JPH0894130A - Air conditioner - Google Patents

Abstract

PURPOSE: To improve the comfortableness by air conditioning and to reduce the operating cost. CONSTITUTION: The air conditioner comprises a heat source equipment A for supplying cooling medium, a dehumidifying cooling unit D having a dehumidifier 5, a cooler 8 which receives the air to be cooled from the dehumidifier, and a blower 4 for feeding the air to be dehumidified and cooled to the dehumidifier and the cooler in such a manner that the dehumidifier and the cooler are connected by pipes to the equipment to circulate the cooling medium to the equipment and a humidity regulating cycle regenerator connected to the dehumidifier by a pipe to supply absorbing solution having high concentration to the dehumidifier, to return the solution which absorbs moisture from the the dehumidifier and the vapor is separated from the solution. The indoor is held comfortable by the dehumidifying by the solution, the operating efficiency of the equipment is improved, and the operating cost is reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an air conditioner, and more particularly, to an air conditioner for cooling or heating and dehumidifying or humidifying.

[0002]

2. Description of the Related Art For example, in Japanese Unexamined Patent Publication No. 5-306848, an outdoor unit provided with a compressor and an outdoor heat exchanger and a plurality of indoor units provided with an indoor heat exchanger are provided as a blow pipe switching device and a suction pipe. The outdoor unit is connected to the piping through the switching device and the flow control device, and the date and time from the calendar function, the day of the week, the temperature and humidity information from each indoor unit, the information from the action prediction means that stores the action prediction of the person, and the outdoor unit. Discloses a heat recovery type multi-air conditioner which controls a blow-out pipe switching device, a suction pipe connecting device, and a flow rate control device based on information on an outside air temperature and a refrigerant state.

[0003]

In the heat recovery type multi-air conditioner, for example, when the dehumidifying operation is performed on the rainy season, which is an outside air condition where the sensible heat is small and the latent heat is large, the temperature of the cool air blown out from the indoor heat exchanger decreases. However, the indoor temperature becomes lower than the desired temperature, and a person in the room feels cold, which causes a problem that comfortable air conditioning cannot be performed.

In order to prevent the room temperature from decreasing during the dehumidifying operation as described above, an air conditioner is provided, for example, in which an outdoor heat exchanger is provided with an electric heater to heat dehumidified air and blow it out into the room. is there. However, there is a problem that operating costs increase due to unnecessary power consumption by keeping the indoor heat exchanger at a low temperature for dehumidification and increase in power consumption due to energization of an electric heater for heating cold air. Occur.

Further, for example, when the heat recovery type multi-air conditioner is used for heating operation in winter when the temperature is low and the humidity is low, the indoor humidity is lowered and it is not good for the health. It also prevented the humidity from dropping. However, it takes time and effort to purchase a humidifier separate from the air conditioner, install it indoors in the winter, and clean it up in the spring, for example. There has been a demand for an air conditioner that can be maintained at.

[0006]

In order to solve the above problems, the present invention provides a heat source device for supplying a cooling medium, a dehumidifier, and a cooling device in which cooled air flows from the dehumidifier. And a dehumidifier having a blower for supplying cooling air to be dehumidified to the dehumidifier, the dehumidifier, and the cooler, the dehumidifier and the cooler being pipe-connected to the heat source unit, and the cooling medium circulating between the dehumidifier and the heat source unit, and the dehumidifier. An air conditioner equipped with a humidity control cycle regenerator that is connected to piping to supply a high-concentration absorbent to the dehumidifier, returns the absorbent that has absorbed water from the dehumidifier, and separates the vapor from this absorbent. It is provided.

Further, the invention of claim 2 is a heat source device for supplying a heating medium, a humidifier, a heater into which heated air flows from the humidifier, a humidifier, and a blower for flowing the humidified heated air to the heater. The humidifier and the heater are connected to the heat source unit by piping, and the heating medium is circulated between the heating medium and the heat source unit.The humidifier and the humidifier are connected to the pipe to supply the absorbent with a low concentration to the humidifier. The air conditioner is provided with a humidity control cycle regenerator that replenishes the absorbed liquid with the absorbed liquid separated from the humidifier.

[0008]

According to the first aspect of the invention, the absorbent is circulated between the humidity control cycle regenerator and the dehumidifier of the dehumidifying cooling unit to cool the indoor air by the moisture absorbing action of the concentrated absorbent in the dehumidifier. It can be dehumidified without performing the dehumidification, and the dehumidified air can be passed through a cooler to be blown into the room at an appropriate temperature. Especially, it is dehumidified even in the season when the humidity is high and the temperature is relatively low, such as the rainy season. It is possible to blow air into the room at a temperature almost equal to the temperature of to keep the room comfortable.

Further, it is sufficient that the dehumidifier in which the concentrated absorbent flows from the humidity control cycle dehumidification dehumidifies the room air, and the cooler of the dehumidification cooling unit exerts the ability to cool the room air. It is no longer necessary to lower the temperature of the cooler significantly below the temperature required to cool the indoor air,
The operation efficiency of the heat source machine is improved, and the operation cost can be reduced.

According to the second aspect of the present invention, the dilute absorption liquid replenished with water by the humidity control cycle regenerator is sent to the humidifier of the humidification heating unit, and the moisture of the absorption liquid is evaporated and dried by the humidifier. The formed room air is humidified by the moisture from the absorbing liquid. Humidified air is heated to an appropriate temperature by a heater and blown out indoors.For example, if a humidifying heating unit is installed in the room, not only indoor temperature but also humidity can be easily maintained and dryness can be avoided. It is possible to keep the room comfortable even in the dry season.

[0011]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the air conditioner of the present invention will be described in detail below with reference to the drawings. A shown in FIG. 1 is a heat source machine such as an air-cooled absorption type refrigerator using water as a refrigerant and a lithium bromide (LiBr) solution as an absorption liquid (solution), and B is a humidity control cycle regenerator (hereinafter, humidity control). The outdoor unit C is composed of the humidity control regenerator B and the heat source unit A. Further, 1 is an evaporator of the heat source unit A. D is an indoor unit which is a dehumidifying and cooling unit installed in a room and having a dehumidifying and cooling function, for example.

The indoor unit D will be described below.
Reference numeral 2 denotes an air inlet for sucking indoor air, 3 a filter, 4 a blower provided downstream of the filter 3, 5 a dehumidifier provided downstream of the blower 4, and 6 accommodated in the dehumidifier 5. A heat exchanger for adjusting humidity (hereinafter referred to as a first heat exchanger), 7 is an absorbent sprayer provided above the first heat exchanger 6, and 8 is provided downstream of the dehumidifier 5. Cooler, 9
Is a heat exchanger for cooling (hereinafter referred to as a second heat exchanger) housed in the cooler 8, and 10 is an air outlet for blowing the dehumidified and cooled air into the room. The dehumidifying and cooling unit D is provided with a flow path for indoor air from the air suction port 2 to the air outlet 10. Further, 11 is an absorption liquid reservoir formed below the dehumidifier 25, and 12 is an eliminator provided in the air passage between the dehumidifier 5 and the cooler 8.

Reference numerals 13 and 14 are cold water pipes,
The cold water pipe 13 is connected between the evaporator 1 and the second heat exchanger 9, and the cold water pipe 14 is connected between the first heat exchanger 6 and the evaporator 1. A medium circulation pump 15 (hereinafter referred to as a first circulation pump) is provided. Reference numeral 16 denotes an outside air introducing duct, and an outside air suction port 16A at one end of this duct 16 is opened to the outside of the room, and the other end is opened between the air suction port 2 of the dehumidifying and cooling unit D and the filter 3. A damper 17 that opens every predetermined time when the blower 4 is operating is provided in the middle of the outside air introducing duct 16. Reference numeral 18 denotes an opening / closing controller of the damper 17.

The humidity control regenerator B will be described below. The humidity adjusting regenerator B is provided at a position lower than the indoor unit D, and 19 is a regenerator heat exchanger provided in the absorbing liquid pool 20 of the humidity adjusting regenerator B. The regenerator heat exchanger 19 is connected to, for example, the heat source unit A by piping as shown by the broken line in FIG. 1, and from the heat source unit A, for example, high temperature refrigerant vapor or exhaust gas circulates. Reference numeral 21 denotes a rare absorbent flow outlet provided in a gas phase portion above the regenerator heat exchanger 19, and reference numeral 22 denotes a discharge port formed above the rare absorbent flow outlet 21. 23 to 25 are absorption liquid circulation pipes, and 26 is an absorption liquid circulation pump (hereinafter referred to as a second circulation pump). Then, a flow path of the absorption liquid is formed from the absorption liquid pool 20 to the absorption liquid distribution pipe 7 of the dehumidifier 5 through the absorption liquid circulation pipe 23, the second circulation pump 26, and the absorption liquid circulation pipe 24.
Further, a flow path of the absorbent is formed from the absorbent reservoir 11 of the dehumidifying / humidifying humidifier 5 through the absorbent circulating pipe 25 to the rare absorbent outlet 21.

The operation of the air conditioner during dehumidifying and cooling operations will be described below. During the dehumidifying and cooling operation, the first and second circulation pumps 15 and 2 of the outdoor unit C
6 is driving. Then, the water flowing through the evaporator 1 is cooled by the operation of the heat source device A. And, for example, 25 ℃
Then, cold water having a higher temperature than before flows from the evaporator 1 to the dehumidifying and cooling unit D, and the cold water circulates between the evaporator 1 and the indoor unit D.

In the humidity control regenerator B, for example, triethylene glycol, lithium chloride (LiB
The absorbing liquid such as r) and lithium bromide (LiBr) is heated by, for example, high-temperature refrigerant vapor flowing through the regenerator heat exchanger 19, and the moisture in the absorbing liquid becomes vapor and is separated. The separated steam is discharged to the outside air through the discharge port 22. The concentrated absorption liquid from which the water is separated flows to the indoor unit D. The concentrated absorbent is sprayed from the absorbent spraying device 7 of the dehumidifier 5 to the first heat exchanger 6, and the rare absorbent that has absorbed water in the dehumidifier 5 flows out from the absorbent pool 11. The rare absorbent flows into the humidity control regenerator B, and flows out from the rare absorbent outlet 21 into the absorbent reservoir 20.

The operation of the indoor unit D when the heat source unit A and the humidity control regenerator B are operating as described above will be described below. By the operation of the blower 4, the indoor air is sucked into the indoor unit D and flows as shown by the solid arrow in FIG. The indoor air sucked in is the filter 3
After passing through, the dust and the like are filtered and then flow to the dehumidifier 5.
In the dehumidifier 5, the concentrated absorbent is sprayed on the first heat exchanger 6,
Moisture is absorbed from the indoor air passing through and is cooled by exchanging heat with the cold water flowing through the first heat exchanger 6. The rare absorption liquid that has absorbed water is accumulated in the absorption liquid reservoir 11 and is sent to the humidity control regenerator B as described above. In addition, the dehumidifying humidifier 5
At this time, the air whose moisture is absorbed by the absorbing liquid and the humidity is lowered passes through the eliminator 12 and flows to the cooler 8. And
The air exchanges heat with the cold water flowing through the second heat exchanger 9 in the cooler 8 to lower its temperature. For example, air having a temperature of 25 ° C. and a humidity of 45% is blown into the room from the air outlet 10.

When the dehumidifying and cooling operation is performed as described above, the opening / closing control device 18 operates to open the damper 17 at every predetermined time. When the damper 17 is opened, the outside air is sucked from the outside air suction port 16A through the duct 16 to the air suction port 2 side of the indoor unit D. Then, the outside air is mixed with the indoor air and flows through the indoor unit D, and the dehumidification and cooling are performed as described above.

According to the above embodiment, the dehumidifier 5 is provided in the indoor unit D, the first heat exchanger 6 for circulating cold water is provided in the dehumidifier 5, and the dehumidifying humidifier 5 and the humidity adjusting regenerator are further provided. Since B is connected to the pipe by piping, it is possible to circulate the absorbing liquid and dehumidify the room air by the water absorbing action of the absorbing liquid. As a result, dehumidified air can be blown into the room without significantly lowering the temperature, and even in seasons such as the rainy season when the humidity is high and the temperature is relatively low, the air that has been dehumidified and has almost the same temperature as the room can be delivered to the room. You can keep the air balloon and the room comfortable.

Further, since moisture is absorbed from the indoor air by the moisture absorbing action of the absorbing liquid to perform dehumidification, it is sufficient that the cooler 8 of the indoor unit D exerts the ability to cool the indoor air. Therefore, the temperature of the cooler 8 does not have to be lowered significantly below the temperature required for cooling the indoor air, and the operating efficiency of the heat source device A is improved and the operating cost can be reduced.

An air conditioner for humidifying and heating, which is an embodiment of the second aspect of the present invention, will be described below with reference to FIG. In FIG. 2, the same components as those in FIG. 1 are designated by the same reference numerals, and detailed description thereof will be omitted. 30
Is a humidifier provided in the indoor unit D in the same manner as the dehumidifier 6 of FIG. 1, and 31 is a first heat exchanger of the humidifier 30. Three
2 is a heater provided downstream of the humidifier 30, and 33 is a second heat exchanger of the heater 32.

Next, the humidity control regenerator B will be described. Reference numeral 34 is an absorbent dispersion device provided at the end of the absorbent liquid circulation pipe 25 on the temperature control regenerator B side, and the absorption liquid sprayer 34 is provided above the gas phase part in the temperature control regenerator B. . Reference numeral 35 is, for example, a water pipe for replenishing city water, the outlet is located above the absorbent sprayer in the gas phase, and an on-off valve 36 is provided in the middle. Reference numeral 37 is an outside air inlet formed above the absorbent sprayer 34.

The operation of the air conditioning apparatus having the above-described configuration during the humidifying and heating operations will be described. During the humidifying and heating operation, the heat source unit A of the outdoor unit C performs so-called boiler operation, and high-temperature and high-pressure refrigerant vapor flows into the evaporator 1. In the evaporator 1, hot water is heated by the refrigerant vapor,
The warm water whose temperature has risen is sent to the indoor unit D.

Further, in the humidity control regenerator B, the absorbing liquid is sprayed from the absorbing liquid sprinkler 34, and the absorbing liquid absorbs the moisture in the outside air, and at this time absorbs the heat of the outside air. Further, when the absorption of water from the outside air is insufficient and the concentration of the absorbing liquid does not sufficiently decrease, the opening / closing valve 36 is opened and water is supplied from the water pipe 35. Then, the diluted diluted absorption liquid is absorbed liquid circulation pipe 2
It flows to the indoor unit D through 3, 24 and the second circulation pump 26. In addition, the concentrated absorbent having a high concentration due to the separation of water in the indoor unit D is sent to the humidity control regenerator B through the absorbent circulation pipe 25 and sprayed from the absorbent sprayer 34.

The operation of the indoor unit D when the heat source unit A and the humidity control regenerator B are operating as described above will be described below. By operating the blower 4, the indoor air is sucked into the indoor unit D, passes through the filter 3, and then flows into the humidifier 30. In the humidifier 30, the rare absorbent is the first
Is sprayed on the heat exchanger 31 of
Water is supplied to the passing indoor air. Further, at this time, the heat obtained from the outside air is released to the indoor air, so that a so-called heat pump operation is performed, and the operation efficiency of the indoor unit D can be improved.

The diluted absorbent, which has released water and has a lowered temperature, is heated by exchanging heat with the hot water flowing through the first heat exchanger 31, and flows to the humidity control regenerator B. In addition, the air whose humidity has been increased by replenishing water with the humidifier 30 is eliminator 1
2 and flows to the heater 32. Then, the air exchanges heat with the warm water flowing through the second heat exchanger 33 in the heater 32, and the temperature rises. For example, air at 22 ° C. and a humidity of 60% is blown out into the room from the air outlet 10.

According to the above embodiment, the indoor unit D is provided with the humidifier 30, the humidifier 30 is provided with the first heat exchanger 31 for circulating cold water or hot water, and the humidifier 3 is also provided.
Since 0 and the humidity control regenerator B are connected by piping, the absorbing liquid can be circulated to humidify the room air by separating water from the absorbing liquid. As a result, both humidification and heating can be performed without significantly increasing the temperature of the discharged air.

Further, for example, if the indoor unit D is installed in the room, the indoor air can be heated and humidified at the same time to avoid drying, and the room can be kept comfortable even in the dry season such as winter. It should be noted that the present invention is not limited to the above embodiments, and various implementations are possible without departing from the gist of the present invention.

For example, in the embodiment shown in FIGS. 1 and 2, the heat source unit A has been described as an absorption type refrigerator, but the heat source unit A may be an electric or engine driven compressor and an outdoor heat exchanger. Even when the heat source unit and the indoor unit D are connected to each other by piping to form a refrigerant circulation path using the outdoor unit including the above, the same operational effect can be obtained. Further, FIG. 3 shows an air conditioner capable of performing both a dehumidifying cooling operation and a humidifying heating operation. In this air conditioner, the heat source unit A is used similarly to the air conditioner shown in FIGS. 1 and 2.
The indoor unit D and the indoor unit D are connected by piping, the regenerator heat exchanger 19 is provided in the absorbing liquid reservoir 20 of the humidity control regenerator B, and the absorbing liquid disperser 34 is provided in the gas phase portion, and the opening / closing valve 36 is provided.
Is connected to the water pipe 35. Further, the indoor unit D is provided with a dehumidifying / humidifying device 40 that also serves as dehumidifying and humidifying and a cooling heater 41 that also serves as cooling and heating. This air conditioner is operated in the same manner as the air conditioner shown in FIG. 1 during the dehumidifying cooling operation, and is operated in the same manner as the air conditioner shown in FIG. 2 during the humidifying and heating operation. Circulates. As a result, it is possible to provide an air conditioner that can easily perform both the dehumidifying cooling operation and the humidifying heating operation.

FIG. 4 is a view showing an outdoor dehumidifying / cooling unit or a humidifying / heating unit (hereinafter referred to as an outdoor unit D2) of the present invention, in which 42 is a wall of a building.
43 is an inlet for indoor air, 44 is a filter, 45 is a dehumidifier or humidifier, 46 is an eliminator, 47 is a cooler or heater, 48 is a blower, 49 is an outlet for indoor air, and 50 is an absorbent sprayer. , 51 are absorption liquid pools. Also, 52 and 53 are ducts, respectively, and 52A is duct 5.
A duct for introducing outside air connected to 2 and a damper 52B. Then, an air flow path from the suction port 43 to the air outlet 49 is formed. Also, 54 and 55 are the first heat exchanger for humidity adjustment and the second heat exchanger for cooling or heating, as in the embodiment shown in FIG. 1 or FIG. The outdoor unit D2 is also provided with the pipes 13, 14, 24, 2 as indicated by the same reference numerals as those in FIGS. 1 and 2.
5 is connected. Then, as in the above embodiment, the dehumidifying cooling operation or the humidifying heating operation can be performed by circulating the cold water or the hot water and the absorbing liquid, and the room can be kept comfortable. In addition, by installing the unit outdoors, it is possible to use the room effectively, and it is possible to reduce the penetration of the operating noise, such as the absorption liquid sprayer 50 from the absorption liquid sprayer 50, into the room, which further improves comfort. Can be improved.

In the embodiment of the air conditioner shown in FIGS. 1 and 2, the heat source unit A and one indoor unit D are connected by piping, but the heat source unit A is described.
When the humidity control regenerator B and a plurality of indoor units D are connected by piping, the indoor units D can not only keep the room comfortable, but also improve the operating efficiency of each indoor unit and improve the air quality. The operating cost of the harmony device can be further reduced.

Further, the indoor unit D may be installed indoors or embedded in the ceiling or under the floor.

[0033]

The present invention is the air conditioner configured as described above, and according to the invention of claim 1, the absorbent is circulated between the humidity control cycle regenerator and the dehumidifier of the dehumidifying cooling unit. The dehumidifier's water absorption function of the concentrated absorbent can dehumidify the room air without cooling it, and the dehumidified air can be passed through the cooler and blown into the room at an appropriate temperature. Even when the humidity is high and the temperature is relatively low, it is dehumidified and blows air at a temperature almost equal to the temperature inside the room to avoid overcooling the room.
You can keep the room comfortable.

Further, the indoor air is dehumidified by the dehumidifier through which the concentrated absorbent flows from the humidity control cycle dehumidification, and the cooler of the dehumidifying and cooling unit has only to exhibit the ability to cool the indoor air. It is not necessary to significantly lower the temperature of the device below the temperature required to cool the indoor air, the operating efficiency of the heat source device is improved, and the operating cost can be reduced. .

According to the second aspect of the present invention, the dilute absorption liquid replenished with water by the humidity control cycle regenerator is sent to the humidifier of the humidification heating unit, and the moisture of the absorption liquid is evaporated and dried by the humidifier. The formed room air is humidified by the moisture from the absorbing liquid. Humidified air is heated to an appropriate temperature by a heater and blown out indoors.For example, if a humidification heating unit is installed in the room, not only indoor temperature but also humidity can be easily maintained to avoid dryness, such as during winter. The room can be kept comfortable even in the dry season.

[Brief description of drawings]

FIG. 1 is a schematic configuration diagram of an air conditioner showing an embodiment of claim 1 of the present invention.

FIG. 2 is a schematic configuration diagram of an air conditioner showing an embodiment of claim 2 of the present invention.

FIG. 3 is a schematic configuration diagram of an air conditioner showing another embodiment of the present invention.

FIG. 4 is a schematic configuration diagram of a dehumidifying / cooling unit or a humidifying / heating unit according to another embodiment of the present invention.

[Explanation of symbols]

 1 Evaporator A Heat source device B Humidity control regenerator (humidity control cycle regenerator) C Outdoor unit D Indoor unit 1 Evaporator 4 Blower 5 Dehumidifier 8 Cooler 19 Regenerator heat exchanger 20 Absorbing liquid pool 30 Humidifier 32 Heating Device 34 Absorber sprayer 35 Water pipe

Claims (2)

[Claims] 1. A heat source device for supplying a cooling medium, a dehumidifier,
A cooler into which the air to be cooled flows from this dehumidifier, a dehumidifier, and a blower that flows the dehumidified cooling air to the cooler, and the dehumidifier and the cooler are connected to the heat source device by piping to connect the cooling medium to the heat source device. A dehumidifying cooling unit that circulates between the dehumidifier and a pipe connected to the dehumidifier to supply a high-concentration absorbent to the dehumidifier, and the absorbent that has absorbed water is returned from the dehumidifier and the humidity is adjusted to separate the vapor from this absorbent. An air conditioner comprising a cycle regenerator. 2. A heat source device for supplying a heating medium, a humidifier,
It has a heater to which heated air flows from this humidifier, a humidifier and a blower for flowing the humidified heated air to the heater, and the humidifier and the heater are connected to the heat source device by piping to connect the heating medium to the heat source device. Humidity heating unit that circulates between the humidifier and piping connected to the humidifier to supply the absorbent with a low concentration to the humidifier, and the absorbent separated from the water is returned from the humidifier, and the humidity is adjusted to replenish the absorbent with water. An air conditioner comprising a cycle regenerator.