and a receiver for condensing, the condenser comprising: a casing; An exhaust fan installed on the ceiling of the casing; A drop plate installed below the exhaust fan to prevent water droplets from being discharged by the exhaust fan; A watering device installed at a lower portion of the water drop removing plate and spraying water downward; A cooling coil installed at a lower portion of the sprinkler and communicating with the side of the casing with one end of a high temperature and high pressure refrigerant gas compressed by the refrigerant compressor; A water tank installed at a lower end of the cooling coil; Replenishment water supply means installed at an upper side of the reservoir; And a cooling water circulation device connecting the watering device and the reservoir to circulate the cooling water.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention. However, the same parts as in the prior art will be described using the same symbols.

3 is a schematic diagram of an evaporative integrated condensing unit according to the present invention to which an evaporative condenser is applied, and FIG. 4 is a schematic view showing the arrangement of each component in an embodiment of the evaporative integrated condensing unit.

As shown in the figure, the evaporative integrated condensing unit according to the present invention includes a refrigerant compressor 10, an oil separator 12, an evaporative condenser 40, a receiver 27, a filter dryer 29, and the like. Unit. Here, the refrigerant compressor 10 is a device for making the refrigerant gas of low temperature and low pressure at a high temperature and high pressure, and the oil separator 12 is a device that separates the oil mixed in the refrigerant gas. The receiver 27 is a device that temporarily stores the refrigerant converted into the liquid in the condenser 40, and then discharges the refrigerant to the evaporator (not shown) through the discharge pipe 3, the filter dry 29 is through the discharge pipe (3) It functions to filter out impurities and remove moisture from the refrigerant liquid discharged to the evaporator. The above apparatus is the same as the components of a conventional air-cooled condensing unit or a water-cooled condensing unit, except that only the kind of condenser used is different.

The condenser 40 is a device for making a refrigerant gas compressed at a high temperature and high pressure in the refrigerant compressor 10 into a low temperature high pressure refrigerant liquid. The evaporative condenser 40 according to the present invention includes a casing 49 and an exhaust fan ( 41, a water droplet removing plate 42, a watering device 43, a refrigerant coil 47, a water storage tank 44, a supplemental water supply means 48 and a cooling water circulation device 45.

Exhaust fan 41 is installed on the ceiling of the casing 49, the external air is introduced through the air inlet (41a) provided in the lower portion of the casing 49 to be discharged through the refrigerant coil 47 to evaporate the coolant Helps to facilitate this.

The water droplet removing plate 42 is installed on the lower side of the exhaust fan 41 so as to block the front end surface of the casing 49, and the cooling water that comes out toward the exhaust fan along with the suction air sucked by the exhaust fan 41. It is a device to remove water droplets.

In addition, the sprinkling apparatus 43 is a pipe 46 which is installed in the lower portion of the water droplet removing plate 42 and is provided with a plurality of injection nozzles for spraying coolant to the refrigerant coil 47 installed in the downward direction. One end is connected to the circulation pump of the cooling water circulation device 45 so that the cooling water contained in the reservoir 44 can be continuously sprayed. Here, the reservoir 44 is installed at the bottom of the casing 49, which is the lower side of the refrigerant coil 47, and is a container in which cooling water injected from the water sprinkling apparatus 43 falls through the refrigerant coil 47 and is contained therein. It has the capacity to hold the coolant. If the coolant in the reservoir 44 is less than the set amount, the supplementary water supply means 48 installed at one end of the reservoir 44 is operated to fill the coolant to the set amount.

The refrigerant coil 47 is installed in a space between the watering device 43 and the water storage tank 44, and the refrigerant having a high temperature and high pressure compressed by the refrigerant compressor 10 is connected to one side of the casing 49. The gas is drawn in, and the other end is provided so that the coolant liquid of low temperature and high pressure is discharged to the receiver 27.

The operation of the evaporative integrated condensing unit having the above configuration will be described.

By the heat exchange with the hot air in the evaporator, the refrigerant in a gaseous state at low temperature and low pressure is introduced into the compressor 10 through the inlet pipe 1. The compressor 10 compresses the introduced low temperature low pressure refrigerant gas and converts the refrigerant gas into high temperature high pressure refrigerant. The type of compressor 10 used at this time is various, such as a single stage / two stage compressor, hermetic / semi-sealed / open type / screw type. The compressed high-temperature high-pressure refrigerant gas is introduced into the condenser 40 in a state where oil is removed through the oil separator 12. The high temperature and high pressure refrigerant gas introduced into the condenser 40 is discharged to the receiver 27 as a refrigerant liquid of low temperature and high pressure by latent heat of evaporation by cooling water and suction air. That is, the condenser 40 sprays the coolant to the outside of the refrigerant coil 47 while the high temperature and high pressure refrigerant gas compressed by the refrigerant compressor 10 is circulated through the refrigerant coil 47 of the condenser 40. The external air is passed from the lower portion of the refrigerant coil 47 to the upper portion of the refrigerant coil 47 in a manner of being sprayed by the spray nozzle of the nozzle and forcedly sucked by the exhaust fan 41. The high temperature and high pressure refrigerant gas flowing through the inside of the refrigerant coil 47 is condensed into the low temperature and high pressure refrigerant liquid by using the latent heat of evaporation of the cooling water in contact with 47). In addition, the sprinkling device 43 has a pipe shape and the cooling water is continuously supplied by the circulation pump of the cooling water circulating device 45 connected to one end to the upper portion of the refrigerant coil 47 through a plurality of sprinkling nozzles installed at the other end. Cooling water will be sprayed. This sprinkled coolant is sprinkled to the upper portion of the refrigerant coil 47 through a plurality of sprinkling nozzles, and at the same time, a part of the coolant is introduced into the external air introduced through the air intake port 41a on the side of the reservoir 44 by the exhaust fan 41. Heavy droplet particles are caught by the droplet removal plate 42 provided at the bottom of the exhaust fan 41 in the evaporation process and fall into the reservoir 44, and some of the cooling water removes droplets in the form of fine moisture particles. It passes through the plate 42 and evaporates into the outside air. As a result, when the amount of cooling water contained in the reservoir 44 is reduced, the supplemental water supply means 48 is operated to fill the amount of cooling water to a predetermined value.

The refrigerant converted from the condenser 40 to the refrigerant liquid of low temperature and high pressure is temporarily stored in the receiver 27, and then discharged to the evaporator through the discharge pipe 3 through the filter and the dry 29.

The advantages obtained when the above-described evaporative condenser 40 is used in the condensing unit are as follows when compared to the case of the integrated condensing unit using the conventional air-cooled condenser 20 and the water-cooled condenser 30.

First, compared with the air-cooled condenser 20, the capacity of the air-cooled condenser 20 is calculated based on the dry bulb temperature of the outside air, the capacity of the evaporative condenser 40 is calculated on the basis of the wet bulb temperature of the outside air. However, since the wet bulb temperature is about 8 to 12 degrees Celsius lower than the dry bulb temperature, when the evaporative condenser 40 is used, the condensation temperature can be lowered by about 8 to 12 degrees Celsius, and thus the power consumption of the system including the compressor 10 is 20 to 20 degrees Celsius. You can save about 30%. Table 1 below is a table showing the operating efficiency of the air-cooled 20 and the evaporative condenser 40 when the evaporation temperature of the compressor 10 is -10 degrees, the refrigerant R22. Here, the coefficient of performance is the value obtained by dividing the freezer capacity (KW) by the power consumption (KW).

division Freezing capacity Power consumption Coefficient of performance percentage Air-cooled (condensation temperature + 45 degrees) 84.3KW 30.2KW 2.79 100% Evaporation type (condensation temperature +35 degrees) 97.5KW 27.6KW 3.53 126%

In addition, compared to the water-cooled condenser 30, the water-cooled condenser 30 is discharged first to the cooling water supplied to the water-cooled condenser 30 and then to the atmosphere by using a cooling tower (cooling tower) while the evaporative The condenser 40 discharges the heat of condensation into the atmosphere at one time. Therefore, the evaporative condenser 40 does not require a circulation pump, a cooling tower, and related auxiliary equipment of the cooling water circulator 45 required by the water-cooled condenser 30, and reduces the power consumption of the compressor 10 because the condensation temperature is lower than that of the water-cooled condenser. The efficiency of the system can be improved by up to 15%. Table 2 is a table showing the operating efficiency of the water-cooled and evaporative condenser when the evaporation temperature of the compressor 10 is -10 degrees, refrigerant R22. Here, the coefficient of performance refers to a value obtained by dividing the refrigerator capacity (KW) by the power consumption (KW), and in the case of water cooling, power of the cooling water pump and the cooling tower is additionally consumed.

division Freezing capacity Power consumption Coefficient of performance percentage Water-cooled (condensation temperature + 40 degrees) 90.9KW 29.0KW 3.13 100% Evaporation type (condensation temperature +35 degrees) 97.5KW 27.6KW 3.53 113%

As described above, according to the present invention, it is possible to provide an evaporative integrated condensing unit which has high cooling efficiency, less power consumption than conventional air-cooled or water-cooled condensing units, and does not require additional equipment such as a cooling tower. do.

Although the preferred embodiments of the present invention have been illustrated and described above, the present invention is not limited to the above-described specific preferred embodiments, and the present invention belongs without departing from the gist of the present invention as claimed in the following claims. Those skilled in the art will be able to implement various modifications.

Claims (1)

In the integrated condensing unit comprising a refrigerant compressor for compressing the expanded refrigerant gas, an oil separator for separating the oil contained in the compressed refrigerant gas, a condenser and a receiver for condensing the refrigerant gas into a liquid, The condenser, casing; An exhaust fan installed at the ceiling of the casing; A droplet removal plate installed under the exhaust fan and preventing water from being discharged by the exhaust fan; A watering device installed at a lower portion of the water drop removing plate and spraying water downward; A refrigerant coil installed at a lower portion of the sprinkler and communicating with the side of the casing, at one end of a high temperature and high pressure refrigerant gas compressed by the refrigerant compressor, and a second end of a refrigerant coil at a low temperature and high pressure; A water reservoir installed at a lower end of the refrigerant coil; Replenishment water supply means installed at an upper side of the reservoir; And a cooling water circulation device connecting the watering device and the water storage tank to circulate the cooling water.