JP7473364B2 - How to renovate your air conditioning system - Google Patents

Description

The present invention relates to a method for retrofitting an air conditioning system .

Conventionally, simultaneous cooling and heating type (so-called free cooling and heating type) air conditioning systems capable of simultaneously generating cold and hot heat have been proposed as air conditioning systems to be installed in, for example, commercial and industrial buildings.

For example, Patent Document 1 discloses an air conditioning system in which a general-purpose multi-type air-cooling heat pump package is repurposed for use in a clean room. The outdoor unit of the multi-type air-cooling heat pump package is assumed to be a simultaneous cooling and heating outdoor unit. And according to the air conditioning system described in Patent Document 1, at least two or more simultaneous cooling and heating outdoor units are connected to the casing of an outdoor air processing air conditioner, which allows the cooling coil and reheat coil to be used simultaneously in the outdoor air processing air conditioner.

JP 2017-78525 A

However, as disclosed in Patent Document 1, when an air-cooled heat pump package is applied to an air conditioning system, the coil installed inside the casing of the outdoor air processing air conditioner needs to be connected to an outdoor unit installed outside the building (e.g., on the roof), and the piping connecting the coil and the outdoor unit becomes long. And when the piping becomes long in this way, the construction costs for installing the piping increase. In addition, since the outdoor unit needs to be installed outside the building, the installation space for the air conditioning system becomes large. Furthermore, when the piping becomes long in this way, the power consumption for circulating hot and cold water inside the piping increases when the air conditioning system is in operation, which means that energy efficiency decreases.

In addition, generally, when applying a free-heating and cooling system to a central air-conditioning system, it is necessary to circulate cold water and hot water back and forth between a heat source unit, such as a turbo chiller or absorption chiller, and an air conditioner (corresponding to the outdoor air processing air conditioner described in Patent Document 1). For this reason, it is necessary to install at least four pipes forming the outward and return paths (hereinafter referred to as a "four-pipe system"), and the number of pipes for connecting the heat source unit and the coil is large. And when there are such a large number of pipes, the installation costs for the pipes increase and the installation space for the pipes also becomes larger.

As such, conventional air conditioning systems left room for improvement in terms of installation space, construction costs, and energy.

The present invention was made in consideration of the above circumstances, and aims to provide a two-pipe air conditioning system that realizes a free-heating and cooling system and can reduce installation space, construction costs, and energy compared to conventional technologies.

In order to achieve the above object, the present invention is a method for retrofitting an existing air conditioning system that processes process air including outside air and return air to a retrofitted air conditioning system as described below.
In other words, the renovated system is an air conditioning system equipped with an air conditioner that processes process air including outside air and return air, and is equipped with a cold/hot water coil that circulates cold/hot water between two cold/hot water pipes that form an inbound and return path and performs sensible heat processing of the process air, and a water source heat pump that performs at least latent heat processing of the process air, wherein the water source heat pump has a water heat source machine that circulates cold/hot water between the cold/hot water pipes, and a direct expansion coil that circulates refrigerant between the water heat source machine and performs heat exchange between the process air and the refrigerant, and within the casing of the air conditioner, the cold/hot water coil and the direct expansion coil are arranged in order from the upstream side in the flow direction of the process air.
The existing air conditioner equipped in the existing air conditioning system includes a cold water coil that circulates cold water between two cold water pipes forming an outbound and return path, and a hot water coil that circulates hot water between two hot water pipes forming an outbound and return path, and is characterized in that the hot water coil and the hot water pipe are removed, and the direct expansion coil is installed inside the existing air conditioner in the space where the existing hot water coil was installed, the water heat source machine is installed and connected to the direct expansion coil, and the water heat source machine is connected to the existing cold water pipe.
According to the present invention, for example, an existing four-pipe air conditioning system can be modified to a two-pipe air conditioning system according to the present invention. This allows the number of hot and cold water pipes installed in the air conditioning system to be reduced from the conventional four to two. In other words, after the modification, the installation space for the hot and cold water pipes in the air conditioning system can be appropriately reduced, and the construction cost can also be appropriately reduced.
Generally, the temperature of the cold water flowing through the cold water pipes in an air conditioning system is lower than that of the hot water pipes, so the degree of corrosion of the cold water pipes is smaller than that of the hot water pipes. Therefore, by removing the hot water pipes in an existing air conditioning system and reusing the cold water pipes as in the present invention, the life of the renovated air conditioning system can be extended compared to the case where the cold water pipes are removed.
It is preferable to circulate medium temperature water at 9°C to 40°C in place of the cold water in the existing cold water pipes.
By circulating medium-temperature water (9°C to 40°C) instead of cold water, the operating efficiency of central heat source equipment such as cooling towers and air-cooled heat pump chillers that produce the medium-temperature water can be improved, thereby reducing the energy required to operate the renovated air conditioning system.

According to the present invention, since a water-source heat pump, i.e., a water-cooled heat pump, is applied to the renovated air conditioning system, the direct expansion coil provided in the casing of the air conditioner and the water heat source unit can be installed close to each other. Specifically, for example, the water heat source unit can be installed in the same room as the air conditioner, so that the installation space of the air conditioning system can be appropriately reduced. In addition, since the water heat source unit and the air conditioner can be installed in the same room in this way, the length of the refrigerant piping for connecting them can be shortened, and the construction cost can be appropriately reduced.

In addition, according to the present invention, a two-pipe air conditioning system is configured in which a common hot and cold water pipe is connected to the hot and cold water coil and the water-source heat pump, so the number of hot and cold water pipes can be reduced compared to conventional four-pipe or more air conditioning systems. In other words, the installation space for the air conditioning system can be further appropriately reduced, and construction costs can be further appropriately reduced.

The direct expansion coils may be connected in parallel to the water heat source unit, and the direct expansion coils may be arranged in series downstream of the hot and cold water coil in the flow direction.

It is desirable that the cold/hot water flowing through the cold/hot water pipe be medium-temperature water between 9°C and 40°C.

According to the present invention, by using medium-temperature water of 9°C to 40°C as hot and cold water, it is possible to improve the operating efficiency of central heat source equipment such as cooling towers and air-cooled heat pump chillers that produce the medium-temperature water. This in turn makes it possible to reduce the energy required to operate the air conditioning system.

The air conditioner has an outside air processing path and a return air processing path that process the outside air and the return air independently, and a plurality of the direct expansion coils are connected in parallel to the water heat source unit. The outside air processing path may have the hot and cold water coil and the direct expansion coil arranged in order from the upstream side in the flow direction of the outside air, and the return air processing path may have the hot and cold water coil and the direct expansion coil arranged in order from the upstream side in the flow direction of the return air.

Downstream of the hot and cold water coil in the outside air treatment path, multiple direct expansion coils may be arranged in series.

The air conditioner may mix the outside air and the return air that have been treated in the outside air treatment path and the return air treatment path, respectively, and then supply the air to the space to be air-conditioned.

A humidifier for humidifying the treatment air may be provided downstream of the direct expansion coil.

The air conditioner and the water source unit of the water source heat pump may be configured as one unit.

The present invention provides a two-pipe air conditioning system that realizes a free-heating and cooling system and can reduce installation space, construction costs, and energy consumption compared to conventional technologies.

1 is an explanatory diagram showing an outline of a building configuration equipped with an air conditioning system according to a first embodiment; 1 is an explanatory diagram showing an outline of the configuration of an air conditioner included in an air conditioning system according to a first embodiment; FIG. 2 is a psychrometric chart during cooling operation of the air conditioning system according to the first embodiment. FIG. 2 is an explanatory diagram showing the state of the air conditioning system according to the first embodiment during cooling operation. FIG. 11 is an explanatory diagram showing another example of the configuration of the air conditioner. FIG. 11 is an explanatory diagram showing another configuration example of the air conditioner. FIG. 11 is an explanatory diagram showing an outline of the configuration of an air conditioner according to a second embodiment. FIG. 11 is a psychrometric chart during cooling operation of an air conditioning system according to a second embodiment. FIG. 11 is an explanatory diagram showing the state of an air conditioning system according to a second embodiment during cooling operation. FIG. 11 is a psychrometric chart during heating operation of the air conditioning system according to the second embodiment. FIG. 11 is an explanatory diagram showing a state during heating operation of an air conditioning system according to a second embodiment. FIG. 1 is an explanatory diagram showing a method for repairing an existing air conditioning system. FIG. 1 is an explanatory diagram showing a method for repairing an existing air conditioning system. FIG. 1 is an explanatory diagram showing a method for repairing an existing air conditioning system.

Embodiments of the present invention will be described below with reference to the drawings. Note that in this specification and the drawings, elements having substantially the same functional configuration are designated by the same reference numerals to avoid redundant description.

<Air Conditioning System According to First Embodiment>
Fig. 1 is an explanatory diagram showing a part of the configuration of a building to which an air conditioning system according to a first embodiment of the present invention is applied. Fig. 2 is an explanatory diagram showing an enlarged part of the air conditioning system of Fig. 1.

As shown in FIG. 1, inside the building 1, an air-conditioned space R and a machine room M are formed adjacent to each other. In the present invention, an air-conditioning system 10 described below is used to process a mixture of outside air OA as process air and return air RA from the air-conditioned space R, and supply it to the air-conditioned space R as supply air SA. Note that the number and arrangement of the air-conditioned spaces R and machine rooms M formed in the building 1 are not limited to the example shown in the figure.

The air conditioning system 10 has a variable air volume device 20 (so-called VAV: Variable Air Volume), an air conditioner 30, and a water-source heat pump 40. The variable air volume device 20 supplies the treated air in the air conditioner 30 as supply air SA to the conditioned space R. The air conditioner 30 is equipped with various devices that perform the desired treatment on the mixed air MA that is taken in. The water-source heat pump 40 performs latent heat treatment on the mixed air MA that is taken in by the air conditioner 30.

The variable air volume devices 20 are provided in the space 2 above the ceiling of the air-conditioned space R, and supply air processed by an air conditioner 30 (described below) to the air-conditioned space R as supply air SA via a duct 20d and an air supply port 21 formed in the ceiling surface of the air-conditioned space R. In the illustrated example, three variable air volume devices 20 are provided for the space 2 above the ceiling of the air-conditioned space R, but the number and arrangement of the variable air volume devices 20 can be selected as desired.

The air conditioner 30 is installed in the machine room M. As shown in FIG. 2, a filter 31, a hot and cold water coil 32, a humidifier 33, a blower 34, and direct expansion coils 42 and 43 of a water-source heat pump 40 described below are provided in the casing 30a of the air conditioner 30. The filter 31, the hot and cold water coil 32, the direct expansion coils 42 and 43, the humidifier 33, and the blower 34 are arranged in series from the upstream side to the downstream side of the flow direction of the mixed air MA in the casing 30a.

Ducts 20a and 20d are also connected to the casing 30a of the air conditioner 30. Duct 20d is connected to the air volume changer 20 as described above, and forms a flow path for sending the mixed air MA processed in the casing 30a to the air volume changer 20. Duct 20a forms a flow path for introducing the mixed air MA (outdoor air OA and return air RA) as processed air into the casing 30a.

The filter 31 removes impurities such as dust contained in the mixed air MA (outdoor air OA and return air RA) that is introduced into the air conditioner 30 as the treated air.

As shown in FIG. 1, the hot and cold water coil 32 is connected to two hot and cold water pipes 50a, 50b, which form the forward and return paths, via two pipes 32a, 32b. Medium-temperature water, for example, about 9°C to 40°C, flows through the hot and cold water pipes 50a, 50b, and thus medium-temperature water circulates between the hot and cold water pipes 50a, 50b inside the hot and cold water coil 32. The hot and cold water coil 32 exchanges heat between the mixed air MA introduced into the air conditioner 30 and the medium-temperature water, thereby pre-cooling (when cooling) or pre-heating (when heating) the mixed air MA.

The humidifier 33 adjusts the supply air SA to the air-conditioned space R to the desired humidity. The configuration of the humidifier 33 can be selected arbitrarily.

The blower 34 blows the mixed air MA that has been processed in the casing 30a to the variable air volume device 20. The blowing operation of the blower 34 for the mixed air MA is controlled by an inverter control circuit (not shown).

The water-source heat pump 40 has a configuration in which a water-source unit 41 and direct expansion coils 42, 43 are interconnected by refrigerant piping 40a. Inside the water-source unit 41, a water heat exchanger (not shown), an expansion valve (not shown), a compressor (not shown), and a four-way valve (not shown) are provided. The water-source heat pump 40 is configured to be able to circulate refrigerant inside.

The direct expansion coil 42 and the direct expansion coil 43 are each connected to the water heat source unit 41 via refrigerant piping 40a so that the refrigerant can be circulated independently. In other words, the direct expansion coil 42 and the direct expansion coil 43 are each connected in parallel to the water heat source unit 41, and are configured to be able to process the mixed air MA independently within the casing 30a of the air conditioner 30.

The water heat source unit 41 is provided in the machine room M. As shown in FIG. 1, the water heat source unit 41 is connected to the hot and cold water pipes 50a, 50b via two pipes 40b, 40c. As a result, medium-temperature water circulates between the water heat source unit 41 and the hot and cold water pipes 50a, 50b. The water heat source unit 41 exchanges heat between the refrigerant circulating between the direct expansion coils 42, 43 and the medium-temperature water by the aforementioned water heat exchanger provided inside. Note that the water heat source unit 41 may be connected to the hot and cold water pipes 50a, 50b by branching the pipes 32a, 32b instead of the two pipes 40b, 40c.

The expansion valve is provided, for example, inside the water heat source unit 41 and expands the refrigerant circulating inside the water heat source heat pump 40.

The compressor is installed, for example, inside the water heat source unit 41, and circulates the refrigerant inside the water heat source heat pump 40 and compresses the circulating refrigerant.

The four-way valve is provided, for example, inside the water heat source unit 41, and switches the direction of circulation of the refrigerant circulating inside the water heat source heat pump 40, thereby switching between cooling operation and heating operation of the water heat source heat pump 40.

The direct expansion coil 42 is provided inside the casing 30a of the air conditioner 30. The direct expansion coil 42 exchanges heat between the refrigerant and the mixed air MA inside the casing 30a, for example, to cool and dehumidify the mixed air MA (during cooling) or heat the mixed air MA (during heating).

The direct expansion coil 43 is provided inside the casing 30a of the air conditioner 30. The direct expansion coil 43 exchanges heat between the refrigerant and the mixed air MA inside the casing 30a, for example, to reheat (when cooling) or heat (when heating) the mixed air MA.

The hot and cold water pipes 50a, 50b are installed penetrating the ceiling and floor of the machine room M, and one end of each is connected, for example, to a cooling tower (not shown) installed on the roof of the building 1, or a central heat source device that produces medium-temperature water, such as an air-cooled heat pump chiller, and the other ends are connected to each other, allowing medium-temperature water to circulate inside. In addition, the medium-temperature water circulating through the hot and cold water pipes 50a, 50b is controlled to a predetermined temperature (for example, about 9°C to 40°C) by the cooling tower or air-cooled heat pump chiller.

In the illustrated example, two direct expansion coils 42, 43 are arranged in series inside the casing 30a of the air conditioner 30, but under conditions where the process air can be sufficiently heated or cooled by the hot and cold water coil 32, for example, only one direct expansion coil may be installed inside the casing 30a.

As described above, the air conditioning system 10 according to the present invention is configured as a two-pipe air conditioning system equipped with two hot and cold water pipes 50a, 50b.

<Air conditioning system operation>
Next, an example of the operation of the air conditioning system 10 during cooling will be described with reference to Figures 3 and 4. Figure 3 is a psychrometric chart of the air conditioning system 10 during cooling operation, and Figure 4 is an explanatory diagram showing the flow of process air during cooling operation of the air conditioning system 10. Note that the temperatures shown in the following description are merely examples.

The 35°C outside air OA taken into the building 1 is mixed with the return air RA (26°C, 50% RH, 10.5 g/kg') from the air-conditioned space R to become mixed air MA at 29°C, which is introduced into the casing 30a of the air conditioner 30 (S1 in Figures 3 and 4). The mixed air MA introduced into the air conditioner 30 has impurities removed by the filter 31, and is introduced into the hot and cold water coil 32.

The mixed air MA introduced into the hot and cold water coil 32 is pre-cooled to 16°C by heat exchange with the medium-temperature cold water (15°C) circulating inside the hot and cold water coil 32 (S2 in Figs. 3 and 4). Next, the mixed air MA is heat exchanged by the direct expansion coil 42, cooled to 13°C and dehumidified at the same time (S3 in Figs. 3 and 4). The cooled and dehumidified mixed air MA is then reheated by the direct expansion coil 43 (S4 in Figs. 3 and 4). The reheated mixed air MA is then sent from the air conditioner 30 to the variable air volume device 20 by the blower 34, and supplied to the conditioned space R as supply air SA (15°C, 9.64 kg').

The supply air SA supplied to the conditioned space R is then heat exchanged with the indoor air (S5 in Figures 3 and 4) and then mixed again with the outdoor air OA as return air RA (26°C, 50% RH), becoming mixed air MA, which is introduced into the air conditioner 30.

<Effects of air conditioning system>
The air conditioning system 10 according to this embodiment is configured as a two-pipe air conditioning system connected to two hot and cold water pipes 50a, 50b as described above. Therefore, compared to a conventional four-pipe or more air conditioning system, the number of pipes to be installed can be reduced, and as a result, the installation space and construction cost of the air conditioning system 10 can be appropriately reduced, and further, the construction period of the air conditioning system 10 can be shortened.

In addition, the air conditioning system 10 according to this embodiment uses a water-source heat pump 40, which is a water-cooled heat pump. This eliminates the need to install a water-source unit 41 (corresponding to an outdoor unit in an air-cooled heat pump) outside the building 1, thereby further reducing the installation space of the air conditioning system 10 and the refrigerant piping 40a. Specifically, for example, by installing the water-source unit 41 and the direct expansion coils 42 and 43 that constitute the water-source heat pump 40 in the same machine room M, the installation space of the air conditioning system 10 can be appropriately reduced, and the extension of the refrigerant piping 40a connecting the water-source unit 41 and the direct expansion coils 42 and 43 can be shortened, which means that the construction cost of the air conditioning system 10 can be reduced. In addition, by shortening the extension of the refrigerant piping 40a in this way, the power consumption of the compressor when circulating the refrigerant can be reduced, and the running cost of the air conditioning system 10 can be reduced.

The installation position of the water heat source unit 41 can be changed as desired as long as the refrigerant can be properly circulated between the direct expansion coils 42, 43 installed inside the air conditioner 30. For example, while FIG. 1 illustrates an example in which the water heat source unit 41 is installed on the floor of the machine room M, it may also be fixed to the ceiling or wall of the machine room M. In such a case, the footprint (installation space) in the machine room M can be suitably reduced.

For example, the water heat source unit 41 may be configured integrally with the air conditioner 30. Note that "configuring the water heat source unit 41 integrally with the air conditioner 30" refers to a case where the air conditioner 30 and the water heat source unit 41 are stacked as shown in FIG. 5, for example, or a case where the water heat source unit 41 is disposed within the casing 30a of the air conditioner 30 as shown in FIG. 6. By configuring the water heat source unit 41 integrally with the air conditioner 30 in this way, the installation space of the air conditioning system 10 can be further saved.

According to the air conditioning system 10 of this embodiment, the mixed air MA of the outside air OA and return air RA used as the process air is pre-cooled (sensible heat treatment) as much as possible with medium-temperature chilled water (e.g., 15°C), and the remaining latent heat is removed by the direct expansion coil 42 of the water heat source heat pump 40. In this way, there is no need to use the low-temperature chilled water (e.g., 5 to 8°C) used in conventional air conditioning systems, and the energy required for processing the process air can be reduced.

In addition, in the air conditioner 30 of the air conditioning system 10 according to this embodiment, a direct expansion coil 42 that cools and dehumidifies (when cooling) or heats (when heating) the process air, and a direct expansion coil 43 that reheats (when cooling) or heats (when heating) the process air are arranged in series in the flow direction of the process air. This allows humidity control (dehumidification and reheating) of the process air using heat recovery inside the air conditioner 30, so that the temperature and humidity of the supply air SA supplied to the air-conditioned space R can be appropriately controlled. In other words, the two-pipe air conditioning system 10 according to the present invention can realize humidity-controlled air conditioning and a free-heating and cooling system that are realized in conventional four-pipe and six-pipe air conditioning systems.

It should be noted that it is not necessary to arrange two direct expansion coils in series within the casing 30a of the air conditioner 30. For example, under conditions where the air to be treated can be sufficiently heated or cooled by the hot and cold water coil 32, only one direct expansion coil may be installed within the casing 30a.

In addition, according to the air conditioning system 10 of this embodiment, the water heat source unit 41 and the air conditioner 30 can be installed in the same machine room M as described above, so that in the water heat source heat pump 40, the power consumption of the compressor when circulating the refrigerant between the water heat source unit 41 and the direct expansion coils 42, 43 can be reduced. In other words, the energy related to the treatment of the process air can be further reduced.

In the air conditioning system 10 according to the first embodiment, the air conditioner 30 processes mixed air MA, which is a mixture of outdoor air OA and return air RA. However, the outdoor air OA and return air RA may be processed independently in the air conditioner 30.

<Air Conditioning System According to Second Embodiment>
7 is an explanatory diagram showing an outline of the configuration of an air conditioner 130 provided in an air conditioning system 100 according to a second embodiment. The air conditioning system 100 according to this embodiment processes the outside air OA and the return air RA introduced into the air conditioner independently. In the following description, elements having substantially the same functional configuration as those in the above embodiment are denoted by the same reference numerals, and duplicated description will be omitted.

As shown in FIG. 7, an outside air processing path 131 that processes the taken-in outside air OA, a return air processing path 132 that processes the taken-in return air RA, and a confluence path 133 are formed within the casing 130a of the air conditioner 130 provided in the air conditioning system 100 according to the second embodiment.

In the outside air processing path 131, a filter 31, a hot/cold water coil 32, a direct expansion coil 42, and a direct expansion coil 43 are arranged in this order from the upstream side to the downstream side in the flow direction of the outside air OA.

In the return air treatment path 132, a filter 31, a hot/cold water coil 32, a direct expansion coil 42, and a humidifier 33 are arranged in this order from the upstream side to the downstream side in the flow direction of the return air RA.

The junction path 133 is formed by the junction of the downstream side of the direct expansion coil 43 in the outdoor air processing path 131 and the downstream side of the humidifier 33 in the return air processing path 132. A blower 34 is provided in the junction path 133. In the junction path 133, the outdoor air OA and the return air RA after being processed in the outdoor air processing path 131 and the return air processing path 132, respectively, are mixed to become mixed air MA, which is blown by the blower 34 to the air volume variable device 20. The mixed air MA blown to the air volume variable device 20 is supplied to the conditioned space R as supply air SA.

In the air conditioning system 100, the direct expansion coils 42, 43 provided in the outdoor air processing path 131 and the direct expansion coil 42 provided in the return air processing path 132 are each connected to a water heat source unit 41 provided outside the casing 130a.

The hot and cold water coil 32 provided in the outside air processing path 131, the hot and cold water coil 32 provided in the return air processing path 132, and the water heat source unit 41 are connected to two hot and cold water pipes 50a and 50b that form the forward and return paths, respectively, and the air conditioning system 100 is configured as a two-pipe air conditioning system.

<Operation of Air Conditioning System According to Second Embodiment>
Next, an example of the operation of the air conditioning system 100 during cooling in summer will be described with reference to Fig. 8 and Fig. 9. Fig. 8 is a psychrometric chart of the air conditioning system 100 during cooling operation, and Fig. 9 is an explanatory diagram showing the flow of the process air during cooling operation of the air conditioning system 100. Note that the temperatures shown in the following description are merely examples.

The 35°C outside air OA taken into the building 1 is introduced into the outside air processing path 131 in the casing 130a of the air conditioner 130. The outside air OA introduced into the air conditioner 130 has impurities removed by the filter 31 and is introduced into the hot and cold water coil 32.

The outside air OA introduced into the hot/cold water coil 32 is pre-cooled to 16°C by heat exchange with the medium-temperature cold water (15°C) circulating inside the hot/cold water coil 32 (S1 in Figs. 8 and 9). Next, the outside air OA is heat exchanged by the direct expansion coil 42, and is cooled to 10°C and dehumidified at the same time (S2 in Figs. 8 and 9). The outside air OA cooled and dehumidified by the direct expansion coil 42 is sent to the junction path 133.

On the other hand, the return air RA at 26°C from the conditioned space R is introduced into the return air treatment path 132 in the casing 130a of the air conditioner 130. The return air RA introduced into the air conditioner 130 has impurities removed by the filter 31 and is introduced into the hot and cold water coil 32.

The return air RA introduced into the hot/cold water coil 32 is pre-cooled to 16°C by heat exchange with the medium-temperature cold water (15°C) circulating inside the hot/cold water coil 32 (S3 in Figs. 8 and 9). The return air RA is then heat exchanged by the direct expansion coil 42, and is cooled to 12°C and dehumidified at the same time (S4 in Figs. 8 and 9). The return air RA cooled and dehumidified by the direct expansion coil 42 is sent to the junction path 133.

The treated outside air OA and return air RA sent to the junction path 133 are mixed in the junction path 133 to become mixed air MA (S5 in Figures 8 and 9). The mixed air MA is sent from the air conditioner 130 to the variable air volume device 20 by the blower 34, and is then supplied to the conditioned space R as supply air SA at 11°C (S5 in Figures 8 and 9).

The supply air SA supplied to the conditioned space R is then heat exchanged with the indoor air (S6 in Figures 8 and 9) and is then introduced back into the return air treatment path 132 of the air conditioner 130 as return air RA at 26°C.

Next, an example of the operation of the air conditioning system 100 during heating in winter will be described with reference to Figures 10 and 11. Figure 10 is a psychrometric chart of the air conditioning system 100 during heating operation, and Figure 11 is an explanatory diagram showing the flow of treated air during heating operation of the air conditioning system 100. Note that the temperatures shown in the following description are examples.

The 2°C outside air OA taken into the building 1 is introduced into the outside air processing path 131 in the casing 130a of the air conditioner 130. The outside air OA introduced into the air conditioner 130 has impurities removed by the filter 31 and is introduced into the hot and cold water coil 32.

The outside air OA introduced into the hot/cold water coil 32 is preheated to 26°C by heat exchange with the medium-temperature hot water (30°C) circulating inside the hot/cold water coil 32 (S1 in Figs. 10 and 11). The outside air OA is then heat exchanged by the direct expansion coil 43 and heated to 35°C (S2 in Figs. 10 and 11). The outside air OA heated by the direct expansion coil 43 is sent to the junction path 133.

Meanwhile, the return air RA at 23°C from the conditioned space R is introduced into the return air treatment path 132 in the casing 130a of the air conditioner 130. The return air RA introduced into the air conditioner 130 has impurities removed by the filter 31 and is introduced into the hot and cold water coil 32.

The return air RA introduced into the hot/cold water coil 32 is preheated to 26°C by heat exchange with the medium temperature hot water (30°C) circulating inside the hot/cold water coil 32 (S3 in Figs. 10 and 11). The return air RA is then heat exchanged by the direct expansion coil 42 and heated to 35°C (absolute humidity 7.9 g/kg') (S4 in Figs. 10 and 11). The return air RA heated by the direct expansion coil 42 is then humidified by the humidifier 33 to 28°C (absolute humidity 10.8 g/kg') (S5 in Figs. 10 and 11). The return air RA humidified by the humidifier 33 is sent to the junction path 133.

The treated outside air OA and return air RA sent to the junction path 133 are mixed in the junction path 133 to become mixed air MA (S6 in Figs. 10 and 11). The mixed air MA is sent from the air conditioner 130 to the variable air volume device 20 by the blower 34, and is then supplied to the conditioned space R as supply air SA at 30°C (absolute humidity 7.9 g/kg').

The supply air SA supplied to the air-conditioned space R is then heat exchanged with the indoor air and is then introduced back into the return air treatment path 132 of the air conditioner 130 as return air RA at 23°C.

<Effects of the Air Conditioning System According to the Second Embodiment>
The air conditioning system 100 according to this embodiment is configured as a two-pipe air conditioning system similar to the air conditioning system 10 according to the first embodiment. That is, compared to conventional four-pipe or six-pipe air conditioning systems, the number of pipes to be installed can be reduced, and as a result, the installation space and construction costs of the air conditioning system 100 can be appropriately reduced, and further, the construction period of the air conditioning system 100 can be shortened.

In the examples shown in Figures 8 to 11, the air conditioning system 100 is used for cooling operation in summer and heating operation in winter, but by controlling the operation of the various devices installed in the casing 130a and the flow rate of medium-temperature water circulating through the hot and cold water pipes 50a and 50b, the temperature and humidity of the supply air SA can be appropriately adjusted throughout the year, not just in summer or winter. In other words, the two-pipe air conditioning system 10 of the present invention can realize the humidity-controlled air conditioning and free-heating and cooling systems realized in conventional four-pipe and six-pipe air conditioning systems.

Specifically, for example, the sensible heat treatment of the treatment air can be efficiently controlled by the operation of the hot and cold water coil 32 provided in the casing 130a.

Thus, according to the air conditioning system 100 of this embodiment, by configuring an air conditioning system using a water-source heat pump 40 and medium-temperature water (e.g., 9°C to 40°C), even a two-pipe air conditioning system can achieve humidity control air conditioning and free heating and cooling systems that are equal to or better than conventional four-pipe and six-pipe air conditioning systems. In addition, because the air conditioning system uses medium-temperature water in this way, it is possible to achieve significant energy savings in the air conditioning system compared to conventional cases in which low-temperature cold water (e.g., about 5°C to 8°C) or high-temperature hot water (e.g., about 45°C) is used.

<How to renovate your air conditioning system>
The air conditioning system 10 and the air conditioning system 100 according to the embodiment of the present invention are particularly useful when installed in place of an existing air conditioning system in a building 1, i.e., when renovating an existing air conditioning system.

Figures 12 to 14 are explanatory diagrams showing an example of a construction procedure when an existing air conditioning system 200 installed in a building 1 is retrofitted to an air conditioning system 10. Note that in the following explanation, an example will be given of retrofitting an existing four-pipe air conditioning system 200 to a two-pipe air conditioning system 10.

As shown in FIG. 12(a), the existing air conditioning system 200 has an air conditioner 230 equipped with a filter 31, a cold water coil 201, a hot water coil 202, and a humidifier 33 inside a casing 230a. The cold water coil 201 circulates cold water between two cold water pipes 250a, 250b that form an outward path and a return path. The hot water coil 202 circulates hot water between two hot water pipes 251a, 251b that form an outward path and a return path. In other words, the existing air conditioning system 200 constitutes a four-pipe air conditioning system connected to a total of four cold and hot water pipes.

When renovating an existing air conditioning system 200, first, the existing hot water pipes 251a and 251b are removed as shown in FIG. 12(b). The space created by removing the hot water pipes 251a and 251b may be used as future piping renewal space to be used, for example, when further renovating the renovated air conditioning system 10.

After the hot water pipe 251 is removed, the hot water coil 202 installed in the casing 230a of the air conditioner 230 is then removed, as shown in FIG. 13(a).

After the hot water coil 202 is removed from the casing 230a, two direct expansion coils 42, 43 are then arranged in series between the cold water coil 201 and the humidifier 33 in the casing 230a of the air conditioner 230, i.e., in the space where the existing hot water coil 202 was arranged, as shown in FIG. 13(b). Therefore, the space vacated by removing the hot water coil 202 can be effectively utilized.

Next, the water heat source unit 41 is installed. The installation location of the water heat source unit 41 can be determined arbitrarily, but for example, by arranging it on top of the air conditioner 230 as one unit as shown in FIG. 14(a), the installation space of the air conditioning system can be saved. Then, once the water heat source unit 41 is installed, the direct expansion coils 42 and 43 are connected independently and in parallel to the water heat source unit 41, and the water heat source unit 41 is connected to two cold water pipes 250a and 250b, as shown in FIG. 14(b).

When the newly installed water-source heat pump 40 is connected to the cold water pipes 250a, 250b in this manner, the series of modifications to the existing air conditioning system 200 is completed. In the modified air conditioning system 10, medium-temperature cold water (e.g., about 9°C to 40°C) is passed through the remaining cold water pipes 250a, 250b. In other words, after the modification to the air conditioning system 10, the cold water pipes 250a, 250b are used as cold and hot water pipes according to the present invention.

<Effects of the repair method according to this embodiment>
According to this renovation method, an existing four-pipe air conditioning system 200 can be easily retrofitted to a two-pipe air conditioning system 10 by simply removing the hot water system (hot water coil 202 and hot water pipe 251) and installing a water-source heat pump 40 (water-source unit 41 and direct expansion coils 42, 43).

In addition, by modifying a four-pipe air conditioning system to a two-pipe air conditioning system in this way, the number of pipes installed in the machine room M is reduced from four to two, making it possible to appropriately reduce the installation space for the air conditioning system in the machine room M. In addition, because the number of pipes is reduced in this way, construction costs and construction time can also be appropriately reduced.

In addition, according to the above-mentioned renovation method, direct expansion coils 42, 43 are installed in the casing 230a instead of the hot water coil 202, and these direct expansion coils 42, 43 are connected to a water heat source unit 41 arranged in the machine room M (stacked with the air conditioner 230 in the illustrated example). This makes it possible to significantly reduce the power consumption of the compressor when circulating the refrigerant, compared to the case before the renovation where the refrigerant is circulated between the outdoor unit (not shown) installed on the roof of the building 1, for example.

Generally, the higher the temperature of the circulating cold and hot water, the faster the corrosion rate of the cold and hot water pipes that circulate the cold and hot water inside, and the sooner they reach the end of their life. In other words, in the existing air conditioning system 200 shown in Figures 12 to 14, the hot water pipe 251 corrodes faster than the cold water pipe 250, and reaches the end of its life sooner.

Therefore, according to the renovation method of this embodiment, the hot water system of the air conditioning system 200 is removed, and the cold water system is reused as a cold and hot water pipe of the renovated air conditioning system 10. As described above, at the time of renovation, the cold water pipe 250 is less corroded than the hot water pipe 251, so by leaving the existing cold water pipe 250 in this way and reusing it as a cold and hot water pipe of the present invention, the life of the renovated air conditioning system 10 can be extended.

In the above renovation method, the cold water pipe 250 is left in place and reused as a cold or hot water pipe in the renovated air conditioning system 10, but for example, the cold water pipe 250 may be removed and new cold or hot water pipes 50a, 50b may be installed.

In addition, in the above renovation method, the hot water pipe 251 is removed, but it is not necessary to remove the hot water pipe 251. For example, the hot water pipe 251 may be left inside the building 1 and used as a future renewal pipe for further renovation of the air conditioning system 10 after renovation.

In the above-mentioned renovation method, an example has been described in which a four-pipe air conditioning system 200 is renovated, but even if the air conditioning system 200 is a four-pipe or more type, for example a six-pipe air conditioning system, it can be appropriately renovated to a two-pipe air conditioning system 10, 100 according to an embodiment of the present invention. Generally, a six-pipe air conditioning system is connected to a return cold water pipe, a hot water pipe, and a medium temperature cold water pipe, but by renovating it to a two-pipe air conditioning system while leaving the cold water pipe or the medium temperature cold water pipe, for example, the installation space and renovation costs of the air conditioning system can be reduced.

In addition, the above renovation method has been described using an example of renovating a four-pipe air conditioning system 200, but it goes without saying that even if the air conditioning system 200 is a two-pipe system, it is possible to appropriately renovate the air conditioning systems 10 and 100 according to the embodiments of the present invention.

Although the embodiments of the present invention have been described above, the present invention is not limited to these examples. It is clear that a person skilled in the art can come up with various modified or revised examples within the scope of the technical ideas described in the claims, and it is understood that these also naturally fall within the technical scope of the present invention.

The present invention is particularly useful in technology that processes outside air and return air to adjust the temperature and humidity of conditioned spaces within buildings.

1 Building 2 Space above the ceiling of the space to be air-conditioned 10 Air conditioning system 20 Variable air volume device

30 Air conditioner 31 Filter 32 Hot and cold water coil

33 Humidifier 34 Blower 40 Water source heat pump

41 Water heat source device 42 Direct expansion coil 43 Direct expansion coil 50a Hot and cold water pipe 50b Hot and cold water pipe 100 Air conditioning system 130 Air conditioner

131 Outside air processing path 132 Return air processing path 133 Confluence path 200 Existing air conditioning system

R Air-conditioned space M Machine room MA Mixed air OA Outside air RA Return air SA Supply air

Claims (9)

A method for retrofitting an existing air conditioning system that processes process air including outdoor air and return air to a retrofit air conditioning system as described below ,
The air conditioning system after the renovation is as follows:
An air conditioning system including an air conditioner that processes process air including outside air and return air,
A cold/hot water coil that circulates cold/hot water between two cold/hot water pipes that form a forward path and a return path and performs sensible heat treatment of the treatment air;
A water source heat pump that performs latent heat treatment of at least the process air,
The water source heat pump comprises:
A water heat source machine that circulates hot and cold water between the hot and cold water pipes;
A direct expansion coil that circulates a refrigerant between the water heat source and the treatment air and exchanges heat between the treatment air and the refrigerant,
The hot and cold water coil and the direct expansion coil are arranged in the casing of the air conditioner in this order from the upstream side in the flow direction of the treatment air,
The existing air conditioner provided in the existing air conditioning system is
a cold water coil for circulating cold water between two cold water pipes forming a forward path and a return path;
A hot water coil that circulates hot water between two hot water pipes that form a forward path and a return path,
Remove the hot water coil and the hot water pipe;
Inside the existing air conditioner, the direct expansion coil is installed in a space where the existing hot water coil was installed,
The water heat source is installed and connected to the direct expansion coil;
A method for renovating an air conditioning system, comprising connecting the water heat source machine to the existing cold water pipe. The method for renovating an air conditioning system according to claim 1, characterized in that medium-temperature water at 9°C to 40°C is circulated in place of the cold water in the existing cold water pipes. A plurality of the direct expansion coils are connected in parallel to the water heat source machine,
The method for renovating an air conditioning system according to claim 1 or 2 , wherein the direct expansion coils are arranged in series downstream of the hot and cold water coil in the flow direction. The method for repairing an air conditioning system according to any one of claims 1 to 3 , characterized in that the cold or hot water flowing through the cold or hot water pipe is medium-temperature water at 9°C to 40°C. The air conditioner has an outside air processing path and a return air processing path that process the outside air and the return air independently,
A plurality of the direct expansion coils are connected in parallel to the water heat source machine,
The outside air processing path includes the cold/hot water coil and the direct expansion coil arranged in this order from the upstream side in the flow direction of the outside air,
The method for renovating an air conditioning system according to any one of claims 1 to 4 , characterized in that the cold/hot water coil and the direct expansion coil are arranged in the return air treatment path in this order from the upstream side in the flow direction of the return air. 6. The method for repairing an air conditioning system according to claim 5 , wherein a plurality of the direct expansion coils are arranged in series downstream of the hot and cold water coil in the outside air treatment path. 7. The method for renovating an air conditioning system according to claim 5 , wherein the air conditioner mixes the outside air and the return air that have been treated in the outside air treatment path and the return air treatment path, respectively, and then supplies the air to a space to be air-conditioned. The method for renovating an air conditioning system according to any one of claims 1 to 7 , characterized in that a humidifier for humidifying the process air is provided downstream of the direct expansion coil. The method for renovating an air conditioning system according to any one of claims 1 to 8 , wherein the air conditioner and the water source unit of the water source heat pump are integrally constructed.

Images