KR20190023011A - Continuous heating Air Conditioner system for green house - Google Patents

Abstract

The present invention relates to a continuous heating air conditioner system for a green house. The continuous heating air conditioner system includes: a heat storage tank; a heat storage heat exchanger disposed in a refrigerant circulation pipe between a compressor and a condenser; a heat storage pipe passing through the heat storage heat exchanger and an inlet and an outlet connected to the heat storage tank such that a heat medium of the heat storage tank flows; a defrost heat exchanger disposed adjacent to a first defrost three-way valve positioned at an inlet end of the heat storage pipe, a second defrost three-way valve positioned at an outlet of the heat storage pipe, and a first heating heat exchanger connected to the condenser; and a defrosting pipe passing through the defrost heat exchanger and having an inlet connected to the first defrost three-way valve and an outlet connected with the second defrost three-way valve. The heat medium flowing through the heat storage pipe exchanges heat with the refrigerant flowing in the refrigerant circulation pipe in the heat storage heat exchanger.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a continuous heating air conditioning system,

The present invention relates to a continuous heating air conditioning system for facility horticulture.

In the air conditioner, the refrigerant compressed in the compressor during the cooling operation flows into the outdoor heat exchanger, and the refrigerant condensed in the outdoor heat exchanger passes through the indoor heat exchanger and heat-exchanges with the room air to cool the room air.

In the air conditioner, the refrigerant compressed in the compressor during the heating operation flows into the indoor heat exchanger, is heat-exchanged with the room air, is condensed, passes through the outdoor heat exchanger, evaporates, and then flows into the compressor. The relative humidity of the air around the outdoor heat exchanger is increased by the refrigerant passing through the outdoor heat exchanger, and the water in the air condenses on the surface of the outdoor heat exchanger, thereby causing a freezing phenomenon.

The defrosting power source is executed to remove the defects during the heating operation. In the defrosting operation, the high-temperature and high-pressure refrigerant compressed by the compressor flows into the outdoor heat exchanger and melts the property generated on the surface of the outdoor heat exchanger. However, since the defrosting operation is performed in a state in which the heating operation is completed, the room temperature is lowered. However, when defrosting, the refrigerant supplied from the compressor had to be used.

Registration No. 10-0764707 (Oct. 1, 2007)

The present invention provides a continuous heating air conditioning system for facility gardening which stores discharge end heat of a compressor in a heat storage tank and performs defrosting using stored heat.

The continuous heating air conditioning system for facility horticulture according to an embodiment of the present invention includes a heat storage tank, a heat storage heat exchanger disposed in a refrigerant circulation pipe between a compressor and a condenser, and an inlet and an outlet end connected to the heat storage tank via the heat storage heat exchanger A first defrost three-way valve located at an inlet end of the heat storage pipe, a second defrost three-way valve located at a discharge end of the heat storage pipe, A first defrost heat exchanger connected to the condenser, a defrost heat exchanger disposed adjacent to the condenser, and a defrost heat exchanger connected to the first defrost three-way valve via a defrost heat exchanger, Wherein the heat medium flowing through the heat storage pipe flows through the refrigerant circulating pipe through the heat storage heat exchanger, The.

Wherein the defrost heat exchanger includes a defrost main body having the inlet and the outlet and having a flow space for the heating medium and at least one heat exchanger for connecting the defrost main body and the first heat exchanger and transferring the heat of the heating medium to the first heat exchanger And may include a transfer portion.

The heat transfer portion may be a heat pipe.

Wherein the expansion valve is disposed between the first heating heat exchanger and the condenser, and the first heating three-way valve (1) disposed in the refrigerant circulation pipe between the first heating heat exchanger and the expansion valve a second heating three-way valve disposed in the refrigerant circulation pipe between the first heating heat exchanger and the compressor, and an inlet end connected to the first heating three-way valve and a discharge end connected to the second heating three- And a second heat exchanger connected to the heating three-way valve, wherein the heat medium flowing through the heat storage pipe flows along the defrost pipe by the first defrost three-way valve and the second three- Wherein the first heating three-way valve and the second heating three-way valve are connected to each other through the first heating heat exchanger and the first heating heat exchanger, And the refrigerant flowing through the refrigerant circulation pipe through the second heating three-way valve control can flow to the second heat exchanger.

According to the embodiment of the present invention, when the defrosting operation is started, the heating medium of the heat storage tank flows in the direction of the defrost heat exchanger by the control of the first defrost three-way valve and the second defrost three-way valve, and the first heat- The second heat exchanger is operated. In this way, even during defrosting operation, the interior of the horticulture can be continuously heated.

According to the embodiment of the present invention, it can be seen that a heat loss occurs due to a high degree of superheat of the heat of the sections (2) - (3) in the P-h diagram. The heat of ② - ③ discharged from the compressor is stored in the heat storage tank, and when it is necessary to defrost, the stored heat is sent to the defrost heat exchanger to perform defrosting. Thus, energy consumption due to defrosting can be minimized.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic view of a continuous heating air conditioning system for utility gardening in accordance with an embodiment of the present invention. FIG.
Fig. 2 is a diagram of a continuous heating air conditioning system heat pump cycle Ph for facility horticulture of Fig. 1; Fig.
3 is a schematic view showing a connection state of the defrost heat exchanger and the first heating heat exchanger of FIG.
Fig. 4 is a schematic view showing the heating operation state of the continuous heating air conditioning system for facility horticulture in Fig. 1; Fig.
Fig. 5 is a schematic view showing a defrosting operation state of the continuous heating air conditioning system for facility horticulture in Fig. 1; Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Like parts are designated with like reference numerals throughout the specification.

A continuous heating air conditioning system for facility gardening according to an embodiment of the present invention will now be described with reference to FIGS. 1 to 3. FIG.

FIG. 1 is a schematic view showing a continuous heating air conditioning system for facility horticulture according to an embodiment of the present invention, FIG. 2 is a diagram of a continuous heating air conditioning system heat pump cycle Ph for facility horticulture in FIG. 1, FIG. 2 is a schematic view showing a connection state of the defrost heat exchanger and the first heating heat exchanger of FIG.

1 to 3, the continuous heating air conditioning system for institutional gardening 1 according to the present embodiment includes a heat storage tank 20, a heat storage heat exchanger 30, a heat storage pipe 31, a first defrost three-way valve 31a, a second defrosting three-way valve 31b, a defrost heat exchanger 40 and a defrosting pipe 50. The continuous heating air conditioning system 1 for a horticultural use includes a compressor 11, a condenser 12, an expansion valve 13, a first heating heat exchanger 14a, a second heating heat exchanger 14b, The second heating three-way valve 15b and the refrigerant circulation pipe 16. The heat of the discharge end of the compressor 11 is stored in the heat storage tank 20 and defrosted by the stored heat.

The defrost heat exchanger 40 and the first heating heat exchanger 14a according to the present embodiment are disposed in a heating exclusive duct (not shown) for supplying heating to the greenhouse and the room, and the second heating heat exchanger 14b And the condenser 12 are disposed in a duct (not shown) dedicated to the heat source to receive the heat source from the outside air. The inside of the heating-only duct and the inside of the heat-source-only duct are separated from each other.

The compressor 11, the condenser 12, the expansion valve 13 and the first heating heat exchanger 14a are connected to the refrigerant circulation pipe 16. The refrigerant compressed in the compressor 11 flows along the refrigerant circulation pipe 16 and can circulate through the condenser 12, the expansion valve 13, the second heating heat exchanger 14b, and the compressor 11. The pressure and temperature of the refrigerant at the discharge end of the compressor (11) differ from the pressure and temperature of the refrigerant discharged from the condenser. Therefore, as shown in Fig. 2, it can be seen that the heat loss occurs due to the high degree of superheat of the sections 2 - 3. Therefore, the ② - ③ section line discharged from the compressor (11) is stored and used in the defrosting operation.

The first heating three-way valve 15a is connected to the refrigerant circulation pipe 16 connecting the first heating heat exchanger 14a and the expansion valve 13 and the second heating three-way valve 15b is connected to the second heating three- Is connected to a refrigerant circulation pipe (16) connecting the compressor (14a) and the compressor (11).

The first heating three-way valve 15a controls the refrigerant flowing in the refrigerant circulation pipe 16 to flow in the direction of the first heating heat exchanger 14a during the heating operation. However, the first heating three-way valve 15a controls the refrigerant flowing in the refrigerant circulation pipe 16 to flow in the direction of the second heating heat exchanger 14b during the defrosting operation. The second heating three-way valve 15b controls the refrigerant flowing in the first heating heat exchanger 14a or the second heating heat exchanger 14b to flow in the direction of the compressor 11.

The compressor 11, the condenser 12, the expansion valve 13, the first heating heat exchanger 14a, the second heating heat exchanger 14b, the first heating three-way valve 15a, The detailed construction of the heating three-way valve 15b is the same as that of a known heat pump compressor, a condenser, an expansion valve, an evaporator (heat exchanger), and a three-way valve.

The heat storage heat exchanger 30 is disposed in a refrigerant circulation pipe 16 adjacent to the discharge end of the compressor 11 and connecting the compressor 11 and the condenser 12. The refrigerant flowing through the refrigerant circulation pipe (16) can flow inside the heat storage heat exchanger (30). The heat storage heat exchanger 30 is formed in a preheater structure.

A heat medium can be accommodated in the heat storage tank 20 and is connected to the heat storage heat exchanger 30 through the heat storage pipe 31.

The inlet and outlet ends of the heat storage pipe (31) are connected to the heat storage tank (20) and pass through the heat storage heat exchanger (30). The heat storage pipe (31) is provided with a pump (21) for flowing the heating medium of the heat storage tank (20). The heating medium of the heat storage tank 20 can flow into the heat storage tank 20 after flowing through the heat storage heat exchanger 30 through the heat storage pipe 31 by the operation of the pump 21. [ The heat medium can be heat-exchanged with the refrigerant flowing through the refrigerant circulation pipe (16) when flowing through the heat storage heat exchanger (30). Since the temperature of the refrigerant is higher than the temperature of the heating medium, the heat of the refrigerant can be transferred to the heating medium, and the heating medium having the increased temperature can be stored in the heat storage tank 20. The heat of the refrigerant discharged from the compressor (11) can be stored in the heat storage tank (20) through the heating medium.

The first defrosting three-way valve 31a is disposed at the inlet end of the heat storage pipe 31 and the second defrosting three-way valve 31b is disposed at the outlet end of the heat storage pipe 31. [ The first defrosting three-way valve 31a is connected to the inflow end of the defrosting pipe 50 and the second defrosting three-way valve 31b is connected to the discharge end of the defrosting pipe 50. [

During the heating operation, the first defrosting three-way valve 31a controls the heating medium to flow toward the heat storage heat exchanger 30. In the defrosting operation, the first defrosting three-way valve 31a controls the heating medium to flow in the inflow end direction of the defrosting pipe 50 . The second defrosting three-way valve 31b controls the heat medium flowing through the heat storage pipe 31 to flow in the direction of the heat storage tank 20 during the defrosting operation.

The defrost heat exchanger 40 includes a defrost main body 41 and a heat transfer portion 42 and can remove the impregnation of the first heating heat exchanger 14a by using the heat medium column of the heat storage tank 20. [

3, the defrost main body 41 is disposed adjacent to the first heating heat exchanger 14a and has an inlet port 412 and a discharge port 413 and a flow space 411 formed therein . A defrosting pipe 50 connected to the first defrosting three-way valve 31a is coupled to the inlet port 412 and a defrosting pipe 50 connected to the second defrosting three-way valve 31b is coupled to the outlet port 413.

The heating medium 20 can be discharged through the discharge port 413 after flowing through the defrosting main body 41 through the defrosting pipe 50 under the control of the first defrosting three-way valve 31a.

The heat transfer part 42 is formed of a heat pipe in which a heating medium is accommodated. The heat transfer portion (42) is arranged along the defrost main body (41). The spacing of the arranged heat transfer parts 42 may vary according to the fin tube standard of the first heating heat exchanger 14a.

One side of the heat transfer part 42 is connected to the defrost main body 41 and is located in the flow space 411 and the other side is inserted into the fin tube of the first heat exchanger 14a. The heat of the heat medium in the flow space 411 is transferred to the second heat exchanger 14b through the heat medium of the heat transfer unit 42 to remove the impurities adhering to the second heat exchanger 14b. Although the heat transfer unit 42 has been described as a heat pipe in the above description, a variety of heat transfer units 42 may be used as long as they can transfer the refrigerant heat in the flow space 411 to the second heat exchanger 14b.

Next, the operation of the continuous heating air conditioning system for a facility gardening described above will be described with reference to [Figure 4] and [Figure 5].

First, the heating operation will be described with reference to FIG.

The first heating three-way valve 15a controls the refrigerant to flow toward the first heating heat exchanger 14a during the heating operation and the second heating three-way valve 15b controls the refrigerant flowing through the first heating heat exchanger 14a, To flow toward the compressor (11).

The first defrosting three-way valve 31a controls the heating medium of the heat storage tank 20 to flow toward the heat storage heat exchanger 30 and the second defrosting three-way valve 31b controls the heat medium flowing through the heat storage heat exchanger 30, (20).

In operation of the compressor 11, the refrigerant flows through the condenser 12, the expansion valve 13, the first heating heat exchanger 14a and flows through the heating-only duct when flowing through the first heating heat exchanger 14a Heat exchanges to increase air temperature.

The refrigerant discharged from the compressor (11) exchanges heat with the heat medium flowing through the heat storage pipe (31) by the operation of the pump (21) while flowing through the heat storage heat exchanger (30). As the heat of the refrigerant moves to the heating medium, the temperature of the heating medium may rise. The heating medium whose temperature has risen can be stored in the heat storage tank 20.

On the other hand, during the heating operation, water in the air of the heating-dedicated duct is adhered to the first heat-exchanging heat exchanger 14a, thereby forming a solid on the surface of the first heat-exchanging heat exchanger 14a.

Next, defrosting operation will be described with reference to Fig.

The first heating three-way valve 15a controls the refrigerant to flow in the direction of the second heating heat exchanger 14b while the second heating three-way valve 15b controls the refrigerant flowing in the second heating heat exchanger 14b, To flow toward the compressor (11).

The first defrosting three-way valve 31a controls the heating medium in the storage tank 20 to flow in the direction of the defrost heat exchanger 40 and the second defrosting three-way valve 31b controls the heating medium in the defrost heat exchanger 40, (20).

In operation of the compressor 11, the refrigerant flows through the condenser 12, the expansion valve 13, the second heating heat exchanger 14b and the heat exchanger 14b. Thereby increasing the temperature of the air. Therefore, the heating operation can proceed through the second heating heat exchanger 14b even if the refrigerant does not flow through the first heating heat exchanger 14a.

The heat storage tank 20 storing the heat of the refrigerant can flow through the defrost heat exchanger 40 through the defrosting pipe 50 under the control of the first defrosting three-way valve 31a by the operation of the pump 21. [

Here, the heating medium may flow into the flow space 411 of the defrost main body 41. The heat medium in the fluid space 411 can be transferred to the heat medium in the heat transfer portion 42 and the heat medium in the heat transfer portion 42 is transferred into the first heat exchanger 14a. Thus, the frost cast on the first heating heat exchanger 14a is defrosted by the heat of the heat transfer medium. Here, since a part of the heat transfer portion 42 is inserted into the first heat exchanger 14a, heat is generated in the first heat exchanger 14a, so that the defrost efficiency can be increased.

Therefore, when the defrosting operation is started, the heating medium of the storage tank 20 flows toward the defrost heat exchanger 40 by the control of the first defrosting three-way valve 31a and the second defrosting three-way valve 31b, 1 The heating heat exchanger is stopped and the second heating heat exchanger is operated. In this way, even during defrosting operation, the interior of the horticulture can be continuously heated.

As shown in the flowchart of the normal operation of the continuous heating air conditioning system for the facility gardening in this embodiment, it is seen that the heat loss occurs due to the high degree of superheat of the heat of the section between the points P and h in the P-h diagram of FIG. The heat of ② - ③ discharged from the compressor is stored in the heat storage tank, and when it is necessary to defrost, the stored heat is sent to the defrost heat exchanger to perform defrosting. Thus, energy consumption due to defrosting can be minimized.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

1: Continuous heating air conditioning system for facility gardening
11: compressor 12: condenser
13: expansion valve 14a: first heating heat exchanger
14b: second heating heat exchanger 15a: first heating three-way valve
15b: second heating three-way valve 16: refrigerant circulation pipe
20: heat storage tank 21: pump
30: heat storage heat exchanger 31: heat storage pipe
31a: first defrosting three-way valve 31b: second defrosting three-way valve
40: defrost heat exchanger 41: defrost main body
411: flow space 412: inlet
413: Exhaust port 42: Heat transfer part
50: Defrosting piping

Claims (4)

Heat storage tank,
A heat storage heat exchanger disposed in the refrigerant circulation pipe between the compressor and the condenser,
A heat storage pipe connected to the heat storage tank via the heat storage heat exchanger and having an inlet end and an outlet end,
A first defrost three-way valve located at an inlet end of the heat storage pipe,
A second defrost three-way valve located at a discharge end of the heat storage pipe,
A first heat exchanger connected to the condenser, a defrost heat exchanger disposed adjacent to the first heat exchanger,
Wherein the first defrosting three-way valve is connected to the first defrosting heat exchanger through the defrost heat exchanger and the discharge end is connected to the defrosting pipe connected to the second defrosting three-
/ RTI >
The heat medium flowing through the heat storage pipe is heat-exchanged with the refrigerant flowing in the refrigerant circulation pipe in the heat storage heat exchanger
Continuous heating air conditioning system for facility gardening. The method of claim 1,
The defrost heat exchanger includes:
A defrosting main body having the inlet and the discharge port and having a flow space for the heating medium;
At least one heat transfer unit for connecting the defrost main body and the first heat exchanger and transferring heat of the heat medium to the first heat exchanger,
Containing
Continuous heating air conditioning system for facility gardening. 3. The method of claim 2,
Wherein the heat transfer portion is a heat pipe. The method of claim 1,
A first heating three-way valve disposed in the refrigerant circulation pipe between the first heating heat exchanger and the expansion valve, an expansion valve disposed between the first heating heat exchanger and the condenser,
A second heating three-way valve disposed in the refrigerant circulation pipe between the first heating heat exchanger and the compressor,
A second heating heat exchanger connected to the first heating three-way valve and having a discharge end connected to the second heating three-
Further comprising:
The heat medium flowing through the heat storage pipe flows along the defrost pipe by the first defrosting three-way valve and the second three-way valve control and can exchange heat with the first heating heat exchanger in the defrost heat exchanger,
Wherein the refrigerant flowing through the refrigerant circulation pipe through the first heating three-way valve and the second heating three-way valve during the heat exchange of the defrost heat exchanger and the first heating heat exchanger flows into the second heat exchanger
Continuous heating air conditioning system for facility gardening.

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