KR101013526B1 - A boiler-waste heat recovery hot-water generating device - Google Patents

Abstract

PURPOSE: A hot water generating device using boiler-waste heat recovery is provided to compensate the temperature of a heat source supply unit by collecting waste heat discharged from a flue of a boiler. CONSTITUTION: A hot water generating device using boiler-waste heat recovery comprises a cooling and heating cycle unit(20), a regenerating unit(30), a heat source supply unit(40), and waste heat converting units(50). In the cooling and heating cycle unit, a compressor(210), a condenser(220), an expansion valve(230), and an evaporator(240) form one cycle. The regenerating unit is connected to the boiler and condenser to produce hot water through heat exchange between a boiler and a condenser. The heat source supply unit supplies heat for vaporization of refrigerant through heat exchange. The heat source supply unit use outer water source as thermal medium. The waste heat converting unit is installed in the flue of the boiler.

Description

Boiler-Waste Heat Recovery Hot-water Generating Device

The present invention relates to a boiler waste heat recovery hot water generating device that can increase the energy efficiency by connecting the existing boiler and the hot water generating device, more specifically, in producing hot water using the boiler in conjunction with the hot water generating device of the boiler In addition to improving the efficiency of hot water production, it can be used to compensate the temperature of the heat source supply part of the hot water generator by recovering waste heat emitted from the flue of the boiler. When air in the air is used, the influence of the change in the air temperature can be minimized, or after the refrigerant circulating in the heating / cooling cycle part passes through the expansion valve and directly absorbs the waste heat of the boiler while passing through the waste heat exchange part. Partial vaporization can reduce the absorption of heat in the evaporator Depending on the consumption of air to be supplied to the evaporator is also reduced, which can increase the energy efficiency of the system, the waste heat recovery boiler hot water generating apparatus.

In general, a boiler is used to heat a building or facility. A boiler used to heat hot water consumes a lot of energy, and thus a large amount of hot water can be produced using less energy. Enhancing energy efficiency has become an important challenge.

In addition, the conventional hot water growth value is a system that can implement cooling and heating by changing the circulation direction of the refrigerant by using water or air as a heat source, referring to Figure 1, the conventional general hot water growth value compressor 210 The high-temperature, high-pressure gaseous refrigerant flowing out from the hot water is heated through heat exchange while passing through the condenser 220 and then converted into a liquid state, and changes to a low-temperature low-pressure liquid state while passing through the expansion valve 230. A refrigerant is phase-changed back to a gas state through heat exchange while passing through the evaporator 240. To this end, the hot water generating device requires a heat source of the heat source supply unit 40 capable of supplying heat from the evaporator 240. As a conventional heat source, a heat source method using ground water and air in the air are used. There is an air heat source method, but in the case of a hydrothermal source method, since the temperature of the ground water after passing through the evaporator 240 is rapidly lowered and cannot be reused, a large amount of water is consumed, such as having to supply new ground water again. There is a problem that can only be, and in the case of the air heat source method, there is a problem that a lot of deviation occurs in the function as a constant heat source according to the change in the atmospheric temperature in the atmosphere.

Therefore, the present invention has been made in view of the problem of the need for a new system that can be solved by integrating the problems of the existing boiler and the problems of the existing hot water generating device as described above.

The present invention has been made to solve the above problems,

An object of the present invention is to increase the efficiency of hot water production of the boiler by connecting the hot water generator in producing hot water using the boiler, as well as the temperature of the heat source supply unit of the hot water generator by recovering the waste heat emitted from the boiler's flue The boiler waste heat recovery hot water generator can reduce the consumption of water when water is used in the heat source supply and minimize the effects of air temperature change when air is used in the heat source supply. To provide.

Another object of the present invention to further compensate the temperature of the heat source of the heat source supply unit by using the heat of the refrigerant passing through the condenser to prevent waste of water (ground water, etc.) used as a heat source or to change the atmospheric temperature It is to provide a boiler waste heat recovery hot water generating device that can efficiently use air as a heat source.

Still another object of the present invention is to allow the refrigerant discharged from the condenser to selectively pass through or through the second heat exchange unit according to the temperature control state of the heat source supply unit, so that the boiler waste heat recovery hot water can adjust the vaporization temperature of the refrigerant in the evaporator. It is to provide a generator.

Another object of the present invention is to further compensate for the temperature of the heat source of the heat source supply unit by using the heat of the high-temperature refrigerant passing through the condenser of the separate air heat source hot water generating device water (ground water, etc.) It is to provide a boiler waste heat recovery hot water generating device that can prevent the waste of waste or efficiently use the air in the atmosphere as a heat source regardless of the change of the atmospheric temperature.

Still another object of the present invention is that the line branched from the heat storage unit receives heat while passing through the second heat exchange unit to further heat the hot water of the heat storage unit, as well as the heat source supply unit using the hot water produced in the heat storage unit. It is to provide a boiler waste heat recovery hot water generating device that can reduce the production cost and increase the energy efficiency by utilizing the hot water produced by itself without supplying a heat source or other external heat source of a separate external system.

Another object of the present invention is to reduce the amount of heat absorption in the evaporator by allowing the refrigerant circulating in the heating and cooling cycle portion to pass through the waste heat exchange part directly to absorb the waste heat of the boiler to pass through the expansion valve to vaporize the partial heat. Accordingly, the consumption of external air supplied to the evaporator is also reduced to provide a boiler waste heat recovery hot water generating device that can increase the energy efficiency of the system.

Boiler waste heat recovery hot water growth value for achieving the above object of the present invention includes the following configuration.

Boiler waste heat recovery hot water growth value according to an embodiment of the present invention and the heating and cooling cycle connected to the compressor, condenser, expansion valve, evaporator to form one cycle: connected to the boiler and condenser through the heat exchange with the boiler and condenser A heat storage unit for generating and supplying hot water; A heat source supply unit connected to the evaporator to supply heat required to vaporize the refrigerant through heat exchange with the evaporator, and having an external water source as a heat medium; A waste heat exchanger connected to the heat source supply unit and installed in the flue of the boiler to compensate the temperature by supplying waste heat discharged from the flue to the heat source supply unit; And the water source of the heat source supply unit receives heat transfer through the waste heat recovered by the waste heat exchanger to compensate for the temperature of the heat source supply unit.

According to another embodiment of the present invention, the boiler waste heat recovery hot water growth growth value according to the present invention further includes a second heat exchanger between the condenser and the expansion valve, and the line branched from the heat source supply unit passes through the second heat exchanger. While receiving the heat is characterized in that the temperature of the heat source supply can be compensated.

According to another embodiment of the present invention, the boiler waste heat recovery hot water growth value according to the present invention is branched between the condenser and the second heat exchange unit is connected between the second heat exchange unit and the expansion valve bypass line having a selection valve By further comprising, it is possible to prevent the refrigerant discharged from the condenser selectively go through or through the second heat exchange unit in accordance with the temperature control state of the heat source supply unit to adjust the vaporization temperature of the refrigerant in the evaporator. It is done.

According to another embodiment of the present invention, the boiler waste heat recovery hot water growth growth value according to the present invention is connected to the line branched from the heat source supply unit in parallel with the condenser of the separate air heat source hot water generating device temperature of the heat source supply unit through heat exchange Characterized in that can be rewarded.

According to another embodiment of the present invention, the boiler waste heat recovery hot water generating apparatus according to the present invention, the condenser is located in the heat accumulator, and further comprising a second heat exchanger between the condenser and the expansion valve, The branched line may be supplied with heat while passing through the second heat exchanger to further heat the hot water of the heat storage unit.

According to still another embodiment of the present invention, the boiler waste heat recovery hot water growth value according to the present invention is branched between the second heat exchange part and the heat storage part is connected to the line branched from the heat source supply part, the second having a selection valve By further including a bypass line, it is possible to compensate the temperature of the heat source supply unit by the heat storage unit.

Boiler waste heat recovery hot water growth value according to another embodiment of the present invention and the heating and cooling cycle unit connected to the compressor, condenser, expansion valve, evaporator to form a cycle: connected to the boiler and condenser to exchange heat with the boiler and condenser A heat storage unit for generating and supplying hot water; A waste heat exchanger connected between the expansion valve and the evaporator and installed in the flue of the boiler to recover waste heat discharged from the flue of the boiler; And the refrigerant flows out through the expansion valve and flows into the waste heat exchange unit, and receives heat transfer from the waste heat exchange unit and flows into the evaporator in a partially evaporated state. By evaporating the remaining refrigerant not vaporized through the heat transfer of characterized in that the refrigerant can be vaporized even in a small amount of outdoor air.

According to another embodiment of the present invention, the boiler waste heat recovery hot water generating apparatus according to the present invention further comprises a second heat exchanger between the condenser and the expansion valve, the branch branched from the evaporator passes through the second heat exchanger While receiving the heat is characterized in that the temperature of the outside air can be compensated.

According to another embodiment of the present invention, the boiler waste heat recovery hot water growth value according to the present invention is branched between the condenser and the second heat exchange unit is connected between the second heat exchange unit and the expansion valve bypass line having a selection valve By further comprising, it is possible to prevent the refrigerant discharged from the condenser selectively go through or through the second heat exchange unit in accordance with the temperature of the outside air of the evaporator to adjust the vaporization temperature of the refrigerant in the evaporator It is done.

According to another embodiment of the present invention, the boiler waste heat recovery hot water growth growth value according to the present invention is connected to the line branched from the evaporator in parallel with the condenser of the air heat source hot water generating device can be compensated for the temperature of the outside air through heat exchange It is characterized by being.

The present invention can achieve the following effects by the configuration, combination, and use relationship described above with the present embodiment.

The present invention can improve the hot water production efficiency of the boiler by connecting the hot water generating device in producing hot water using the boiler, as well as recover the waste heat emitted from the boiler's flue to compensate the temperature of the heat source supply unit of the hot water generating device. It can be used to reduce the consumption of water when water is used in the heat source supply unit, and has the effect of minimizing the effect of atmospheric temperature change when air in the air is used in the heat source supply unit.

The present invention can further compensate the temperature of the heat source of the heat source supply unit by using the heat of the refrigerant passing through the condenser to prevent waste of water (ground water, etc.) used as the heat source or to maintain air regardless of the change in the atmospheric temperature. It has an effect that can be used efficiently as a heat source.

According to the present invention, the refrigerant discharged from the condenser may be selectively or not passed through the second heat exchange unit according to the temperature control state of the heat source supply unit, thereby controlling the vaporization temperature of the refrigerant in the evaporator.

The present invention can be further compensated for the temperature of the heat source of the heat source supply unit by using the heat of the high-temperature refrigerant passing through the condenser of the separate air heat source hot water generator to prevent waste of water (ground water, etc.) used as a heat source In addition, regardless of the change in the atmospheric temperature, the air in the atmosphere can be used efficiently as a heat source.

According to the present invention, the line branched from the heat storage unit receives heat while passing through the second heat exchange unit to further heat the hot water of the heat storage unit, and compensates the temperature of the heat source supply unit using the hot water produced in the heat storage unit. By making it possible, it is possible to reduce production costs and increase energy efficiency by utilizing hot water produced by itself without supplying a heat source or other external heat source of a separate external system.

According to the present invention, after the refrigerant circulating in the heating / cooling cycle part passes through the expansion valve and directly passes through the waste heat exchange part, the waste heat of the boiler can be absorbed and partially vaporized, thereby reducing the amount of heat absorbed by the evaporator. The consumption of external air supplied to the evaporator is also reduced, thereby increasing the energy efficiency of the system.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the boiler waste heat recovery hot water generating apparatus according to the present invention will be described in detail.

2 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to an embodiment of the present invention, Figure 3 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to another embodiment of the present invention, 4 to 6 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to another embodiment of the present invention, Figure 7 schematically shows a boiler waste heat recovery hot water generating apparatus according to another embodiment of the present invention 8 to 10 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to another embodiment of the present invention.

Referring to Figure 2, the boiler waste heat recovery hot water growth growth value according to an embodiment of the present invention, the compressor 210, the condenser 220, the expansion valve 230, the evaporator 240 is installed to form a cycle heating and heating A cycle unit 20 and a heat storage unit 30 connected to the boiler 10 and the condenser 220 to generate hot water through heat exchange with the boiler 10 and the condenser 220; A heat source supply unit 40 connected to the evaporator 240 to supply heat necessary for vaporizing the refrigerant through heat exchange with the evaporator 240 and having an external water source as a heat medium; Waste heat exchanger 50, which is installed in the flue 110 of the boiler 10 and connected to the heat source supply part 40, compensates the temperature by supplying the waste heat discharged from the flue 110 to the heat source supply part 40. To; And the source of the heat source supply unit may receive heat transfer through the waste heat recovered by the waste heat exchanger to compensate for the temperature of the heat source supply unit.

The boiler 10 is a heating device for producing hot water for the purpose of heating, and the like is heated using oil or gas. In the present invention, in the production of hot water using the boiler 10 can increase the hot water production efficiency of the boiler by connecting the hot water generating device, as well as the flue 110 of the boiler 10, which is smoke or heat generated from the boiler Waste heat discharged from the heat source supply part of the hot water generator can be used to compensate the temperature of the heat source supply part of the hot water generating device. There is a technical feature to provide a system that can minimize the effects of air temperature changes when air is used.

The cooling and heating cycle unit 20 is for heating or cooling through heat exchange with the surroundings in the process of the refrigerant circulating the compressor 210, the condenser 220, expansion valve 230 and the evaporator 240 in one cycle It can be used as a configuration. The compressor 210, the condenser 220, the expansion valve 230 and the evaporator 240 constituting the basic cycle of the heating and cooling cycle 20 are conventionally used components, the basic description of this is In order not to obscure the core, the heat exchange in the process of circulating the compressor 210, the condenser 220, the expansion valve 230 and the evaporator 240 is also omitted in the prior art bar. Do it.

The heat storage unit 30 is connected to the boiler 10 and the condenser 220, respectively, to produce and supply hot water through heat exchange with the boiler 10 and the condenser 220, to accommodate hot water, such as a storage tank. Can be utilized. Conventionally, the heat storage unit 30 supplies hot water produced using heat generated from the boiler 10, and when using only the boiler 10 to produce hot water of the heat storage unit 30, the boiler ( The heat to be consumed in 10) is increased to decrease the efficiency of the boiler 10 and increase the production cost. Therefore, in the present invention, the boiler 10 by allowing the hot water of the heat storage unit 30 to be additionally supplied with heat transferred from the condenser 220 of the cooling / heating cycle unit 20 in addition to the boiler 10. In addition to increasing the efficiency of the system, production costs can also be reduced. Referring to this in more detail with reference to Figure 2, the heat storage unit 30 forms a separate branching line 31 in addition to the inflow and outflow of the boiler 10, the line 31 is the air-conditioning It is connected to the condenser 220 of the cycle unit 20 in parallel. In this case, the high-temperature, high-pressure gaseous refrigerant flowing out of the compressor 210 (the temperature of the refrigerant is about 85 ° C. to 90 ° C.) passes through the condenser 220 and lines 31 of the heat storage unit 30. Heat exchange is performed to transfer heat to the heat sink. Thus, hot water is produced or heated in the line 31 and is recovered to the heat storage unit 30.

The heat source supply unit 40 is connected to the evaporator 240 to supply heat necessary for vaporizing the refrigerant through heat exchange with the evaporator 240, and heats the evaporator 240 through the heat source supply unit 40. As a heat source for supplying water, a water source (usually groundwater or tap water is used) or outdoor air (usually atmospheric air is used) is used. When water is used as a heat source, water used as a heat source drops rapidly and is reused. Since this is not possible, there is a problem of consuming a large amount of water such as groundwater used as a heat source, and when using the air in the air as a heat source, there is a problem that the efficiency as a heat source fluctuates significantly according to the change of the atmospheric temperature. In the present invention, the temperature of the heat source (that is, the water source or the outside air) of the heat source supply unit 40 is compensated by recovering the waste heat discharged through the flue 110 of the boiler 10 By making it possible, water (groundwater) used as a heat source can be reused many times, which can drastically reduce water consumption.If air is used as a heat source, it can maintain a constant temperature despite the change of atmospheric temperature. Therefore, the functional efficiency as a heat source can be improved. Since the compensation of the heat source temperature of the heat source supply unit 40 is made in the waste heat exchange unit 50, it will be described below.

The waste heat exchange unit 50 is installed in the flue 110 of the boiler 10 to compensate for the temperature of the heat source supply unit 40 through heat exchange with waste heat emitted from the flue 110, FIG. 2. A line 41 branched from the heat source supply unit 40 is connected to the waste heat exchange unit 50 installed in the flue 110 of the boiler 10, as shown in FIG. After the heat source (water source or outside air) leaked through the line 41 passes through the waste heat exchange unit 50, the heat is absorbed from the waste heat of the boiler discharged through the flue 110 of the boiler 10. By recovering the heat source supply unit 40 again, the heat source temperature of the heat source supply unit 40 is compensated. In more detail, the heat source (water source or outside air) introduced into the heat source supply unit 40 emits heat while passing through the evaporator 240 through a line 42 connected to the evaporator 240 so that the temperature is high. In this case, the waste heat of the boiler is absorbed while passing through the waste heat exchange unit 50 through a line 41 connected to the waste heat exchange unit 50 to receive a temperature compensation, and thus a new heat source (water source). Or it can be reused without the supply of outside air to reduce the waste of the heat source, as well as to maintain a constant temperature of the heat source.

The boiler waste heat recovery hot water growth value according to an embodiment of the present invention as described above can produce hot water by connecting the boiler and the condenser of the heating and cooling cycle, thereby improving the efficiency of the boiler and reducing the production cost, as well as recovering the waste heat of the boiler. By compensating for the temperature of the heat source supply unit, it is possible to prevent waste of water (ground water, etc.) used as a heat source or to efficiently use air as a heat source regardless of the change in the atmospheric temperature.

3, the boiler waste heat recovery hot water growth value according to another embodiment of the present invention further includes a second heat exchanger 60 between the condenser 220 and the expansion valve 230, the heat source supply unit The line branched at 40 may receive heat while passing through the second heat exchanger 60 to compensate for the temperature of the heat source supply unit 40.

The second heat exchange unit 60 is configured to compensate for the temperature of the heat source of the heat source supply unit 40 by using the heat of the refrigerant passing through the condenser 220, as shown in FIG. The line 21 of the refrigerant passing through the condenser 220 and the line 43 branched from the line 42 connected to the evaporator 240 in the heat source supply unit 40 are connected in parallel to each other to heat the refrigerant. The supply of the heat source 40 is compensated for the temperature of the heat source. In detail, the high-temperature, high-pressure gaseous refrigerant flowing out of the compressor 210 (the temperature of the refrigerant is about 85 ° C. to 90 ° C.) passes through the condenser 220 to heat transfer to the heat storage unit 30. Even though the temperature is usually maintained at about 54 ℃ ~ 57 ℃ bar, in the present invention using the heat source of the refrigerant after passing through the condenser 220 as described above, the heat source (water source or outside air of the heat source supply unit 40) The line branched from the line 21 of the refrigerant passing through the condenser 220 and the line 42 connected to the evaporator 240 in the heat source supply unit 40 to further compensate the temperature of After the second heat exchanger 60 is formed in parallel with each other, the second heat exchanger 60 passes through the evaporator 240, and then the temperature of the heat source 40 is rapidly reduced. The heat source by compensating through heat exchange at It can be recovered to the unit 40 to enable reuse of the heat source and maintain a constant temperature. In this case, as shown in FIG. 3, an on / off valve 421 (usually a 3-way type valve) is formed at a point at which the line 43 branches from the line 42 connected to the evaporator 240 in the heat source supply part 40. Is formed to adjust the opening and closing of the line according to the temperature control state of the heat source supply unit 40 so that the heat source passing through the evaporator 240 in the heat source supply unit 40 passes or passes through the second heat exchange unit 60. It can be adjusted so as not to.

As such, the boiler waste heat recovery hot water growth value further including the second heat exchange part 60 further compensates the temperature of the heat source of the heat source supply part 40 by using the heat of the refrigerant passing through the condenser 220. It is possible to prevent waste of water (groundwater, etc.) used as a heat source, or to efficiently use air as a heat source regardless of changes in atmospheric temperature.

Referring to FIG. 4, the boiler waste heat recovery hot water growth growth value according to another embodiment of the present invention is branched between the condenser 220 and the second heat exchange part 60 to expand the second heat exchange part 60 and the expansion valve. By further including a bypass line 22 connected between the 230 and having a selection valve 221, the refrigerant discharged from the condenser 220 selectively according to the temperature control state of the heat source supply unit 40 The second heat exchanger 60 may be passed or not to pass through, so that the vaporization temperature of the refrigerant in the evaporator 240 may be adjusted.

The bypass line 22 is branched before the second heat exchange part 60 in the line 21 of the refrigerant passing through the condenser 220 as shown in FIG. 4 and the second heat exchange part 60. The line is connected between the expansion valve 230, the configuration so that the refrigerant passing through the condenser 220 can be adjusted so as not to pass or pass through the second heat exchange unit (60). To this end, a separate selection valve (221, which is also a conventional 3-WAY type valve) is formed on the bypass line 22 to control the opening and closing of the refrigerant passing through the condenser 220 to the second heat exchange. It is possible to selectively adjust so as not to pass through the portion 60 or the second heat exchanger 60 through the bypass line 22. The criterion for selecting the refrigerant passing through the condenser 220 not to pass through or through the second heat exchanger 60 is a temperature control state of the heat source supply unit 40, that is, the temperature of the heat source supply unit 40 is too high. Low temperature is determined depending on the need for additional temperature compensation through the second heat exchanger 60 and when it is not, and the refrigerant passing through the condenser 220 does not pass through or pass through the second heat exchanger 60. If not, the vaporization temperature of the refrigerant in the evaporator 240 can also be adjusted.

Referring to Figure 5, the boiler waste heat recovery hot water growth growth value according to another embodiment of the present invention is a condenser (a) of the line 42 branched from the heat source supply unit 40 is a separate air heat source hot water generating device (A) ) Is connected in parallel to the heat source supply unit 40 is compensated for by the heat exchange.

The condenser (a) of the air heat source hot water generating device (A) refers to a condenser of a separate hot air generating device (with air as a heat source) in addition to the air-conditioning cycle unit 20, and generates a separate air heat source hot water. Using the heat emitted from the condenser (a) of the device (A) to form a system to be compensated for the temperature of the heat source supply (40). That is, as shown in FIG. 5, the line 42 branched from the heat source supply unit 40 to be connected to the evaporator 240 passes through the evaporator 240, and then the condenser of the air heat source hot water generator A is formed. When formed to be connected in parallel with the a) the heat source (water source or outside air) of the heat source supply unit 40 is rapidly dropped after passing through the evaporator 240 to supply heat (compensation) through the condenser (a) It is received by the heat source supply unit 40 is recovered.

As such, the line 42 branched from the heat source supply unit 40 is connected to the condenser a of the separate air heat source hot water generating device A in parallel to form a heat exchanger for the boiler waste heat recovery hot water. By using the heat of the high temperature refrigerant passing through the condenser (a) can be further compensated for the temperature of the heat source of the heat source supply unit 40 to prevent waste of water (ground water, etc.) used as a heat source or Regardless of the change, the air in the atmosphere can be efficiently used as a heat source.

Referring to FIG. 6, the boiler waste heat recovery hot water growth growth value according to another embodiment of the present invention is the condenser 220 is located in the heat storage unit 30, and between the condenser 220 and the expansion valve 230. Further comprising a second heat exchanger 60, the line 32 branched from the heat storage unit 30 receives heat while passing through the second heat exchange unit 60 receives the hot water of the heat storage unit 30. It can be heated further.

As described above, the condenser 220 constitutes a cooling / heating cycle part 20. In this embodiment, the condenser 220 is positioned in the heat storage part 30 unlike the other embodiments. The temperature of the refrigerant passing through 220 is about 85 ° C. to 90 ° C. as described above to directly heat water in the heat storage unit 30 to generate hot water or to maintain the temperature of the hot water above a predetermined temperature. .

In addition, the refrigerant passing through the condenser 220 is the second heat exchanger 60 formed between the condenser 220 and the expansion valve 230, which is the same configuration as the second heat exchanger 60 described above, and thus, a detailed description thereof will be omitted. (The temperature of the refrigerant is usually about 54 ℃ ~ 57 ℃ as described above), the line 32 branched from the heat storage unit 30 is further and the second heat exchange unit 60 and By being connected in parallel it is possible to further heat the water of the heat storage unit 30 by using the heat of the refrigerant passing through the second heat exchange unit (60). In this case, the bypass line 22 branched before the second heat exchange part 60 in the line 21 of the refrigerant passing through the condenser 220 and connected between the second heat exchange part 60 and the expansion valve 230. ) May be additionally formed to adjust the refrigerant passing through the condenser 220 so as not to pass through or pass through the second heat exchanger 60, wherein the bypass line 22 and the selection valve 221 Since the configuration is the same as described above, a detailed description thereof will be omitted to avoid overlapping.

In addition, the line 32 branched from the heat storage unit 30 passes through the second heat exchange unit 60 and then branches between the second heat exchange unit 60 and the heat storage unit 30 to supply the heat source supply unit 40. It may further include a second bypass line (33) connected to the line (42) branched from the valve having a selector valve (331), which is produced in the heat storage unit (30) and the second heat exchange unit ( This is to directly compensate the temperature of the heat source (water) of the heat source supply unit 40 by using hot water heated through the 60. That is, the heated hot water of the line 32 branched from the heat storage unit 30 and passed through the second heat exchange unit 60 is branched separately from the heat storage unit 30 instead of being recovered to the heat storage unit 30. The heat source supply unit 40 of the heat source supply unit 40 of which the temperature is lowered while passing through the evaporator 240 is supplied directly to the heat source supply unit 40 through the second bypass line 33 connected to the branched line 42. Temperature can be compensated. To this end, the second bypass line 33 is provided with a separate selection valve 331 that can control the opening and closing of the line, which is also a conventional 3-way type valve, to adjust the moving direction of hot water (in this case, , The selection criteria for determining the opening and closing of the selection valve 331 is normally the temperature control state of the heat source supply unit 40). By using the hot water produced in the heat storage unit 30 as described above to compensate the temperature of the heat source supply unit 40 by utilizing the hot water produced by itself without the supply of heat sources or other external heat source of a separate external system It can reduce production cost and increase energy efficiency.

Referring to FIG. 7, the boiler waste heat recovery hot water growing value according to another embodiment of the present invention is installed such that the compressor 210, the condenser 220, the expansion valve 230, and the evaporator 240 form one cycle. Cooling and heating cycle unit 20 and: the heat storage unit 30 is connected to the boiler 10 and the condenser 220 to generate hot water through heat exchange with the boiler 10 and the condenser 220; A waste heat exchanger (50 ') connected between the expansion valve (230) and the evaporator (240) and installed in the flue (110) of the boiler (10) to recover waste heat discharged from the flue (110); It includes, the refrigerant circulating the cooling and heating cycle unit 20 flows out through the expansion valve 230 flows into the waste heat exchange unit 50 'and receives heat transfer from the waste heat exchange unit 50' partially In the evaporated state, the evaporator 240 is introduced into the evaporator 240. The evaporator 240 may evaporate the refrigerant even in a small amount of outdoor air by evaporating the remaining refrigerant which is not evaporated through heat transfer with the introduced refrigerant. It is characterized by being. Hereinafter, descriptions of components overlapping with the above-described components will be omitted, and descriptions will be given based on components having a difference.

In this embodiment, the low-temperature, low-pressure liquid refrigerant passing through the expansion valve 230 passes directly through the waste heat exchange unit 50 '. The waste heat exchange unit 50' is a waste heat exchange unit described above ( Similarly to 50, the configuration is such that the waste heat of the boiler discharged through the flue 110 is located on the flue 110 of the boiler 10. Therefore, while the refrigerant passing through the expansion valve 230 passes through the waste heat exchange unit 50 ′, the waste heat of the boiler discharged through the flue 110 is absorbed and partly vaporized, and the evaporator 240 is again While passing through the fan (fan) to absorb the heat of the outside air flowing into the evaporator 240 from the outside, the refrigerant is completely vaporized.

As such, the refrigerant circulating in the heating / cooling cycle unit 20 passes through the waste heat exchange unit 50 'directly after passing through the expansion valve 230, thereby absorbing the waste heat of the boiler and partially vaporizing it. The amount of heat absorbed by the evaporator 240 may be reduced, and accordingly, the amount of heat consumed by the outside air supplied to the evaporator 240 may also be reduced, thereby allowing the refrigerant to be vaporized even with a small amount of outside air, thereby increasing energy efficiency of the system. .

8 to 10 show a boiler waste heat recovery hot water generating device according to another embodiment of the present invention, each of the condenser 220 on the boiler waste heat recovery hot water generating device according to the embodiment shown in FIG. And a second heat exchanger 60 between the expansion valve 230 and the line 42 branched from the evaporator 240 to receive heat while passing through the second heat exchanger 60. To compensate for the temperature, branched between the condenser 220 and the second heat exchanger 60, connected between the second heat exchanger 60 and the expansion valve 230, and provided with a selection valve 221. Including the bypass line 22 to prevent the refrigerant discharged from the condenser 220 to selectively pass through or pass through the second heat exchange unit 60 according to the temperature of the outside air of the evaporator 240. Vaporization temperature of the refrigerant in the evaporator 240 The line 43 branched from the evaporator 240 is connected to the condenser (a) of the separate air heat source hot water generator (A) to be compensated for the temperature of the outside air through heat exchange. Since these are each utilizing the same principle as the system described above with reference to FIGS. 3 to 5, a separate description thereof will be omitted to avoid redundant descriptions.

In the above, the Applicant has described preferred embodiments of the present invention, but these embodiments are merely one embodiment for implementing the technical idea of the present invention, and any changes or modifications may be made as long as the technical idea of the present invention is implemented. Should be interpreted as being within the scope.

1 is a schematic view showing a conventional hot water generating device

Figure 2 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to an embodiment of the present invention

Figure 3 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to another embodiment of the present invention

4 to 6 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to another embodiment of the present invention

Figure 7 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to another embodiment of the present invention

8 to 10 is a schematic view showing a boiler waste heat recovery hot water generating apparatus according to another embodiment of the present invention

* Explanation of the main symbols used in the drawings

10: boiler 110: flue

20: air conditioning heating unit 210: compressor 220: condenser 230: expansion valve

240: evaporator 22: bypass line 221: selector valve

30: heat storage unit 40: heat source supply unit 50, 50 ': waste heat exchange unit

60: second heat exchanger 33: second bypass line 331: selection valve

Claims (10)

A cooling and heating cycle unit connected to the compressor, the condenser, the expansion valve, and the evaporator to form one cycle: a heat storage unit connected to the boiler and the condenser to generate hot water through heat exchange with the boiler and the condenser; A heat source supply unit connected to the evaporator to supply heat necessary for vaporizing the refrigerant through heat exchange with the evaporator and having an external water source as a heat medium; A waste heat exchanger connected to the heat source supply unit and installed in the flue of the boiler to compensate the temperature of the heat source supply unit by supplying waste heat discharged from the flue to the heat source supply unit; Include, Further comprising a second heat exchanger between the condenser and the expansion valve, the line branched from the heat source supply may be supplied with heat passing through the second heat exchanger to compensate for the temperature of the heat source supply, And a bypass line branched between the condenser and the second heat exchanger, connected between the second heat exchanger and the expansion valve, and including a selection valve, to discharge the refrigerant from the condenser according to the temperature control state of the heat source supply unit. May selectively prevent or pass through the second heat exchanger to adjust the vaporization temperature of the refrigerant in the evaporator, And a line branched from the heat source supply unit is connected in parallel with the condenser of the air heat source hot water generator to compensate for the temperature of the heat source supply unit through heat exchange. delete delete delete According to claim 1, wherein the boiler waste heat recovery hot water growth value The condenser is located in the heat storage unit, and further includes a second heat exchanger between the condenser and the expansion valve, and the line branched from the heat storage unit receives heat while passing through the second heat exchange unit to further receive hot water of the heat storage unit. Boiler waste heat recovery hot water generator, characterized in that the heating. The method of claim 5, wherein the boiler waste heat recovery hot water growth value And further comprising a second bypass line branched between the second heat exchange part and the heat storage part and connected to a line branched from the heat source supply part, the second bypass line including a selection valve, thereby compensating the temperature of the heat source supply part by the heat storage part. Boiler waste heat recovery hot water generator, characterized in that. A cooling and heating cycle unit connected to the compressor, the condenser, the expansion valve, and the evaporator to form one cycle: a heat storage unit connected to the boiler and the condenser to generate hot water through heat exchange with the boiler and the condenser; A waste heat exchanger connected between the expansion valve and the evaporator and installed in the flue of the boiler to recover waste heat discharged from the flue of the boiler; Including, the refrigerant circulating the air-conditioning cycle portion flows out through the expansion valve flows into the waste heat exchange unit and receives heat transfer from the waste heat exchange unit flows into the evaporator in a partially evaporated state, the evaporator supplies the outside air By evaporating the remaining refrigerant that is not vaporized through heat transfer with the introduced refrigerant, the refrigerant can be vaporized even with a small amount of outside air. Further comprising a second heat exchanger between the condenser and the expansion valve, the line branched from the evaporator may be supplied with heat while passing through the second heat exchanger to compensate for the temperature of the outside air, And a bypass line branched between the condenser and the second heat exchanger, connected between the second heat exchanger and the expansion valve, and including a selector valve, thereby discharging the refrigerant from the condenser according to the temperature of the outside air of the evaporator. May selectively prevent or pass through the second heat exchanger to adjust the vaporization temperature of the refrigerant in the evaporator, And a line branched from the evaporator is connected in parallel with a condenser of an air heat source hot water generating device to compensate for the temperature of the outside air through heat exchange. delete delete delete

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