KR200246301Y1 - Refrigerator suppling hot and cold water - Google Patents

Abstract

The present invention is a compressor; Condenser coil; Expansion valve; Evaporator coil; Hot water storage tank; Cold water storage tank; Solenoid valves; A refrigeration system is composed of an auxiliary condenser and an auxiliary evaporator, and the auxiliary condenser and the auxiliary evaporator are installed in one auxiliary heat exchange chamber, and the air condensation and evaporation is performed by an air cooling method using a fan or the heat exchange method of the auxiliary heat exchanger is performed. It relates to a cold and hot water supply refrigerator to provide a refrigeration system that can maintain the energy balance according to the amount of cold and hot water by condensation and evaporation using a water cooling method using a constant temperature geothermal or ground water.

Description

Cold and hot water supply freezer {REFRIGERATOR SUPPLING HOT AND COLD WATER}

The present invention relates to a cold and hot water supply refrigerator, in particular, to form a bypass pipe to maintain the energy balance of the refrigeration system when the temperature of either cold or hot water is high or low, and the auxiliary heat exchanger, that is, the auxiliary condenser and the auxiliary evaporator The present invention relates to a cold / hot water supply refrigerator for operating a solenoid valve according to a low pressure setting value of a refrigerant according to a use purpose to use a cold water storage tank as an ice storage tank.

Conventional cold and hot water supply freezers have resulted in energy losses by selectively using cold and hot water as a refrigeration system for maintaining the required temperature of the freezer and discharging available heat sources into the atmosphere. In addition, the conventional cold and hot water production refrigerators were unable to operate normally due to the imbalance of energy transfer of the whole system when either load was large or insufficient.

The present invention was devised to solve the above problems, and an object of the present invention is to recover the high and low temperature heat energy generated in a conventional refrigerator from a condenser and an evaporator, and use the same to make cold water and hot water. Energy condensation by adjusting the flow rate by installing condenser and evaporator in storage tank and hot water storage tank respectively, and installing solenoid valve operated by temperature and pressure on bypass condenser equipped with auxiliary condenser and auxiliary evaporator, that is, auxiliary heat exchanger. In order to minimize the installation space by maintaining the auxiliary heat exchanger in one auxiliary heat exchange chamber.

1 is a system schematic diagram of a cold / hot water supply refrigerator according to the present invention,

2 is a system schematic diagram of a cold / hot water supply refrigerator according to another embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

1: compressor 2: hot water storage tank

21: subcondenser 22: condenser coil

3: expansion valve 4: cold water storage tank

41: auxiliary evaporator 42: evaporator coil

51: hot water pump 52: cold water pump

6: check valve 7: bypass piping

81: hot water outlet 82: hot water inlet

91: cold water outlet 92: cold water inlet

10: auxiliary heat exchange room 11: fan

P: Pressure sensor S1, S2: Temperature sensor

SV1, SV2: Solenoid Valve

TS1, TS2: Thermostat

In order to achieve the above object, the present invention is a compressor; Condenser coil; In a refrigeration system formed by sequentially arranging an expansion valve and an evaporator coil, the condenser coil is embedded in a closed hot water tank to seal the hot water storage tank and the evaporator coil to supply hot water by heat exchange between high temperature refrigerant and heating water. A cold water storage tank is provided in the cold water tank to supply cold water by heat exchange between low temperature refrigerant and cooling water, and a high temperature refrigerant gas is controlled by controlling a solenoid valve operated by a temperature sensor at the outlet of the condenser coil. A bypass pipe is formed between the condenser coil and the expansion valve so as to flow in a bypass manner, and the temperature is controlled by a solenoid valve operated by a temperature sensor at the outlet of the cold water storage tank and a pressure sensor at the outlet of the evaporator coil. The expansion valve to bypass the refrigerant gas below the pressure to the secondary evaporator flows A bypass pipe is formed between the compressor, and the auxiliary condenser and the auxiliary evaporator are installed together in one auxiliary heat exchange chamber, and the heat exchange means is connected between the auxiliary condenser and the auxiliary evaporator to perform heat exchange by condensation and evaporation. A system is configured through a fan or geothermal or ground water of constant temperature is used as a heat exchange means of the subcondenser and the subevaporator, and the subcondenser and the subevaporator are passed through to perform heat exchange by condensation and evaporation. It relates to a cold and hot water supply refrigerator characterized in that.

When described in detail by the accompanying drawings an embodiment of the cold and hot water supply refrigerator according to the present invention.

1 shows a system schematic diagram of a cold / hot water supply refrigerator according to the present invention, and the refrigerator according to the present invention includes a compressor (1); Condenser coil 22; Expansion valve (3); Evaporator coil 42; An auxiliary heat exchange chamber (10) comprising an auxiliary condenser (21) and an auxiliary evaporator (41); In the system consisting of a hot water storage tank (2) and a cold water storage tank (4), a bypass pipe between the outlet of the condenser coil 22 passing through the hot water storage tank (2) and the inlet of the expansion valve (3). (7) was formed to allow the high temperature refrigerant to flow through the auxiliary condenser 21, and also formed a bypass pipe (7) before the inlet of the cold water storage tank (4) expansion valve (3) The system is configured to bypass the refrigerant below a predetermined temperature or pressure through the auxiliary evaporator 41. The high temperature and high pressure refrigerant gas discharged by the compressor (1) flows into the condenser coil (22), where the condenser coil (22) is embedded in a hot water storage tank (2) storing hot water for heating. And directly heat exchange with the hot water, and the hot water having high temperature heat energy from the condenser coil 22 is heated, heated or heated by a hot water pump 51 provided at the hot water outlet 81 of the hot water storage tank 2. The hot water supplied to the use, such as hot water supply, achieves the above object is formed in a separate hot water circulation system is returned to the hot water storage tank (2) to obtain heat energy again. Since the amount of hot water used is small, the temperature of the hot water at the outlet of the condenser coil 22 rises above a predetermined temperature, thereby lowering the cooling performance when entering the expansion valve 3, thereby further increasing the outlet temperature of the condenser coil 22. It is necessary to lower. Therefore, after detecting the temperature by installing the temperature sensor (S1) at the outlet of the condenser coil 22, if the wet steam refrigerant of a predetermined temperature or more from the outlet of the condenser coil 22 by the thermostat (TS1) The solenoid valve SV1 of the bypass pipe 7 formed between the outlet of the condenser coil 22 and the expansion valve 3 is blocked to allow the high temperature refrigerant to pass through the auxiliary condenser 21 for further cooling. It was. Here, the auxiliary condenser 21 is located in the auxiliary heat exchange chamber 10, and the cooling method of the auxiliary condenser 21 uses an air cooling method by the fan 11. On the other hand, the low-temperature, high-pressure wet steam refrigerant passing through the condenser coil 22 or the condenser coil 22 and the auxiliary condenser 21 is axially expanded while passing through the expansion valve (3) to form a low-temperature low-pressure gas refrigerant Change. The gas refrigerant passing through the expansion valve 3 flows into the evaporator coil 42 embedded in the cold water storage tank 4 to supply cold water during the day, but when there is no load, the cold water storage tank (4) can also be used as an ice storage tank. According to the use of the cold water, the solenoid valve (SV2) by operating the thermostat (TS2) the temperature sensed by the temperature sensor (S2) installed in the cold water outlet 91 of the cold water storage tank (4), if necessary Some of the refrigerant to the auxiliary evaporator 41 provided on the bypass pipe 7 by the control of the solenoid valve SV2 by the control of the pressure sensor P installed at the outlet of the evaporator coil 42. The flow rate was increased to increase the compression efficiency. The auxiliary evaporator 41 is also located in the auxiliary heat exchange chamber 10 together with the auxiliary condenser 21 to effectively use the installation space, and the heat exchange method of the auxiliary evaporator 41 is also performed by the fan 11. Air cooling method is used. In addition, the cold water heat exchanged in the cold water storage tank (4) is supplied to applications such as cooling, refrigeration or cold water supply by the cold water pump (2) installed in the cold water outlet (91), cold water that achieves the object is stored in cold water A separate cold water circulation system is returned to the tank (4) to obtain thermal energy again. In the cold and hot water supply refrigeration system, a check valve 6 is installed at the outlet of the auxiliary condenser 41 and the outlet of the evaporator coil 42, respectively, to prevent a relatively high pressure refrigerant from flowing back.

2 shows a system schematic diagram of a cold / hot water supply refrigerator according to another embodiment of the present invention, wherein the refrigerator is configured in the same manner as that of FIG. 1, and the constant temperature of the auxiliary condenser 21 and the auxiliary evaporator 41 is changed. More efficient heat exchange was performed by passing geothermal or ground water, and the heat energy obtained from the subcondenser 21 was provided back to the sub evaporator 41 to construct an effective refrigeration system that can increase the compression efficiency of the compressor. The high temperature and high pressure refrigerant gas discharged by the compressor 1 flows into the condenser coil 22. The condenser coil 22 is embedded in the hot water storage tank 2 filled with hot water to exchange heat with the hot water. And hot water obtained with thermal energy is supplied by the hot water pump 51 to achieve the purpose of heating, hot water supply or hot water supply. In addition, the hot water achieving the above object forms a separate hot water circulation system introduced into the hot water storage tank (2) again. The condenser coil 22 is equipped with a temperature sensor (S1) detects the temperature of the coolant liquid of the medium temperature and high pressure heat exchanged from the hot water storage tank (2), if the set temperature is higher than the operation of the thermostat (TS1) The solenoid valve SV1 is opened and closed to allow the refrigerant liquid to flow to the auxiliary condenser 21 on the bypass pipe 7 to perform primary heat exchange with geothermal or ground water at constant temperature. The low temperature and high pressure refrigerant liquid passing through the auxiliary condenser 21 undergoes throttle expansion while passing through the expansion valve 3, and changes into a low temperature low pressure gas vapor and flows into the evaporator coil 42. The evaporator coil 42 is also internal to the cold water storage tank 4 filled with cold water to take heat energy from the cold water to generate cold water of low temperature necessary for cooling or refrigeration by cooling the cold water by evaporation latent heat, and the cold water pump According to (52), it consists of a separate cold water circulation system for supplying each element for the purpose of cooling, refrigeration and cold water supply. The pressure sensor P installed at the outlet side of the evaporator coil 42 and the temperature sensor S2 installed at the outlet side of the cold water storage tank have a low temperature due to the temperature of the cold water storage tank 4 being too low, A large number of solenoid valves formed on the bypass pipe 7 when the outlet pressure of the evaporator coil 42 falls below a predetermined pressure or the temperature of the outlet of the cold water storage tank 4 falls below a predetermined temperature. (SV2) was opened to transfer the low-temperature low-pressure gas refrigerant to the auxiliary evaporator 41 to prevent the pressure of the refrigerant flowing into the compressor 1 from being too low. On the other hand, the low-temperature low-pressure refrigerant gas introduced into the auxiliary condenser 21 is the geothermal or ground water of the constant temperature absorbed thermal energy from the auxiliary evaporator 41 flows into the auxiliary evaporator 41 to perform secondary heat exchange, The low pressure refrigerant gas was converted into a state of low and medium temperature, and sent to the compressor 1 to increase the freezing effect.

As described above, the present invention installs a hot water storage tank and a cold water storage tank to supply hot water and cold water using heat energy generated during conventional condensation and evaporation, thereby supplying the heat energy for heating, cooling, hot water, refrigerating, hot water and cold water. In order to solve the imbalance of heat energy sorghum of condenser and evaporator at the time when the usage amount is low in the cold and hot water supply, a bypass pipe is formed at the condenser coil outlet and the expansion valve outlet, and the temperature is used. And supplying a cold / hot water supply refrigerator capable of maintaining the energy balance and improving the performance of the refrigerator by adjusting the flow according to the pressure, and placing the auxiliary condenser and the auxiliary evaporator in one auxiliary heat exchange room, To enable normal operation The.

Claims (2)

Compressor 1; Condenser coil 22; In the refrigeration system formed by sequentially arranging the expansion valve (3) and the evaporator coil (42), By embedding the condenser coil 22 in a sealed hot water tank, the hot water storage tank 2 for supplying hot water by heat exchange between high temperature refrigerant and heating water and the evaporator coil 42 are embedded in a closed cold water tank. Cold water storage tank 4 for supplying the cold water by the heat exchange between the refrigerant and cooling water of the By controlling the solenoid valve SV1 operated by the temperature sensor S1 at the outlet of the condenser coil 22, the condenser coil 22 and the expansion valve are made to bypass the high temperature refrigerant gas to the auxiliary condenser 21. The bypass pipe (7) is formed between (3), By controlling the solenoid valve SV2 operated by the temperature sensor S2 at the outlet of the cold water storage tank 4 and the pressure sensor P at the outlet of the evaporator coil 42, the refrigerant gas below a predetermined temperature or pressure is supplied. Bypass piping 7 is formed between the expansion valve 3 and the compressor 1 so as to bypass the secondary evaporator 41, The auxiliary condenser 21 and the auxiliary evaporator 41 are installed together in one auxiliary heat exchange chamber 10 and between the auxiliary condenser 21 and the auxiliary evaporator 41 to perform heat exchange by condensation and evaporation. Cold and hot water supply refrigerator, characterized in that the fan 11 which is a heat exchange means interposed therebetween. The method of claim 1, Geothermal heat or ground water of constant temperature is used as a heat exchange means of the auxiliary condenser 21 and the auxiliary evaporator 41, and the heat is generated by condensation and evaporation by passing it through the auxiliary condenser 21 and the auxiliary evaporator 41. Cold and hot water supply freezer characterized in that.