KR20100037772A - Drying system using heat pump - Google Patents

Abstract

PURPOSE: A dry system using a heat pump is provided to perform dehumidifying effect by discharging condensation to outside through an outlet. CONSTITUTION: A dry system using a heat pump comprises a drying room(10), a heat pump, a radiating part, an endothermic part(31), and ducts. The drying room dries materials using heat source. The heat pump is installed outside the drying room. The heat pump comprises a compressor(21), a condenser(22), an expansion valve(23), an evaporator(24) and a closed loop. The duct interlinks the radiating part, the endothermic part, and the drying room.

Description

Drying system using heat pump {DRYING SYSTEM USING HEAT PUMP}

The present invention relates to a drying system using a heat pump, and more particularly, using a heat pump without directly discharging the high-temperature wet steam generated in the dryer when drying the product containing moisture in the high temperature dryer. The present invention relates to a drying system using a heat pump that is circulated into a dryer by a heat exchange method and reused.

In general, a variety of methods are used to dry a product, which can be divided into natural drying and artificial drying depending on the presence or absence of a heat source, and the artificial drying method is spray drying using hot air, steam, electricity, heating medium, conveyor, etc. The method, cabinet method, rotation method, steam tube method, microwave method, ultrasonic method and the like are used. These methods are used to select the appropriate method according to the type and characteristics of the product to be dried.

In general dryers, a high temperature drying method is mainly used. The internal air is heated to a high temperature by heat supplied to the dryer chamber, and the heated air is in contact with the product to be dried, causing heat exchange to obtain energy by evaporating moisture contained in the product. Thereby mixing with the air in the chamber, the hot wet steam mixed with the air is discharged through the outlet of the chamber. The conventional drying method by hot air is not efficient because high temperature wet steam is immediately discharged out of the chamber when discharging the wet steam, resulting in a large amount of heat loss, thereby increasing fuel costs and eventually leading to a cost increase of the product. There is a problem that reduces the competitiveness of the.

The present invention has been made to solve the above problems, an object of the present invention, the heat pump without hot water vapor generated in the dryer when drying the product containing the moisture in the dryer immediately out of the dryer It is to provide a drying system using a heat pump that can reduce the fuel cost by improving the heat efficiency by reducing the heat loss by circulating into the dryer by the heat exchange method using.

Drying system using a heat pump according to the present invention for solving the above problems, the drying chamber receiving a heat source to dry the dry matter; A heat pump installed outside the drying chamber and configured in a closed circuit by connecting a compressor, a condenser, an expansion valve, and an evaporator in series; A heat dissipation unit and a heat absorbing unit respectively installed corresponding to the evaporator and the condenser of the heat pump; And a duct connecting the heat dissipation unit and the heat absorbing unit to the drying chamber, respectively.

Preferably, the duct connected to each inlet side of the heat dissipating unit and the heat absorbing unit is further provided with a fan for introducing steam from the drying chamber, respectively, the inlet of the heat dissipating unit and the drying chamber are connected by a first duct, The outlet and the drying chamber are connected by a fourth duct, the outlet and the drying chamber of the heat dissipation portion are connected by the second duct, and the inlet and the drying chamber of the heat absorbing portion are installed by the third duct.

In the drying system using the heat pump according to the present invention having the characteristics as described above, the thermal efficiency is improved by reusing the high-temperature wet steam generated when drying the dried object in the drying chamber immediately without leaving the drying chamber. In addition, the fuel cost is reduced and economical, and the condensate generated from the radiator and the evaporator is discharged to the outside through the discharge pipe, so that there is a dehumidification effect, and the heat generated in the drying chamber can be continuously used, thereby reducing the fuel cost and economical.

An embodiment of a drying system using a heat pump according to the present invention will be described with reference to FIG. 1.

The drying system using the heat pump includes a drying chamber 10 for drying a dry object by receiving a heat source; A heat pump 20 installed outside the drying chamber and configured to connect a compressor 21, a condenser 22, an expansion valve 23, and an evaporator 24 in series to form a closed circuit; A heat dissipation unit 30 and a heat absorbing unit 31 corresponding to the evaporator and the condenser of the heat pump, respectively; It comprises a duct connecting the heat dissipation unit and the heat absorbing unit and the drying chamber 10, respectively.

Fans 44 and 45 for introducing steam from the drying chamber 10 are further provided in the first and third ducts 40 and 42 connected to the inlet sides of the heat dissipation unit 30 and the heat absorbing unit 31, respectively. The damper (opening and closing) is provided at a drying chamber side end portion of the first duct 40 and the fourth duct 43 connecting the heat dissipation part 30, the heat absorbing part 31, and the drying chamber 10. It is preferable to install the dampers 72 and 73 which are provided with 70, 71 and also open and close at the drying chamber side ends of the second duct 41 and the third duct 42, and the first duct 40 and The end of the fourth duct 43 is provided at the inlet side of the drying chamber, and the end portions of the second duct 41 and the third duct 42 are provided at the outlet side of the drying chamber.

The compressor 21 constituting the heat pump 20 increases the pressure by applying energy to the gas refrigerant, and the high pressure refrigerant from the compressor 21 is converted into a high pressure liquid refrigerant by phase conversion in the condenser 22. After dissipating heat to the outside, it is converted into a low pressure liquid state in the expansion valve 23 to reach the evaporator 24, the evaporator 24 absorbs heat from the outside (heat source) and is converted into a low pressure gas state A circulation process of moving back to the compressor 21 is continuously performed, and refrigerant is injected into the pipe 50 constituting the closed circuit.

If the heat source 60 is supplied to the drying chamber after arranging the dry matter in the drying chamber 10, the internal temperature of the drying chamber 10 is increased to dry the dried object containing moisture, thereby heating the drying chamber 10. It meets with the air which has been formed to produce high temperature wet steam. The high temperature wet steam is introduced into the heat dissipation unit 30 by the fan 44 installed at the inlet side of the heat dissipator 30. The heat dissipation unit 30 is installed in the first chamber 80 together with the evaporator 24, and an inlet of the heat dissipation unit 30 is connected to the drying chamber 10 by the first duct 40. The outlet of the part 30 is connected to the drying chamber 10 by the second duct 41. In addition, the inlet of the heat absorbing portion 31 and the drying chamber 10 are connected by the third duct 42, and the outlet of the heat absorbing portion 31 and the drying chamber 10 are connected by the fourth duct 43. .

The high temperature wet steam introduced into the heat dissipation unit 30 is removed from the heat dissipation unit 30 and the evaporator 24 corresponding to the heat dissipation unit, and is changed to a low temperature dry steam, and then the heat absorbing unit 31 through the ducts 41 and 42. Is moved to. At this time, the condensed water generated in the evaporator 24 is discharged to the outside through a separate pipe 46. In addition, after drying of the dried object is completed, it is necessary to take out the dried product from the drying chamber 10, so it is necessary to lower the temperature of the dried object. At this time, since the low temperature dry steam deprived of heat from the heat dissipation unit 30 is discharged into the drying chamber through the second duct 41 to cool the dry object, the dry object is discharged at a low temperature from the drying chamber.

When the low temperature dry steam, which is changed in the heat dissipation unit 30, moves to the heat absorbing unit 31 corresponding to the condenser 22 through the third duct 42 by the fan 45, the heat absorbing unit 31. The heat discharged from the condenser 22 corresponding to the heat is transferred to the low temperature dry steam flowing in the heat absorbing portion 31, so that the low temperature dry steam obtains heat and is converted into high temperature steam, and then opens the fourth duct 43. Through it is discharged again into the drying chamber 10 is used to maintain the internal temperature of the drying chamber. The heat absorbing portion 31 is installed in the second chamber 81 together with the condenser 22, and the first and second chambers 80 and 81 are spaced apart from each other so that the heat exchange action generated in the chamber does not interfere with each other. It is desirable to install.

The high temperature steam discharged into the drying chamber 10 and the wet steam in the drying chamber are moved to the heat radiating unit 30 through the first duct 40 by a fan 44 installed at the inlet of the heat radiating unit 30 to the evaporator 24. The heat is taken away by) and the circulating action that changes into the low temperature dry steam occurs continuously.

That is, the high temperature wet steam introduced from the drying chamber 10 is deprived of heat by the corresponding evaporator 24 in the heat dissipation unit 30 so that the temperature of the high temperature wet steam is lowered to change to the low temperature dry steam to absorb the endothermic portion 31. The low temperature dry steam introduced into the heat absorbing portion 31 is supplied with heat from the corresponding condenser 22, is converted into high temperature steam, and discharged into the drying chamber.

Referring to another embodiment according to the present invention with reference to Figure 2, the first chamber 80 is further provided with a water flow tube 91 for absorbing and using the heat emitted from the heat dissipation unit 30, the first Cold water introduced into the cold water inlet 92 of the water flow tube 91 and the heat dissipation unit 30 through which the high temperature wet steam flows from the drying chamber 10 through the duct 40 passes through the flow tube 91. During the heat exchange to the hot water vapor of the heat dissipation unit 30 is changed to the hot water to increase the temperature is discharged to the outside through the hot water outlet 93, the steam lowered while passing through the heat dissipation unit 30, the second And the heat absorbing part 31 is moved to the heat absorbing part 31 through the third ducts 41 and 42, and heat-exchanges with the heating part 90 corresponding to the heat absorbing part 31, and the temperature of steam is raised to be discharged to the drying chamber. Steam, hot water or thermal oil flows through the heating unit 90 to perform heat exchange. The above operation is also made continuously can reuse the high temperature wet steam of the drying chamber, hot water discharged from the hot water outlet 93 can be reused in the bathroom.

3 is another embodiment according to the present invention, in which the second duct 41 and the third duct 42 are connected, and the second duct 41 and the third duct 42 are outside the drying chamber. The low temperature dry steam generated by the heat dissipation unit 30 is directly connected to each other and flows directly to the heat absorbing unit 31 without passing through the drying chamber to be converted into high temperature steam and discharged into the drying chamber 10. will be. If necessary, the second duct 41 and the third duct 42 may be directly connected to each other in the drying chamber 10, and a connection portion in which the second duct 41 and the third duct 42 are connected to each other. A damper that can be opened and closed may be installed in the.

The above methods reduce heat loss generated by discharging the wet steam generated in the drying chamber to a separate outlet (not shown), thereby improving thermal efficiency, and reducing the fuel cost by reusing the hot steam discharged through the endothermic section. And by discharging the condensate generated from the evaporator to the outside, there is a dehumidification effect, it is possible to continuously use the heat generated in the drying chamber improves the drying capacity.

The above description is only illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains various modifications and variations without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention but to describe the present invention, and the technical scope of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

1 is a block diagram showing a drying system using a heat pump according to the present invention.

2 is a partial configuration diagram showing another embodiment of a drying system according to the present invention.

3 is a partial configuration diagram showing another embodiment of a drying system according to the present invention.

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

10. Drying Room 20. Heat Pump

21. Compressor 22. Condenser

23. Expansion valve 24. Evaporator

30. Heat dissipation part 31. Heat absorbing part

40. First duct 41. Second duct

42. Third duct 43. Fourth duct

44,45. Fan 46.

50. Piping 60. Heat source

70,71,72,73. Damper 80. First chamber

81. Second chamber 90. Heating section

91. Water flow line 92. Cold water inlet

93. Hot water outlet

Claims (6)

In a drying system using a heat pump, A drying chamber supplied with a heat source to dry the object to be dried; A heat pump installed outside the drying chamber and configured in a closed circuit by connecting a compressor, a condenser, an expansion valve, and an evaporator in series; A heat dissipation unit and a heat absorbing unit respectively installed corresponding to the evaporator and the condenser of the heat pump; A duct connecting the heat dissipation unit, the heat absorbing unit, and a drying chamber, respectively; Drying system using a heat pump, characterized in that configured to include. The method of claim 1, A duct connected to each inlet side of the heat dissipation unit and the heat absorbing unit is further provided with a fan for introducing steam from the drying chamber. The method of claim 1, The inlet of the heat dissipation unit and the drying chamber are connected by the first duct, the outlet of the heat absorbing unit and the drying chamber are connected by the fourth duct, the outlet of the heat dissipation unit and the drying chamber are connected by the second duct, Drying system using a heat pump, characterized in that the drying chamber is installed so as to be connected by a third duct. The method of claim 1, And the evaporator and the heat dissipation unit are disposed in the first chamber, and the condenser and the heat absorbing unit are respectively disposed in the second chamber. The method of claim 4, wherein The first chamber further comprises a water flow pipe for absorbing and using heat emitted from the heat dissipation unit. The method of claim 3, wherein And the second duct and the third duct are connected to each other outside the drying chamber.

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