KR100416368B1 - An energysaving thermohygrostat in one device and the method thereof - Google Patents

Abstract

The present invention is a computer room, precision measuring room, engine laboratory, electromagnetic plate production room, hospital delivery room, clinical laboratory, X-ray imaging room, pharmaceutical production line, etc. where the electronic equipment is very sensitive to temperature and humidity installed in the outside temperature and humidity A fully integrated energy saving constant temperature and humidity air conditioning system unit that maintains a constant temperature and humidity at all times regardless of the four components of the refrigeration unit: compressors, condensers, evaporators, hot gas reheat coils, expansion valves, and heating units. It relates to an integrated energy-saving thermo-hygrostat built in one unit, such as a humidifier that is forced to evaporate and forced to blow, and an external air compensator that maintains a constant temperature and pressure of the condensed refrigerant.

The present invention is designed to be energy-saving in accordance with the government policy, and in particular, the high temperature and high pressure hot gas heat source generated from the compressor for the refrigerator passes through the coil-type heat exchanger in the humidifier to heat the supplementary water for humidification and hot. By using the gas reheating coil to heat and dehumidify, it uses hot gas heat efficiently and checks the refrigerant circulation pressure in three stages so that the temperature of the condenser is kept constant regardless of the temperature of the outside air. It is characterized by the use of the main control inverter to control the rotation speed.

Description

An energysaving thermohygrostat in one device and the method

The present invention relates to an integrated energy saving thermo-hygrostat.

More specifically, the present invention relates to an integrated energy-saving thermo-hygrostat that does not require a separate heat source by fully utilizing a heat source of hot gas generated in a compressor for a refrigerator.

Conventional thermo-hygrostat is equipped with cooling refrigerant cycle and separate electric heater or using only part of heat source generated from compressor for freezer, and insufficient energy is operated by using electric heater and separate high temperature and high pressure gas condenser By manufacturing and installing outdoors, there was a problem in that power consumption, installation cost increase and space should be secured.

The present invention is to solve the above problems, by completely utilizing the energy required for humidification, warming, dehumidification in the constant temperature and humidity as only a heat source of high temperature and high pressure generated in the compressor so that it is not necessary to install a separate electric heater It is an object to provide an integrated energy saving thermo-hygrostat that saves energy.

In order to achieve the above object, the hot gas source of high temperature and high pressure generated in the compressor for cooling is passed through the coil heat exchanger in the humidifier before passing through the condenser to heat the supplementary water for humidification and send it to the hot gas reheat coil to heat and dehumidify it. The main control inverter that uses hot gas heat efficiently and checks the refrigerant circulation pressure in three stages to maintain the constant temperature without changing the temperature of the condenser. It is characterized by using.

1 is an external view of a thermo-hygrostat

2 is an internal configuration diagram of a thermo-hygrostat

3 is a device configuration circuit diagram

4 is a configuration diagram of the humidifier

5 is a circuit diagram of an external air compensation device.

<Description of the symbols for the main parts of the drawings>

1. Main Unit 2. Operation Control Panel

3. Pressure gauge panel 4. Indoor air supply

5. Condensed air intake 6. Condensed air suction

7. Condensed air exhaust port 8. Indoor air intake

9. Indoor air suction filter 10. Compressor

11. Condensing coil 12. Dry filter

13. Site glass 14. Liquid tube electronic valve

15. Expansion valve 16. Cooling coil

17. Hot gas reheat coil 18. Refrigerant circulation piping

19. Hot gas reheat coil solenoid 20. Hot gas bypass solenoid

21. Pressure switch 22. Main control inverter

23. Blower for condenser 24. Motor

25. Coil type heat exchanger 26. Fill water tank

27. Electropump 28. Piping pipe

29. Spray Nozzle 30. Forced Blower

31. Control electrode electrode 32. Drain pipe

33. Reverse displacement 34. Air supply blower

35. Water supply electronic valve 36. Humidifier evaporation box

37. Compressor suction strainer 38. Humidifier

39. Alarm pressure switch 40. Griddle

41. Outside air compensator

The present invention will be described in detail with reference to the drawings.

As shown in FIG. 1 of the present invention, the control panel 2 for operation and a pressure gauge panel 3 for checking the operation state with pressure are attached to the center of the front surface of the outside of the main body 1, and to the right of the room air supply port. (4) is installed and condensed air exhaust port (7), condensed air intake port (5) and condensed air intake damping wave (6) for controlling the air volume are installed on the left side, and the indoor air intake port (8) and indoor air are located at the rear The indoor air suction filter 9 for purifying the air is installed, and the operation control panel 2 has a temperature and humidity memory function so as to be automatically operated by a single operation switch.

In the main body 1, the heat generated after condensation is catastrophically assembled between the condensed air exhaust port 7 and the indoor air intake port 8 by an iron plate 40 with heat insulation so that the heat generated after condensation does not affect the indoor air. The pressure of the refrigerant condensed by the cooling coil 16 to expand and cool, the compressor 10 to compress the refrigerant, and the condensing coil 11 and the condensing coil 11 to condense the compressed high-temperature high-pressure refrigerant gas are precisely determined. Three pressure switches (21) installed for reading and a main control inverter (22) and a compressor (10) for controlling the rotation speed of the motor (24) of the condenser blower (23) to maintain a constant temperature and pressure of the condensation refrigerant. Humidifier (38) humidifying using hot gas and high temperature hot gas generated in the air and remove the moisture contained in the cooling air from the first dew point dehumidification from the cooling coil (16) using hot gas and heating is required When hot to warm Switch reheat coil (17), dry filter (12) for filtering foreign matter in refrigerant, site glass (13) for knowing the flow of refrigerant in the refrigerant pipe, and liquid pipe solenoid (14) for blocking or supplying the refrigerant. And an expansion valve 15 and a cooling coil 16 for cooling the indoor air.

Referring to the operation of the present invention, first, when cooling by lowering the indoor temperature, the indoor air outside the main body 1 introduced through the indoor air intake port 8 is purified by the indoor air intake filter 9 and the compressor for the refrigerator ( 10) is operated where the compressed high-temperature high-pressure refrigerant gas is heat exchanged with the condensation coil 11 through the coil type heat exchanger 25 and the hot gas bypass solenoid 20 and closes the hot gas reheat coil solenoid 19. The condensed coolant passes through the site glass 13 through which the dry filter 12 filters the moisture and foreign matter in the coolant so that the flow of the coolant can be seen, and through the liquid pipe electromagnetic valve 14 and the expansion valve 15, a cooling coil ( 16) cooling takes place. At this time, dew point dehumidification is performed by air cooling, and dew point dehumidified cooling air is heated and dehumidified or humidified according to a set temperature and humidity to allow room air to be constant temperature and humidity.

The refrigerant heat-exchanged with the indoor air is filtered by the compressor 10 by filtering impurities in the refrigerant by a compressor suction strainer 37 connected to the compressor.

In addition, the condensation temperature is not constant according to the outside air temperature during the year, especially during the winter and summer, as shown in FIG. , There is a difference in performance coefficient and efficiency, and the pressure in the refrigerant circulation pipe 18 is read by three pressure switches 21 by three pressure switches 21 by an external air compensation device 41 for maintaining a constant temperature and pressure of the condensed refrigerant. To the main control inverter 22, and the main control inverter 22 automatically adjusts the rotation speed of the motor 24 of the condenser blower 23 to a strong, medium, or weak air by giving a percentage operating value according to the Hz change. By condensing to a constant temperature irrespective of the temperature change, it maintains a constant temperature and pressure of the condensation refrigerant to increase the condensation efficiency.

The heat dehumidification operation opens the hot gas reheat coil solenoid 19 and closes the hot gas bypass solenoid 20 to exchange heat with the cooling coil 16 to dehumidify the dew point. Reduce the relative humidity to keep it constant at the required room humidity.

As shown in FIG. 4, the humidification operation causes the compressed refrigerant gas of the high temperature and high pressure generated by the compressor 10 to flow to the coil type heat exchanger 25 installed in the supplemental water tank 26, so that water of the supplementary water tank 26 Heat exchange, and the hot water is sprayed to the humidifier evaporation box 36 through the pipe pipe 28 and the spray nozzle 29 by the electronic pump 27 that operates by sensing the humidity of the room and to the forced blower 30 A small amount of indoor air is sucked in, and only fine particles are supplied to the room by the air supply blower 34 through the discharge pipe, and the large particles of water are supplied to the replenishment water tank 26 by the drain pipe 32 of the humidifier evaporation box 36. Transfer to. In addition, the amount of water in the replenishment water tank 26 is controlled by opening or closing the water supply electromagnetic valve 35 by the control control electrode 31 signal.

At this time, by using the hot gas of the high temperature and high pressure generated in the refrigerator compressor 10 during the operation before passing through the condensation coil 11, it is possible to completely use the required energy without using a separate electric heater to reduce power consumption. have.

In the heating operation, during operation, the compressor 10 for the refrigerator is operated and the compressed high-temperature high-pressure refrigerant gas moves through the hot gas reheat coil electromagnetic valve 19 and the cooling gas 16 by the hot gas reheat coil 17. Incoming indoor air is warmed and supplied to the room by the air supply blower 34. At this time, the hot gas bypass solenoid 20 is closed to allow the discharged refrigerant gas to flow through the hot gas reheat coil solenoid 19.

The other operation method is the same as the cooling dehumidification method and the hot gas reheat coil electromagnetic valve 19 and the hot gas bypass electromagnetic valve 20 are controlled in parallel.

In addition, the outlet gas of the hot gas reheating coil 17 has a reverse valve 33 in order to block the gas due to the reverse flow so that the normal refrigeration cycle is made.

The present invention is a fully-integrated constant temperature and humidity air conditioning system installed inside the main body of the indoor condenser that discharges heat to efficiently control the temperature of the room, that is, heating and dehumidification, by using the hot gas of the high pressure and high pressure gas from the compressor for freezing. In addition, by using the whole amount for the humidification operation, no separate heating energy is required, and there is a very useful effect of reducing maintenance cost, manufacturing cost, installation cost, and power energy.

In addition, the pressure of the refrigerant circulation pipe is read by three pressure switches, and the main control inverter has a device to control the motor rotation speed of the condenser blower so that the refrigerant can be condensed efficiently. In this case, the refrigerant gas is less condensed at a high temperature during summer, thereby preventing the gas from remaining in the refrigerant, thereby completely liquefying the refrigerant, thereby effectively cooling the refrigerant during expansion.

During humidification operation, hot water generated by heat exchange between the high-pressure and high-pressure compressed refrigerant gas before passing through the condensation coil and the water in the replenishment water tank is sprayed to the humidifier evaporation box by using an electronic pump and a spray nozzle, and the air is blown out by the air supply blower through the discharge pipe. Since it does not need a separate electric reheat heater, it reduces power consumption and maximizes humidification efficiency.

Claims (6)

Refrigerant expander, compressor, condenser and humidifier are installed inside the main body. Humidification, dehumidification, and heating are performed by using energy from the compressor. Selective opening and closing of hot gas reheat coil and hot gas bypass electric valve connected in parallel In the thermo-hygrostat controlled by the compressor, the refrigerant gas of the high temperature and high pressure from the compressor 10 passes directly through the coil-type heat exchanger 25 of the humidifier 38, and then the cooling air from the cooling coil 16 The refrigerant condensed by the condensation coil 11 is condensed by entering the condensation coil 11 through the hot gas reheat coil 17 or through the hot gas reheat coil 17 so as to be dehumidified or heated. Integrated energy-saving thermo-hygrostat device, characterized in that consisting of an external air compensation device (41) for controlling to maintain a constant temperature and pressure. According to claim 1, wherein the outside air compensation device 41 is for the condenser according to the pressure divided into three pressure switches 21 for reading the pressure of the refrigerant circulation pipe 18, and three steps read from the pressure switch 21 An integrated energy-saving thermo-hygrostat device, comprising: a main control inverter (22) for controlling the amount of air flow by controlling the rotation speed of the motor (24) of the blower (23). A refrigerant expander, compressor, condenser, and humidifier are installed inside the main body, and humidification, dehumidification, and heating are performed using energy from the compressor, and the selective opening and closing of the hot gas reheat coil electromagnetic valve and the hot gas bypass electric valve connected in parallel In the constant temperature / humidity method of controlling by heating, the hot gas reheating coil after heating the high temperature and high pressure refrigerant gas from the compressor 10 directly to the coil type heat exchanger 25 of the humidifier 38 to heat the water for humidification ( 17) to heat and dehumidify or warm the cooling air from the cooling coil 16 to the condensing coil 11 or to the condensing coil 11 without passing through the hot gas reheat coil 17 to condense. , Energy-saving constant temperature and humidity method characterized in that to maintain a constant temperature and pressure of the refrigerant condensed by the air compensation device (41). The refrigerant condensation by the external air compensator 41 reads the pressure in the refrigerant circulation pipe 18 by three pressure switches 21 and transfers the pressure into the main control inverter 22 in three stages. The control inverter 22 automatically adjusts the rotation speed of the motor 24 of the condenser blower 23 to a percentage operating value according to a Hz change, and automatically adjusts it to strong, medium, or weak to maintain a constant temperature and pressure regardless of the change in the outside air temperature. Integrated constant temperature energy saving constant temperature and humidity method characterized in that. delete delete