JP7216063B2 - air conditioning system - Google Patents

Description

The present invention relates to an air conditioning system having a plurality of groups including one or more air conditioners.

Conventional air conditioners include a GHP (gas heat pump air conditioner) equipped with an outdoor unit including an engine-driven compressor driven by a gas engine, and an electrically driven compressor driven by an electric motor. and an EHP (Electric Heat Pump Air Conditioner) equipped with an outdoor unit.

Since the EHP does not have a gas engine, there is no need for maintenance such as replenishment or replacement of engine oil, replacement of the oil filter, inspection or replacement of spark plugs, which are necessary for the GHP, and maintenance costs are not incurred.

On the other hand, in addition to heating with a heat pump (heating indoor air), GHP can heat the air by recovering the exhaust heat of the gas engine, so it can warm the room more efficiently than EHP. becomes. In addition, since the GHP consumes almost no power, it has the advantage of being able to significantly reduce power consumption compared to the EHP.

Thus, GHP and EHP have different advantages. Therefore, in order to take advantage of the advantages of each, an engine-driven compressor, an electrically-driven compressor, an outdoor heat exchanger, and various sensors are housed in an outdoor unit composed of one housing. is disclosed (for example, Patent Literature 1).

JP 2007-10291 A

In an outdoor unit unit that is integrally composed of a gas consuming device that consumes gas, such as the engine-driven compressor, and a power consuming device that consumes power, such as an electrically driven compressor, the gas consuming device and the power Since sensors and control mechanisms are shared with consuming devices, if common parts such as sensors and control mechanisms fail, the entire outdoor unit becomes unusable and the air conditioner cannot operate.

In addition, depending on the region where the air conditioner is installed, the power supply company and the gas supply company may differ. In the case of having A and facility B, even if the air conditioners of facility A and facility B are driven with the same operating output, there is a predetermined rate regulation for electric power and a predetermined charge regulation for gas. , the energy usage conditions such as the amount of carbon dioxide emissions corresponding to the amount of electric power will be different. Therefore, there is a demand for a comprehensive grasp of air conditioners located in different regions by power supply companies and gas supply companies to reduce electricity charges, gas charges, and carbon dioxide emissions resulting from use. There is

In view of such problems, the present invention provides a plurality of air conditioners having both a gas consuming device and a power consuming device, which are arranged under different energy usage conditions. An object of the present invention is to provide an air conditioning system that can be comprehended comprehensively.

In order to solve the above problems, an air conditioning system according to the present invention includes a plurality of groups each including one or more air conditioners, and a host controller that communicates with each group. A system, an air conditioner comprising: a gas consuming unit for heating or cooling a refrigerant or water; a gas consuming unit configured independently of the gas consuming unit; or a power consumption unit that heats or cools water, an indoor heat exchanger that exchanges heat between the refrigerant or water heated or cooled by the gas consumption unit and the power consumption unit and the indoor air, and an indoor heat exchanger and one or more indoor unit units having an indoor air blower for sending air to and promoting heat exchange, wherein the plurality of groups are owned by one operator, the groups are owned by other groups, A contract with a power supply company , a contract with a gas supply company, and energy usage conditions are set independently. A host communication unit that communicates with each, a condition acquisition unit that acquires energy usage conditions for each of a plurality of groups through the host communication unit, and a recommended power supply for each group based on the acquired energy usage conditions. and a computing unit for performing company and gas supplier selection , wherein the energy usage conditions are a predetermined rate rule for electricity, a predetermined rate rule for gas, and a carbon dioxide corresponding to the amount of power. carbon emissions, and the computing unit is selected from the group of a predetermined rate rule for electricity, a predetermined rate rule for gas, and a carbon dioxide emission corresponding to the amount of power across the plurality of groups. estimating the recommended value of the operating ratio of the air conditioners in each group and selecting the recommended electric power supply company and gas supply company in each group so as to minimize one or more of the

The group also includes an output value deriving unit that derives an operating output value of the gas consumption unit and an operation output value of the power consumption unit in the air conditioner based on the recommended value of the operation ratio estimated by the calculation unit, and an output value derivation unit. and an operation control unit that controls the operation output of the gas consumption unit and the operation output of the power consumption unit in the air conditioner so as to achieve the operation output value derived by the unit.

In addition, each group has a contract power, which is the maximum amount of power used in the group for a predetermined period, and if the group uses power in excess of the contract power, a penalty charge is imposed and the output value is derived. The part derives the operating output value of the power consumption unit so that the sum of the power consumption of the power consumption unit and the power consumption of other devices in the group falls within a predetermined limit value less than the contract power. You may

Further, when the output value derivation unit derives the operation output value of the power consumption unit so as to fall within a range of a predetermined limit value, and when the predetermined air conditioning load required by the indoor unit cannot be realized, derives an operating output value such that the operation of the gas consuming unit is started when the gas consuming unit is inactive, and the operating output exceeds the current operating output of the gas consuming unit when the gas consuming unit is in operation. Output values may be derived.

Further, the output value deriving unit may derive the operation output value of the power consuming unit so that the amount of carbon dioxide emissions generated by the power consumption of the power consuming unit falls within a predetermined limit value.

According to the present invention, when a plurality of air conditioners having both a gas consumption device and a power consumption device are arranged under different energy usage conditions, a plurality of air conditioners can be grasped comprehensively. be able to.

BRIEF DESCRIPTION OF THE DRAWINGS It is a figure for demonstrating the structure of the air conditioning system concerning embodiment. It is a figure for demonstrating the structure of an air conditioner. 4 is a diagram for explaining the configuration of a host control device; FIG. It is a figure which shows an operation output value table. It is a figure explaining a GHP chiller. It is a figure explaining an absorption-type chiller-heater. It is a figure explaining an EHP chiller. It is a figure explaining a centrifugal chiller.

Preferred embodiments of the present invention will be described in detail below with reference to the accompanying drawings. The dimensions, materials, and other specific numerical values shown in these embodiments are merely examples for facilitating understanding of the invention, and do not limit the invention unless otherwise specified. In the present specification and drawings, elements having substantially the same function and configuration are given the same reference numerals to omit redundant description, and elements that are not directly related to the present invention are omitted from the drawings. do.

[Air conditioning system 100]
FIG. 1 is a diagram for explaining the configuration of an air conditioning system 100 according to this embodiment. As shown in FIG. 1, the air conditioning system 100 includes a plurality of groups 110 (indicated by 110a and 110b in FIG. 1), a communication network 120, and a host controller .

A group 110 is a collection of one or more (here, two) air conditioners 150, and all of the groups 110 are formed under one contract with an energy supply source (power supply company, gas supply company). Energy (electric power, gas) is supplied to the air conditioner 150 . Therefore, as long as the contract is the same, the group 110 may be, for example, one facility, or may be a group of facilities such as buildings, schools, etc. in an area with the same power supply company or gas supply company.

The air conditioning system 100 according to this embodiment includes a plurality of (here, two) groups 110a and 110b each having different contracts with energy supply sources and different energy usage conditions. Here, the energy usage conditions are one or more selected from the group of predetermined rate rules for electricity, predetermined rate rules for gas, and carbon dioxide emissions corresponding to the amount of power, For example, the group 110a and the group 110b are located in different regions, and the group 110a power supply company and gas supply company are different from the group 110b power supply company and gas supply company.

Group 110 includes a semiconductor integrated circuit including a CPU (Central Processing Unit), reads programs and parameters for operating the CPU itself from ROM, and cooperates with RAM as a work area and other electronic circuits. A group control unit 112 is provided that functions to manage and control the entire air conditioners 150 that constitute the group 110 .

In this embodiment, the group control section 112 also functions as a group communication section 114 , an output value derivation section 116 and an operation control section 118 . Group communication unit 114 communicates with host control device 130 via communication network 120 .

The output value derivation unit 116 derives the operation output value of the air conditioner 150 based on the operation ratio of the air conditioner 150 transmitted from the host control device 130 . The process of deriving the operating output value of the air conditioner 150 by the output value deriving unit 116 will be described in detail later.

The operation control unit 118 switches the circulation direction of the refrigerant according to the user's operation input to the operation unit (for example, a remote controller), switches the function of the indoor unit 300 described later to cooling or heating, or derives an output value. The operation of the air conditioner 150 is controlled so as to achieve the operation output value derived by the unit 116 .

The air conditioners 150 that make up the group 110 perform air conditioning for the facilities of the group 110 . FIG. 2 is a diagram for explaining the configuration of the air conditioner 150. As shown in FIG. The air conditioner 150 is installed in a facility belonging to one group 110 such as a building or a school, and includes a GHP unit 210 functioning as an outdoor unit and an EHP separate from the GHP unit 210 and functioning as an outdoor unit. It includes a unit 250 , one or a plurality of indoor units 300 , and a refrigerant pipe 330 for circulating the refrigerant to the GHP unit 210 , the EHP unit 250 and the indoor units 300 . In FIG. 2, the flow of the refrigerant during cooling is indicated by a solid arrow, and the signal line is indicated by a broken line.

The GHP unit 210 (gas consuming unit) includes a gas engine 212 (gas consuming device), an engine-driven compressor 214 (gas consuming device) driven by the gas engine 212, a four-way valve 220, a refrigerant and an outdoor unit. It includes a GHP outdoor heat exchanger 230 that exchanges heat with air, a GHP blower section 232 that feeds air to the GHP outdoor heat exchanger 230 to promote heat exchange, and a GHP control section 240 . The outlet of the engine-driven compressor 214 is connected by a refrigerant pipe 330 to the first port of the four-way valve 220 (indicated by “1” in FIG. 2), and the inlet of the engine-driven compressor 214 is It is connected to the third port of valve 220 (indicated by "3" in FIG. 2). One end side of the GHP outdoor heat exchanger 230 is connected to the second port (indicated by “2” in FIG. 2) of the four-way valve 220 through a refrigerant pipe 330 . The other end side of the GHP outdoor heat exchanger 230 is connected to the pressure reducing section 310 of the indoor unit 300 to be described later by a refrigerant pipe 330 . A fourth port (indicated by “4” in FIG. 2 ) of the four-way valve 220 is connected by a refrigerant pipe 330 to one end of an indoor heat exchanger 320 of the indoor unit 300 to be described later. The GHP control unit 240 is composed of a semiconductor integrated circuit including a CPU (central processing unit). sensors, etc.).

The EHP unit 250 (power consumption unit) is configured independently of the GHP unit 210, and includes an electric motor 252 (power consumption device), an electrically driven compressor 254 (power consumption device) using the electric motor 252 as a drive source, A four-way valve 260, an EHP outdoor heat exchanger 270 that exchanges heat between refrigerant and outdoor air, an EHP air blower 272 that sends air to the EHP outdoor heat exchanger 270 to promote heat exchange, and an EHP controller 280. Consists of The outlet of the electrically driven compressor 254 is connected by a refrigerant pipe 330 to the first port of the four-way valve 260 (indicated by “1” in FIG. 2), and the inlet of the electrically driven compressor 254 is It is connected to the third port of valve 260 (indicated by "3" in FIG. 2). One end side of the EHP outdoor heat exchanger 270 is connected to the second port (indicated by “2” in FIG. 2) of the four-way valve 260 through a refrigerant pipe 330 . The other end of the EHP outdoor heat exchanger 270 is connected to the decompression section 310 of the indoor unit 300 via a refrigerant pipe 330 . A fourth port (indicated by “4” in FIG. 2 ) of the four-way valve 260 is connected to one end side of the indoor heat exchanger 320 of the indoor unit 300 by a refrigerant pipe 330 . The EHP control unit 280 is configured by a semiconductor integrated circuit including a CPU (Central Processing Unit), based on the control command from the operation control unit 118, the entire EHP unit 250 (for example, the electric motor 252, the EHP blower unit 272, various sensors etc.).

In this embodiment, the air conditioner 150 includes two indoor units 300 (indicated by 300a and 300b in FIG. 2). The indoor unit 300 includes a decompression unit 310 (expansion valve) that decompresses the refrigerant, an indoor heat exchanger 320 that is connected to the decompression unit 310 by a refrigerant pipe 330 and performs heat exchange between the refrigerant and indoor air, and an indoor heat exchange unit. and an indoor blower 322 for sending air to the vessel 320 to promote heat exchange. As described above, one end of the pressure reducing unit 310 is connected to the other end of the GHP outdoor heat exchanger 230 and the EHP outdoor heat exchanger 270 through the refrigerant pipe 330, and the other end of the pressure reducing unit 310 is connected through the refrigerant pipe 330. One end of the indoor heat exchanger 320 is connected to the fourth ports of the four-way valves 220 and 260 via the refrigerant pipe 330 .

Therefore, when the engine-driven compressor 214 or the electrically-driven compressor 254 is driven, the refrigerant circulates through the refrigerant pipes 330, and the refrigerant pipes 330 form a series of circulation paths. Further, in the present embodiment, the series of circulation paths through which the refrigerant circulates include a circulation path passing through the GHP unit 210, the EHP unit 250, and the indoor unit 300a, and a circulation path passing through the GHP unit 210, the EHP unit 250, and the indoor unit 300b. It branches off into a road.

When the indoor unit 300 functions as a cooler, the first port and the second port of the four-way valve 220 are connected, the fourth port and the third port are connected, and the first port of the four-way valve 260 is connected. By connecting the second port and connecting the fourth port and the third port, the refrigerant is circulated in the direction indicated by the arrow in FIG. Send to heat exchanger 270 . On the other hand, when the indoor unit 300 functions as a heater, the first port and the fourth port of the four-way valve 220 are connected, the second port and the third port are connected, and the first port of the four-way valve 260 is connected. By connecting the fourth port and connecting the second port and the third port, the refrigerant is circulated in the direction opposite to the direction indicated by the arrow in FIG. 320.

Returning to FIG. 1, the communication network 120 is composed of a LAN, a dedicated line, the Internet, etc., and connects the group 110 and the host control device 130 wirelessly or by wire.

The host control device 130 communicates with the group communication unit 114 of each group 110 via the communication network 120, estimates a recommended value for the operation ratio of the air conditioner 150 of each group 110, and recommends a recommended value for each group 110. selection of energy supply sources;

FIG. 3 is a diagram for explaining the configuration of the host control device 130. As shown in FIG. As shown in FIG. 3, the host controller 130 includes a host controller 132. The host controller 132 is composed of a semiconductor integrated circuit including a CPU (Central Processing Unit), and operates the CPU itself from a ROM. It reads a program, parameters, etc. for making the host controller 130 work, and manages and controls the entire host controller 130 in cooperation with the RAM as a work area and other electronic circuits.

In this embodiment, the host control section 132 functions as a host communication section 134 , a condition acquisition section 136 and a calculation section 138 . The host communication unit 134 communicates with each of the groups 110 via the communication network 120 .

The condition acquisition unit 136 acquires, through the host communication unit 134, energy usage conditions for each of the plurality of groups 110 (predetermined rate rules for electricity, predetermined rate rules for gas, carbon dioxide emissions corresponding to the amount of power ).

The calculation unit 138 estimates a recommended value for the operating ratio of each group 110 based on the energy usage conditions of each of the plurality of groups 110 acquired by the condition acquisition unit 136, and calculates a recommended energy supply source for each group 110. selection, or both.

As described above, contracts with energy supply sources and energy usage conditions are set independently for each group 110. Therefore, for each group 110, a predetermined rate regulation for electricity and a predetermined rate for gas are set. Tariff rules and CO2 emissions corresponding to the amount of electricity may differ.

Therefore, based on the energy usage conditions of each of the plurality of groups 110, the calculation unit 138 calculates a predetermined rate regulation for electricity, a predetermined charge regulation for gas, and a power amount for the entire plurality of groups 110. A recommended value for the operating ratio of each group 110 is estimated so that one or more selected from the group of carbon dioxide emissions corresponding to . For example, when the derived current operation ratio of the group 110a and the group 110b is 100%:100%, when realizing the same operating output, a predetermined rate regulation for electricity and a predetermined rate regulation for gas If the charge regulation and the amount of carbon dioxide emissions corresponding to the amount of electric power of the group 110b is smaller than that of the group 110a, the calculation unit 138 sets the recommended value of the operation ratio of the group 110a and the group 110b to 80%:120%. Guess.

With such a configuration, it is possible to propose a recommended value of the operation ratio that can reduce the electricity fee, the gas fee, and the amount of carbon dioxide emissions resulting from use while maintaining the total operation ratio in the entire air conditioning system 100. It becomes possible.

In recent years, in the same area, multiple power supply companies and multiple gas supply companies have come to supply energy (electricity, gas). It is now possible to select a power supply company or a gas supply company.

Therefore, based on the current energy usage conditions of each of the plurality of groups 110, the calculation unit 138 sets the predetermined rate rules for electricity, the predetermined rate rules for gas, and Selection of an energy supply source that minimizes one or more selected from a group of carbon dioxide emissions corresponding to power consumption is performed.

As a result, it is possible to propose an energy supply source capable of reducing the power charge, the gas charge, and the amount of carbon dioxide emissions resulting from the use of the air conditioning system 100 as a whole.

Next, the operation output value derivation process by the output value derivation unit 116 of the group 110 will be described.

The output value derivation unit 116 derives the operation output value of the GHP unit 210 and the operation output value of the EHP unit 250 in the air conditioner 150 based on the recommended value of the operating ratio estimated by the calculation unit 138 .

Furthermore, the output value derivation unit 116 calculates the GHP unit 210 and the EHP unit based on an operation output value table stored in advance in a storage unit (not shown) within the range of the recommended value of the operating ratio estimated by the calculation unit 138. 250 is derived. Here, the operation output value table is the sum of the power consumption of other devices (for example, lighting, personal computers, refrigerators, etc.) in the group 110 in which the air conditioner 150 is installed and the power consumption of the EHP unit 250, Predetermined rate rules for the gas of the GHP unit 210, predetermined rate rules for the power of the EHP unit 250, operating conditions determined based on the contract power, and demanded in the indoor unit 300 It is for uniquely deriving one operation output value based on the air conditioning load.

FIG. 4 is a diagram showing an operation output value table. FIG. 4 shows an operation output value table in which the operation ratios of the GHP unit 210 and the EHP unit 250 are set when the maximum air conditioning load required in the indoor unit 300 is 200%. An air conditioner 150 designed with a capacity ratio of 100%:100% with respect to the unit 250 will be described as an example.

Further, as operating conditions, "normal A mode" and "normal B mode" are referred to when operating normally, "GHP main mode" is referred to when mainly operating the GHP unit 210, For example, "EHP main mode" which is referred to when driving at high speed, "demand 1 mode" and "demand 2 mode" which are referred to when the power consumption of other equipment is close to the contract power. explain.

For each group 110, the maximum power consumption (kWh) in the group 110 in a predetermined period (for example, one year) (more specifically, for example, the maximum average power consumption for a predetermined period of time (for example, 30 minutes) value) is set. And if you use electricity in excess of the contracted electricity, you will be charged a penalty fee.

Therefore, the output value derivation unit 116 grasps the operating status based on the demand signal from the detector for detecting the power consumption provided in the group 110 in which the air conditioner 150 is installed. The detector detects the difference Z between the contract power and the power consumption of the entire facility (total of the power consumption of other devices in the group 110 in which the air conditioner 150 is installed and the power consumption of the EHP unit 250). In response, demand signal 1 and demand signal 2 are transmitted. Here, for example, when the contract power is 100 kW, the detector sends the demand signal 1 to the output value derivation unit 116 when the difference Z is 30 kW (that is, the power consumption of the entire group 110 is 70 kW). Demand signal 2 is output to output value deriving section 116 when difference Z reaches 10 kW (that is, the power consumption of the entire group 110 is 90 kW).

When neither the demand signal 1 nor the demand signal 2 is received, the output value derivation unit 116 refers to the "normal A mode" or "normal B mode" of the operation output value table to perform normal operation, Operating output values for GHP unit 210 and EHP unit 250 are derived. In the "normal A mode", the GHP unit 210 is started up first when driving the GHP unit 210 and the EHP unit 250 in parallel, and in the "normal B mode", the GHP unit 210 and the EHP unit 250 are driven in parallel. It is configured so that the EHP unit 250 is started up first when it is driven. Therefore, when executing normal operation, the output value derivation unit 116 alternately refers to the “normal A mode” and the “normal B mode”, thereby substantially reducing the number of times the GHP unit 210 and the EHP unit 250 are driven. is homogenized to

Also, in the case of normal operation, for example, depending on the energy supply source, the time of day, etc., the power charge required when the EHP unit 250 is driven at the maximum operation output value is the maximum operation of the GHP unit 210. If it is higher than the cost of the gas required for driving with the output value, the output value deriving unit 116 refers to the "GHP main mode". As a result, the operating output value of the GHP unit 210 can be made higher than that of the EHP unit 250, and the air conditioning load required in the indoor unit 300 can be realized at low cost.

On the other hand, in the case of normal operation, for example, depending on the energy supply source, time of day, etc., the gas charge required when the GHP unit 210 is driven at the maximum operating output value is the maximum operating output value for the EHP unit 250. If it is higher than the charge for the power required for driving with the output value, the output value deriving unit 116 refers to the "EHP main mode". As a result, the operating output value of the EHP unit 250 can be made higher than that of the GHP unit 210, and the air conditioning load required in the indoor unit 300 can be achieved at low cost.

Furthermore, the output value deriving unit 116 receives the demand signal 1 when the power consumption of the entire group 110 is close to the contracted power and the operating output of the EHP unit 250 exceeds the contracted power. In the case, referring to the "demand 1 mode", the total of the power supplied to the EHP unit 250 and the power consumption of other devices falls within a predetermined power value (limit value) less than the contract power, Derive the operating output value.

Specifically, in the "demand 1 mode", the operating output value (e.g., the EHP unit 250 The operating output value is assigned so that the operating output of the engine is 60%). As a result, the output value derivation unit 116 limits the power supplied to the EHP unit 250 so that the sum of the power consumption of the EHP unit 250 and the power consumption of other devices in the facility is less than the contract power. be able to. Therefore, it is possible to avoid a situation in which the total power consumption of the group 110 in which the air conditioning apparatus 150 is installed exceeds the contracted power and a penalty charge is imposed.

At this time, if the predetermined air conditioning load required in the indoor unit 300 cannot be realized, the output value derivation unit 116 causes the GHP unit 210 to start operating if the GHP unit 210 is stopped. , and if the GHP unit 210 is in operation, derive an operating output value that exceeds the current operating output of the GHP unit 210 . This makes it possible to realize the air conditioning load required in the indoor unit 300 while avoiding imposition of penalty charges.

In the "demand 1 mode", when an air conditioning load (for example, 40%, 100%) of the indoor unit 300 that can be realized only by the GHP unit 210 is requested, only the GHP unit 210 is driven. Operating output values are assigned. In addition, when the air conditioning load of the indoor unit 300 (for example, 160%, 200%) that cannot be realized by the GHP unit 210 alone is requested, the EHP unit 250 in addition to the GHP unit 210 is within the limit value at the maximum. The operating output value is assigned so as to drive up to 60% of the operating output value.

In the "demand 1 mode", when the air conditioning load required in the indoor unit 300 is the maximum of 200%, the EHP unit 250 is driven with an operation output value of 60%, which is within the limit value at the maximum. , even if the GHP unit 210 is driven at an operation output value of 100%, it is possible to avoid a situation in which a penalty charge is imposed although the required air conditioning load in the indoor unit 300 cannot be realized.

Further, the output value derivation unit 116 receives the demand signal 2 when the power consumption of the entire group 110 is close to the contracted power and the contracted power is exceeded if the EHP unit 250 is driven. In this case, the output value derivation unit 116 refers to the “demand 2 mode” set so as not to drive the EHP unit 250 . As a result, the output value derivation unit 116 can prevent the air conditioner 150 from exceeding the contract power.

As described above, according to the air conditioning system 100 according to the present embodiment, with the configuration including the host control device 130, a plurality of When the air conditioners 150 are arranged under different energy usage conditions, it is possible to comprehensively understand and control a plurality of air conditioners 150 .

In addition, since the GHP unit 210 and the EHP unit 250 are independently configured in the air conditioner 150, the refrigerant is supplied to the indoor heat exchanger 320 even if one of the GHP unit 210 and the EHP unit 250 fails. The air can be circulated, and the air conditioner 150 can be operated.

In addition, since the GHP unit 210 and the EHP unit 250 are separate units, the air conditioner 150 can be configured by increasing or decreasing the number of the GHP units 210 and the number of the EHP units 250. It is possible to increase or decrease the capacity. Therefore, there is no need to increase the size of the parts of one GHP unit 210 itself or the parts of one EHP unit 250 itself, and it is possible to avoid an increase in cost due to an increase in the size of the parts.

[First modification]
In the above embodiment, the output value derivation unit 116 is configured so that the total amount of power consumption of the EHP unit 250 and the power consumption of other devices in the group 110 falls within a predetermined limit value less than the contract power. , the operating output value of the EHP unit 250 is derived.

However, the output value derivation unit 116 may derive the operation output value of the EHP unit 250 so that the amount of carbon dioxide emissions generated by the use of electric power by the EHP unit 250 falls within a predetermined limit value. . With such a configuration, it is possible to suppress the amount of carbon dioxide emissions caused by operating the air conditioner 150 to a predetermined amount.

[Second modification]
In the above embodiment, the GHP unit 210 was taken as an example of the gas consumption unit that functions as the outdoor unit. However, the gas consumption unit is not limited to its configuration as long as it has a gas consumption device and can heat or cool the refrigerant or water. For example, the gas consuming unit may be a GHP chiller 500 that heats or cools water, or an absorption chiller heater 600 .

Further, in the above embodiment and the first modified example, the EHP unit 250 is taken as an example of the power consumption unit that functions as the outdoor unit. However, the power consuming unit has power consuming equipment and is not limited in configuration as long as it can heat or cool coolant or water. For example, the power consuming unit may be an EHP chiller 700 that heats or cools water, or a turbo chiller 800 .

When the gas consumption unit is the GHP chiller 500 or the absorption chiller-heater 600, and when the power consumption unit is the EHP chiller 700 or the centrifugal chiller 800, the indoor unit 300 The decompression unit 310 is not provided. Water heated or cooled by the GHP chiller 500, the absorption chiller/heater 600, the EHP chiller 700, or the turbo chiller 800 circulates through the indoor unit 300 (indoor heat exchanger 320).

Examples of the GHP chiller 500, the absorption chiller-heater 600, the EHP chiller 700, and the centrifugal chiller 800 will be described below.

[GHP Chiller 500]
FIG. 5 is a diagram illustrating the GHP chiller 500. As shown in FIG. In FIG. 5, the flow of the refrigerant during cooling is indicated by solid arrows. Further, in FIG. 5, the flow of cooling water is indicated by dashed arrows.

As shown in FIG. 5, the GHP chiller 500 includes a refrigerant pipe 510 through which refrigerant circulates, a gas engine 512 (gas consuming device), and an engine-driven compressor 514 (gas consuming device) driven by the gas engine 512. , a four-way valve 520, a chiller outdoor heat exchanger 530 that exchanges heat between the refrigerant and outdoor air, a chiller air blowing unit 532 that sends air to the chiller outdoor heat exchanger 530 to promote heat exchange, and decompresses the refrigerant. It includes a decompression unit 540 (expansion valve), a cooling water heat exchanger 550 and a chiller control unit 560 .

The outlet of the engine-driven compressor 514 is connected by a refrigerant pipe 510 to the first port of the four-way valve 520 (indicated by “1” in FIG. 5), and the inlet of the engine-driven compressor 514 is connected by the refrigerant pipe 510 It is connected to the third port of valve 520 (indicated by "3" in FIG. 5). In addition, one end side of the chiller outdoor heat exchanger 530 is connected to the second port (indicated by “2” in FIG. 5 ) of the four-way valve 520 through the refrigerant pipe 510 . The other end side of the chiller outdoor heat exchanger 530 is connected to one end side of the decompression section 540 by the refrigerant pipe 510 . The other end side of pressure reducing section 540 is connected to one end side of cooling water heat exchanger 550 by refrigerant pipe 510 . The other end of the cooling water heat exchanger 550 is connected to the fourth port (indicated by “4” in FIG. 5) of the four-way valve 520 through a refrigerant pipe 510 . Therefore, when the engine-driven compressor 514 is driven, the refrigerant circulates through the refrigerant pipes 510 and the refrigerant pipes 510 form a series of circulation paths.

Also, the cooling water heat exchanger 550 exchanges heat between the refrigerant and the cooling water returned from the indoor heat exchanger 320 through the cooling water return pipe 10 . The cooling water heat-exchanged by the cooling water heat exchanger 550 is led to the indoor heat exchanger 320 through the cooling water feed pipe 20 .

The chiller control unit 560 is composed of a semiconductor integrated circuit including a CPU (central processing unit), and based on the control command from the operation control unit 118, the entire GHP chiller 500 (for example, the gas engine 512, the chiller blower unit 532, various sensors, etc.).

When the indoor unit 300 is to function as a cooler, the first port and second port of the four-way valve 520 are connected, and the fourth port and third port are connected. , and the compressed refrigerant is delivered to the chiller outdoor heat exchanger 530 . On the other hand, when the indoor unit 300 functions as a heater, by connecting the first port and the fourth port of the four-way valve 520 and connecting the second port and the third port, the solid line arrow in FIG. , and the compressed refrigerant is delivered to the cooling water heat exchanger 550 .

[Absorption chiller heater 600]
FIG. 6 is a diagram illustrating an absorption chiller-heater 600. As shown in FIG. As shown in FIG. 6, the absorption chiller-heater 600 (gas consuming equipment) includes an evaporator 610, an absorber 620, a regenerator 630, a condenser 640, a cooling tower 650, and a cooling water circulation path 660. , and a chiller/heater controller 670 . In FIG. 6, the flow of water, absorption liquid, and water vapor circulating in the absorption chiller-heater 600 is indicated by solid-line arrows. In FIG. 6, the flow of the cooling water circulating in the cooling water circulation path 660 is indicated by dashed-dotted arrows. Further, in FIG. 6, the flow of cooling water circulating in the indoor heat exchanger 320 is indicated by dashed arrows.

Evaporator 610 includes an evaporative heat exchanger 612 therein. The evaporative heat exchanger 612 has one end connected to the cooling water return pipe 10 and the other end connected to the cooling water feed pipe 20 . When the indoor unit 300 functions as a cooler, the evaporator 610 evaporates water (liquid) guided from a condenser 640, which will be described later, and cools the evaporative heat exchanger 612 with the heat of vaporization. Also, when the indoor unit 300 functions as a heater, the evaporator 610 heats the evaporative heat exchanger 612 with high-temperature steam guided from the regenerator 630, which will be described later.

In the evaporator 610 , the steam after heat exchange with the evaporative heat exchanger 612 is guided to the absorber 620 .

The absorber 620 brings the water vapor led from the evaporator 610 into contact with the absorbent (lean absorbent) led from the later-described regenerator 630 to dissolve the water vapor into the absorbent. The absorption liquid is, for example, an aqueous solution of lithium bromide. The absorbing liquid in which water vapor is dissolved (rich absorbing liquid) is led to the regenerator 630 .

Also provided within the absorber 620 is an absorption heat exchanger 622 for cooling the absorbing liquid in order to improve the dissolution of water vapor into the absorbing liquid.

The regenerator 630 (gas consuming device) has a burner that burns gas, and heats the rich absorbent with the burner. Then, the water vapor is vaporized from the rich absorbing liquid, and the water vapor is removed from the rich absorbing liquid. In regenerator 630 , vaporized water vapor is led to evaporator 610 or condenser 640 . Also, the lean absorbent from which water vapor has been removed is returned to absorber 620 .

Condenser 640 includes a condensing heat exchanger 642 therein. Condensing heat exchanger 642 heat-exchanges cooling water guided from cooling tower 650 through cooling water circulation path 660 (to be described later) and steam guided from regenerator 630 . This cools (condenses) the water vapor into water. Water produced in condenser 640 is led to evaporator 610 .

Cooling tower 650 includes tower heat exchanger 652 therein. The tower heat exchanger 652 exchanges heat between the cooling water led from the condensing heat exchanger 642 through the cooling water circuit 660 and the outside air. The cooling water cooled by the condensation heat exchanger 642 is led to the absorption heat exchanger 622 through the cooling water circulation path 660 .

The cooling water heated by heat exchange with the absorbing liquid in the absorption heat exchanger 622 is further heated in the condensation heat exchanger 642 and guided to the tower heat exchanger 652 .

The chiller/heater controller 670 is composed of a semiconductor integrated circuit including a CPU (Central Processing Unit), and controls the entire absorption chiller/heater 600 (for example, burner, valve 680, etc.) based on control commands from the operation controller 118. , 682, various sensors, etc.).

When the indoor unit 300 is to function as a heater, the chiller/heater controller 670 opens the valve 680 provided in the pipe connecting the regenerator 630 and the evaporator 610, and the regenerator 630 and the condenser 640 closes the valve 682 provided in the pipe connecting the . Further, when the indoor unit 300 functions as cooling, the chiller/heater controller 670 closes the valve 680 provided in the pipe connecting the regenerator 630 and the evaporator 610, and closes the regenerator 630 and the condenser. The valve 682 provided in the pipe connecting the 640 is opened.

[EHP Chiller 700]
FIG. 7 is a diagram illustrating an EHP chiller 700. As shown in FIG. In FIG. 7, the flow of the refrigerant during cooling is indicated by solid arrows. Further, in FIG. 7, the flow of cooling water is indicated by dashed arrows.

As shown in FIG. 7, the EHP chiller 700 includes a refrigerant pipe 710 through which refrigerant circulates, an electric motor 712 (power consumption device), an electrically driven compressor 714 (power consumption device) using the electric motor 712 as a drive source, A four-way valve 720, a chiller outdoor heat exchanger 730 that exchanges heat between the refrigerant and outdoor air, a chiller air blower 732 that sends air to the chiller outdoor heat exchanger 730 to promote heat exchange, and a pressure reduction that reduces the pressure of the refrigerant. It includes a section 740 (expansion valve), a cooling water heat exchanger 750 and a chiller control section 760 .

The outlet of the electrically driven compressor 714 is connected by a refrigerant pipe 710 to the first port of the four-way valve 720 (indicated by “1” in FIG. 7), and the inlet of the electrically driven compressor 714 is connected by the refrigerant pipe 710 It is connected to the third port of valve 720 (indicated by "3" in FIG. 7). One end side of the chiller outdoor heat exchanger 730 is connected to the second port (indicated by “2” in FIG. 7) of the four-way valve 720 through a refrigerant pipe 710 . The other end side of the chiller outdoor heat exchanger 730 is connected to one end side of the decompression section 740 by a refrigerant pipe 710 . The other end of decompression section 740 is connected to one end of cooling water heat exchanger 750 by refrigerant pipe 710 . The other end of the cooling water heat exchanger 750 is connected to the fourth port (indicated by “4” in FIG. 7) of the four-way valve 720 via a refrigerant pipe 710 . Therefore, when the electrically driven compressor 714 is driven, the refrigerant circulates through the refrigerant pipes 710 and the refrigerant pipes 710 form a series of circulation paths.

Also, the cooling water heat exchanger 750 exchanges heat between the refrigerant and the cooling water returned from the indoor heat exchanger 320 through the cooling water return pipe 10 . The cooling water heat-exchanged by the cooling water heat exchanger 750 is led to the indoor heat exchanger 320 through the cooling water feed pipe 20 .

The chiller control unit 760 is composed of a semiconductor integrated circuit including a CPU (Central Processing Unit), and based on control commands from the operation control unit 118, controls the entire EHP chiller 700 (for example, the electric motor 712, the chiller blower unit 732, various sensors, etc.).

When the indoor unit 300 is to function as a cooler, the first port and second port of the four-way valve 720 are connected, and the fourth port and third port are connected. , and the compressed refrigerant is delivered to the chiller outdoor heat exchanger 730 . On the other hand, when the indoor unit 300 functions as a heater, by connecting the first port and the fourth port of the four-way valve 720 and connecting the second port and the third port, the solid line arrow in FIG. The refrigerant is circulated in the direction opposite to the direction indicated by , and the compressed refrigerant is delivered to the cooling water heat exchanger 750 .

[Turbo refrigerator 800]
FIG. 8 is a diagram illustrating a turbo chiller 800. As shown in FIG. The turbo chiller 800 causes the indoor unit 300 to function as a cooler. As shown in FIG. 8, a turbo chiller 800 includes a refrigerant pipe 810 through which a refrigerant circulates, an electric motor 812 (power consumption device), and an electrically driven turbo compressor 814 (power consumption device) driven by the electric motor 812. , a condenser 820 , a decompression section 830 , an evaporator 840 and a turbo control section 850 . In addition, in FIG. 8, the flow of the refrigerant is indicated by solid arrows. Further, in FIG. 8, the flow of cooling water circulating in the indoor heat exchanger 320 is indicated by dashed arrows.

An electrically driven turbo compressor 814 compresses the refrigerant. The electrically driven turbo compressor 814 is, for example, a centrifugal compressor. Refrigerant compressed by electrically driven turbo compressor 814 is directed to condenser 820 .

Condenser 820 includes a condensing heat exchanger 822 therein. Cooling water cooled by a cooling tower (not shown) or an air heat exchanger is guided to the condensing heat exchanger 822 . The cooling water heated by exchanging heat with the refrigerant in the condensing heat exchanger 822 is returned to the cooling tower or the air heat exchanger.

The decompression unit 830 is composed of an expansion valve or an economizer. The refrigerant expanded by decompression section 830 is guided to evaporator 840 .

Evaporator 840 includes a cooling water heat exchanger 842 therein. The cooling water heat exchanger 842 exchanges heat between the refrigerant and the cooling water returned from the indoor heat exchanger 320 through the cooling water return pipe 10 . The cooling water heat-exchanged by the cooling water heat exchanger 842 is led to the indoor heat exchanger 320 through the cooling water feed pipe 20 .

The turbo control unit 850 is composed of a semiconductor integrated circuit including a CPU (Central Processing Unit), and controls the entire turbo chiller 800 (for example, the electric motor 812, various sensors, etc.) based on control commands from the operation control unit 118. Control.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, it goes without saying that the present invention is not limited to such embodiments. It is obvious that a person skilled in the art can conceive of various modifications or modifications within the scope described in the claims, and these also belong to the technical scope of the present invention. Understood.

For example, in the above-described embodiment, a configuration using a demand signal has been described as an example in order to grasp the tightness of the power consumption of the entire facility. However, the amount of power used by other equipment in the facility is input in advance, the amount of power used by the GHP unit 210 and the EHP unit 250 is estimated, and the input amount of power used by the other equipment and the GHP unit 210 and the estimated power consumption of the EHP unit 250 may be used to grasp the tightness of the power consumption of the entire facility.

Further, in the embodiment and the first modification described above, the GHP unit 210 is used as the gas consumption unit, and the EHP unit 250 is used as the power consumption unit. However, one or more selected from the group of the GHP unit 210, the GHP chiller 500, and the absorption chiller-heater 600 may be adopted as the gas consumption unit. Also, one or more selected from the group of EHP unit 250, EHP chiller 700, and centrifugal chiller 800 may be employed as power consumption units.

Also, the air conditioner 150 may include a plurality of power consumption units. Similarly, the air conditioner 150 may comprise multiple gas consumption units.

INDUSTRIAL APPLICABILITY The present invention can be used in an air conditioning system having a plurality of groups each including one or more air conditioners.

100 air conditioning system 110 group 114 group communication unit 116 output value derivation unit 118 operation control unit 130 host control device 134 host communication unit 136 condition acquisition unit 138 calculation unit 150 air conditioner 210 GHP unit (gas consumption unit)
212 gas engines (gas consuming equipment)
214 Engine Driven Compressors (Gas Consuming Equipment)
250 EHP unit (power consumption unit)
252 Electric Motors (Power Consuming Devices)
254 Electrically Driven Compressors (Power Consuming Equipment)
300 indoor unit 320 indoor heat exchanger 322 indoor blower 500 GHP chiller (gas consumption unit)
512 Gas Engines (Gas Consuming Equipment)
514 Engine Driven Compressor (Gas Consuming Equipment)
600 Absorption chiller heater (gas consumption unit)
630 regenerator (gas consuming equipment)
700 EHP chiller (power consumption unit)
712 Electric Motors (Power Consuming Devices)
714 Electrically Driven Compressors (Power Consuming Equipment)
800 turbo refrigerator (power consumption unit)
812 Electric Motors (Power Consuming Devices)
814 Electric Driven Turbo Compressor (Power Consuming Equipment)

Claims (5)

An air conditioning system comprising a plurality of groups including one or more air conditioners and a host controller communicating with each group,
The air conditioner is
a gas consuming unit having a gas consuming device for heating or cooling a refrigerant or water;
a power consuming unit configured independently of the gas consuming unit and having a power consuming device for heating or cooling a refrigerant or water;
An indoor heat exchanger that exchanges heat between the refrigerant or water heated or cooled by the gas consumption unit and the power consumption unit and indoor air, and an indoor heat exchanger that sends air to the indoor heat exchanger to promote heat exchange. one or more indoor units having a blower;
with
The plurality of groups are owned by one business operator,
Said group is
Contracts with power supply companies , contracts with gas supply companies, and energy usage conditions are set independently from other groups.
A group communication unit that communicates with the host control device,
The host controller,
a host communication unit that communicates with each of the plurality of groups;
a condition acquisition unit that acquires energy usage conditions for each of the plurality of groups through the host communication unit;
a calculation unit that selects a recommended power supply company and gas supply company for each group based on the acquired energy usage conditions;
with
The energy usage conditions are a predetermined rate regulation for electricity, a predetermined rate regulation for gas, and a carbon dioxide emission amount corresponding to the amount of power,
The computing unit selects one or more from the group of a predetermined rate rule for electricity, a predetermined rate rule for gas, and a carbon dioxide emission amount corresponding to the amount of power for the entire plurality of groups. An air conditioning system that estimates a recommended value for the operation ratio of air conditioners in each group and selects a recommended power supply company and gas supply company for each group so as to minimize the Said group is
an output value derivation unit that derives an operation output value of the gas consumption unit and an operation output value of the power consumption unit in the air conditioner based on the recommended value of the operation ratio estimated by the calculation unit;
an operation control unit that controls the operation output of the gas consumption unit and the operation output of the power consumption unit in the air conditioner so as to achieve the operation output value derived by the output value derivation unit;
The air conditioning system of claim 1, comprising: Each group is set with a contract power, which is the maximum amount of power used in the group for a predetermined period of time,
If the group uses power in excess of the contracted power, a penalty charge will be imposed;
The output value deriving unit calculates the power consumption so that the sum of the power consumption of the power consumption unit and the power consumption of the other devices in the group falls within a predetermined limit value less than the contract power. 3. The air conditioning system according to claim 2 , wherein the operating output value of the unit is derived. When the output value derivation unit derives the operation output value of the power consumption unit so as to fall within the predetermined limit value, the predetermined air conditioning load required in the indoor unit cannot be realized. In this case, the operation output value is derived so that the operation of the gas consuming unit is started when the gas consuming unit is stopped, and the current value of the gas consuming unit is calculated when the gas consuming unit is in operation. 4. The air conditioning system according to claim 3 , wherein an operating output value exceeding the operating output of is derived. 2. The output value derivation unit derives the operation output value of the power consumption unit so that the amount of carbon dioxide emissions generated by the power consumption of the power consumption unit falls within a predetermined limit value. The air conditioning system according to .

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