KR20230001251A - Anti-temperature humidifier and operation control method - Google Patents

Abstract

The present invention relates to a constant temperature humidifier, which has an effect of saving energy. The constant temperature humidifier includes: a cooling heat pump (100) composed of a cycle in which a first compressor (101) compresses a refrigerant, an outside air condenser (102) condenses the refrigerant compressed in the first compressor (101), an expansion valve (104) allows the refrigerant to be expanded, and a first evaporator (105) allows the refrigerant to be evaporated, undergoes heat exchange, and then is circulated into the first compressor (101); and a dehumidification and cooling heat pump (200) composed of a cycle in which a second compressor (201) compresses the refrigerant, a three-way valve (208) controls the refrigerant introduced from the second compressor (201) to be circulated in a direction selectively toward a reheating condenser (203) or an outside air condenser (202) or circulates the refrigerant into both the reheating condenser (203) and the outside air condenser (202), an expansion valve (204) allows the refrigerant condensed in the reheating condenser (203) or the outside air condenser (202) to be expanded, and a second evaporator (205) allows the refrigerant to be evaporated, to undergo heat exchange, and then to be circulated into the second compressor (201). The first evaporator (105) and the second evaporator (205) are provided in a flow path into which return air (220) is introduced to enable the return air to undergo heat exchange.

Description

Operation control method of thermo-hygrostat and thermo-hygrostat {Anti-temperature humidifier and operation control method}

The present invention relates to cooling, dehumidification, heating, etc. using a heat pump, and more specifically, includes a heat pump for dehumidification/cooling and a heat pump for cooling, each having two heat pump cycles, and a heat pump for dehumidification/cooling. is suitable for a production process where the dehumidification load is relatively greater than the cooling load, a warehouse where there are residents, or a space where moisture is generated, mainly for the purpose of satisfying humidity, and the heat pump for cooling is , It relates to a thermo-hygrostat and an operation control method suitable for a space where there are not many workers such as a computer room or a communication room with a relatively small amount of dehumidification, and a space mainly aimed at satisfying the temperature.

In general, quality is deteriorated by a place where various precision manufacturing (eg, semiconductor manufacturing, pharmaceutical manufacturing, etc.) is performed, a place where equipment sensitive to temperature and humidity is provided (eg, computer room, laboratory, communication room, etc.), and temperature and humidity changes. A place where sensitively changing items are stored (for example, a library, a film storage room, etc.) should always be maintained at an appropriate temperature and humidity.

To this end, a thermo-hygrostat is installed and used to maintain the target space at a constant temperature and humidity. The thermo-hygrostat sucks in outside air from indoors or outdoors, passes it inside, filters, cools, heats, and humidifies it, and then discharges it to the target space. By doing so, the constant temperature and humidity conditions of the target space are maintained.

1 is an operating state diagram of a general constant temperature and humidity device according to the prior art.

As shown, the air flow is guided so that the outside air is introduced and discharged.

An air duct 10 is provided, and a blowing fan 60 for blowing air and a filter 20 for filtering foreign substances when external air is introduced are disposed inside the air duct 10, and the filter 20 A cooling module 30, a heating module 40, and a humidifying module 50 are provided to perform cooling, heating, and humidification functions for the air passing through, respectively.

The cooling module 30 is configured to consist of a heat pump cycle composed of a compressor 31 , a condenser 32 , an expansion valve 34 and an evaporator 35 . In this cycle, the refrigerant compressed to high temperature and high pressure through the compressor 31 is supplied to the condenser 32 along the pipe line, is condensed while exchanging heat with the outside in the condenser 32, and the refrigerant condensed through the condenser 32 is After being stored in the receiver 33, it passes through the expansion valve 34 and expands.

The refrigerant that has passed through the expansion valve 34 is supplied to the evaporator 35 and is evaporated while exchanging heat with the inside in the evaporator 35 . The low-temperature, low-pressure gaseous refrigerant that has passed through the evaporator 35 is supplied to the compressor 31 and circulated. In the evaporator 35, since the refrigerant absorbs heat from the inside and is evaporated, the function of cooling and dehumidifying the air is performed.

The heating module 40 is composed of a heating coil operated by receiving power or a heater using a separate steam or hot water, and performs a function of heating the air that has passed through the cooling module 30, It works to increase the temperature or to compensate for the temperature by dehumidification.

The humidification module 50 is configured in such a way that water supplied from the outside is evaporated and mixed with air, and various general humidification devices may be applied and selectively operated when necessary for humidification.

Since the constant temperature and humidity device according to the prior art is composed of a device that requires a separate heat source such as a heating coil or a hot water heater, the heating module 40 operating for temperature compensation according to dehumidification of air, the heating module ( Since energy for the operation of 40) is additionally required, there is a problem in that overall energy efficiency is lowered.

In addition, if the heat pump is designed as one cycle to match the cooling capacity, the required cooling load is small and a lot of cycle driving energy is consumed during operation control when dehumidification is required. In the case of applying, there is a problem in that equipment costs increase.

In addition, since a heater must be used when reheating by dehumidification, there is a problem in that energy consumption increases.

Registered Patent Publication No. 10-0961935 (Announced on June 10, 2010)

The present invention is to solve the above problems, since there is no internal heat generation during the summer rainy season and the mid-season rainy season, reheating is required. By using condensation waste heat, energy saving is achieved, and the capacity of the reheat condenser is halved and the condenser By removing the outdoor unit as a built-in type, it is possible to supply economical products, and it is operated separately for temperature control and humidity control, so if indoor sensible heat cooling is required due to high outdoor air load, only temperature control is required, and if the external temperature is low and it rains, humidity When is high, it is intended to provide a constant temperature and humidity device that can achieve energy savings by dehumidifying operation.

In addition, the present invention can save operating energy by driving only the heat pump for cooling and the heat pump for dehumidification/cooling, and when both cooling and dehumidification are required, the heat pump for cooling and the heat pump for dehumidification/cooling are required. It is intended to provide an operating control method for a thermo-hygrostat that simultaneously or selectively circulates the refrigerant between the outdoor condenser and the reheat condenser of the heat pump for dehumidification/cooling according to the cooling load and dehumidification load during cooling and dehumidification operations. to be.

The thermo-hygrostat according to the first embodiment of the present invention compresses the refrigerant in the compressor, condenses the refrigerant compressed in the first compressor in the outdoor condenser, expands the refrigerant in the expansion valve, evaporates the refrigerant in the first evaporator, and exchanges heat. The cooling heat pump consists of a cycle circulated by the first compressor, the second compressor compresses the refrigerant, and the refrigerant introduced from the compressor selectively controls the circulation direction of the refrigerant from the three-way valve to the reheat condenser or the outdoor condenser, or to the reheat condenser and an outdoor condenser to circulate the refrigerant, the refrigerant condensed in the reheat condenser or the outdoor condenser is expanded in the expansion valve, the refrigerant is evaporated in the second evaporator, heat exchanged, and then circulated to the second compressor. Including a heat pump for cooling; The first evaporator, the second evaporator, and the reheat condenser are provided in a flow path through which return air is introduced to exchange heat or remove moisture from the return air.

In addition, the thermo-hygrostat of the second embodiment compresses the refrigerant in the first compressor, condenses the refrigerant compressed in the first compressor in the outdoor condenser, expands the refrigerant in the expansion valve, and evaporates the refrigerant in the first evaporator to exchange heat. Then, the cooling heat pump consists of a cycle circulated to the first compressor, the second compressor compresses the refrigerant, the refrigerant introduced from the second compressor is condensed in the reheat condenser, the refrigerant is expanded in the expansion valve, and the second evaporator Including a heat pump for dehumidification composed of a cycle in which the refrigerant is evaporated and heat exchanged and then circulated to the second compressor; The first evaporator, the second evaporator, and the reheat condenser are provided in a flow path through which return air is introduced to exchange heat or remove moisture from the return air.

In addition, a pre-filter provided at the inlet of the flow path flowing into the first evaporator and the second evaporator,

A heater provided in the flow path of the return air passing through the first evaporator or the second evaporator and the reheat condenser sequentially, a humidifier provided in the flow path of the return air passing through the heater, and an air supply fan provided in the flow path of the return air passing through the humidifier It is characterized in that it is provided.

In addition, in the method of controlling the operation of the thermo-hygrostat when the cooling load is large in the first embodiment of the present invention, the first compressor of the cooling heat pump is driven to supply the refrigerant → the outdoor condenser → the expansion valve → the first evaporator → the first compressor. and circulates the refrigerant → outdoor condenser → expansion valve → 2nd evaporator → 2nd compressor by driving the 2nd compressor of the heat pump for dehumidification/cooling. Cooling is performed in the first evaporator and the second evaporator, and the refrigerant is not circulated through the reheat condenser when the heat pump for dehumidification/cooling is driven.

In addition, the heat pump for cooling drives the first compressor to circulate the refrigerant → the outdoor condenser → the expansion valve → the first evaporator → the first compressor to cool the return air in the first evaporator, and the heat pump for dehumidification/cooling It is characterized in that the operation control method of the thermo-hygrostat is further provided when the cooling load is small in the first embodiment that is not driven.

In addition, the heat pump for dehumidification/cooling drives the second compressor to circulate the refrigerant → reheat condenser and outdoor condenser simultaneous refrigerant circulation → expansion valve → second evaporator → second compressor, and returns air is cooled in the second evaporator, It is characterized in that the operation control method of the thermo-hygrostat during the dehumidification operation in the first embodiment in which dehumidification is performed, heating and dehumidification in the reheat condenser, and the cooling heat pump is not driven is further provided.

In addition, the first compressor of the cooling heat pump is driven to circulate the refrigerant → the outdoor condenser → the expansion valve → the first evaporator → the first compressor to cool the return air in the first evaporator, and the dehumidification/cooling heat pump In the first embodiment, the second compressor is driven to circulate the refrigerant → the reheat condenser → the expansion valve → the second evaporator → the second compressor to cool and dehumidify the return air in the second evaporator and heat and dehumidify it in the reheat condenser. It is characterized in that a method for controlling the operation of the thermo-hygrostat during the cooling and dehumidifying operation of the present invention is further provided.

In addition, in the method of controlling the operation of the thermo-hygrostat during dehumidification operation in the second embodiment, the second compressor of the heat pump for dehumidification is driven to circulate the refrigerant → the reheat condenser → the expansion valve → the second evaporator → the second compressor, and return It is characterized in that the air is cooled and dehumidified in the second evaporator, heated and dehumidified in the reheat condenser, and the cooling heat pump is not driven.

In addition, the heat pump for cooling drives the first compressor to circulate the refrigerant → the outdoor condenser → the expansion valve → the first evaporator → the first compressor, cools the return air in the first evaporator, and does not drive the heat pump for dehumidification. It is characterized in that the operation control method of the thermo-hygrostat during the cooling operation in the second embodiment is further provided.

In addition, the first compressor of the heat pump for cooling is driven to circulate the refrigerant → the outdoor condenser → the expansion valve → the first evaporator → the first compressor to cool the return air in the first evaporator, and the second heat pump for dehumidification Cooling in the second embodiment in which the compressor is driven to circulate the refrigerant → reheat condenser → expansion valve → second evaporator → second compressor to cool and dehumidify the return air in the second evaporator and heat and dehumidify it in the reheat condenser. It is characterized in that a method for controlling the operation of the thermo-hygrostat during the dehumidifying operation is further provided.

In addition, in the operation method of the first embodiment and the operation method of the second embodiment of the constant temperature humidifier, the return air flowing into the first evaporator or the second evaporator passes through a pre-filter, and the return air passing through the reheat condenser It is characterized in that it is introduced into the indoor space by sequentially passing through the heater → humidifier → air supply fan.

The present invention has an effect of achieving energy savings by performing dehumidification or heating using condensed waste heat during the summer rainy season and the mid-season rainy season.

In addition, by removing the outdoor unit, there is an effect that economical product supply is possible.

In addition, since it is operated separately for temperature control and humidity control, only temperature control is performed when the outdoor air load is high and indoor sensible heat cooling is required, and energy saving can be achieved by dehumidifying operation when the outside temperature is low, raining, and humidity is high. There is an effect.

In addition, operating energy can be saved by driving only the heat pump for cooling or the heat pump for dehumidification/cooling as needed. The heat pump is driven simultaneously, and the refrigerant can be circulated simultaneously or selectively between the outdoor condenser and the reheat condenser of the heat pump for dehumidification/cooling according to the cooling load and dehumidification load during cooling and dehumidification operations.

In addition, it is suitable for operation in a production process where the dehumidification load is relatively greater than the cooling load, in a warehouse where there are residents or where there is moisture, or in a space where the purpose is to satisfy humidity, and the amount of dehumidification is relatively small. There is an effect of being able to operate in a space where there are not many workers such as a computer room and a communication room, and a space mainly aimed at satisfying the temperature.

1 is an operating state diagram of a general constant temperature and humidity device according to the prior art.
2 is a configuration diagram of a first embodiment of a heat pump thermo-hygrostat.
3 is an operating state diagram of the heat pump thermo-hygrostat in the first embodiment when the cooling load is relatively large.
4 is an operating state diagram of the heat pump thermo-hygrostat in the first embodiment when the cooling load is relatively small.
5 is an operating state diagram of the first embodiment of the heat pump thermo-hygrostat during dehumidification operation.
6 is an operating state diagram of the heat pump thermo-hygrostat in the first embodiment during cooling and dehumidifying operation.
7 is a configuration diagram of a second embodiment of a heat pump thermo-hygrostat;
8 is an operating state diagram of a second embodiment of a heat pump thermo-hygrostat during dehumidification operation.
9 is an operating state diagram of the second embodiment of the heat pump thermo-hygrostat during cooling operation.
10 is an operating state diagram of the second embodiment of the thermo-hygrostat during cooling and dehumidifying operation.
11 is a stacked state diagram of a pre-filter.

A preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings. For reference, the size of components, the thickness of lines, etc. shown in the drawings referred to in describing the present invention may be somewhat exaggerated for convenience of understanding.

In addition, the terms used in the description of the present invention are defined in consideration of the functions in the present invention, and may vary depending on the user, operator's intention, convention, and the like. Therefore, the definition of this term deserves to be made based on the contents throughout this specification.

And in this application, terms such as 'include' and 'have' refer to the existence of a specific number, step, operation, component, part, or combination thereof described in the specification, but one or more other It should be understood that the presence or addition of features, numbers, steps, operations, components, parts, or combinations thereof is not precluded.

In addition, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, and only this embodiment makes the disclosure of the present invention complete, and the scope of the invention to those skilled in the art. It is provided for complete information.

Therefore, since the present invention can have various changes and various forms, implementation examples (態樣, aspects) (or embodiments) will be described in detail in the specification. However, this is not intended to limit the present invention to a specific disclosed form, and it should be understood to include all changes, equivalents, and substitutes included in the technical spirit of the present invention, and the singular expression used in this specification is clearly different from the context. Include plural expressions unless otherwise indicated.

However, in describing the present invention, detailed descriptions of known or known functions or configurations will be omitted to clarify the gist of the present invention.

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings.

2 is a configuration diagram of a first embodiment of a heat pump thermo-hygrostat.

As shown, the first embodiment of the thermo-hygrostat of the present invention includes a cycle constituting the heat pump 100 for cooling, a cycle constituting the heat pump 200 for dehumidification/cooling, a pre-filter 209, a heater 206, It is characterized by having a humidifier 207 and an air supply fan 210.

That is, one of the important features of the present invention is that it has two cycles, the heat pump 100 for cooling and the heat pump 200 for dehumidification/cooling as described above.

The cooling heat pump 100 compresses the refrigerant in the first compressor 101, the refrigerant compressed in the first compressor 101 is condensed in the outdoor condenser 102, and the refrigerant expands in the expansion valve 104. In the first evaporator 105, the refrigerant is evaporated, heat exchanged, and then circulated to the first compressor 101.

The first evaporator 105 is provided in a flow path through which the return air 220 flows, has a function of exchanging heat with the return air, and introducing the heat-exchanged return air 200 into the indoor space.

The heat pump 200 for dehumidification/cooling compresses the refrigerant in the second compressor 201, and the refrigerant introduced from the second compressor 201 passes through the three-way valve 208 to the reheat condenser 203 or the outdoor condenser 202. ) to selectively control the circulation direction of the refrigerant, or circulate the refrigerant to both the reheat condenser 203 and the outdoor condenser 202, and the refrigerant condensed in the reheat condenser 203 or the outdoor condenser 202 is expanded by the expansion valve 204 ), the refrigerant is expanded, the refrigerant is evaporated in the second evaporator 205, heat exchanged, and then circulated to the second compressor 201.

The second evaporator 205 is provided in the passage through which the return air 220 is introduced, and has a function of exchanging heat with the return air and introducing the heat-exchanged return air 200 into the indoor space.

The reheat condenser 203 has a dehumidifying function of lowering the relative humidity by heating and exchanging heat with the inflowing return air 220 .

The heat-exchanged return air 200 may be air circulating indoors or outside air may be introduced, and the flow path through which the air is introduced may use a known technology such as a commonly used duct, so the specifics of the flow path Description of the configuration is omitted here.

The pre-filter 209 is provided at the inlet of the flow path flowing into the first evaporator 105 and the second evaporator 205, and has a filtering function of filtering out foreign substances such as dust included in the inflow return air 220. have

The heater 206 is provided in a flow path of the return air 220 sequentially passing through the first evaporator 105 or the second evaporator 205 and the reheat condenser 203 to additionally heat the circulating return air.

The humidifier 207 is provided in the flow path of the return air 220 passing through the heater 206 and has a function of humidifying by spraying water.

The air supply fan 210 is provided in the flow path of the return air 220 passing through the humidifier 207 and has a function of supplying the return air to the indoor space.

The first embodiment of the thermo-hygrostat as described above has two cycles by configuring the heat pump 100 for cooling and the heat pump 200 for dehumidification/cooling, respectively, so that the condenser of the heat pump 200 for dehumidification/cooling Composed of an outdoor condenser 202 and a reheat condenser 203, it is suitable for a production process with a relatively large amount of dehumidification, a space where there are residents such as a storage warehouse, or a space where humidity is generated, mainly for the purpose of satisfying humidity. There is an effect of being able to operate in a space where there are not many workers such as a computer room and a communication room where the amount of dehumidification is relatively low, and the space mainly aimed at satisfying the temperature.

In addition, if the heat pump is designed as one cycle to match the cooling capacity, the required cooling load is small, and if the dehumidification load is large, cycle driving energy is consumed during operation control. In the case of applying, there is a problem in that equipment costs increase.

In addition, since a heater must be used when reheating to adjust the relative humidity after cooling and dehumidification, there is a problem in that energy consumption increases. Alternatively, it is possible to save operating energy by driving only the heat pump 200 for dehumidification/cooling, and when both cooling and dehumidification are required, the heat pump 100 for cooling and the heat pump 200 for dehumidification/cooling Simultaneously driving, and refrigerant can be circulated simultaneously or selectively in the outdoor condenser 202 and the reheat condenser 203 of the dehumidifying/cooling heat pump 200 according to the cooling load and dehumidification load even during cooling and dehumidifying operations It works, it works.

In addition, there is an effect and effect that 1/2 of the maximum design cooling load can be designed and operated as the heat pump 100 for cooling and the heat pump 200 for dehumidification/cooling, respectively.

Hereinafter, the operation control method of the first embodiment of the thermo-hygrostat will be described.

3 is an operating state diagram of the heat pump thermo-hygrostat in the first embodiment when the cooling load is relatively large.

As illustrated, the method for controlling the operation of the thermo-hygrostat when the cooling load is large in the first embodiment.

The first compressor 101 of the cooling heat pump 100 is driven to circulate the refrigerant → the outdoor condenser 102 → the expansion valve 104 → the first evaporator 105 → the first compressor 101,

The second compressor 201 of the heat pump 200 for dehumidification/cooling is driven to circulate the refrigerant → the outdoor condenser 202 → the expansion valve 204 → the second evaporator 205 → the second compressor 201 Both cycles perform cooling operation;

It is characterized by an operation control method in which the refrigerant is not circulated through the reheat condenser 203 when the heat pump 200 for dehumidification/cooling is driven.

Due to this operation control method, the return air 220 has an action and effect of being supplied to the room after being cooled in the first and second evaporators 105 and 205 .

4 is an operating state diagram of the heat pump thermo-hygrostat in the first embodiment when the cooling load is relatively small.

As shown, the operation control method of the thermo-hygrostat when the cooling load is small in the first embodiment.

The cooling heat pump 100 drives the first compressor 101 to circulate the refrigerant → the outdoor condenser 102 → the expansion valve 104 → the first evaporator 105 → the first compressor 101,

The heat pump 200 for dehumidification/cooling is characterized by an operation control method in which it is not driven.

Due to such an operation control method, the return air 220 has the function and effect of being supplied to the room after being cooled in the first evaporator 105 .

5 is an operating state diagram of the heat pump thermo-hygrostat in the first embodiment during dehumidification operation.

As shown, the operation control method of the thermo-hygrostat during the dehumidifying operation in the first embodiment is as follows.

The heat pump 200 for dehumidification/cooling drives the second compressor 201 to circulate the refrigerant → the reheat condenser 203 → the expansion valve 204 → the second evaporator 205 → the second compressor 201 ,

The cooling heat pump 100 is characterized by an operation control method that does not drive.

Due to this operation control method, the return air 220 is cooled and dehumidified in the second evaporator 205 and heated in the reheat condenser 203 to lower the relative humidity, thereby having the action and effect of being dehumidified.

6 is an operating state diagram of the heat pump thermo-hygrostat in the first embodiment during the cooling/dehumidifying operation.

As shown, the operation control method of the thermo-hygrostat during the cooling/dehumidifying operation in the first embodiment is as follows.

The first compressor 101 of the heat pump 100 for cooling is driven to circulate the refrigerant → the outdoor condenser 102 → the expansion valve 104 → the first evaporator 105 → the first compressor 101, and return cooling the air (220) in the first evaporator (105);

The compressor of the heat pump 200 for dehumidification/cooling is driven to circulate the refrigerant → the reheat condenser 203 → the expansion valve 204 → the second evaporator 205 → the second compressor 201, and return air 220 ) is characterized by an operation control method of cooling in the second evaporator (205).

Due to this operation control method, the return air 220 is cooled and dehumidified in the two first and second evaporators 105 and 205 for cooling, and heated in the reheat condenser 203 to lower the relative humidity to dehumidify, It has the action and effect that can perform cooling and dehumidification at the same time.

Hereinafter, the second embodiment of the heat pump thermo-hygrostat will be described.

7 is a configuration diagram of a second embodiment of a heat pump thermo-hygrostat.

As shown, in the second embodiment of the thermo-hygrostat of the present invention, the cycle constituting the heat pump 100 for cooling, the cycle constituting the heat pump 200' for dehumidification, the pre-filter 209, the heater 206, and the humidifier (207), characterized in that it has an air supply fan (210).

That is, one of the important features of the present invention is that it has the above two cycles.

The cooling heat pump 100 compresses the refrigerant in the first compressor 101, the refrigerant compressed in the first compressor 101 is condensed in the outdoor condenser 102, and the refrigerant expands in the expansion valve 104. In the first evaporator 105, the refrigerant is evaporated, heat exchanged, and then circulated to the first compressor 101.

The first evaporator 105 is provided in a flow path through which the return air 220 flows, has a function of exchanging heat with the return air, and introducing the heat-exchanged return air 200 into the indoor space.

The dehumidifying heat pump 200' compresses the refrigerant in the second compressor 201, the refrigerant introduced from the second compressor 201 is condensed in the reheat condenser 203, and the refrigerant in the expansion valve 204 It is expanded, and the refrigerant is evaporated in the second evaporator 205, heat exchanged, and then circulated to the second compressor 201.

The second evaporator 205 is provided in the passage through which the return air 220 is introduced, and has a function of exchanging heat with the return air and introducing the heat-exchanged return air 200 into the indoor space.

The reheat condenser 203 has a dehumidifying function by heating and exchanging heat with the inflowing return air 220 .

The heat-exchanged return air 200 may be air circulating in the room or outside air may be introduced, and the passage through which the air is introduced may use a known technology such as a commonly used tuckt, so the specifics of the passage Description of the configuration is omitted here.

The pre-filter 209 is provided at the inlet of the flow path flowing into the first evaporator 105 and the second evaporator 205, and has a filtering function of filtering out foreign substances such as dust included in the inflow return air 220. have

The heater 206 is provided in a flow path of the return air 220 sequentially passing through the first evaporator 105 or the second evaporator 205 and the reheat condenser 203 to additionally heat the circulating return air.

The humidifier 207 is provided in the flow path of the return air 220 passing through the heater 206 and has a function of humidifying by spraying water.

The air supply fan 210 is provided in the flow path of the return air 220 passing through the humidifier 207 and has a function of supplying the return air to the indoor space.

In the second embodiment of the thermo-hygrostat as described above, the condenser of the heat pump 200' for dehumidification is configured as the reheat condenser 203, and the dehumidification load is relatively greater than the cooling load. There is an action or effect suitable for a space where moisture is generated, a space mainly aimed at satisfying humidity.

In addition, when designing a heat pump to fit the cooling capacity, if it has one cycle, if the cooling amount required is small or dehumidification is required, a lot of cycle driving energy is consumed during operation control. , In the case of applying an inverter, there is a problem of increasing equipment costs, and since a heater must be used when reheating by dehumidification, there is a problem of increasing energy consumption. By driving and operating only the heat pump 100 and the dehumidification heat pump 200', it is possible to save driving energy, and when both cooling and dehumidification are required, the cooling heat pump 100 and the dehumidification heat pump 200' simultaneously, the cooling heat pump 100 is driven during the cooling operation, and only the dehumidifying heat pump 200' is driven during the dehumidifying operation.

Hereinafter, an operation control method of the second embodiment of the thermo-hygrostat will be described.

8 is an operating state diagram of the second embodiment of the heat pump thermo-hygrostat during dehumidification operation.

As shown, the operation control method of the thermo-hygrostat during the dehumidifying operation in the second embodiment is as follows.

The second compressor 201 of the heat pump 200' for dehumidification is driven to circulate the refrigerant → the reheat condenser 203 → the expansion valve 204 → the second evaporator 205 → the second compressor 201,

The cooling heat pump 100 is characterized by an operation control method that does not drive.

According to this operation control method, the return air 220 is cooled and dehumidified in the second evaporator 205 and heated in the reheat condenser 203 to lower the relative humidity and have the effect of being dehumidified.

9 is an operating state diagram of the second embodiment of the heat pump thermo-hygrostat during cooling operation.

As shown, the operation control method of the thermo-hygrostat during the cooling operation in the second embodiment is as follows.

The cooling heat pump 100 drives the first compressor 101 to circulate the refrigerant → the outdoor condenser 102 → the expansion valve 104 → the first evaporator 105 → the first compressor 101,

The heat pump for rehumidification (200') is characterized by an operation control method in which it is not driven.

Due to such an operation control method, the return air 220 has the function and effect of being supplied to the room after being cooled in the first evaporator 105 .

10 is an operating state diagram of a second embodiment of a thermo-hygrostat during a cooling/dehumidifying operation.

As shown, the operation control method of the thermo-hygrostat during the cooling/dehumidifying operation in the second embodiment is as follows.

The first compressor 101 of the heat pump 100 for cooling is driven to circulate the refrigerant → the outdoor condenser 102 → the expansion valve 104 → the first evaporator 105 → the first compressor 101, and return cooling the air (220) in the first evaporator (105);

The second compressor 201 of the heat pump 200' for dehumidification is driven to circulate the refrigerant → the reheat condenser 202 → the expansion valve 204 → the second evaporator 205 → the second compressor 201 2 It is characterized by an operation control method of cooling and dehumidifying in the evaporator (205).

Due to this operation control method, the return air 220 is cooled and dehumidified in the two cooling first and second evaporators 105 and 205 and heated in the reheat condenser 203, so that cooling and dehumidification can be performed simultaneously. It has an action, an effect.

In addition, in the operation method of the first embodiment and the operation method of the second embodiment of the thermo-hygrostat, the return air introduced into the first evaporator 105 or the second evaporator 205 is introduced via the pre-filter 209, The return air 220 passing through the reheat condenser 203 sequentially passes through the heater 206 → humidifier 207 → air supply fan 210 and is introduced into the indoor space. .

By such an operation control method, it is possible to have an action or effect of filtering, additionally heating, or additionally humidifying the return air.

As described above, the present invention performs dehumidification or heating using condensed waste heat during the summer rainy season and the mid-season rainy season, so that energy can be saved, and by removing the outdoor unit, economical products can be supplied, and for temperature control Since it is operated separately for humidity and humidity control, only temperature control is performed when indoor sensible heat cooling is required due to high outdoor air load, and energy savings can be achieved by dehumidifying operation when the external temperature is low and raining or humidity is high. Cooling Operating energy can be saved by driving only the heat pump for cooling and the heat pump for dehumidification/cooling. Even during dehumidification operation, the refrigerant can be circulated simultaneously or selectively between the outdoor condenser and the reheat condenser of the heat pump for dehumidification/cooling depending on the cooling load and dehumidification load. Operation suitable for spaces where there are residents such as warehouses or where humidity is generated, mainly for the purpose of satisfying humidity, and spaces where there are not many workers such as computer rooms and communication rooms where the amount of dehumidification is relatively low, mainly satisfy the temperature There is an effect of driving to suit the space for the purpose of ordering.

In the following embodiments, a detailed configuration of the pre-filter will be described.

This embodiment describes the specific configuration of a pre-filter that filters fine dust, harmful gases, microorganisms, etc. included in return air.

11 is a stacked state diagram of a pre-filter.

As shown, the pre-filter 209 is provided in a state in which a nonwoven fabric, an antibacterial filter, and a nanofilter are stacked on the inside of a cover having a hollow rectangular structure.

The nonwoven fabric has a built-in activated carbon, and the activated carbon has an effect of filtering out harmful substances such as fine dust, harmful gases, and microorganisms by adsorbing harmful substances in the air.

The antibacterial filter is woven of fibers having a net structure, and an antibacterial coating is applied to the outer surface of the fiber, and the antibacterial coating includes 10 to 15 parts by weight of a binder and 4 to 7 parts by weight of titanium dioxide powder based on 100 parts by weight of a solvent. , 2 to 3 parts by weight of a porous material, 30 to 50 parts by weight of silver nanoparticles, and 13 to 33 parts by weight of a curing agent.

The above antibacterial coating composition has the effect of efficiently removing bacteria such as Escherichia coli, Pseudomonas aeruginosa, Pneumococcus, Bacillus subtilis, Enterobacteriaceae, Staphylococcus aureus, Vibrio and various fungi.

The nanofilter is made of an electrifying mesh substrate knitted or woven with filament yarn formed by coating a fiber with an electrifying polymer resin, and is provided with a nanofiber web layer spun and laminated on one side of the mesh substrate to filter out ultrafine dust. has the effect of giving

100: heat pump for cooling 101: first compressor
102: outdoor condenser 104: expansion valve
105: first evaporator
200: heat pump for dehumidification/cooling 200': heat pump for dehumidification
201: second compressor 202: outdoor condenser
203: reheat condenser 204: expansion valve
205: second evaporator 208: three-way valve
206: heater 207: humidifier
209: pre-filter 210: air supply fan
220: return (ventilation) air F: outdoor condenser fan

Claims (9)

The refrigerant is compressed in the first compressor 101, the refrigerant compressed in the first compressor 101 is condensed in the outdoor condenser 102, the refrigerant is expanded in the expansion valve 104, and in the first evaporator 105 A cooling heat pump 100 composed of a cycle in which the refrigerant is evaporated and heat exchanged and then circulated to the first compressor 101;
The second compressor 201 compresses the refrigerant, and the refrigerant introduced from the second compressor 201 selectively controls the circulation direction of the refrigerant from the three-way valve 208 to the reheat condenser 203 or the outdoor condenser 202, or The refrigerant is circulated through both the reheat condenser 203 and the outdoor condenser 202, and the refrigerant condensed in the reheat condenser 203 or the outdoor condenser 202 expands the refrigerant in the expansion valve 204, and the second evaporator ( 205) includes a dehumidifying/cooling heat pump 200 composed of a cycle in which the refrigerant is evaporated and heat exchanged and then circulated to the second compressor 201;
The first evaporator 105, the second evaporator 205, and the reheat condenser 203 are provided in the passage through which the return air 220 is introduced to exchange heat with the return air 220 or remove moisture. thermo-hygrostat.
The refrigerant is compressed in the first compressor 101, the refrigerant compressed in the first compressor 101 is condensed in the outdoor condenser 102, the refrigerant is expanded in the expansion valve 104, and in the first evaporator 105 A cooling heat pump 100 composed of a cycle in which the refrigerant is evaporated and heat exchanged and then circulated to the first compressor 101;
The compressor 201 compresses the refrigerant, the refrigerant introduced from the second compressor 201 is condensed in the reheat condenser 203, the refrigerant is expanded in the expansion valve 204, and the refrigerant in the second evaporator 205 It includes a heat pump for dehumidification (200') composed of a cycle of evaporation, heat exchange, and then circulation to the second compressor (201);
The first evaporator 105, the second evaporator 205, and the reheat condenser 203 are provided in the passage through which the return air 220 is introduced to exchange heat with the return air 220 or remove moisture. thermo-hygrostat.
The first compressor 101 of the cooling heat pump 100 is driven to circulate the refrigerant → the outdoor condenser 102 → the expansion valve 104 → the first evaporator 105 → the first compressor 101,
The second compressor 201 of the heat pump 200 for dehumidification/cooling is driven to circulate the refrigerant → the outdoor condenser 202 → the expansion valve 204 → the second evaporator 205 → the second compressor 201 , both cycles perform cooling operation,
The return air (220) is cooled in the first evaporator (105) and the second evaporator (205),
A method for controlling the operation of a constant temperature and humidity machine, characterized in that the refrigerant is not circulated through the reheat condenser (203) when the heat pump (200) for dehumidification/cooling is driven.
The method of claim 3,
A method for controlling operation of a thermo-hygrostat, characterized in that the heat pump 200 for dehumidification/cooling is not driven.
The method of claim 3,
A method for controlling operation of a thermo-hygrostat, characterized in that the heat pump for cooling (100) is not driven.
The method of claim 3,
The heat pump 200 for dehumidification/cooling is
The second compressor 201 is driven to circulate the refrigerant → reheat condenser 203 → expansion valve 204 → second evaporator 205 → second compressor 201,
A method for controlling the operation of a thermo-hygrostat, characterized in that the return air (220) is cooled and dehumidified in the second evaporator (205) and heated in the reheat condenser (203) to dehumidify the air to lower the relative humidity.
The second compressor 201 of the heat pump 200' for dehumidification is driven to circulate the refrigerant → the reheat condenser 203 → the expansion valve 204 → the second evaporator 205 → the second compressor 201,
The return air 220 is cooled and dehumidified in the second evaporator 205, and heated in the reheat condenser 203 to dehumidify to lower the relative humidity;
A method for controlling the operation of a thermo-hygrostat without driving the heat pump for cooling (100).
The method of claim 7,
The cooling heat pump 100 drives the first compressor 101 to circulate the refrigerant → the outdoor condenser 102 → the expansion valve 104 → the first evaporator 105 → the first compressor 101,
The return air 220 is cooled in the first evaporator 105,
A method for controlling operation of a thermo-hygrostat, characterized in that the heat pump for dehumidification (200') is not driven.
The method of claim 7,
The first compressor 101 of the heat pump 100 for cooling is driven to circulate the refrigerant → the outdoor condenser 102 → the expansion valve 104 → the first evaporator 105 → the first compressor 101, and return cooling the air (220) in the first evaporator (105);
The second compressor 201 of the heat pump 200' for dehumidification is driven to circulate the refrigerant → the reheat condenser 202 → the expansion valve 204 → the second evaporator 205 → the second compressor 201,
A method for controlling the operation of a thermo-hygrostat, characterized in that the return air (220) is cooled and dehumidified in the second evaporator (205), and heated in the reheat condenser (203) to dehumidify to lower the relative humidity.

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