KR101565903B1 - Multi-drying system - Google Patents

Abstract

A multi-drying system according to the present invention radiates heat by supplying heat to a heat pump after heat of cooling water, which cools a microwave generator, stores in a heat storage tank. A stable heat source can be secured due to supplying the heat stored in the heat storage tank, as a heat source of a evaporator in the case of stopping the microwave generator for input, discharge and replacement of articles to be dried. In addition, it has an advantage of a simple configuration without installing a additional heat exchanger as well as the heat exchange efficiency can be improved because three fluids of refrigerant, cooling water and air can exchange heat in the evaporator.

Description

Multi-drying system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a composite drying system, and more particularly, to a combined drying system for drying an object using hot air from a microwave and a heat pump.

In general, a hot air drying apparatus is mainly used to remove moisture from the laundry, such as cereals or medicines. The hot air drying equipment is a facility for supplying hot air to the inside of a drying tank containing the drying subject and drying the drying subject through hot air contact with the drying subject.

However, in the conventional hot air drying apparatus, since the drying is performed from the surface of the drying object in contact with the hot air, the drying of the drying object is not performed, and if the drying is not uniform from the surface to the inside of the drying object There is a problem that quality deteriorates.

Korean Patent No. 10-1252664

An object of the present invention is to provide a composite drying system capable of further improving drying efficiency.

A composite drying system according to the present invention includes: a primary drying unit including a microwave generator and a drying chamber for primarily drying the object using a microwave generated from the microwave generator; A second drying unit including a heat pump and an air flow dryer for secondarily drying an object to be dried from the drying chamber using hot air that absorbs heat of condensation of the heat pump; The microwave generator and the air dryer are operated in a first operation mode in which the high temperature cooling water that has cooled the microwave generator is stored and stored and the stored high temperature cooling water is supplied to the heat source of the evaporator of the heat pump .

A composite drying system according to the present invention includes: a primary drying unit including a microwave generator, a drying chamber for primarily drying an object to be dried using microwaves and hot air generated from the microwave generator; A second drying unit including a heat pump and an air flow dryer for secondarily drying an object to be dried from the drying chamber using hot air that absorbs heat of condensation of the heat pump; A storage tank installed between the microwave generator and the evaporator of the heat pump to store high temperature cooling water cooled by the microwave generator; A heat storage flow path connecting the microwave generator and the heat storage tank to supply high temperature cooling water cooled by the microwave generator to the heat storage tank; A generator circulation flow path connecting the microwave generator and the heat storage tank to circulate the low temperature cooling water stored in the storage tank to the microwave generator; A heat dissipating channel connecting the heat storage tank and the heat pump to supply high temperature cooling water stored in the heat storage tank to the heat pump; A heat storage tank circulation flow path for connecting the heat storage tank and the heat pump to circulate the low temperature cooling water that has passed through the evaporator to the storage tank; A hot air supply passage connecting the condenser of the heat pump and the air flow dryer to supply hot air, which absorbs the heat of condensation of the heat pump, to the air flow dryer; A hot air recovery flow path connecting the air stream dryer and the evaporator of the heat pump to supply hot air dried by the air stream dryer to the evaporator; A drying chamber hot air supply passage branched from the hot air supply passage and connected to the drying chamber to supply at least a part of hot air of the hot air supply passage to the drying chamber; And a drying chamber hot air return flow path for connecting the drying chamber and the hot air return flow path to supply hot air, which is dried in the drying chamber, to the hot air return flow path, wherein both the microwave generator and the air flow dryer operate In the first operation mode, the heat storage tank stores and accumulates high-temperature cooling water that has cooled the microwave generator, and supplies high-temperature cooling water stored therein to the heat source of the evaporator of the heat pump to radiate heat, In the second operation mode in which only the air dryer is operated, the heat storage tank only performs heat dissipation to supply the high temperature cooling water stored therein to the heat source of the evaporator.

In the composite drying system according to the present invention, the heat of the cooling water in which the microwave generator is cooled is stored in the heat storage tank, and then the heat is supplied to the heat pump to dissipate the heat to operate the microwave generator for inputting, The heat stored in the heat storage tank can be continuously supplied to the heat source of the evaporator, so that a stable heat source can be secured.

In addition, in the evaporator, since the three fluids such as the refrigerant, the cooling water, and the air can be heat-exchanged at the same time, the heat exchange efficiency can be improved and there is no need to install an additional heat exchanger.

1 is a view showing a first operation mode of a composite drying system according to an embodiment of the present invention.
2 is a view showing a second operation mode of the composite drying system according to the embodiment of the present invention.
3 is a schematic view showing the inside of a thermal storage tank of a composite drying system according to an embodiment of the present invention.

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

1 is a view showing a first operation mode of a composite drying system according to an embodiment of the present invention. 2 is a view showing a second operation mode of the composite drying system according to the embodiment of the present invention. 3 is a schematic view showing the inside of a thermal storage tank of a composite drying system according to an embodiment of the present invention.

1, a combined drying system according to an embodiment of the present invention includes a primary drying unit 10 including a microwave generator 11 and a drying chamber 14, a heat pump 30, 22) and a heat storage tank (50).

The primary drying unit 10 primarily dries the drying object in the drying chamber 14 by using the microwave generated by the microwave generator 11 and the hot air generated by the heat pump 30 . In this embodiment, microwaves are irradiated into the drying chamber 14 and hot air generated by the heat pump 30, which will be described later, is also supplied at the same time. However, the present invention is not limited to this, and it is also possible that only one of the microwave and the hot air is selected and used depending on the state of the object to be dried and the temperature condition of the hot air.

The microwave generator 11 is a device for generating microwaves. The microwave generator 11 is connected to a magnetron 12 for irradiating the microwave. The magnetron 12 is installed on the upper side of the drying chamber 14 to irradiate the microwave into the drying chamber 14.

The microwave generator (11) is provided with a cooling water heat exchanger (13) through which cooling water passes. The cooling water heat exchanger 13 is connected to a heat storage flow path 51 and a generator circulation flow path 52 to be described later.

The drying chamber 14 is a chamber in which the object to be dried is accommodated. The magnetron 12 is installed at an upper portion of the drying chamber 14. A discharge port 14a is formed in an upper portion of the drying chamber 14 and a discharge port 14b is formed in a lower portion to discharge the dried primary dried product. The charging port opening / closing means 16a is provided in the charging port 14a and the discharging port opening / closing means 16b is provided in the discharging port 14b. The drying chamber hot air supply passage 81 and the drying chamber hot air recovery passage 83 are connected to the drying chamber 14. The drying chamber 14 is provided with an agitator for agitating and conveying the drying object.

The drying chamber hot air supply passages 81 and 82 guide the hot air generated by the heat pump 30 to the drying chamber 14. That is, the drying chamber hot air supply passages 81 and 82 guide at least part of the hot air that absorbs the heat of condensation of the heat pump 30 to the drying chamber 14. In this embodiment, the drying chamber hot air supply passages 81 and 82 are branched from the hot air supply passage 84 to be described later, for example. However, the present invention is not limited to this, and the drying chamber hot air supply passage 81 and 82 may be connected directly to the condenser 32 of the heat pump 30. The drying chamber hot air supply passages 81 and 82 are provided with an auxiliary heater 70 for heating hot air from the heat pump 30. The auxiliary heater (70) is operated when the temperature of hot air from the heat pump (30) deviates from a preset temperature range. The drying chamber hot air supply passages 81 and 82 are provided with first and second valves 91 and 92 for opening and closing the flow passage. The first and second valves 91 and 92 block the drying chamber hot air supply passage 81 and 82 in the second operation mode in which the operation of the microwave generator 11 is stopped.

The drying chamber hot air return flow path 83 is a flow path for drying the object to be dried in the drying chamber 14 and guiding the discharged hot air to the heat pump 30. The hot air from the drying chamber hot air return flow path 83 is used as a heat source for the evaporator 34. In the present embodiment, the drying chamber hot air return flow path 83 is connected to a hot air return flow path 85 to be described later. However, the present invention is not limited thereto, and the drying chamber hot air return flow path 83 may be connected to the evaporator 34 of the heat pump 30 It is of course possible to be connected directly. The drying chamber hot air return flow path 83 is provided with a third valve 93 for opening and closing the flow path. The third valve 93 shuts off the drying-chamber hot air return flow path 83 in the second operation mode in which the operation of the microwave generator 11 is stopped. A blower may be installed in the drying chamber hot air recovery duct 83.

The drying chamber (14) is provided with a drying tank (18). The drying table 18 is a tank in which the drying objects primarily dried in the drying chamber 14 are temporarily stored. The drying tank (18) is disposed below the discharge port (14b) of the drying chamber (14). The upper portion of the drying tank 18 is formed to communicate with the discharge port 14b and the tank outlet 18a and the tank opening and closing portion 18b are provided at a lower portion thereof. The tank opening and closing part 18b is opened when the laundry to be stored in the laundry tank 18 is discharged to the first conveyor 61 and is shielded during operation of the microwave generator 11. [ In this embodiment, the drying chamber 14 and the drying table 18 are separately provided, and the drying chamber 14 is connected to the upper portion of the drying tank 14 through the discharge port 14b of the drying chamber 14 However, the present invention is not limited thereto, and the drying chamber 14 and the drying tank 18 may be integrally formed.

A first conveyor (61) is installed between the drying table (18) and the air dryer (22). The first conveyor (61) conveys the laundry from the drying tank (18) to the air dryer (22).

The secondary drying unit 20 uses the hot air from the heat pump 30 to secondarily dry the laundry in the air dryer 22. The secondary drying unit 20 includes the heat pump 30, the air dryer 22, the hot air supply passage 84, and the hot air recovery duct 85.

The heat pump 30 includes a compressor 31, a condenser 32, an expansion valve 33, and an evaporator 34.

The compressor (31) compresses the refrigerant to high temperature and high pressure. The refrigerant compressed by the compressor (31) flows into the condenser (32).

The condenser 32 heat-exchanges the refrigerant introduced from the compressor 31 with the air that has passed through the evaporator 34, thereby condensing the refrigerant. The hot air supply passage 84 is connected to the condenser 32.

The hot air supply passage 84 connects the condenser 32 and the airflow dryer 22. The hot air supply flow path 84 is a flow path for supplying hot air, which has absorbed the heat of condensation while condensing the refrigerant in the condenser 32, to the air flow dryer 22. The hot-air supply passage 84 is provided with a fourth opening / closing valve 94. The hot air supply passage 84 may be provided with a blower.

The expansion valve (33) expands the refrigerant from the condenser (32).

The evaporator 34 is configured to cool the refrigerant expanded from the expansion valve 33 and the hot air recovered from the drying chamber 11 and the air stream dryer 22 and the high temperature cooling water from the storage tank 50 Heat exchange with each other. That is, the evaporator (34) is a triple heat exchanger in which the refrigerant, the hot air, and the cooling water are heat-exchanged with each other. In the evaporator (34), the refrigerant is evaporated by receiving a heat source from the cooling water and the hot air. The evaporator (34) is composed of a first heat exchange passage (32) having a double pipe structure through which the refrigerant and the cooling water pass through each other, and a second heat exchange passage (32) surrounding the outside of the first heat exchange passage . Since the refrigerant in the first heat exchange passage must be heat-exchanged not only with the cooling water but also with the hot air, the refrigerant pipe through which the refrigerant passes is disposed outside the cooling water pipe through which the cooling water passes. A plurality of fins for increasing the heat exchange area are formed on the surfaces of the first heat exchange channels. The second heat exchange flow path is formed so that the hot air flows in a direction perpendicular to the flow direction of the refrigerant. The hot air return passage 85 is connected to the second heat exchange passage.

The hot air return flow path 85 connects the air flow dryer 22 and the evaporator 34. The hot air return flow path 85 is a flow path for supplying hot air, which is dried by the air dryer 22, to the evaporator 34. A blower may be installed in the hot air return flow path 85.

The hot air return flow path (85) is connected to the hot air flow path (86). The hot air bypass passage 86 is an air passage through which a part of the hot air from the air stream dryer 22 bypasses the evaporator 34. One end of the hot air bypass passage 86 is connected to the hot air return passage 85 and the other end is connected to the hot air supply passage 84. The hot air bypass passage 86 is also connected to a passage 87 connecting the evaporator 34 and the condenser 32 by a connection passage 88. The hot air bypass passage 86 is provided with fifth, sixth and seventh open / close valves 95, 96 and 97. An eighth open / close valve 98 is installed in the connection passage 88. The opening and closing of the fifth, sixth, seventh and seventh open / close valves 95, 96, and 97 can be controlled according to the temperature of the hot air from the air stream dryer 22 and other conditions.

The air flow dryer (22) is a device for secondary drying the laundry using the hot air supplied from the hot air supply passage (84). The air drier (22) is supplied with dried material primarily dried from the first conveyor (61). The air flow dryer (22) has a vertically long cylindrical shape. A discharge unit (23) for discharging the laundry and hot air is formed on one side of the upper part of the air flow dryer (22). A hot air discharge pipe (24) for discharging hot air is connected to the upper end of the discharger (23). The hot air discharge pipe (24) is connected to the hot air return flow path (85). A mixing unit (80) is installed at a position where the hot air discharge pipe (24) and the hot air return flow path (85) are connected. The mixing unit 80 mixes the hot air discharged from the drying chamber hot air return passage 83 and the hot air discharged from the hot air discharge pipe 24 to increase the efficiency of hot air reuse. A discharge port for discharging the object to be dried is formed at the lower end of the discharge unit 23, and a second conveyor 62 for transferring the object to be dried is provided at the lower end of the discharge port.

The heat storage tank 50 stores and accumulates high-temperature cooling water that has cooled the microwave generator 11, and dissipates the stored high-temperature cooling water to be supplied to the heat source of the evaporator 34. The heat storage tank 50 performs both the heat storage and the heat radiation in the first operation mode in which both the microwave generator 11 and the airflow dryer 22 are operated. Meanwhile, in the second operation mode in which the operation of the microwave generator 11 is stopped and only the airflow dryer 22 is operated, the heat storage tank 50 performs only the heat radiation without the heat storage. The microwave generator 11 is stopped when operations such as inputting, replacing, discharging, etc. of the drying object are performed in the drying chamber 14. Since the heat stored in the heat storage tank 50 can be used even if the operation of either the microwave generator 11 or the airflow dryer 22 corresponding to the heat source of the evaporator 34 is stopped, It is possible.

The heat storage tank 50 and the microwave generator 11 are connected to the heat storage passage 51 and the generator circulation passage 52.

The heat storage flow path 51 connects the cooling water heat exchanger 13 provided in the microwave generator 11 and the storage tank 50 so as to cool the high temperature cooling water that has cooled the microwave generator 11 to the storage tank 50 to store and store heat.

The generator circulation flow path 52 connects the cooling water heat exchanger 13 provided in the microwave generator 11 and the storage tank 50 to cool the cooling water stored in the storage tank 50 to the microwave generator It is an euros to circulate. The generator circulation flow path 52 is provided with a first pump 52a.

The heat storage tank (50) and the evaporator (34) are connected to the heat radiation passage (53) and the heat storage tank circulation passage (54).

The heat radiating flow path 53 connects the evaporator 34 and the heat storage tank 50 and supplies the high temperature cooling water stored in the heat storage tank 50 to the evaporator 34 to dissipate heat. A second pump 53a is installed in the heat-radiating flow path 53.

The heat storage tank circulation passage 54 connects the evaporator 34 and the storage tank 50 and circulates the cooling water that has been dissipated while passing through the evaporator 34 to the storage tank 50 again.

3, the thermal storage tank 50 stores high-temperature cooling water flowing in from the heat storage passage 51 and stores low-temperature cooling water flowing from the storage tank circulation passage 54 in the lower portion thereof. The heat storage tank 50 is provided therein with a high-temperature flow path 50a connected to the heat storage flow path 51 for feeding high-temperature cooling water flowing upward from the heat storage flow path 51. The heat storage circulation flow path 54, And a low-temperature channel 50b connected to the heat-storage tank circulation channel 54 for sending the low-temperature cooling water flowing downward from the heat-storage tank circulation channel 54 to the lower part. The high-temperature flow path 50a is located above the heat storage tank 50 and has an upper end formed in a disc shape, for example. Since the high-temperature flow path 50a is a flow path through which high-temperature cooling water flows, the heat storage flow path 51 and the heat radiation flow path 53 are connected. The low-temperature channel 50b is located below the heat storage tank 50, and the lower end of the low-temperature channel 50b has a disk shape. Since the low-temperature flow path 50b is a flow path for the low-temperature cooling water, the heat storage tank circulation path 54 and the generator circulation path 52 are connected. At this time, the temperature difference between the high-temperature cooling water and the low-temperature cooling water is about 5 ° C.

The operation of the composite drying system according to the embodiment of the present invention will be described as follows.

First, referring to FIG. 1, a first operation mode in which the microwave generator 11, the air dryer 22, and the heat pump 30 are all operated will be described. In the first operation mode, both the microwave generator 11 and the airflow dryer 22 are operated so that the drying of the laundry is performed in the drying chamber 14, The secondary drying of the primary drying product is carried out. In the first operation mode, since the microwave generator 11 is operated, heat can be accumulated in the heat storage tank 50, and the heat pump 30 is operated, so that the heat storage tank 50 is also heat- This will be described in detail later.

When the drying object is charged into the drying chamber 14 and the inlet 14a of the drying chamber 14 and the tank outlet 18a of the drying object tank 18 are shielded, Lt; / RTI > During the operation of the microwave generator 11, the inlet 14a and the outlet 14b of the drying chamber 14 are shielded to prevent exposure of the microwave. The microwave generator 11 will be described as an example in which the laundry is not discharged from the drying chamber 14 during operation of the microwave generator 11. However, the present invention is not limited thereto, and it is also possible that the discharge port 14b of the drying chamber 14 is opened and only the tank discharge port 18a is shielded to prevent the microwave from being exposed. During the operation of the microwave generator 11, the stirrer provided in the drying chamber 14 is rotated to dry the laundry in the drying chamber 14 uniformly. In the present embodiment, the tank outlet 18a of the laundry table 18 is also shielded. However, the present invention is not limited thereto, and the tank outlet 18a of the laundry table 18 may be opened It is of course possible that the laundry to be temporarily stored in the laundry tank 18 is discharged to the first conveyor 61. [

Further, the heat pump 30 and the blower installed in the hot air supply passage 84 are operated.

Hot air generated by the heat pump 30 is supplied to the drying chamber 14 through the drying chamber hot air supply passage 81 and 82. The microwave generated by the microwave generator 11 is irradiated to the drying chamber 14.

Therefore, in the drying chamber 14, the drying of the dried material is performed by the microwave and the hot air. In the drying chamber 14, the object to be dried is stirred and conveyed by the rotation of the stirrer installed therein.

The cooling water that has cooled the microwave generator 11 is supplied to the heat storage tank 50 through the heat storage flow path 51. The high temperature cooling water supplied to the heat storage tank (50) is stored in the upper part of the heat storage tank (50). The cooling water of low temperature stored in the lower part of the thermal storage tank 50 is circulated to the microwave generator 11 through the generator circulation channel 52 to cool the microwave generator 11.

The high temperature cooling water stored in the upper part of the heat storage tank 50 is supplied to the evaporator 34 of the heat pump 30 through the heat radiation path 53 and is provided as a heat source of the evaporator 34. Therefore, both the heat storage and the heat radiation are performed in the heat storage tank (50).

The hot air dried in the drying chamber 14 is discharged through the drying chamber hot air discharge path 83 and flows into the hot air return path 85.

On the other hand, the air dryer 22 is in a state in which the dried material dried in the drying chamber 14 is primarily flowed. In the air flow dryer (22), secondary drying of the drying object by hot air supplied from the heat pump (30) is performed.

Hot air from the drying chamber 14 and hot air from the air flow dryer 22 are recovered to the heat pump 30 through the hot air return flow path 85.

Hot air recovered through the hot air return flow path 85 flows into the evaporator 34 of the heat pump 30 and high temperature cooling water is supplied from the heat storage tank 50. Therefore, in the evaporator (34), triple heat exchange is performed between the hot air, the high temperature cooling water and the refrigerant. Therefore, the evaporator 34 can be supplied with a sufficient heat source.

The refrigerant evaporated in the evaporator (34) flows into the condenser (32) through the compressor (31). The condenser 32 exchanges heat between the refrigerant discharged from the compressor 31 and the hot air passing through the evaporator 34. The hot air that has absorbed the heat of condensation through heat exchange in the condenser 32 can be supplied to the air dryer 22 and the drying chamber 14 through the hot air supply passage 84.

Referring to FIG. 2, the second operation mode will be described. In the second operation mode, the operation of the microwave generator 11 is stopped, and the air flow dryer 22 and the heat pump 30 are operated. In the second operation mode, the drying chamber 14 is opened for putting, discharging and replacing the laundry in the drying chamber 14, and the microwave generator 11 is stopped. However, the present invention is not limited to this, and it is of course possible to stop the microwave generator 11 for a fault check or the like. In the second operation mode, the primary drying of the drying object is stopped, but the primary drying of the primary drying material in the airflow dryer 22 can be continued. In the second operation mode, since the operation of the microwave generator 11 is stopped, the heat storage of the heat storage tank 50 is stopped, but the heat pump 30 is operated, so that the heat storage of the heat storage tank 50 continues .

That is, when the inlet 14a is opened to input the object to be dried into the drying chamber 14 or the outlet 14b is opened to discharge the object, the operation of the microwave generator 11 is stopped do. Also, the hot air generated by the heat pump 30 is also prevented from being supplied to the drying chamber 14. That is, the drying chamber hot air supply passages 81 and 82 are also shielded, and the supply of hot air to the drying chamber 14 is blocked.

On the other hand, when the operation of the microwave generator 11 is stopped, the discharge port 14b of the drying chamber 14 is opened. When the discharge port 14b of the drying chamber 14 is opened, the dried material having been primarily dried in the drying chamber 14 is transferred by the transfer of the agitator and is temporarily stored in the dried material tank 18. The tank outlet 18a of the drying tank 18 is also opened so that the primary drying material is transferred to the air dryer 22 through the first conveyor 61. [ When the microwave generator 11 stops operating, it can be rotated or stopped as needed.

On the other hand, the operation of the airflow dryer 22 is maintained, and hot air generated by the heat pump 30 is continuously supplied to the airflow dryer 22.

In the airflow dryer (22), secondary drying of the object to be dried is performed by hot air supplied from the heat pump (30). The hot air from the air flow dryer 22 is returned to the heat pump 30 through the hot air return flow path 85.

Hot air recovered through the hot air return flow path 85 flows into the evaporator 34 of the heat pump 30 and high temperature cooling water is supplied from the heat storage tank 50. The high temperature cooling water previously stored in the heat storage tank 50 may be supplied to the evaporator 34 although the heat storage in the heat storage tank 50 is interrupted. Therefore, in the evaporator 34, triple heat exchange is performed between the hot air, the high-temperature cooling water, and the refrigerant. Even if the microwave generator 11 is stopped, the heat source of the evaporator 34 can be secured.

In the composite drying system according to the present invention, since the heat of the cooling water that has cooled the microwave generator 11 is stored in the heat storage tank 50, the operation of the microwave generator 11 is stopped in the second operation mode It is possible to use the high-temperature cooling water previously stored in the heat storage tank 50 as the heat source of the evaporator 34. Therefore, a shortage of heat source due to the stop of the microwave generator 11 does not occur.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10: Primary drying unit 11: Microwave generator
12: Magnetron 14: Drying chamber
18: Deposition tank 20: Secondary drying unit
22: Air dryer 30: Heat pump
34: Evaporator 50: Heat storage tank
51: heat storage flow path 52: generator circulation flow path
53: heat-dissipating channel 54: heat-storage-tank circulation channel

Claims (11)

A primary drying unit including a microwave generator and a drying chamber for primarily drying the object using a microwave generated from the microwave generator;
A second drying unit including a heat pump and an air flow dryer for secondarily drying an object to be dried from the drying chamber using hot air that absorbs heat of condensation of the heat pump;
The microwave generator, the heat pump, and the air dryer are operated, the microwave generator, the microwave generator, the heat pump, and the air dryer are operated, And a heat storage tank for radiating heat. The method according to claim 1,
The operation of the microwave generator is stopped, and in the second operation mode in which only the heat pump and the air dryer are operated,
Wherein the heat storage is stopped in the heat storage tank and only heat dissipation for supplying the stored high temperature cooling water to the heat source of the evaporator is performed. The method according to claim 1,
Wherein the evaporator comprises:
Wherein the refrigerant circulating through the heat pump and the at least one of the drying chamber and the air stream dryer are used to heat the dehumidifier to heat the hot air recovered and the hot water recovered from the heat storage tank. The method according to claim 1,
A heat storage flow path connecting the microwave generator and the heat storage tank to supply the high temperature cooling water cooled by the microwave generator to the heat storage tank,
And a generator circulation flow path for connecting the microwave generator and the heat storage tank to circulate the low temperature cooling water stored in the storage tank to the microwave generator. The method of claim 4,
A heat radiating flow path for connecting the heat storage tank and the heat pump to supply high temperature cooling water stored in the heat storage tank to the heat pump,
And a heat storage tank circulation flow path for connecting the heat storage tank and the heat pump to circulate the cooling water, which has passed through the evaporator, to the storage tank. The method according to claim 1,
A hot air supply passage connecting the condenser of the heat pump and the air flow dryer to supply hot air that absorbs the heat of condensation of the heat pump to the air flow dryer,
Further comprising a hot air return flow path connecting the air stream dryer and the evaporator of the heat pump to guide the hot air dried by the air stream dryer to the evaporator. The method of claim 6,
A drying chamber hot air supply passage branched from the hot air supply passage and connected to the drying chamber to supply at least a part of the hot air in the hot air supply passage to the drying chamber,
And a drying chamber hot air return flow path for connecting the drying chamber and the hot air return flow path to guide the hot air dried in the drying chamber to the hot air return flow path. The method of claim 7,
And an auxiliary heater provided in the drying chamber hot air supply passage. The method of claim 2,
Wherein the drying chamber is provided with a drying tank for temporarily storing dried materials in the inside,
Wherein the drying tank is shielded in the first operation mode and opened in the second operation mode. The method of claim 9,
Further comprising a conveyor installed between the drying table and the air dryer for conveying drying air from the drying tank to the air dryer. A primary drying unit including a microwave generator, and a drying chamber for primarily drying the object using microwaves and hot air generated by the microwave generator;
A second drying unit including a heat pump and an air flow dryer for secondarily drying an object to be dried from the drying chamber using hot air that absorbs heat of condensation of the heat pump;
A storage tank installed between the microwave generator and the evaporator of the heat pump to store high temperature cooling water cooled by the microwave generator;
A heat storage flow path connecting the microwave generator and the heat storage tank to supply high temperature cooling water cooled by the microwave generator to the heat storage tank;
A generator circulation flow path connecting the microwave generator and the heat storage tank to circulate the low temperature cooling water stored in the storage tank to the microwave generator;
A heat dissipating channel connecting the heat storage tank and the heat pump to supply high temperature cooling water stored in the heat storage tank to the heat pump;
A heat storage tank circulation flow path for connecting the heat storage tank and the heat pump to circulate the low temperature cooling water that has passed through the evaporator to the storage tank;
A hot air supply passage connecting the condenser of the heat pump and the air flow dryer to supply hot air, which absorbs the heat of condensation of the heat pump, to the air flow dryer;
A hot air recovery flow path connecting the air stream dryer and the evaporator of the heat pump to supply hot air dried by the air stream dryer to the evaporator;
A drying chamber hot air supply passage branched from the hot air supply passage and connected to the drying chamber to supply at least a part of the hot air in the hot air supply passage to the drying chamber;
And a drying chamber hot air return flow path connecting the drying chamber and the hot air return flow path to supply the hot air dried in the drying chamber to the hot air return flow path,
In the first operation mode in which both the microwave generator and the air dryer are operated, the storage tank stores and accumulates high-temperature cooling water that has cooled the microwave generator, and stores high-temperature cooling water stored therein in the evaporator of the heat pump Heat is supplied to the heat source,
Wherein the operation of the microwave generator is stopped and only the heat radiating unit supplies heat to the heat source of the evaporator when the heat storage tank stores therein the high temperature cooling water stored in the heat storage tank in the second operation mode in which only the air dryer is operated.

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