KR20130086404A - Apparatus of hot water supplying and heating room using two stage refrigerating cycle - Google Patents

Abstract

The present invention relates to a hot water production and indoor heating apparatus using a dual refrigeration cycle, a compressor for compressing and supplying a gas refrigerant at high temperature and high pressure, a condenser for condensing and supplying a gas refrigerant of high temperature and high pressure supplied from the compressor as a liquid refrigerant, A receiver for storing a liquid refrigerant of high temperature and high pressure supplied from the condenser, an expansion valve for rapidly expanding the high temperature and high pressure liquid refrigerant supplied from the receiver, a fog state rapidly expanded from the expansion valve supplied to the refrigerant An evaporator for exchanging heat with a heat exchange medium, and installed in a double tube structure inside the receiver to store the evaporated gas evaporated by heat exchange in the evaporator, and exchange the evaporated gas with a high temperature and high pressure liquid refrigerant stored in the receiver and then supply it to the compressor. A main refrigeration cycle having a liquid separator;
An auxiliary refrigeration cycle including a compressor such as the main refrigeration cycle, a receiver and a liquid separator having a double pipe structure, an expansion valve, and an evaporator;
In the room heating apparatus using a dual refrigeration cycle configured to connect the main refrigeration cycle and the auxiliary refrigeration cycle to the cascade heat exchanger equipped with the evaporator pipe of the main refrigeration cycle and the condenser pipe of the auxiliary refrigeration cycle,
The main refrigeration cycle is equipped with a hot water tank and an indoor heater,
The compressor outlet line of the main refrigeration cycle is equipped with a temperature sensor for detecting the temperature of the high-temperature, high-pressure gas refrigerant supplied to the condenser of the room heater,
The auxiliary refrigerant cycle is configured to drive when the high temperature and high pressure gas refrigerant temperature supplied from the compressor to the condenser is higher than the set temperature,
The outlet line of the expansion valve for rapidly expanding the liquid refrigerant supplied from the receiver of the main refrigerant cycle is connected to each of the evaporator inlet line and the inlet line of the cascade heat exchanger of the main refrigeration cycle at the same time,
The evaporator side solenoid valve is installed at the inlet line of the evaporator to open when the temperature of the gas refrigerant discharged to the compressor outlet line of the main refrigeration cycle is lower than the set temperature.
The inlet line of the cascade heat exchanger is an invention characterized in that the heat exchanger side solenoid valve is opened when the temperature of the gas refrigerant discharged to the compressor outlet line of the main refrigeration cycle is higher than the set temperature.

Description

Apparatus of hot water supplying and heating room using two stage refrigerating cycle}

The present invention relates to a hot water production apparatus and an indoor heating apparatus using a dual refrigeration cycle, more specifically, when the external temperature is generally image, such as spring, summer, autumn can be selected to operate only the main refrigeration cycle to produce hot water. If the outside temperature is below zero, such as winter, the hot water production system and indoor heating system using a dual refrigeration cycle that can not only produce hot water by simultaneously operating the main refrigeration cycle and auxiliary refrigeration cycle, but also can heat the room. It is about.

In general, a heat pump type refrigeration apparatus is used as an apparatus for heating air or producing hot water using a refrigerant.

The conventional heat pump type refrigerating apparatus is a compressor for compressing a low temperature low pressure gas refrigerant evaporated in an evaporator at high temperature and high pressure, so that the high temperature high pressure gas refrigerant compressed in the compressor is a liquid refrigerant by heat exchange with external air or water. Condenser for condensation, the receiver of the liquid heater for temporarily storing the liquid refrigerant condensed at high temperature and high pressure in the condenser, expansion valve for rapidly expanding the high temperature and high pressure liquid refrigerant supplied from the receiver, the rapid expansion in the expansion valve An evaporator which takes the heat of the low temperature and low pressure refrigerant supplied in the mist state and heats it with heat exchange medium such as external air and water to evaporate it, and is installed in the receiver so that the mist does not evaporate in the evaporator. To exchange heat with the high temperature and high pressure liquid refrigerant stored in the receiver It consists of a structure comprising a liquid separator in the liquid opening.

However, the above-described heat pump refrigeration apparatus of the prior art was capable of producing hot water and heating the room when the outside temperature is -10 ° C or higher. Also, since the lowering of the heating capacity, which is the work of the refrigerant, is reduced, it has been pointed out as a problem that the compressor frequently causes a failure.

In order to solve the problems in the heat pump type refrigerating device as described above, a heat pump type system using a dual refrigeration cycle having a cascade heat exchanger has been introduced as a patent registration No. 10-0639104, which is used for producing hot water and heating indoors. Since the heat transfer (high temperature) refrigeration cycle and the heat acquisition (low temperature) refrigeration cycle must be operated at the same time, the current situation is pointed out as a problem of high power consumption in high oil prices such as these days.

The present invention has been proposed in order to solve the general problems appearing in the prior art as described above, supplementary refrigeration according to the outside air temperature conditions in the hot water production and indoor heating using a binary refrigeration cycle consisting of a main refrigeration cycle and an auxiliary refrigeration cycle It was invented with the aim to reduce power consumption by allowing the device to be selectively operated.

The present invention, as a means for pursuing the above object,

Hot water production apparatus using a binary refrigeration cycle of the present invention,

A compressor for compressing and supplying a gas refrigerant at high temperature and high pressure, A condenser for condensing and supplying a gas refrigerant of high temperature and high pressure supplied from the compressor into a liquid refrigerant, A receiver for storing a liquid refrigerant of high temperature and high pressure supplied from the condenser, The sap Expansion valve for rapidly expanding the high temperature and high pressure liquid refrigerant supplied from the air, an evaporator for exchanging the mist state rapidly supplied from the expansion valve with the heat exchange medium of the outside air, and installed in a double pipe structure inside the receiver. A main refrigeration cycle for storing the evaporated gas evaporated by the heat exchange in the evaporator and heat-exchanging the evaporated gas with the high temperature and high pressure liquid refrigerant stored in the receiver and then supplying the evaporator to the compressor;

An auxiliary refrigeration cycle having a compressor, a condenser, a receiver, an expansion valve, an evaporator, and a liquid separator similar to the main refrigeration cycle;

Two-way refrigeration, which is a cascade heat exchanger, which is installed separately from the main evaporator of the main refrigeration cycle and the heat exchanger side evaporator and the sub-condenser of the auxiliary refrigeration cycle, are connected together to allow heat exchange. In the hot water production apparatus using a cycle,

The main refrigeration cycle is provided with a hot water tank in which the condenser is installed,

The compressor inlet line of the main refrigeration cycle is equipped with a pressure switch for detecting the pressure of the high-temperature, high-pressure gas refrigerant supplied from the liquid separator to the compressor,

The expansion valve outlet line of the main refrigeration cycle is connected to the evaporator inlet line of the main refrigeration cycle and the inlet line of the heat exchanger side evaporator, which is equipped with a heat exchanger side solenoid valve is installed at the same time.

The pressure switch turns on the auxiliary refrigeration cycle when the pressure of the gas refrigerant supplied from the liquid separator to the compressor is below the set pressure (approximately 3 kg / cm 2) and at the same time, the solenoid valve on the heat exchanger side The off-operation and the evaporator-side solenoid valve is characterized in that configured to operate on (on).

In addition, the condenser of the main refrigeration cycle is characterized in that the installation is immersed in hot water stored in the hot water tank.

In addition, the hot water tank is characterized in that the hot water supply line and hot water recovery line for supplying hot water to the circulation pipe for hot water heating for heating the room is connected.

In addition, the hot water tank is characterized in that the hot water supply pipe for supplying hot water is installed.

Indoor heating device using a binary refrigeration cycle of the present invention,

A compressor for compressing and supplying a gas refrigerant at high temperature and high pressure, A condenser for condensing and supplying a gas refrigerant of high temperature and high pressure supplied from the compressor into a liquid refrigerant, A receiver for storing a liquid refrigerant of high temperature and high pressure supplied from the condenser, The sap Expansion valve for rapidly expanding the high temperature and high pressure liquid refrigerant supplied from the air, an evaporator for exchanging the mist state rapidly supplied from the expansion valve with the heat exchange medium of the outside air, and installed in a double pipe structure inside the receiver. A main refrigeration cycle for storing the evaporated gas evaporated by the heat exchange in the evaporator and heat-exchanging the evaporated gas with the high temperature and high pressure liquid refrigerant stored in the receiver and then supplying the evaporator to the compressor;

An auxiliary refrigeration cycle having a compressor, a condenser, a receiver, an expansion valve, an evaporator, and a liquid separator similar to the main refrigeration cycle;

Two-way refrigeration, which is a cascade heat exchanger, which is installed separately from the main evaporator of the main refrigeration cycle and the heat exchanger side evaporator and the sub-condenser of the auxiliary refrigeration cycle, are connected together to allow heat exchange. In the hot water production apparatus using a cycle,

The main refrigeration cycle is equipped with an indoor heating unit in which the condenser is installed,

The compressor inlet line of the main refrigeration cycle is equipped with a pressure switch for detecting the pressure of the high-temperature, high-pressure gas refrigerant supplied from the liquid separator to the compressor,

The expansion valve outlet line of the main refrigeration cycle is connected to the evaporator inlet line of the main refrigeration cycle and the inlet line of the heat exchanger side evaporator, which is equipped with a heat exchanger side solenoid valve is installed at the same time.

The pressure switch turns on the auxiliary refrigeration cycle when the pressure of the gas refrigerant supplied from the liquid separator to the compressor is below the set pressure (approximately 3 kg / cm 2) and at the same time, the solenoid valve on the heat exchanger side The off-operation and the evaporator-side solenoid valve is characterized in that configured to operate on (on).

According to the present invention, when the main refrigeration cycle of the dual refrigeration cycle is driven in winter, when the hot water production and room heating are to be performed, the auxiliary refrigeration cycle can be selectively intermittently driven according to the external temperature change, thereby producing hot water and heating the room. The effect is to reduce power consumption.

1 is a circuit diagram of a binary refrigeration cycle for explaining the hot water production apparatus 장치 ¥ ¼ of the present invention
2 is a circuit diagram of a binary refrigeration cycle for explaining the indoor heating apparatus of the present invention

Referring to the accompanying drawings, a detailed embodiment of a hot water production apparatus and an indoor heating apparatus using a dual refrigeration cycle according to the present invention will be described in detail as follows.

1 is a circuit diagram of a binary refrigeration cycle for a hot water production apparatus, and reference numerals 1 and 2 represent a main refrigeration cycle and an auxiliary refrigeration cycle.

The main refrigeration cycle (1) is a compressor (10) for compressing the gas refrigerant to high temperature and high pressure supply through the outlet line 11, the high temperature and high pressure gas refrigerant discharged to the outlet line of the compressor from the inlet line (21) Condenser 20 to receive the condensed liquid liquid refrigerant, the inlet 31 is connected to the outlet line 22 of the condenser 20 to temporarily store the liquid refrigerant of the high temperature and high pressure supplied from the condenser (30), an expansion valve (40) having an inlet line (41) connected to an outlet (32) of the receiver (30) to rapidly expand the high temperature and high pressure liquid refrigerant discharged from the receiver (30); An evaporator 50 having an inlet line 51 connected to an outlet line 42 of the expansion valve 40 and a heat exchange medium external to the evaporator 50 in order to receive a refrigerant in a state of rapid expansion in the expansion valve. Supply evaporated gas by heat exchange with It is provided with a liquid separator 33 having an inlet 34 to which the outlet line 52 of the evaporator 50 is connected for receiving, and a compressor 10 connected to the outlet 35 of the liquid separator 33. Supply the gas refrigerant discharged through the inlet line 12 of the compressor to the compressor 10, the compressor 10 is supplied to the condenser 20 by compressing the gas refrigerant supplied from the liquid separator 33 at a high temperature and high pressure It will be repeated to do the action.

The auxiliary refrigeration cycle (2) also compresses the gas refrigerant to high temperature and high pressure to supply the compressor 100 through the outlet line 110, the high temperature and high pressure gas refrigerant discharged to the outlet line 110 of the compressor 100 Condenser 200 is supplied from the inlet line 210 to condense into the liquid refrigerant, the inlet 310 is connected to the outlet line 220 of the condenser 200 to temporarily store the liquid refrigerant of the high temperature and high pressure supplied from the condenser An inlet line 410 connected to the outlet 320 of the receiver 300 in order to rapidly expand the receiver 300 is formed, the liquid refrigerant of the high temperature and high pressure discharged from the receiver 300 Valve 400, the evaporator 500 is connected to the inlet line 510 to the outlet line 420 of the expansion valve 400 in order to receive the refrigerant of the rapid expansion in the expansion valve 400, the Heat exchange effect with the external heat exchange medium in the evaporator 500 In order to receive the evaporated gas to the evaporator 500 is provided with a liquid separator 330 is formed an inlet 340 is connected to the outlet line 520 of the evaporator 500, the outlet 350 of the liquid separator 330 Compressor 100 is supplied to the gas refrigerant discharged through the inlet line 120 is to repeat the action of supplying the gas refrigerant to the condenser 200 by compressing the gas refrigerant at a high temperature and high pressure.

The main refrigeration cycle (1) is configured to exchange heat between the refrigerant circulating each of the heat exchanger side evaporator 60 and the condenser 200 of the auxiliary refrigeration cycle (2) which are additionally formed separately from the evaporator (50) installed outdoors. The cascade heat exchanger 70 is provided.

The present invention is characterized in that the main refrigeration cycle (2) when the pressure of the gas refrigerant discharged from the liquid separator (33) of the main refrigeration cycle (1) supplied to the compressor (10) is a set pressure (approximately 3 kg / ㎠) or more Evaporator side solenoid valve 53 installed in the inlet line 51 of the evaporator 50 is turned on to supply the refrigerant in a state of rapid expansion from the expansion valve 40 of the evaporator 50 to the evaporator 50. On the other hand, when the pressure of the gas refrigerant supplied from the liquid separator 33 to the compressor 10 is lower than the set pressure (approximately 3 kg / cm 2), the auxiliary refrigeration cycle (2) is operated and at the same time the main refrigeration cycle Inlet line 61 of the heat exchanger side evaporator 60 such that the refrigerant in the state of fog rapidly expanding in the expansion valve 40 of (1) is supplied to the heat exchanger side evaporator 60 installed in the cascade heat exchanger 70. The solenoid valve 63 on the heat exchanger side installed in the Is in.

To this end, a pressure switch P is installed in the inlet line 12 of the compressor 10 connected to the outlet 35 of the liquid separator 33 of the main refrigeration cycle 1, and the pressure switch P The evaporator side solenoid valve 53 is installed in the inlet line 51 of the evaporator 50 of the main refrigerant cycle 1 by detecting the pressure of the gas refrigerant discharged to the outlet 35 of the liquid separator 33. The auxiliary refrigeration cycle (2) is selectively turned on and off at the same time as the solenoid valve of the heat exchanger side solenoid valve (63) installed in the inlet line (61) of the heat exchanger side evaporator (60). ) Is also configured to be turned on and off.

For example, when the outside air temperature is below 10 ° C, the evaporation temperature and the saturation pressure of the refrigerant that exchanges heat with the outside in the evaporator 50 of the main refrigeration cycle 1 installed outdoors maintain the normal value. The pressure of the gas refrigerant supplied to the compressor 10 from the liquid separator 33 of the main refrigeration cycle 1 is equal to or higher than the set pressure (about 3 kg / cm 2). Therefore, the pressure switch P installed in the inlet line 12 of the compressor 10 of the main refrigeration cycle 1 is detected as a pressure equal to or greater than a set pressure (approximately 3 kg / cm 2), and thus the pressure switch P Since the on-evaporator side solenoid valve 53 installed in the evaporator inlet line 51 of the main refrigeration cycle (1) is turned on (on), the refrigerant in the state of mist rapidly expanding in the expansion valve 40 is evaporator (5). ) Is supplied.

On the contrary, when the outside air temperature is below 15 ° C. or lower, the evaporation temperature of the refrigerant that exchanges heat with the outside air in the evaporator 50 of the main refrigeration cycle 1 is lowered and the saturation pressure of the refrigerant is also lowered. When the refrigerant gas is supplied to the liquid separator 33 while the evaporator temperature and the saturation pressure of the refrigerant that exchange heat with the outside in one evaporator 50 are low, the pressure of the gas refrigerant discharged from the liquid separator 33 is a set pressure ( Since the pressure is lowered to about 3 kg / cm 2 or less, the pressure switch P detects that the pressure of the gas refrigerant discharged from the liquid separator 33 is lower than or equal to the set pressure, and turns on the auxiliary refrigerant cycle 2. on) and simultaneously turn on the heat exchanger side solenoid valve 63 installed in the inlet line 61 of the heat exchanger side evaporator 60, while the evaporator side solenoid valve 53 is off. Expansion bell The refrigerant in the mist state rapidly expanding in the bar 40 is supplied to the heat exchanger-side evaporator 60 installed in the cascade heat exchanger 70, and the refrigerant in the mist state supplied to the heat exchange-side evaporator 60 is Since the heat exchange with the high temperature and high pressure liquid refrigerant circulating the condenser 200 of the auxiliary refrigeration cycle (2) installed together in the cascade heat exchanger (70), the refrigerant in the fog state circulating the heat exchanger side evaporator (60) The evaporation temperature and the saturation pressure are evaporated to be discharged to the outlet line 62 and supplied to the liquid separator 33.

Another feature of the present invention is that the main refrigeration cycle (1) is provided with a hot water tank (80) for producing hot water.

To this end, the condenser 20 is immersed in hot water stored in the hot water tank 80, and the hot water supply pipe 81 is installed inside the hot water tank 80.

In addition, the hot water tank 80 is hot water for supplying and recovering hot water to the hot water circulation circulation pipe (83) in order to circulate the hot water through the hot water heating circulation pipe (83) piped to the ondol floor 82 of the room. Supply line 84 and the hot water recovery line 85 is connected.

In addition, the hot water supply pipe 81 is connected to a water supply pipe 86 for supplying water and a hot water supply pipe 87 for supplying hot water to the kitchen or bathroom, the water supply pipe 86 is a hot water supply pipe (81). In addition to supplying water) is configured to replenish the water in the hot water tank (80).

In addition, when the main refrigeration cycle (1) is not operated in the hot water tank 80, the temperature sensor 88 for detecting the temperature of the water stored in the hot water tank 80 and the temperature detected by the temperature sensor 88 is 0 When the temperature is lower than or equal to 0 ° C, an electric heater 89 is installed to prevent the water from freezing by heating.

Another feature of the present invention is that the main refrigeration cycle (1) as shown in Figure 2 to heat the room is provided with an indoor heater (90) for heating the room.

2 is a circuit diagram of a binary refrigeration cycle for an indoor heating apparatus. In this embodiment, the same components as those of the above-described hot water production apparatus will be described with the same names and the same reference numerals.

A condenser 20 is installed inside the indoor heater 90, and each of the inlet line 91 and the outlet line 92 formed in the indoor heater 90 is connected to the condenser 20. The inlet line 91 is connected to the outlet line 11 of the compressor 10, and the outlet line 92 is connected to the inlet 31 of the receiver 30.

On the other hand, the main refrigeration cycle (1) and the auxiliary refrigeration cycle (2) for controlling the back flow of the oil separator and the refrigerant for recovering oil in each of the outlet lines (11, 110) of the compressor (10) (100) Check valves (not shown) are provided.

In addition, the main refrigeration cycle (1) in order to eliminate the frost attached to the evaporator 50, the outlet line 11 of the compressor 10 and the inlet line 51 of the evaporator 50 is the solenoid valve (13) The frost attached to the evaporator 50 by allowing the compressor 10 to supply the gas refrigerant compressed at high temperature and high pressure to the evaporator 50. In order to remove the frost attached to the evaporator 500 of the auxiliary refrigeration cycle (2) and also to the outlet line (110) of the compressor (100) and the inlet line (510) of the evaporator (500). The valve 130 is connected to the bypass line 140 is installed, the gas refrigerant compressed at high temperature and high pressure in the compressor 100 is supplied to the evaporator 500 is attached to the evaporator 500 Frost can be eliminated.

The operation of the present invention configured as described above will be described.

1 is an embodiment of the hot water production apparatus, the refrigerant in the mist state supplied to the evaporator 50 of the main refrigeration cycle (1) is a heat exchange action with the temperature of the outside air (for example, below -10 ℃) When the evaporation temperature and the saturation pressure of the refrigerant are made normal, the main refrigeration cycle 1 is operated and the auxiliary refrigeration cycle 2 is stopped.

The refrigerant in the mist state supplied to the evaporator 50 of the main refrigeration cycle 1 is evaporated to a high evaporation temperature and a saturation pressure due to heat exchange with the outside air, and then flows into the liquid separator 33 to the outlet 35. The pressure of the gas refrigerant at the time of discharge is maintained at a pressure equal to or greater than the set pressure (approximately 3 kg / cm 2). At this time, the pressure detected by the pressure switch P is equal to or greater than the set pressure (approximately 3 kg / cm 2). The evaporator side solenoid valve 53 installed in the inlet line 51 of the c) is operated on.

Therefore, the gas refrigerant compressed by the high temperature and high pressure in the compressor 10 of the main refrigerating cycle 1 is the condenser 20 → the receiver 30 → the expansion valve 40 → the evaporator installed in the hot water tank 80 ( 50), the operation of circulating the compressor 10 through the liquid separator 33 is repeated. The evaporator side solenoid valve 53 of the main refrigeration cycle 1 is turned on to operate the expansion valve 40. The secondary refrigeration cycle (2) is in a non-operational state when the fog refrigerant rapidly expanding in the air is supplied to the evaporator 50.

As described above, when the main refrigeration cycle 1 is operated, hot water stored in the hot water tank while the gas refrigerant extruded at high temperature and high pressure from the compressor 10 circulates the condenser 20 disposed in the hot water tank 80. Condensed into the liquid phase while being heated hot by the heat exchange action with and is discharged to the outlet line (22).

Therefore, the hot water stored in the hot water tank 80 is heated hot by the condenser 20 is supplied to the hot water heating circulation pipe 83 piped to the ondol floor 82 to heat the ondol floor 82. In addition, the hot water stored in the hot water tank (80) and heated hot by the condensation (20) indirectly heats the hot water supply pipe (81) piped inside the hot water tank (80), so that the hot water supply pipe (81) The water supplied to) is heated to be able to supply hot water to the bath and kitchen through the hot water supply pipe (87).

The high temperature and high pressure liquid refrigerant discharged to the outlet line 22 of the condenser 20 of the main refrigeration cycle 1 is stored in the receiver 30 and discharged through the outlet 32 to the expansion valve 40. The liquid refrigerant supplied to the expansion valve is rapidly expanded in a mist state and discharged to the outlet line 42. The refrigerant in the mist state discharged to the outlet line 42 of the expansion valve 4 is turned on. It is supplied to the evaporator 50 through the inlet line 51 of the evaporator 50 by the evaporator side solenoid valve 53.

The refrigerant in the fog state supplied to the evaporator 50 is evaporated by heat exchange with the outside air. At this time, when the ambient air temperature is below 10 ° C., the refrigerant in the fog state supplied to the evaporator 50 has a higher evaporation temperature and a saturation pressure. In the elevated state is discharged to the outlet line 52 is supplied to the liquid separator 33, the boil-off gas supplied to the liquid separator 33 is stored with the high temperature and high pressure liquid refrigerant stored in the receiver 30 The refrigerant in the mist state mixed in the evaporation gas in the state of being unable to evaporate from the evaporator 50 by the heat exchange action is evaporated in the liquid separator 33, so that gas is discharged to the outlet 35 of the liquid separator 33. Only the refrigerant is discharged. At this time, the pressure of the gas refrigerant discharged through the outlet 35 of the liquid separator 33 is equal to or higher than the set pressure (approximately 3 kg / cm 2). While only the operation cycle (1) would be to produce hot water.

When the refrigerant supplied in the mist state to the evaporator 50 of the main refrigeration cycle (1) is the temperature of the outside air to exchange heat (for example, below minus 15 ℃) the evaporation temperature of the refrigerant is lowered and the saturation pressure is also lowered When the vaporized refrigerant is supplied to the liquid separator 33 under such conditions, the pressure of the gas refrigerant discharged to the outlet 35 is lowered below a set pressure (about 3 kg / cm 2), in which case the main refrigeration The pressure switch P installed in the inlet line 12 of the compressor 10 of the cycle 1 senses the pressure of the gas refrigerant discharged to the outlet 35 of the liquid separator 33 and sets the detected pressure. When the pressure is about 3 kg / cm 2 or less, the auxiliary catamaran cycle 2 is operated and at the same time, the heat exchanger side installed in the inlet line 61 of the heat exchanger side evaporator 60 installed in the main refrigeration cycle 1. The solenoid valve 63 is turned on while the evaporator side The magnetic valve 53 is turned off.

Therefore, the auxiliary refrigeration cycle (2) is operated, and at the same time the refrigerant in the mist state that is rapidly expanded in the expansion valve 40 of the main refrigeration cycle (1) and discharged to the outlet line 42 is the evaporator (50) installed outdoors It is supplied to the heat exchanger-side evaporator 60 installed in the cascade heat exchanger 70 without flowing to), wherein the high-temperature high-pressure gas refrigerant compressed by the compressor 100 of the auxiliary refrigeration cycle (2) is the heat exchanger side It is supplied to the condenser 200 installed in the cascade heat exchanger 70 together with the evaporator 60, and the gas refrigerant and the condenser supplied to the heat exchange-side evaporator 60 installed together in the cascade heat exchanger 70. Since the high temperature and high pressure gas refrigerants supplied to the 200 are heat-exchanged with each other, the gas refrigerant supplied to the condenser 200 is condensed into the liquid refrigerant of the high temperature and high pressure, and the heat exchanger side evaporates. The gas refrigerant supplied to the 60 is supplied to the liquid separator 33 in a state where the evaporation temperature and the saturation pressure are increased, so that the pressure of the gas refrigerant discharged from the liquid separator 33 of the main refrigeration cycle 1 is set at a pressure ( Since the main refrigeration cycle (1) is supplied to the compressor 10 in about 3kg / ㎠ or more to produce and supply hot water while operating normally.

As described above, when the temperature of the outside air (for example, below 15 ° C. or less) is too low, the main refrigeration cycle (1) and the auxiliary refrigeration cycle (2) operate simultaneously to produce hot water, and the temperature of the outside air gradually increases and the temperature is higher. When the auxiliary refrigeration cycle (2) stops and the main refrigeration cycle (1) is operated, for example, it is to produce hot water.

The auxiliary refrigeration cycle (2) is a gas refrigerant compressed at high temperature and high pressure in the compressor (100) is condensed into a liquid refrigerant of high temperature and high pressure while passing through the condenser pipe 200 installed in the cascade heat exchanger (70) to the receiver 300 → the evaporator 500 → the liquid separator 330, the circulation operation supplied to the compressor 100 is repeated repeatedly.

On the other hand, when the main refrigeration cycle (1) does not operate when the outside air temperature drops below zero when the hot water stored in the hot water tank (80) becomes 0 ° C temperature sensor 88 detects this and the electric heater 89 By operating the will prevent the hot water stored in the hot water tank (80) freezing so that the hot water tank (80) is freezing.

2 is an embodiment of the indoor heating apparatus, which is similar to the embodiment of the hot water producing apparatus described above, and the main refrigeration cycle 1 has an evaporation temperature of the refrigerant in the evaporator 50 installed outdoors and Depending on the saturation pressure, only the main refrigeration cycle (1) is operated to heat the room, or the main refrigeration cycle (1) and the auxiliary refrigeration cycle (2) while operating at the same time to heat the room.

Therefore, the indoor heater 90 of the above-described embodiment heats the room by operating only the main refrigeration cycle 1 when the temperature of the outside air changes, for example, at an ambient temperature of 10 ° C. or more, and when the outside air temperature is below 15 ° C. or less. The main internal movement cycle (1) and the auxiliary refrigeration cycle (2) is operated at the same time to heat the room, the operation state of the main refrigeration cycle (1) and the auxiliary refrigeration cycle (2) for this is an embodiment of the above-mentioned hot water production apparatus Since it is the same as the detailed description thereof will be omitted.

However, in the indoor heating apparatus, the gas refrigerant compressed at high temperature and high pressure by the compressor 100 of the main refrigeration cycle 1 is supplied to the condenser 20 installed in the indoor heating unit 90 and exchanges heat with the indoor air while circulating. By supplying warm air into the room, the gas refrigerant supplied to the condenser 20 of the indoor heater 90 is condensed into a liquid refrigerant of high temperature and high pressure is supplied to the receiver 30.

1: main refrigeration cycle 2: auxiliary refrigeration cycle
10,100: Compressor 20,200: Condenser and condenser piping
30,300: Fluid receiver 33,330: Liquid separator
40,400: Expansion valve 50,500: Evaporator
60: evaporator piping 53: evaporator side solenoid valve
63: solenoid valve on the heat exchanger side 70: cascade heat exchanger
80: hot water tank 81: hot water supply piping
82: ondol floor 83: circulation pipe for hot water heating
84: hot water supply line 85: hot water recovery line
86: water supply pipe 87: hot water supply pipe
88: temperature sensor 89: electric heater
90: indoor heater P: pressure switch

Claims (5)

A compressor for compressing and supplying a gas refrigerant at high temperature and high pressure, A condenser for condensing and supplying a gas refrigerant of high temperature and high pressure supplied from the compressor into a liquid refrigerant, A receiver for storing a liquid refrigerant of high temperature and high pressure supplied from the condenser, The sap Expansion valve for rapidly expanding the high temperature and high pressure liquid refrigerant supplied from the air, an evaporator for exchanging the mist state rapidly supplied from the expansion valve with the heat exchange medium of the outside air, and installed in a double pipe structure inside the receiver. A main refrigeration cycle for storing the evaporated gas evaporated by the heat exchange in the evaporator and heat-exchanging the evaporated gas with the high temperature and high pressure liquid refrigerant stored in the receiver and then supplying the evaporator to the compressor;
An auxiliary refrigeration cycle having a compressor, a condenser, a receiver, an expansion valve, an evaporator, and a liquid separator similar to the main refrigeration cycle;
Two-way refrigeration, which is a cascade heat exchanger, which is installed separately from the main evaporator of the main refrigeration cycle and the heat exchanger side evaporator and the sub-condenser of the auxiliary refrigeration cycle, are connected together to allow heat exchange. In the hot water production apparatus using a cycle,
The main refrigeration cycle is provided with a hot water tank installed in a state immersed in the hot water stored condenser,
The compressor inlet line of the main refrigeration cycle is equipped with a pressure switch for detecting the pressure of the high-temperature, high-pressure gas refrigerant supplied from the liquid separator to the compressor,
The expansion valve outlet line of the main refrigeration cycle is connected to the evaporator inlet line of the main refrigeration cycle and the inlet line of the heat exchanger side evaporator, which is equipped with a heat exchanger side solenoid valve is installed at the same time.
The pressure switch turns on the auxiliary refrigeration cycle when the pressure of the gas refrigerant supplied from the liquid separator to the compressor is below the set pressure (approximately 3 kg / cm 2) and at the same time, the solenoid valve on the heat exchanger side Hot water production apparatus using a binary refrigeration cycle characterized in that the off operation and the evaporator-side solenoid valve is configured to operate on (on).
The method of claim 1,
The hot water tank is a hot water production apparatus using a dual refrigeration cycle characterized in that the hot water supply line and hot water recovery line for supplying hot water to the circulation pipe for hot water heating for heating the room is connected.
The method of claim 1,
The hot water tank is a hot water production apparatus using a dual refrigeration cycle, characterized in that the hot water supply pipe for supplying hot water is installed.
The method of claim 1,
The hot water tank is a hot water production apparatus using a two-way refrigeration cycle, characterized in that the temperature sensor for sensing the temperature of the hot water and the electric heater is heated by the temperature sensor so that the hot water does not freeze.
A compressor for compressing and supplying a gas refrigerant at high temperature and high pressure, A condenser for condensing and supplying a gas refrigerant of high temperature and high pressure supplied from the compressor into a liquid refrigerant, A receiver for storing a liquid refrigerant of high temperature and high pressure supplied from the condenser, The sap Expansion valve for rapidly expanding the high temperature and high pressure liquid refrigerant supplied from the air, an evaporator for exchanging the mist state rapidly supplied from the expansion valve with the heat exchange medium of the outside air, and installed in a double pipe structure inside the receiver. A main refrigeration cycle for storing the evaporated gas evaporated by the heat exchange in the evaporator and heat-exchanging the evaporated gas with the high temperature and high pressure liquid refrigerant stored in the receiver and then supplying the evaporator to the compressor;
An auxiliary refrigeration cycle having a compressor, a condenser, a receiver, an expansion valve, an evaporator, and a liquid separator similar to the main refrigeration cycle;
Two-way refrigeration, which is a cascade heat exchanger, which is installed separately from the main evaporator of the main refrigeration cycle and the heat exchanger side evaporator and the sub-condenser of the auxiliary refrigeration cycle, are connected together to allow heat exchange. In the hot water production apparatus using a cycle,
The main refrigeration cycle is provided with a condenser is installed inside the indoor heat exchanger is configured to blow the warm air to heat the condenser and the indoor heat exchange,
The compressor inlet line of the main refrigeration cycle is equipped with a pressure switch for detecting the pressure of the high-temperature, high-pressure gas refrigerant supplied from the liquid separator to the compressor,
The expansion valve outlet line of the main refrigeration cycle is connected to the evaporator inlet line of the main refrigeration cycle and the inlet line of the heat exchanger side evaporator, which is equipped with a heat exchanger side solenoid valve is installed at the same time.
The pressure switch turns on the auxiliary refrigeration cycle when the pressure of the gas refrigerant supplied from the liquid separator to the compressor is below the set pressure (approximately 3 kg / cm 2) and at the same time, the solenoid valve on the heat exchanger side Indoor operation apparatus using a two-way refrigeration cycle characterized in that the off operation and the evaporator side solenoid valve is configured to operate on.

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