KR102343077B1 - Heat pump system of drying equipment with evaporation pressure compensation and overheat compensation - Google Patents

Abstract

The present invention includes a normally open main intake port and an auxiliary intake port opened and closed by the auxiliary intake damper, and performs an evaporation pressure compensation operation mode that opens the auxiliary intake damper when the suction pressure of the compressor is greater than or equal to a set suction pressure. Since it is possible to prevent an increase in the evaporation pressure of the evaporator due to an increase in temperature or humidity of the evaporator, the evaporator load can be reduced and the coefficient of performance of the system can be improved. In addition, when the discharge pressure of the compressor is equal to or greater than the set discharge pressure, the refrigerant is condensed using an auxiliary condenser installed outdoors, thereby preventing overheating of the refrigerant.

Description

Heat pump system for drying equipment with evaporation pressure compensation and overheat compensation

The present invention relates to a heat pump system for a drying device, and more particularly, to a heat pump system for a drying device with improved energy efficiency by enabling evaporation pressure compensation and overheat compensation.

In general, a drying device is required in various industrial fields such as agricultural and fishery products, formulations, textiles, wood, and food. The drying device consumes a lot of energy because it heats and dries the object to be dried.

Most industrial drying apparatuses use hot air as a heat source, and since the efficiency is very low at 30-50%, there is a problem in that enormous heat energy is lost as exhaust heat.

Recently, interest in a drying device using a heat pump is increasing.

Korean Patent Registration No. 10-0407144

SUMMARY OF THE INVENTION It is an object of the present invention to provide a heat pump system for a drying device capable of compensating for evaporation pressure and compensating for overheating, which can improve energy efficiency.

According to the present invention, there is provided a heat pump system for a drying device capable of compensating for evaporation pressure and compensating for overheating, comprising: a case installed indoors and having a main intake port, an auxiliary intake port, and an exhaust port; an evaporator installed in the inside of the case opposite the main intake port to dehumidify the low-temperature and high-humidity air in the room sucked in through the main intake port by exchanging heat with a refrigerant; a main condenser installed inside the case to heat at least one of the air dehumidified by the evaporator and the low-temperature and high-humidity air in the room sucked in through the auxiliary intake port by exchanging heat with the refrigerant; an auxiliary condenser installed outdoors to heat the outdoor air by heat exchange with the refrigerant; a compressor discharge passage connected to the discharge port of the compressor installed inside the case; a main condenser suction passage branching from the compressor discharge passage and guiding the refrigerant from the compressor to the main condenser; an auxiliary condenser suction passage branching from the compressor discharge passage and guiding the refrigerant from the compressor to the auxiliary condenser; an expansion device installed inside the case and expanding the refrigerant from at least one of the main condenser and the auxiliary condenser; a blower installed opposite the exhaust port in the case to blow the dehumidified air inside the case to the exhaust port; a compressor suction pressure sensor for measuring the suction pressure of the compressor; a compressor discharge pressure sensor for measuring the discharge pressure of the compressor; an auxiliary intake damper rotatably coupled to the auxiliary intake port to open and close the auxiliary intake port; a condenser control valve installed in at least one of the main condenser suction passage and the auxiliary condenser suction passage to open and close the main condenser intake passage and the auxiliary condenser intake passage; When the suction pressure of the compressor is greater than or equal to the preset suction pressure, the auxiliary intake damper is opened to increase the air flow rate flowing in through the auxiliary intake port and decrease the air flow rate flowing into the main intake port, thereby evaporating the evaporator. Control to prevent pressure rise, and when the discharge pressure of the compressor is greater than or equal to a preset discharge pressure, control the condenser control valve to open the auxiliary condenser suction flow path, so that at least a portion of the refrigerant from the compressor is removed from the auxiliary condenser It is condensed in and includes a control unit for controlling to prevent overheating of the main condenser.

When the suction pressure of the compressor is equal to or greater than the set suction pressure, the controller proportionally controls the opening rate of the auxiliary intake damper according to the suction pressure.

In the controller, when the suction pressure of the compressor is less than the set suction pressure, the auxiliary intake damper blocks the auxiliary intake port.

The control unit, when the discharge pressure of the compressor is less than the set discharge pressure, the condenser control valve blocks the auxiliary condenser suction flow path and opens only the main condenser suction flow path, so that the refrigerant from the compressor is condensed only in the main condenser control as much as possible.

The condenser control valve includes a first control valve installed in the main condenser suction passage and a second control valve installed in the auxiliary condenser suction passage.

When the discharge pressure of the compressor is equal to or greater than the set discharge pressure, the control unit closes the first control valve and opens the second control valve.

The condenser control valve is a three-way valve installed at a point where the main condenser suction passage and the auxiliary condenser suction passage branch from the compressor discharge passage.

When the discharge pressure of the compressor is equal to or greater than the set discharge pressure, the control unit controls the three-way valve to increase the flow rate of the refrigerant flowing into the auxiliary condenser suction passage in proportion to the discharge pressure, and to the main condenser suction passage The flow rate of the incoming refrigerant is reduced.

The main intake port is formed to be opened at one side of the upper portion of the case, the auxiliary intake port is formed on the upper surface of the case and opened and closed by the auxiliary intake damper, and the exhaust port is formed to be opened on one side of the lower side of the case. The evaporator is disposed to face the main intake port, and the main condenser is disposed on the upper portion of the case to partition upper and lower spaces of the case, and diagonally to face the evaporator and the auxiliary intake port direction to heat exchange between the air passing through the evaporator and the air passing through the auxiliary intake port with the refrigerant, and the blower is disposed opposite the exhaust port at the lower part of the case.

A heat pump system for a drying device capable of compensating for evaporation pressure and compensating for overheating according to another aspect of the present invention is installed indoors, a main intake port is formed on one side of the upper surface, an auxiliary intake port is formed on the upper surface, and one side is located on the lower side. a case in which an exhaust port is formed; an evaporator installed in the inside of the case opposite the main intake port to dehumidify the low-temperature and high-humidity air in the room sucked in through the main intake port by exchanging heat with a refrigerant; a main condenser installed inside the case to heat at least one of the air dehumidified by the evaporator and the low-temperature and high-humidity air in the room sucked in through the auxiliary intake port by exchanging heat with the refrigerant; an auxiliary condenser installed outdoors to heat the outdoor air by heat exchange with the refrigerant; a compressor discharge passage connected to the discharge port of the compressor installed inside the case; a main condenser suction passage branching from the compressor discharge passage and guiding the refrigerant from the compressor to the main condenser; an auxiliary condenser suction passage branching from the compressor discharge passage and guiding the refrigerant from the compressor to the auxiliary condenser; an expansion device installed inside the case and expanding the refrigerant from at least one of the main condenser and the auxiliary condenser; a blower installed in the interior of the case opposite the exhaust port to guide the dehumidified air inside the case to a lower portion of the case to blow the air through the exhaust port; a compressor suction pressure sensor for measuring the suction pressure of the compressor; a compressor discharge pressure sensor for measuring the discharge pressure of the compressor; an auxiliary intake damper rotatably coupled to the auxiliary intake port to open and close the auxiliary intake port; a condenser control valve installed in at least one of the main condenser suction passage and the auxiliary condenser suction passage to open and close the main condenser intake passage and the auxiliary condenser intake passage; When the suction pressure of the compressor is greater than or equal to the preset suction pressure, the auxiliary intake damper is opened to increase the air flow rate flowing in through the auxiliary intake port and decrease the air flow rate flowing into the main intake port, thereby evaporating the evaporator. Control to prevent pressure rise, and when the discharge pressure of the compressor is greater than or equal to a preset discharge pressure, control the condenser control valve to open the auxiliary condenser suction flow path, so that at least a portion of the refrigerant from the compressor is and a control unit for controlling to be condensed in a condenser to prevent overheating of the main condenser, wherein when the suction pressure of the compressor is equal to or greater than the set suction pressure, the opening rate of the auxiliary intake damper is proportional to the suction pressure control, and when the suction pressure of the compressor is less than the set suction pressure, the auxiliary intake damper shields the auxiliary intake port, and when the discharge pressure of the compressor is less than the set discharge pressure, the condenser control valve is the auxiliary condenser suction By blocking the flow path and opening only the main condenser suction flow path, the refrigerant discharged from the compressor is controlled to be condensed only in the main condenser.

The present invention includes a normally open main intake port and an auxiliary intake port opened and closed by the auxiliary intake damper, and performs an evaporation pressure compensation operation mode that opens the auxiliary intake damper when the suction pressure of the compressor is greater than or equal to a set suction pressure. Since it is possible to prevent an increase in the evaporation pressure of the evaporator due to an increase in temperature or humidity of the evaporator, the evaporator load can be reduced and the coefficient of performance of the system can be improved.

In addition, when the discharge pressure of the compressor is equal to or greater than the set discharge pressure, the refrigerant is condensed using an auxiliary condenser installed outdoors, thereby preventing overheating of the refrigerant.

1 is a view showing a general operation mode in which an auxiliary intake port is shielded in a heat pump system for a drying apparatus according to a first embodiment of the present invention.
2 is a block diagram showing a refrigerant flow in a normal operation mode of the heat pump system for a drying apparatus according to the first embodiment of the present invention.
3 is a view showing an evaporation pressure compensation operation mode in which the auxiliary intake port is opened in the heat pump system for a drying apparatus according to the first embodiment of the present invention.
4 is a block diagram illustrating a refrigerant flow in an evaporation pressure compensation and overheat compensation operation mode of the heat pump system for a drying apparatus according to the first embodiment of the present invention.
5 is a configuration diagram illustrating a flow of refrigerant in an evaporation pressure compensation and overheat compensation operation mode of the heat pump system for a drying apparatus according to a second embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described with reference to the accompanying drawings.

A heat pump system according to an embodiment of the present invention is provided in a drying room for agricultural and marine products such as seaweed, sucks low-temperature and high-humidity air from the inside of the drying room, heats and dehumidifies it, and then supplies it to the room of the drying room.

1 is a view showing a general operation mode in which an auxiliary intake port is shielded in a heat pump system for a drying apparatus according to a first embodiment of the present invention. 2 is a block diagram showing a refrigerant flow in a normal operation mode of the heat pump system for a drying apparatus according to the first embodiment of the present invention.

The heat pump system may be divided into a refrigeration unit 2 , a dehumidification unit 4 , and an overheat compensation unit 6 , and the refrigeration unit 2 and the dehumidification unit 4 are provided inside the drying room. and the overheat compensation unit 6 is installed outside the drying room. In this embodiment, the refrigeration unit 2 and the dehumidification unit 4 will be described as being integrally provided in one case 10 . However, the present invention is not limited thereto, and the refrigerating unit 2 and the dehumidifying unit 4 may be provided in separate cases, respectively, and may be connected to each other through a refrigerant passage.

1 and 2, the heat pump system includes a case 10, a compressor 20, a main condenser 30, an auxiliary condenser 40, an evaporator 50, an expansion device 60, a blower ( 70), the auxiliary intake damper 100 and the condenser control valve 110 are included.

The case 10 is installed inside the drying chamber, and the compressor 20, the main condenser 30, the evaporator 50, the expansion device 60 and the blower 70 are installed therein. do.

A main intake port 11 through which low-temperature and humid indoor air is introduced is formed at an upper portion of one side of the case 10, and an exhaust port 13 for discharging the heated and dehumidified air from the inside into the room is formed at the lower side of one side. do. In addition, an auxiliary intake port 12 for additionally introducing low-temperature and high-humidity air in the room is formed on the upper surface of the case 10 .

The main intake port 11 is always in an open state.

The auxiliary intake damper 100 is installed in the auxiliary intake port 12, and is selectively opened and closed according to the control of the control unit (not shown).

The auxiliary intake damper 100 is a plurality of dampers rotatably coupled to the auxiliary intake port 12 to open and close the auxiliary intake port 12 under the control of the controller (not shown). An opening rate of the auxiliary intake damper 100 is controlled according to the control of the controller (not shown).

The compressor 20 is included in the refrigeration unit 2 .

The compressor 20 is installed in the lower inner side of the case 10 to compress the refrigerant. A compressor suction passage 21 is connected to the suction port of the compressor 20 , and the compressor discharge passage 22 is connected to the discharge port of the compressor 20 .

An accumulator 23 is installed in the compressor suction passage 21 .

A compressor suction pressure sensor 25 for measuring the suction pressure of the compressor is installed in the compressor suction passage 21 .

An oil separator 24 is installed in the compressor discharge passage 22 .

The compressor discharge flow path 22 is branched into a main condenser suction flow path 31 and an auxiliary condenser suction flow path 41, which will be described later.

A compressor discharge pressure sensor 26 for measuring the discharge pressure of the compressor is installed in the compressor discharge passage 22 .

The main condenser 30 , the evaporator 50 and the blower 70 are included in the dehumidification unit 4 .

The main condenser 30 is installed inside the case 10 . The main condenser 30 divides the inner space of the case 10 into upper and lower spaces in the inside of the case 10 , and diagonally faces the main intake port 11 and the auxiliary intake port 12 . placed in the direction The upper end of the main condenser 30 is fixed to the upper portion of the case 10 , and the lower end is fixed to the horizontal support 10a provided inside the case 10 . The main condenser 30 heats the refrigerant discharged from the compressor 20 with at least one of the air dehumidified in the evaporator 50 and the low-temperature and humid air introduced into the auxiliary intake port 12, so that the refrigerant is condensed and the air is heated.

A main condenser suction passage 31 is connected to the inlet of the main condenser 30 .

The main condenser suction passage 31 is a passage branching from the compressor discharge passage 22 to guide the refrigerant from the compressor 20 to the main condenser 30 .

A main condenser discharge passage 32 is connected to the discharge port of the main condenser 30 .

The auxiliary condenser 40 is installed in the overheat compensation unit 6 installed outside the drying room, and heats the refrigerant discharged from the compressor 20 with outdoor air.

The auxiliary condenser suction passage 41 is connected to the suction port of the auxiliary condenser 40 .

The auxiliary condenser suction passage 41 is branched from the compressor discharge passage 22 and guides the refrigerant from the compressor 20 to the auxiliary condenser 40 .

The auxiliary condenser discharge passage 42 is connected to the discharge port of the auxiliary condenser 40 .

The expansion device 60 is installed inside the case 10 and is an expansion valve for expanding the refrigerant from at least one of the main condenser 30 and the auxiliary condenser 40 .

The expansion device suction flow path 61 is connected to the suction side of the expansion device 60 , and the expansion device discharge flow path 62 is connected to the discharge side.

The main condenser discharge passage 32 and the auxiliary condenser discharge passage 42 are connected to the expansion device suction passage 61 . In addition, the receiver 63 is installed in the suction passage 61 of the expansion device.

The evaporator 50 is disposed to face the main intake port 11 inside the case 10 , and all air introduced into the main intake port 11 passes through the evaporator 50 . The evaporator 50 is disposed elongated in the vertical direction so as to face the main intake port 11 from the inner upper side of the case 10 . The evaporator 50 exchanges heat between the refrigerant discharged from the expansion device 60 and the low-temperature and humid air sucked from the main intake port 11 to evaporate the refrigerant and dehumidify the air.

The blower 70 is installed opposite to the exhaust port 13 on the inner lower side of the case 10 . The blower 70 blows the air that has passed through the main condenser 30 to the exhaust port 13 .

The condenser control valve 110 is installed in at least one of the main condenser suction passage 31 and the auxiliary condenser suction passage 32, and the main condenser suction passage 31 according to the control of the controller (not shown). ) and control the opening and closing of the auxiliary condenser suction passage (32).

The condenser control valve 110 includes a first control valve 111 installed in the main condenser suction passage 31 and a second control valve 112 installed in the auxiliary condenser suction passage 32 . The first control valve 111 and the second control valve 112 will be described as an on-off valve, respectively.

The control unit (not shown) controls the operations of the condenser control valve 110 and the auxiliary intake damper 100 according to values detected by the compressor suction pressure sensor 25 and the compressor discharge pressure sensor 26 . do.

The operation of the heat pump system for a drying apparatus according to the first embodiment of the present invention configured as described above will be described as follows.

First, the heat pump system operates by being divided into a general operation mode and an evaporation pressure compensation operation mode depending on whether the auxiliary intake port 12 is opened or closed, and according to the discharge pressure of the compressor 20 in the evaporation pressure compensation operation mode It can be converted to evaporation pressure compensation and overheat compensation operation mode.

1 and 2 show the flow of refrigerant and air in a normal operation mode.

1 and 2, in the normal operation mode, when the suction pressure of the compressor 20 is less than a preset suction pressure, the control unit (not shown) controls the auxiliary intake damper 100 to activate the auxiliary intake port ( 12), and the second control valve 112 is blocked to block the auxiliary condenser suction passage 41.

Accordingly, the air in the drying chamber is introduced into the interior of the case 10 only through the main intake 11 .

The flow of air in the normal operation mode will be described as follows.

When the auxiliary intake port 12 is blocked, the air in the drying chamber is introduced into the interior of the case 10 only through the main intake port 11 when the blower 70 is operated.

The air flow rate sucked into the main intake port 11 corresponds to the blowing flow rate of the blower 70 .

The air sucked in through the main intake port 11 is dehumidified by heat exchange while passing through the evaporator 50 .

The air dehumidified in the evaporator 50 is heated by heat exchange while passing through the main condenser 30 .

The air heated in the main condenser 30 is discharged to the drying chamber through the exhaust port 13 .

In the normal operation mode, the refrigerant passes through the compressor 20 , the main condenser 30 , the expansion device 60 , and the evaporator 50 in order, and then circulates back to the compressor 20 .

As described above, when the blowing flow rate of the blower 70 is 100 in the normal operation mode, the air intake flow rate sucked into the main intake port 11 is 100. In addition, the refrigerant compressed in the compressor 20 does not flow into the auxiliary condenser 40 , but only flows into the main condenser 30 .

Accordingly, after the low-temperature and humid air introduced through the main intake port 11 is dehumidified in the evaporator 50 , it is sufficiently heated through heat exchange with the refrigerant in the main condenser 30 .

On the other hand, when the temperature or relative humidity of the indoor air in the drying room is too high, the evaporation pressure in the evaporator 50 is increased.

Accordingly, the normal operation mode is switched to the evaporation pressure compensation operation mode according to the evaporation pressure of the evaporator 50 , that is, the suction pressure of the compressor 20 .

When the suction pressure of the compressor 20 is equal to or greater than a preset suction pressure, the controller (not shown) determines that the evaporation pressure has risen and switches to the evaporation pressure compensation operation mode.

3 shows the flow of refrigerant and air in the evaporation pressure compensation operation mode.

In the evaporation pressure compensation operation mode, the controller (not shown) controls the auxiliary intake damper 100 to open the auxiliary intake port 12 .

At this time, the opening rate of the auxiliary intake damper 100 is proportionally controlled according to the suction pressure. That is, the opening rate of the auxiliary intake damper 100 may be preset according to the suction pressure, and the higher the suction pressure, the higher the opening rate of the auxiliary intake damper 100 is set.

Since the blowing flow rate of the blower 70 is maintained, when the auxiliary intake port 12 is additionally opened while the main intake port 11 is open, the air flow rate introduced through the auxiliary intake port 12 is By increasing, the air flow rate introduced through the main intake port 11 is relatively reduced.

When the flow rate of air introduced through the main intake port 11 is reduced, the load of the evaporator 50 may be reduced. When the load of the evaporator 50 is reduced, the evaporation pressure of the evaporator 50 may decrease again.

When both the main intake port 11 and the auxiliary intake port 12 are opened, the air introduced through the main intake port 11 and dehumidified in the evaporator 50 and the indoor air introduced through the auxiliary intake port 12 The low-temperature and humid air passes through the main condenser 30 .

Air heated while passing through the main condenser 30 is discharged to the drying chamber through the exhaust port 13 .

In the evaporation pressure compensation operation mode, the refrigerant passes through the compressor 20 , the main condenser 30 , the expansion device 60 , and the evaporator 50 in order, and then circulates back to the compressor 20 . .

In the main condenser 30 , heat exchange between the air dehumidified in the evaporator 50 and the low-temperature and high-humidity air introduced through the auxiliary intake port 12 and the refrigerant is performed. That is, since some of the air introduced into the main condenser 30 is air that has not been heat-exchanged in the evaporator 50 , the refrigerant may be overheated.

Therefore, in order to prevent overheating of the refrigerant during the evaporation pressure compensation operation mode, the controller (not shown) controls the evaporation pressure compensation and overheat compensation operation mode in the evaporation pressure compensation operation mode according to the discharge pressure of the compressor 20 . can be converted to

4 shows the flow of refrigerant in the evaporation pressure compensation and overheat compensation operation modes.

Referring to FIG. 4 , when the discharge pressure of the compressor 20 is greater than or equal to a preset discharge pressure while performing the evaporation pressure compensation operation mode, the control unit (not shown) includes the first control valve 11 . shields and opens the second control valve 112, and switches to the evaporation pressure compensation and overheat compensation operation mode.

Here, the set discharge pressure will be described as an example of about 35 bar.

In the evaporation pressure compensation and overheat compensation operation modes, the auxiliary intake port 12 is in an open state.

The flow of the refrigerant in the evaporation pressure compensation and overheat compensation operation mode will be described as follows.

When the first control valve 11 is closed and the second control valve 112 is opened, the refrigerant discharged from the compressor 20 is supplied only to the auxiliary condenser 40 .

In the auxiliary condenser 40, heat exchange between the refrigerant and outdoor air is made.

After being condensed in the auxiliary condenser 40 , the refrigerant passes through the expansion device 60 and the evaporator 50 in order, and then circulates back to the compressor 20 .

The flow of air during the evaporation pressure compensation and overheat compensation operation mode will be described as follows.

When both the main intake port 11 and the auxiliary intake port 12 are opened, the air introduced through the main intake port 11 and dehumidified in the evaporator 50 and the indoor air introduced through the auxiliary intake port 12 The low-temperature and humid air passes through the main condenser 30 .

At this time, since the refrigerant does not pass through the main condenser 30 , heat exchange between the air and the refrigerant is not performed in the main condenser 30 .

On the other hand, the control unit (not shown), while performing the evaporation pressure compensation operation mode, when the discharge pressure of the compressor 20 is less than a preset discharge pressure, the first control valve 11 is opened and the The second control valve 112 is shielded.

As described above, in the evaporation pressure compensation and overheat compensation operation mode, it is possible to prevent an increase in evaporation pressure of the evaporator 50 by additionally introducing indoor air through the auxiliary intake port 12 , and the auxiliary condenser By using (40) the refrigerant is heat-exchanged with outdoor air and condensed to prevent overheating of the refrigerant due to additional inflow of indoor air.

5 is a block diagram showing the flow of refrigerant and air in a heat pump system for a drying apparatus according to a second embodiment of the present invention.

Referring to FIG. 5 , in the heat pump system for a drying apparatus according to the second embodiment of the present invention, a condenser control valve 210 is provided in the main condenser suction passage 31 and the auxiliary condenser in the compressor discharge passage 22 . It is different from the first embodiment in that it is a three-way valve installed at a branching point of the suction flow passage 41, and the rest of the configuration and operation are similar to those of the first embodiment, so the same reference numerals are used for similar components, and accordingly Detailed description will be omitted.

The condenser control valve 210 is a flow rate control valve for controlling the flow rate of the refrigerant flowing into the main condenser suction passage 31 and the auxiliary condenser suction passage 41 according to the discharge pressure of the compressor 20, respectively. can be used

When the discharge pressure of the compressor 20 is equal to or greater than the set discharge pressure, the control unit (not shown) proportionally proportional the flow rate of the refrigerant flowing into the auxiliary condenser suction passage 41 according to the discharge pressure of the compressor 20 . Control. That is, as the discharge pressure of the compressor 20 increases, the refrigerant flow rate flowing into the auxiliary condenser suction passage 32 may increase, and the refrigerant flow rate flowing into the main condenser suction passage 31 may decrease.

However, the present invention is not limited thereto, and the condenser control valve 210 may block the main condenser suction passage 31 when the auxiliary condenser suction passage 32 is opened.

Although the present invention has been described with reference to the embodiment shown in the drawings, which is merely exemplary, it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. Accordingly, the true technical protection scope of the present invention should be determined by the technical spirit of the appended claims.

10: Case 11: Main intake
12: auxiliary intake port 20: compressor
25: compressor suction pressure sensor 26: compressor discharge pressure sensor
30: main condenser 31: main condenser suction flow path
40: auxiliary condenser 41: auxiliary condenser suction flow path
50: evaporator 60: expansion device
70: blower 100: auxiliary intake damper
110, 210: condenser control valve

Claims (10)

A main intake port installed in the room of the drying room and through which indoor air is introduced, an auxiliary intake port formed separately from the main intake port and selectively opened and closed to additionally introduce indoor air, and exhausts heated and dehumidified air from the inside into the room a case in which an exhaust port is formed;
an evaporator installed in the inside of the case opposite the main intake port to dehumidify the low-temperature and high-humidity air in the room sucked in through the main intake port by exchanging heat with a refrigerant;
The main condenser is disposed to face the evaporator and the auxiliary intake port inside the case, and heats at least one of the air passing through the evaporator and the air flowing in through the auxiliary intake port and not passing through the evaporator with a refrigerant to heat it. Wow;
an auxiliary condenser installed outside the drying chamber to heat the outdoor air by heat exchange with a refrigerant;
a compressor discharge passage connected to the discharge port of the compressor installed inside the case;
a main condenser suction passage branching from the compressor discharge passage and guiding the refrigerant from the compressor to the main condenser;
an auxiliary condenser suction passage branching from the compressor discharge passage and guiding the refrigerant from the compressor to the auxiliary condenser;
an expansion device installed inside the case and expanding the refrigerant from at least one of the main condenser and the auxiliary condenser;
a blower installed opposite the exhaust port in the case to blow the dehumidified air inside the case to the exhaust port;
a compressor suction pressure sensor for measuring the suction pressure of the compressor;
a compressor discharge pressure sensor for measuring the discharge pressure of the compressor;
an auxiliary intake damper rotatably coupled to the auxiliary intake port to open and close the auxiliary intake port;
a condenser control valve installed in at least one of the main condenser suction passage and the auxiliary condenser suction passage to open and close the main condenser intake passage and the auxiliary condenser intake passage;
A control unit for controlling the operation of the condenser control valve and the auxiliary intake damper according to the value detected by the compressor suction pressure sensor and the compressor discharge pressure sensor,
The control unit is
When the suction pressure of the compressor is less than the preset suction pressure, the auxiliary intake port and the auxiliary condenser suction passage are blocked, and the air introduced into the main intake port and dehumidified in the evaporator is heated through heat exchange with the refrigerant in the main condenser. perform normal driving mode;
When the suction pressure of the compressor is equal to or greater than the set suction pressure, the auxiliary intake damper is opened to increase the air flow rate flowing in through the auxiliary intake port and decrease the air flow rate flowing into the main intake port to reduce the load on the evaporator. Evaporation pressure compensation operation mode that controls to prevent an increase in the evaporation pressure of the evaporator, and heats the air introduced into the main intake port and dehumidified in the evaporator and air introduced through the auxiliary intake port through heat exchange with the refrigerant in the main condenser do,
If the discharge pressure of the compressor is equal to or greater than a preset discharge pressure while performing the evaporation pressure compensation operation mode, the condenser control valve controls the auxiliary condenser suction passage to open, so that at least some of the refrigerant from the compressor is Condensed in the auxiliary condenser to perform evaporation pressure compensation and overheat compensation operation mode to prevent overheating of the main condenser,
While performing the evaporation pressure compensation operation mode, if the discharge pressure of the compressor is less than the set discharge pressure, the condenser control valve blocks the auxiliary condenser suction flow path and opens only the main condenser suction flow path, A heat pump system for a drying device capable of compensating for evaporation pressure and compensating for overheating that controls the refrigerant to be condensed only in the main condenser. The method according to claim 1,
The control unit is
When the suction pressure of the compressor is equal to or greater than the set suction pressure, the opening rate of the auxiliary intake damper is proportionally controlled according to the suction pressure. delete delete The method according to claim 1,
The condenser control valve,
A heat pump system for a drying device capable of compensating for evaporation pressure and compensating for overheating, comprising a first control valve installed in the main condenser suction passage and a second control valve installed in the auxiliary condenser suction passage. 6. The method of claim 5,
The control unit is
When the discharge pressure of the compressor is equal to or greater than the set discharge pressure, the first control valve is closed and the second control valve is opened. A heat pump system for a drying device capable of compensating for evaporation pressure and compensating for overheating. The method according to claim 1,
The condenser control valve,
A heat pump system for a drying device capable of evaporating pressure compensation and overheat compensation, which is a three-way valve installed at a point where the main condenser suction flow path and the auxiliary condenser suction flow path branch from the compressor discharge flow path. 8. The method of claim 7,
The control unit is
When the discharge pressure of the compressor is equal to or greater than the set discharge pressure,
Evaporation pressure compensation and overheat compensation are possible by controlling the three-way valve to increase the flow rate of the refrigerant flowing into the auxiliary condenser suction passage in proportion to the discharge pressure and decreasing the flow rate of the refrigerant flowing into the main condenser suction passage Heat pump system for the device. The method according to claim 1,
The main intake port is formed to be opened at one side of the upper portion of the case,
The auxiliary intake port is formed on the upper surface of the case and is opened and closed by the auxiliary intake damper,
The exhaust port is formed to be opened on one side of the lower side of the case,
The evaporator is disposed opposite to the main intake port,
The main condenser is disposed on the upper part of the case to partition the upper and lower spaces of the case, and is disposed in a diagonal direction to face the evaporator and the auxiliary intake port, and passes through the air passing through the evaporator and the auxiliary intake port heat exchanges the air with the refrigerant,
The blower is a heat pump system for a drying device capable of compensating for evaporation pressure and compensating for overheating disposed opposite to the exhaust port at the lower part of the case. A main intake port installed in the room of the drying room and through which indoor air is introduced, an auxiliary intake port formed separately from the main intake port and selectively opened and closed to additionally introduce indoor air, and exhausts heated and dehumidified air from the inside into the room a case in which an exhaust port is formed;
an evaporator installed in the inside of the case opposite the main intake port to dehumidify the low-temperature and high-humidity air in the room sucked in through the main intake port by exchanging heat with a refrigerant;
a main condenser that is disposed inside the case to face the evaporator and the auxiliary intake port and heats at least one of the air that has passed through the evaporator and the air introduced through the auxiliary intake port with a refrigerant to heat it;
an auxiliary condenser installed outside the drying chamber to heat the outdoor air by heat exchange with a refrigerant;
a compressor discharge passage connected to the discharge port of the compressor installed inside the case;
a main condenser suction passage branching from the compressor discharge passage and guiding the refrigerant from the compressor to the main condenser;
an auxiliary condenser suction passage branching from the compressor discharge passage and guiding the refrigerant from the compressor to the auxiliary condenser;
an expansion device installed inside the case and expanding the refrigerant from at least one of the main condenser and the auxiliary condenser;
a blower installed in the interior of the case opposite the exhaust port to guide the dehumidified air inside the case to a lower portion of the case to blow the air through the exhaust port;
a compressor suction pressure sensor for measuring the suction pressure of the compressor;
a compressor discharge pressure sensor for measuring the discharge pressure of the compressor;
an auxiliary intake damper rotatably coupled to the auxiliary intake port to open and close the auxiliary intake port;
a condenser control valve installed in at least one of the main condenser suction passage and the auxiliary condenser suction passage to open and close the main condenser intake passage and the auxiliary condenser intake passage;
A control unit for controlling the operation of the condenser control valve and the auxiliary intake damper according to the value detected by the compressor suction pressure sensor and the compressor discharge pressure sensor,
The main intake port is formed to be opened at one side of the upper portion of the case,
The auxiliary intake port is formed on the upper surface of the case,
The evaporator is disposed long in the vertical direction to face the main intake port,
The main condenser is disposed on the upper part of the case to partition upper and lower spaces of the case, and is diagonally disposed to face the evaporator and the auxiliary intake port, and the air passing through the evaporator and the auxiliary intake port are introduced into the main condenser. and heat-exchanges the air that has not passed through the evaporator with the refrigerant,
The control unit is
When the suction pressure of the compressor is less than the set suction pressure, the auxiliary intake port and the auxiliary condenser suction passage are blocked, and the air introduced into the main intake port and dehumidified in the evaporator is heated through heat exchange with the refrigerant in the main condenser. perform normal driving mode;
When the suction pressure of the compressor is greater than or equal to the preset suction pressure, the opening rate of the auxiliary intake damper is proportionally controlled according to the suction pressure to increase the air flow rate introduced through the auxiliary intake port and the air flow rate introduced into the main intake port is controlled to reduce the load on the evaporator to prevent an increase in the evaporation pressure of the evaporator, and the air introduced into the main intake port and dehumidified in the evaporator and the air introduced through the auxiliary intake port are combined with the refrigerant in the main condenser Performs evaporation pressure compensation operation mode that heats through heat exchange,
While performing the evaporation pressure compensation operation mode, if the discharge pressure of the compressor is equal to or greater than a preset discharge pressure, the condenser control valve controls the auxiliary condenser suction passage to open, so that at least some of the refrigerant from the compressor is Condensed in the auxiliary condenser to perform evaporation pressure compensation and overheat compensation operation mode to prevent overheating of the main condenser,
While performing the evaporation pressure compensation operation mode, if the discharge pressure of the compressor is less than the set discharge pressure, the condenser control valve blocks the auxiliary condenser suction flow path and opens only the main condenser suction flow path, A heat pump system for a drying device capable of compensating for evaporation pressure and compensating for overheating that controls the refrigerant to be condensed only in the main condenser.

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