KR200158049Y1 - Screw compression cooling device - Google Patents

Abstract

The present invention provides a screw compression chiller capable of operating and operating status at a point away from the chiller, and the screw compression chiller is equipped with a coolant and a cold water circulation detector and a coolant temperature detector to monitor these sensors remotely. It is a cooling device that can easily grasp the operation and operation state of the cooling device from a long distance by electrically connecting it to the.

Description

Screw compression chiller

1 is a schematic diagram of a conventional screw compression cooling apparatus.

2 is a schematic configuration diagram of a screw compression cooling device of the present invention.

3 is a wiring diagram of an operation preparation circuit of a screw compression cooling apparatus according to an embodiment of the present invention.

Figure 4 is a flow chart showing the operation sequence of the screw compression cooling apparatus according to the practice of the present invention.

Figure 5 is a schematic diagram showing an embodiment of the coolant circulation detector of the present invention.

6 is a schematic view showing an embodiment of the coolant temperature sensor of the present invention.

* Explanation of symbols for main parts of the drawings

2: control box 10: screw compressor

20: condenser 30: cooling tower

34: coolant pump 40: evaporator

50: fan coil unit 56: cold water pump

60: coolant temperature detector 70: coolant circulation detector

80: cold water circulation detector

The present invention relates to an improvement of a screw compression chiller, and more specifically, to provide a cold water circulation detector, a coolant circulation detector, and a coolant temperature change detector, which can be operated at a point away from the chiller and can understand the operating situation. It relates to a cooling device.

The screw compression chiller is used in a cooling chamber, a constant temperature and humidity chamber, a low humidity chamber, a process cooler in a factory, a heat storage cooler, etc., and this conventional screw compression chiller is shown in FIG.

As shown in FIG. 1, the conventional screw compression cooling apparatus includes a screw compressor 10, a condenser 20, a cooling tower 30, an evaporator 40, and a fan coil unit 50 (FCU).

The screw compressor 10 compresses the gas by the rotation of the positive rotor and the negative rotor, which is a control box 2 for supplying and cutting off power, a condenser 20 for liquefying refrigerant gas, and heat of refrigerant and heat of cold water. Is connected to the evaporator 40 which lowers the temperature of the cold water. The low pressure gauge 12, the high pressure gauge 14, and the high and low pressure switch 16 are connected between the compressor 10 and the evaporator 40. The high and low pressure switch 16 is provided between the low pressure gauge 12 and the high pressure gauge 14. The high and low pressure switch 16 is also connected to a conduit 18 connecting the compressor 10 and the condenser 20.

The condenser 20 is connected to the cooling tower 30 via conduits 22 and 32. Cooling water for cooling the condenser 20 circulates through the conduits 22 and 32. In the middle of the conduit 32 a coolant pump 34 is provided to assist in the circulation of the coolant. The condenser 20 is also connected to the evaporator 40 via a conduit 48 for refrigerant. In the middle of the conduit 48 is a filter drier 42, a sight glass 44, and an expansion valve 46.

The evaporator 40 is connected to the screw compressor 10 via a conduit 11 for refrigerant. The evaporator 40 is also connected to the two fan coil units 50 via the cold water conduits 52, 54, respectively.

Hereinafter, the operation of the conventional screw cooling device configured as described above will be described.

Referring to FIG. 1, the refrigerant gas compressed at high pressure by the screw compressor 10 is delivered to the condenser 20 through the conduit 18. The refrigerant delivered in a compressed state is compressed in the condenser 20 and liquefied. At this time, the heat generated during the liquefaction of the refrigerant is absorbed by the cooling water flowing from the conduit (32). The heat-absorbing cooling water is discharged to the cooling tower 30 through the conduit 22.

The refrigerant liquefied in the condenser 20 is supplied to the evaporator 40 through the conduit 48. Here, the refrigerant is expanded and vaporized and supplied to the compressor 10 through the conduit 11 again. By absorbing heat from the surrounding cold water during expansion and evaporation of the refrigerant in the evaporator 40, the cold water is supplied to each fan coil unit 50 via the conduit 52 in the cooled state. The supplied cold water is again fed to the evaporator via conduit 54.

In the above-described conventional screw cooling apparatus, there is a disadvantage that can not be immediately confirmed when the failure of the pumps 34, 56.

For example, the coolant is circulated through the conduits 22 and 34 and the condenser 20 and the cooling tower 30. However, if the coolant pump 34 fails, the coolant does not flow into the condenser 20 so that the condenser Since the heat generated at the time of vaporization of the refrigerant cannot be absorbed at (20), the function of the condenser is drastically lowered, and the cooling efficiency of the entire cooling device is significantly reduced. In addition, the temperature of the coolant is greatly influenced by the ambient temperature and humidity, but this cannot be controlled.

In addition, the coolant cools the cold water while expanding and evaporating it in the evaporator 40, and the cold water is supplied to each fan coil unit 50 through the cold water pump 56. At this time, if a failure occurs in the cold water pump 56, the refrigerant is supplied to the screw compressor 10 through the evaporator 40 in the no-load state. Therefore, in the compressor 10, the compressor 10 is often damaged by wet compression or liquid compression.

In other words, when a problem occurs in the supply of cooling water, temperature control, and supply of cold water, this directly affects the screw compressor 10, resulting in various troubles in the compressor 10 and a decrease in efficiency.

Therefore, an object of the present invention is to solve the problems of the conventional screw compression cooling apparatus.

In order to achieve the above object, the present invention is characterized by providing a cooling water and cold water circulation detector to the cooling water and cold water conduit, and also to provide a screw compression cooling device electrically connecting these devices to a separate remote operation monitoring device. .

A coolant temperature sensor is also provided in the coolant conduit, which is electrically connected to the remote operation monitoring device.

Therefore, according to the present invention, since the circulation of the cooling water and the cold water can be easily confirmed at a long distance, when an abnormality occurs in the circulation of the cooling water and the cold water, there is an advantage of identifying the cause and immediately coping with it.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the present invention, the same reference numerals are given to the same components as those of the conventional screw compression cooling apparatus shown in FIG. 1, and the description thereof will be omitted.

Referring to FIG. 2, the screw compression cooling apparatus according to an embodiment of the present invention provides a coolant temperature sensor 60 and a coolant circulation detector 70 to a coolant supply conduit 32, and a cold water discharge conduit 52. A cold water circulation detector 80 is provided. And these components are electrically connected to the remote operation monitoring device 100 via the control box (2). The cooling water pump 34 and the cooling water pump 56 are also electrically connected to the remote operation monitoring apparatus 100 through the control box 2.

The remote operation monitoring device 100 is provided with various lamps, a cooling device operation start push button, and a cooling device operation stop push button.

The operation preparation of the cooling device will be described with reference to FIGS. 3 and 4. When the operator turns on the operation start pushbutton switch SW (step S1), the cold water pump relay RY ₁ is activated so that the relay switch S _R1 is turned on so that the cold water pump 56 operates (step S2). The cold water pump lamp L ₁ on the apparatus 100 is turned on to check whether there is an abnormality of the cold water pump 56 (step S3). Then, while the coolant pump 34 operates (step S4), the coolant pump relay RY ₂ is operated to turn on the relay switch S _R2 , so that the coolant pump lamp L ₂ on the monitoring device 100 is turned on and the coolant is switched on. The abnormality of the pump 34 is checked (step S5). Thereafter, while the cooling tower 30 is operated (step S6), the cooling tower fan relay RY _F is operated so that the relay switch RY _F is turned on so that the cooling tower lamp L _F on the monitoring device 100 is turned on. The signal is transmitted to the main panel so that the main switch SW _M is turned on. This completes the preparation for operation of the cooling device of step S ₇ .

According to the present invention, the operation of the cold water pump 56, the cooling water pump 34 and the cooling tower 30 can be easily detected by the remote operation monitoring apparatus 100 while the compressor 10 is operated. . Therefore, it is possible to confirm in advance the operating state of the accessory device before the compressor 10 is operated.

When the preparation for the operation of the cooling device is completed, the screw compressor 10 is operated and the compressor lamp on the monitoring device is turned on. The compressor 10 serves to compress the refrigerant gas sucked from the evaporator 40 through suction, extrusion and discharge operations.

The refrigerant passing through the compressor 10 condenses in the condenser 20 to exchange heat with the cooling water introduced from the conduit 32. This is because the heat of condensation is generated when the gas condenses, and this heat is absorbed by the cooling water. The cooling water dissipates heat of condensation in the cooling tower 30 and is supplied to the condenser 20 by the pump 34. And some of the refrigerant from the compressor 10 passes through the high pressure gauge 14, the pressure is displayed on the instrument.

The refrigerant completely liquefied in the condenser 20 is supplied to the evaporator 40 through the filter drier 42, the inspection window 44 and the expansion valve 46. The filter drier 42 removes moisture from the refrigerant passing therethrough, thereby preventing the efficiency of the refrigerant from decreasing. In addition, the operator can visually check the refrigerant passing through the inspection window (44). When the refrigerant passes through the expansion valve 46, the pressure and the temperature decrease rapidly to vaporize. At this time, the refrigerant is in a saturation state where the liquid and the gas coexist, and heat exchange with the cold water while passing through the evaporator 40 to repeat the vaporization action. The cold water is thereby quenched.

The cooled cold water is delivered to the fan coil unit 50 through the conduit 52 by the cold water pump 56. Cold water in the fan coil unit 50 discharges the cold air to the outside, and is supplied to the evaporator 40 again.

The refrigerant discharged from the evaporator 40 is almost vaporized, and a portion of the refrigerant passes through the low pressure gauge 12, and the pressure is displayed on the instrument. The high and low pressure switch 16 may maintain the pressure balance manually or automatically with reference to the pressure of the high pressure gauge 14 and the pressure of the low pressure gauge 12 described above.

5 shows a coolant circulation detector 70. The detector 70 is a female threaded portion 72 welded to a hole formed in one side of the conduit 32, a screwed portion of the female threaded portion 72, and a flexible portion 75 provided at the upper end thereof. A screw portion 74, a movable contact portion 82 is attached to one end, and a wing portion 76 is attached to the other end, and a lever 78 passing through the flexible gear portion 75 of the male screw portion 74. ), A fixed contact portion 83 in a position capable of contacting the movable contact portion 82 at one end of the lever 78, and providing the elastic force in the flow direction of the coolant to the lever 78 A spring 84 is provided.

Referring to FIG. 5, when the coolant is flowing, the coolant pressurizes the blade 76, and the movable contact 82 is moved from the fixed contact 83 by the movement of the blade 76. FIG. Contact. This contact state is a normal operation state. On the contrary, when the coolant is not flowing, the contact parts 82 and 83 may fall to detect an abnormality of the coolant pump 34. For reference, since the structure of the cold water circulation detector 80 is also the same as the cooling water detector 70 described above, its illustration and description will be omitted.

6 shows the coolant temperature sensor 60 in detail. The detector 60 is welded to a hole formed in a portion of the conduit 32 and has a female thread portion 33 and a male thread portion formed therein and a threaded thread formed therein, and is sealed with the female thread portion 33. A male thread portion 61, a sensor 62 projecting from the center of the male thread portion 61 into the conduit 32, a movable portion 65, and a capillary tube 64 connecting the male thread portion 61 and the movable portion 65. ), A set temperature controller 67 which is elastically supported by the spring 66 on the movable part 65, and a lever 68 which is moved up and down by the spring 66 and has a contact 69 attached to one end thereof. ). The cooling water temperature detector 60 shown in FIG. 6 serves to maintain the cooling water at an appropriate temperature by adjusting the fan of the cooling tower 30. The gas inside the sensor unit 62 contracts or expands according to the temperature to control the fan motor of the cooling tower 30 by turning the contact 69 on and off.

According to the embodiment according to the present invention, the compression, expansion process of the refrigerant can be surely maximized to maximize the cooling efficiency, the operation of the compressor by checking the operation of the cold water, cooling water pump in advance before the compressor operates Can be prevented.

In addition, since each component is electrically connected to a remote operation monitoring device, each operation state can be easily checked at a long distance.

Claims (1)

The condenser 20 connected to the screw compressor 10, the condenser 20 connected to the screw compressor 10, the cooling tower 30, and the condenser 20 connected to the condenser 20 via the cooling water conduits 22 and 32. 20) and a chiller having an evaporator 40 connected to the screw compressor 10 and a fan coil unit 50 connected to the evaporator 40 via cold water conduits 52 and 54. In the, comprising a means for checking the operating state, and a remote operation monitoring device 100 is electrically connected to the cooling tower 30 consisting of a cooling device operation start push button and the cooling device operation stop push button, the coolant The coolant temperature detector 60, the coolant circulation detector 70, and the coolant pump 34 installed in the conduit 32 are electrically connected to the remote operation monitoring device 100, and the cold water conduits 52, 54. Cold water pump 56 installed in any one of the other cold water conduit Cold water circulation sensor (80) installed in the screw compression cooling device, characterized in that configured to be electrically connected to the remote operation monitoring device (100).