KR200339347Y1 - Hybrid heat pump using air heat and water heat - Google Patents

Abstract

The present invention relates to a hybrid heat pump using air heat and a heat source.

In particular, an evaporator for recovering heat by heat-exchanging the heat medium and high temperature wastewater, and an evaporation coil for heat exchange with the heat medium by air heat are connected to the compressor, and the heat medium and cold water introduced through the condenser are heat-exchanged. It is configured to regulate the flow of the heat medium through the valve.

Accordingly, the heat medium and heat exchange are performed by using the waste heat water discharged from the air heat and the factory, respectively, thereby greatly reducing the energy use cost and increasing the mechanical efficiency.

Description

HYBRID HEAT PUMP USING AIR HEAT AND WATER HEAT}

The present invention relates to a hybrid heat pump using air heat and a heat source, an evaporator for exchanging heat medium and high temperature wastewater, a compressor for compressing the heat medium passing through the evaporator, and a condenser for discharging hot water through heat exchange with the heat medium. And, an expansion valve for depressurizing (throttling) the heat medium at low temperature and low pressure, a receiver for temporarily storing the heat medium, a four-way valve for regulating the flow of the heat medium, and a fluid receiver and 4 for heat exchange with the heat medium by air heat. Consists of evaporation coils connected between the way valves, during the daytime heat exchange with the heat medium using waste hot water, and heat heat with the heat medium during the night time by using heat of the air to increase energy efficiency air heat and water heat It relates to a hybrid heat pump using a circle.

In general, a heat pump means a device capable of moving heat from a low temperature to a high temperature. The structure and operation of a cycle are the same as those of a freezer. In the case of using high temperature heat, it becomes a heat pump.

Heat pumps are classified into compression type, chemical formula, absorption type, and absorption type according to the principle of absorbing heat and dissipating heat. Among them, the type of heat pump is a compression type heat pump. For example, in the case of air conditioning for cooling purposes, heat is absorbed by the heat exchanger of the indoor unit installed indoors, and heat is radiated using the heat exchanger of the outdoor unit installed outdoors. On the contrary, the heat pump absorbs heat from the heat exchanger of the outdoor unit. The heat is radiated using the heat exchanger of the indoor unit installed in the.

The basic components of the heat pump cycle are divided into four elements: the evaporator, the low temperature heat exchanger, the condenser, the expansion valve, and the expansion valve. In addition, the low temperature low pressure wet steam heat medium absorbs the heat of evaporation from the surroundings as it is evaporated in the evaporator and is discharged into the low temperature low pressure dry saturated heat medium. The heat medium in the low temperature and low pressure dry saturated vapor state discharged from the evaporator is adiabatically compressed in the compressor and becomes a heat medium in the high temperature and high pressure superheated steam state and flows into the condenser.

Then, the heat medium of the high temperature and high pressure superheated steam introduced into the condenser releases the heat of condensation and becomes the heat medium of the saturated liquid state of the high temperature and high pressure and flows into the expansion valve. In addition, the heat medium in the high temperature and high pressure saturated liquid state is adiabatic expansion in the expansion valve and flows into the evaporator into the heat medium in the low temperature and low pressure wet steam state.

In addition, the evaporator, which is a low temperature heat exchanger, is installed outdoors to absorb heat from the surroundings, and the high temperature condenser is installed indoors to release heat to the surroundings for use in heating.

On the other hand, in bathhouses and factories, the waste water of about 30-40 ℃ is used as it is, which consumes enormous thermal energy.In addition, when high temperature waste water is leaked out, it is impossible to grow microorganisms to purify water. In order to solve this problem, a heat pump using waste heat of domestic wastewater as a heat source or a plurality of geothermal heat exchange pipes buried in the ground is used to solve the problems. The heat pump using the waste water as a heat source uses the waste heat of the domestic wastewater discharged from public baths or factories with the waste heat as a heat source of the heat pump evaporator, and produces hot water through a condenser to supply hot water. It is composed.

However, in such a heat pump using waste heat, a heat source is not supplied at a time such as dawn or late night when waste water is not provided, such that heat exchange using a heat source such as waste water is not properly performed.

The purpose of the present invention for improving this is to provide a hybrid heat pump using air heat and water heat source to increase the mechanical efficiency of the heat pump by the heat exchange of the heat pump continuously using the waste water heat and air heat.

1 is a block diagram showing a hybrid heat pump using air heat and water heat sources according to the present invention.

Figure 2 is a block diagram showing a hybrid heat pump using the air heat and water heat source according to another embodiment of the present invention.

<Code Description of Main Parts of Drawing>

100 ... Evaporator 200 ... Compressor

300 ... condenser 400 ... expansion valve

500 ... Receiver 600 ... 4 Way Valve

700 ... Supercooling Unit

In order to achieve the above object, the present invention is an evaporator for recovering heat by heat-exchanging the introduced heat medium and the high temperature wastewater introduced; A compressor for compressing the heat medium passing through the evaporator to a high temperature and a high pressure; A condenser for dissipating hot water by heat-exchanging cold water introduced through a high temperature and high pressure heat medium passing through the compressor and a feed water pump; An expansion valve for reducing (throwing) the pressure and temperature of the heat medium to low temperature and low pressure; A receiver for temporarily storing the heat medium in the liquid state passing through the condenser; 4-way valve for controlling the flow of the heat medium from the compressor; It consists of a configuration including an evaporation coil connected between the receiver and the four-way valve to heat exchange with the heat medium by the air heat.

In addition, preferably between the condenser and the receiver, the temperature of the heat medium is lowered to further cool the supercooling device to be cooled to a low temperature heat medium.

In addition, the evaporator may be further used for a day in which wastewater heat is supplied, and the evaporator coil may be further provided with a timer device alternately connected for a predetermined time so as to be used at night time when wastewater heat is not supplied.

First, in the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The following terms are terms set in consideration of functions in the present invention, which may vary depending on the intention or custom of the producer, and the definitions should be made based on the contents throughout the present specification.

Hereinafter, the technical configuration of the present invention in detail according to the accompanying drawings.

The present invention, as shown in Figure 1, the heat exchanged heat medium and waste water largely introduced, the evaporator 100 for recovering heat, the compressor 200 for compressing the heat medium to high temperature and high pressure, and the cold water introduced into the heat medium and The condenser 300 for discharging hot water by heat exchange, the expansion valve 400 for depressurizing (throwing) the heat medium at low temperature and low pressure, the receiver 500 temporarily storing the heat medium, and the heat medium from the compressor 200. Four-way valve 600 for controlling the flow of, and the evaporation coil (100 ') heat exchange is made by the heat of air.

The evaporator 100 is configured to exchange heat with the heat medium by high temperature wastewater or geothermal heat generated in a bathroom or factory so that the heat exchange efficiency is increased.

In addition, the compressor 200 is a device that absorbs heat from the evaporator 100 and sucks the heat medium which becomes a gas and compresses it in an easy state at room temperature. The compressor 200 is connected to the outlet side of the evaporator 100 to obtain a high temperature and high pressure. Multiple compression units are installed.

For example, the heat medium introduced into the compressor 200 is compressed to high temperature and high pressure by the compressor 200, and the condenser 300 is connected to one side of the compressor 200 to heat exchange the high temperature and high pressure heat medium.

The condenser 300 discharges hot water by heat exchange with cold water introduced through a feed water pump while passing through a heat medium compressed at high temperature and high pressure, and may store hot water in a heat storage tank (not shown).

In addition, as shown in Figure 2, between the condenser 300 and the receiver 500, by lowering the temperature of the heat medium is further provided with a supercooling device 700 to cool to a low temperature heat medium, the expansion valve of the heat medium After moving to the furnace, it is possible to prevent the non-condensing gas and to increase the expansion efficiency of the expansion valve.

In addition, one side of the condenser 300 is integrally connected to the receiver 500 for temporarily storing or recovering the heat medium while liquefying the heat medium passing through the condenser 300, the receiver 500 is a condenser ( In 300), the liquefied heat medium is temporarily stored, and when stopped, the heat medium is recovered and stored.

In addition, the expansion valve 400 is installed between the receiver 500 and the evaporator 100 as a pressure reducing device for receiving the liquid heat medium passing through the filter 510 and converting the liquid medium into low temperature and low pressure by the throttling action. It is made of a configuration that can control the flow of the heat medium from the compressor 200 through the four-way valve 600.

On the other hand, between the receiver 500 and the four-way valve 600, the evaporation coil 100 'is provided with an expansion valve 400' so as to exchange heat between the air heat and the heat medium.

That is, during the day in which a heat source such as waste water is supplied by the control of the four-way valve 600, the heat exchange is performed through the heat source in connection with the evaporator 100, and the air heat at night is difficult to supply the heat source. It is connected to the evaporation coil (100 ') that can be heat exchanged by the use of hot water at night and by heat storage in the heat storage tank by the heat of air can be used in the morning.

Referring to the operation of the present invention made of such a configuration as follows.

First, after the heat medium is changed to a state of high temperature and high pressure in a plurality of compressors 200, the heat medium of high temperature and high pressure passes through the oil separator 210 and the four-way valve 600 to be introduced into the condenser 300.

The cold water of the low temperature introduced through the pump in the condenser 300 is heat-exchanged with the heat medium of the high temperature and high pressure to accumulate in the heat storage tank or hot water is supplied to the room.

In addition, the heat medium discharged from the condenser 300 is introduced into the receiver 500 through the accumulator 220. When the temperature of the hot water is high by the heat storage tank, the heat medium is condensed in the expansion valve properly. The heat medium may be passed through the supercooling device 700 provided between the accumulator 220 and the receiver 500 to prevent it from being supported.

Subsequently, the heat medium changed into a liquid state by heat exchange with cold water through the condenser 300 is temporarily stored in the receiver 500 and then passes through the filter 510.

When the heat medium passing through the filter 510 is heat-exchanged by the waste heat source, the heat medium is introduced into the evaporator 100. In the evaporator 100, the heat medium is discharged from a bathroom or a factory by a pump. The high temperature wastewater of about -35 ° C flows in, and the heat medium circulating with the high temperature waste water exchanges heat, and the heat medium in the low temperature and low pressure state in the liquid phase is changed to the dry saturated vapor state at the low temperature and low pressure, and then passes through the accumulator again to the compressor (200). Will be moved to).

On the other hand, when the heat medium passing through the filter 510 is to be heat exchanged by the heat of air, the valve is adjusted to flow into the evaporation coil (100 ') connected between the filter 510 and the four-way valve 600. In the evaporation coil 100 ′, after the heat exchange with the heat medium is performed by air, the evaporation coil 100 ′ passes through the four-way valve 600 and moves to the compressor 200.

As described above, the present invention improves energy efficiency by improving the performance of heating / heating or hot water supply by heat exchange between the heat medium and the heat medium by using the waste water heat source and the air heat source according to the time determined by the timer, and the cost according to the waste heat recovery. There is an advantage to reduce.

Although the present invention has been shown and described with respect to specific embodiments, it has been found that the present invention can be variously modified and changed without departing from the spirit or the field of the present invention provided by the following Utility Model Registration Claims. I want to.

In this way, according to the present invention, the heat recovery with heat medium by using waste hot water flowing out of the bath or factory in the day time to ensure the effective heat recovery of waste heat recovery, and the heat exchange with the heat medium by using the heat of the air at night time In addition to increasing the mechanical efficiency of the heat pump, there is an effect that can significantly reduce the energy use cost.

Claims (3)

An evaporator 100 for recovering heat by heat-exchanging the introduced heat medium and the introduced high temperature wastewater, A compressor (200) for compressing the heat medium passing through the evaporator (100) at high temperature and high pressure; A condenser 300 for dissipating hot water by heat-exchanging the cold water introduced by the high temperature and high pressure heat medium and the feed water pump passing through the compressor 200; Expansion valve 400 for reducing (throwing) the pressure and temperature of the heat medium to low temperature, low pressure, A receiver 500 for temporarily storing the heat medium in the liquid state that has passed through the condenser 300, 4-way valve 600 for controlling the flow of the heat medium from the compressor 200, and Hybrid heat pump using an air heat and a heat source, characterized in that it comprises an evaporation coil (100 ') connected between the receiver 500 and the four-way valve 600 so that heat exchange with the heat medium by the heat of the air. According to claim 1, Between the condenser 300 and the receiver 500, the air heat and the heat source characterized in that the subcooler 700 is further provided to lower the temperature of the heat medium to cool to a low temperature heat medium Hybrid heat pump using. According to claim 1, wherein the evaporator 100 is used during the day when the wastewater heat is supplied, the evaporator coil (100 ') is a timer device for alternately connecting a predetermined time to be used at night time when the wastewater heat is not supplied Hybrid heat pump using air heat and water heat source, characterized in that further provided.