JP7201495B2 - air conditioning system - Google Patents

Description

The present invention relates to air conditioning systems.

Conventionally, a cogeneration system is known (see Patent Literature 1, for example). This cogeneration system consists of a hot water heating section that heats hot water by recovering exhaust heat from a power generation section, and a hot water heating section that stores the hot water heated by the hot water heating section and supplies the hot water to a predetermined hot water outlet or heat load. It comprises a hot water storage tank provided so as to be able to supply hot water, an auxiliary heat source machine having a burner and a heat exchanger, and a control means.

Further, conventionally, an air conditioner is known that includes a hot water supply device including a hot water source such as a boiler in addition to a compressor and an expansion valve that constitute a refrigeration cycle (see, for example, Patent Document 2).

In this air conditioner, during dry operation, the refrigerant from the compressor is flowed to the outdoor heat exchanger for air cooling, and the air-cooled refrigerant returns to the compressor through the expansion valve and the indoor refrigerant heat exchanger, A cooled cold refrigerant flows through the . The air sucked from the front opening at the center of the front surface of the indoor unit is cooled by the indoor refrigerant heat exchanger and moisture is removed.

During dry operation, hot water from the hot water supply device flows through the hot water heat exchanger. The air cooled by the indoor refrigerant heat exchanger and dehydrated is warmed by the hot water heat exchanger and returned to an appropriate temperature, and is blown out from the outlet (Patent Document 2, paragraphs [0021], [0022] and [ 0026], etc.).

In the cogeneration system described in Patent Document 1, the hot water in the hot water storage tank can be supplied to the heat load (see claim 1 of Patent Document 1). If a hot water heat exchanger as described in Patent Document 2 is employed as this heat load, a highly efficient hot water air conditioner incorporated in a cogeneration system can be configured.

JP 2014-25681 A JP-A-2006-132846

By the way, in the cogeneration system, when the remaining amount of hot water in the hot water storage tank becomes 0 or falls below the allowable lower limit, the hot water cannot be used. In this case, the auxiliary heat source machine is operated to make up for the shortage of heat due to the unavailability of hot water.

In the cogeneration system, the cost of generating the exhaust heat recovered from the power generation section is low, and the utilization of the exhaust heat recovered from the power generation section is highly energy-saving. On the other hand, the heat generated by operating the auxiliary heat source equipment is expensive to generate, and the energy efficiency of using the heat generated by operating the auxiliary heat source equipment is low. For this reason, in a cogeneration system, the auxiliary heat source machine should not be operated as much as possible, and a large amount of hot water collected from the power generation unit should be stored in a hot water storage tank, and the hot water stored in this hot water storage tank should be used. preferable.

In the case of the conventional example described above, when the amount of hot water remaining in the hot water storage tank is large, even if the hot water stored in the hot water storage tank is used for the hot water air conditioner, the auxiliary heat source machine does not operate, resulting in high energy saving.

However, when the remaining amount of hot water in the hot water storage tank becomes 0 or falls below the allowable lower limit, the auxiliary heat source machine operates, resulting in low energy efficiency. Moreover, if the use of the auxiliary heat source is not presupposed, the use of hot water in the hot water air conditioner is stopped, so that the hot water air conditioner cannot be used continuously.

SUMMARY OF THE INVENTION It is an object of the present invention to provide an air conditioning system that can continuously use hot water while maintaining high energy efficiency.

In order to solve the above problems, an air conditioning system according to claim 1 includes a heat pump unit, a hot water storage unit, a hot water heat exchanger, and a control unit. The heat pump unit includes a compressor, an outdoor refrigerant heat exchanger, an expansion mechanism, and an indoor refrigerant heat exchanger that exchanges heat with air blown into the room. The hot water storage unit includes: a power generation section; a hot water flow path through which hot water collected by exhaust heat from the power generation section flows; a hot water storage section provided in the hot water flow path; a hot water flow adjusting section for adjusting the amount of hot water discharged from the hot water flow path; and a hot water supply section for supplying hot water to the hot water flow path or the hot water storage section. The hot water heat exchanger is provided in the hot water outlet passage, and heat-exchanges with the air blown into the room through which the hot water flows. The controller controls the heat pump unit and the hot water storage unit.

When the heat pump unit and the hot water storage unit are operated and the air heat-exchanged with the indoor refrigerant heat exchanger and the hot water heat exchanger is blown into the room , the hot water recovery operation is performed. The stored hot water amount recovery operation is an operation for controlling the output hot water amount adjusting unit to reduce the output hot water amount when the amount of hot water stored in the hot water storage unit has decreased to an allowable lower limit value.

Further, the invention according to claim 2 is the invention according to claim 1, wherein the operation in which the air heat-exchanged with the indoor-side refrigerant heat exchanger and the hot water heat exchanger is blown indoors is performed when the air is blown into the room. It is a reheat dehumidifying operation in which the refrigerant is cooled by the inner refrigerant heat exchanger and heated by the hot water heat exchanger. When the amount of hot water stored in the hot water storage unit decreases to a lower limit preliminary value that is larger than the allowable lower limit by a predetermined amount while the reheat dehumidifying operation is being performed, the control unit and stores the operating state of the heat pump unit.

According to a third aspect of the invention, in the second aspect of the invention, the air-conditioning system further includes a blowout temperature detection section for detecting a blowout temperature of the air blown into the room. The control unit changes the stored operating state of the heat pump unit when the amount of hot water stored in the hot water storage unit decreases to the allowable lower limit when the reheat dehumidification operation is being performed. Based on this, the heat pump unit is controlled so that the blowing temperature is maintained within a predetermined range.

Further, the invention according to claim 4 is the invention according to claim 2, wherein, when the reheat dehumidification operation is being performed, the control unit controls the amount of hot water stored in the hot water storage unit to be within the allowable range. When the temperature has decreased to the lower limit, the heat pump unit is controlled based on the stored operating state of the heat pump unit so that the ability of the indoor refrigerant heat exchanger to cool the air is maintained within a predetermined range. do.

In the invention according to claim 1, the amount of hot water output is reduced by the stored hot water amount recovery operation. As a result, the amount of hot water stored becomes less than the allowable lower limit, hot water stored in the hot water storage part cannot be discharged, and the interruption of hot water use in the hot water heat exchanger is suppressed, and continuous hot water in the hot water heat exchanger is suppressed. can be used. In addition, the continuous use of hot water in the hot water heat exchanger means that the exhaust heat collected from the power generation unit is continuously used, so energy saving is high.

In the invention according to claim 2, in the reheat dehumidifying operation, the stored hot water amount recovery operation can be performed based on the operating state before the stored hot water amount recovery operation.

In the invention according to claim 3, the blow-out temperature is maintained within a predetermined range in the reheat dehumidification operation.

In the invention according to claim 4, in the reheat dehumidifying operation, the ability of the indoor-side refrigerant heat exchanger to cool air is maintained within a predetermined range.

Drawing 1 is a lineblock diagram showing roughly the whole air-conditioning system concerning a first embodiment. FIG. 2 is a block diagram showing a control system of the air conditioning system of the same. FIG. 3 is a flowchart of hot water storage amount recovery control in Operation Example 1 of the air conditioning system according to the second embodiment. FIG. 4 is a flowchart of hot water storage amount recovery control in Operation Example 2 of the air conditioning system. FIG. 5 is a diagram showing the relationship between the coefficient of performance and the load in the refrigeration cycle of the air conditioning system. FIG. 6 is a flowchart of refrigerating cycle optimization control in Operation Example 2 of the air conditioning system.

TECHNICAL FIELD The present disclosure relates to an air conditioning system (air conditioning system), and more particularly to an air conditioning system including a heat pump unit and a hot water storage unit. A first embodiment of an air conditioning system according to the present disclosure will be described below with reference to FIGS. 1 and 2. FIG. The embodiments of the air conditioning system according to the present disclosure are not limited to the following embodiments, and various modifications are possible without departing from the technical idea of the present disclosure.

The air conditioning system not only establishes a refrigerating cycle with a heat pump unit, but also heats the air blown into the room via hot water and water that are unrelated to the refrigerating cycle. As shown in FIG. 1, the air conditioning system 1 includes a heat pump unit 2, a hot water storage unit 3, a hot water heat exchanger 4, and a controller 10 (see FIG. 2). The air conditioning system 1 of the first embodiment is a so-called hot water air conditioner incorporated in a cogeneration system, and has a reheat dehumidification function.

The heat pump unit 2 has a compressor 21, an outdoor refrigerant heat exchanger 22, an expansion mechanism 23, an indoor refrigerant heat exchanger 24, and a heat pump controller 20 (see FIG. 2). A refrigerating cycle is established by operating the heat pump unit 2 .

The heat pump unit 2 has an outdoor unit 201 and an indoor unit 202 . The outdoor unit 201 includes a casing (not shown), a compressor 21 housed in the casing, an outdoor refrigerant heat exchanger 22, an expansion mechanism 23, a four-way valve 25, a blower device 26, and other devices. have.

The expansion mechanism 23 is composed of a capillary tube, an electronic expansion valve, or the like. One end of the flow path of the expansion mechanism 23 is connected to one end of the flow path of the outdoor refrigerant heat exchanger 22 via the refrigerant flow path 27 . The outdoor refrigerant heat exchanger 22 is arranged in the middle of an outdoor air flow path (not shown) inside the outdoor unit 201 . The casing of the outdoor unit 201 has an intake port (not shown) for sucking outside air and an outlet port (not shown) for blowing out air. It is formed. A fan as a blower 26 is further arranged in the middle of the outside air flow path.

The other end of the flow path of the outdoor refrigerant heat exchanger 22 is connected to the first port 251 of the four-way valve 25 via the refrigerant flow path 27 . A second port 252 of the four-way valve 25 is connected to one end of the flow path of the compressor 21 via the refrigerant flow path 27 . The other end of the flow path of compressor 21 is connected to third port 253 of four-way valve 25 via refrigerant flow path 27 . The refrigerant flow path 27 connected to the other end of the flow path of the expansion mechanism 23 and the refrigerant flow path 27 connected to the fourth port 254 of the four-way valve 25 are led out from the outdoor unit 201 and supplied to the indoor unit 202. be introduced.

The indoor unit 202 has a casing (not shown), and equipment such as an indoor-side refrigerant heat exchanger 24, a hot water heat exchanger 4, and a blower 28 housed in the casing. However, although the hot water heat exchanger 4 is an element that constitutes the air conditioning system 1, it is not an element that constitutes the heat pump unit 2 (that is, an element for establishing a refrigeration cycle). The casing of the indoor unit 202 has an intake port (not shown) for sucking indoor air and an outlet port (not shown) for blowing out air. A path (not shown) is formed. An indoor refrigerant heat exchanger 24, a hot water heat exchanger 4, and a fan as a blower 28 are arranged in this order from the inlet side to the outlet side in the middle of the indoor flow path.

The indoor-side refrigerant heat exchanger 24 exchanges heat with the air blown into the room. More specifically, the indoor-side refrigerant heat exchanger 24 cools the air flowing through the indoor flow path during cooling operation or reheat dehumidification operation (dry operation), which will be described later. Further, as will be described later, the hot water heat exchanger 4 imparts heat to the air flowing through the indoor flow path during the reheat dehumidification operation.

One end of the flow path of the indoor-side refrigerant heat exchanger 24 is connected to the fourth port 254 of the four-way valve 25 via the refrigerant flow path 27 . The other end of the flow path of the indoor-side refrigerant heat exchanger 24 is connected to the other end of the flow path of the expansion mechanism 23 via the refrigerant flow path 27 .

The four-way valve 25 has a state in which the first port 251 and the second port 252 communicate and a third port 253 and a fourth port 254 communicate, and a state in which the first port 251 and the third port 253 communicate. It can be arbitrarily switched to either state in which both the second port 252 and the fourth port 254 are in communication.

The heat pump control section 20 controls the heat pump unit 2 . The heat pump control unit 20 has, for example, a microcomputer, and controls the operations of the elements constituting the heat pump unit 2 by executing programs stored in a storage medium such as a ROM (Read Only Memory). Specifically, the heat pump control unit 20 controls the amount of refrigerant conveyed by the compressor 21 per unit time (l/s), the unit Air volume per hour (m ³ /s) and switching of the four-way valve 25 can be controlled. The heat pump control unit 20 is provided in the indoor unit 202, but may be provided in the outdoor unit 201, and the place of installation is not particularly limited.

The heat pump unit 2 includes a suction temperature detector 203 (see FIG. 2) in the first embodiment. The suction temperature detection unit 203 is arranged near the suction port of the indoor flow path of the indoor unit 202 . The suction temperature detection unit 203 is composed of a thermistor, but various temperature sensors can be appropriately used in addition to the thermistor, and there is no particular limitation. The suction temperature detection unit 203 detects the suction temperature Tr (° C.) of the air sucked into the indoor flow path of the indoor unit 202 (that is, the indoor temperature). The suction temperature Tr information detected by the suction temperature detection unit 203 is received by the heat pump control unit 20 .

The heat pump unit 2 in the first embodiment includes an outside air temperature detector 204 (see FIG. 2). The outside air temperature detection unit 204 is arranged near the intake port of the outside air passage of the outdoor unit 201 . The outside air temperature detection unit 204 is composed of a thermistor, but various temperature sensors other than the thermistor can be used as appropriate, and are not particularly limited. The outside air temperature detection unit 204 detects the outside air temperature To (° C.) of the air (outside air) sucked into the outside air flow path of the outdoor unit 201 . The outside temperature To information detected by the outside temperature detection unit 204 is received by the heat pump control unit 20 .

The heat pump unit 2 is equipped with the blowing temperature detection part 205 (refer FIG. 2) in 1st embodiment. The blowout temperature detection unit 205 is arranged near the blowout port of the indoor flow path of the indoor unit 202 . Blow-out temperature detection unit 205 is composed of a thermistor, but various temperature sensors other than thermistor can be used as appropriate, and are not particularly limited. Blow-out temperature detection unit 205 detects a blow-out temperature Ts (° C.) of air flowing through an indoor flow path of indoor unit 202 and blown out from a blow-out port. The blowing temperature Ts information detected by the blowing temperature detection unit 205 is received by the heat pump control unit 20 .

The heat pump unit 2 includes an air conditioning operation section 29 (see FIG. 2) in the first embodiment. The user can arbitrarily set the indoor target temperature Ta (° C.) and the air volume q (m ³ /s) blown out from the outlet of the indoor unit 202 by operating the air conditioning operation unit 29 . Information on the indoor target temperature Ta and the air volume q input from the air conditioning operation unit 29 is received by the heat pump control unit 20 .

This heat pump unit 2 can selectively operate cooling operation and heating operation by a refrigeration cycle. In the cooling operation, the heat pump control unit 20 puts the four-way valve 25 in a state in which the first port 251 and the second port 252 communicate and the third port 253 and the fourth port 254 communicate. As a result, a refrigerant flow path 27 leading to the compressor 21, the outdoor refrigerant heat exchanger 22 (condenser), the expansion mechanism 23, the indoor refrigerant heat exchanger 24 (evaporator), and the compressor 21 is formed. A refrigeration cycle for cooling operation is established.

In the cooling operation, the heat pump control unit 20 controls the suction temperature Tr so that it becomes the indoor target temperature Ta. The indoor target temperature Ta is a generally comfortable temperature such as 26°C. The heat pump control unit 20 performs feedback control, for example, so that the suction temperature Tr falls within a predetermined temperature range including the indoor target temperature Ta. The predetermined temperature range is a temperature range between the allowable upper limit temperature Tu (° C.), which is equal to or higher than the indoor target temperature Ta, and the allowable lower limit temperature Tl (° C.). Specifically, the heat pump control unit 20 adjusts the number of revolutions per unit time of the motor of the compressor 21 to control the amount of refrigerant conveyed. The heat pump control unit 20 also adjusts the number of revolutions per unit time of the motor of the air blower 28 arranged in the indoor unit 202 to control the air volume q blown out from the outlet of the indoor unit 202 . Also, the heat pump control unit 20 adjusts the number of revolutions per unit time of the motor of the blower device 26 arranged in the outdoor unit 201 to control the amount of air flowing through the outdoor air flow path of the outdoor unit 201 .

In the heating operation, the four-way valve 25 is set so that the first port 251 communicates with the third port 253 and the second port 252 communicates with the fourth port 254 . As a result, a refrigerant flow path 27 is formed that leads to the compressor 21, the indoor refrigerant heat exchanger 24 (condenser), the expansion mechanism 23, the outdoor refrigerant heat exchanger 22 (evaporator), and the compressor 21 again. , heating operation is performed. The heat pump control unit 20 controls the suction temperature Tr so that it becomes the indoor target temperature Ta in the same manner as in the cooling operation. Such a heat pump unit 2 is conventionally widely known, various types can be used as appropriate, and there is no particular limitation. Also, the heat pump unit 2 may appropriately have a device such as an accumulator.

The hot water storage unit 3 includes hot water, a power generation section 31, a hot water flow path 32, a hot water storage section 33, a hot water discharge flow path 34, a hot water discharge amount adjustment section 35, a hot water supply section 36, and a hot water storage control section 30 (Fig. 2 ) and In the first embodiment, hot water (water) is used as a heat medium for recovering exhaust heat from the power generation unit 31, but it does not have to be hot water, and other liquids and various solutions may be used. not.

The power generation unit 31 heats hot water. In the first embodiment, the power generation unit 31 is configured by a polymer electrolyte fuel cell (abbreviated as PEFC). Heat (exhaust heat) generated in the fuel cell along with power generation is applied to hot water via the heat exchanger 311 . Note that the power generation unit 31 is not limited to a PEFC, and may be another type of fuel cell, or may be other than a fuel cell. For example, the power generation unit 31 may be a power generation device that operates a generator with an engine or a gas turbine.

Hot water from which exhaust heat is recovered from the power generation unit 31 flows through the hot water flow path 32 . The hot water channel 32 has a conveying device 321 such as a pump and a flow control valve 322 on the way.

The hot water storage part 33 is provided in the hot water flow path 32 . The hot water storage part 33 stores hot water flowing through the hot water flow path 32 . The hot water storage unit 33 is configured by a hot water storage tank in the first embodiment, but may not be configured by a hot water storage tank, and is not limited. The hot water channel 32 and the hot water storage part 33 form a circulating hot water channel.

Hot water outlet channel 34 is a channel for outlet of hot water from hot water storage unit 33 . The upstream end of hot water outlet channel 34 is connected to the upper portion (upper end) of hot water storage portion 33 . A hot water heat exchanger 4 is provided in the middle of the hot water outlet channel 34 .

Hot water discharged from the hot water storage part 33 flows through the hot water heat exchanger 4 . The hot water heat exchanger 4 exchanges heat with the air blown into the room. During the reheat dehumidification operation, the hot water heat exchanger 4 gives heat to the air flowing through the indoor flow path. The hot water that has flowed through the hot water heat exchanger 4 is discharged to the hot water outlet channel 34 and discharged from the downstream end of the hot water outlet channel 34 .

The hot water amount adjustment unit 35 adjusts the amount of hot water (hot water amount Qd) discharged from the hot water storage unit 33 through the hot water discharge channel 34 . In the first embodiment, the outlet hot water amount adjustment unit 35 is composed of a flow rate adjustment valve, and is capable of switching execution and stop of hot water outlet from the hot water storage unit 33 and adjusting the outlet hot water amount Qd.

The hot water supply unit 36 supplies hot water to the hot water flow path 32 or the hot water storage unit 33 . In the first embodiment, the hot water supply unit 36 is composed of a water supply pipe 361 and an adjustment valve 362 provided in the water supply pipe 361 . The upstream end of the water supply pipe 361 is connected to a water supply source (not shown) such as tap water, and the downstream end of the water supply pipe 361 is connected to the bottom (lower end) of the hot water storage section 33 . The hot water supply unit 36 can switch between execution and stop of water supply to the hot water storage unit 33, and can adjust the water supply amount Qs.

Note that the hot water supply unit 36 is not limited to the water supply pipe 361 and the adjustment valve 362 connected to such a water supply source. Alternatively, the hot water supply unit 36 may supply water to the hot water channel 32 instead of the hot water storage unit 33, and the downstream end of the water supply pipe 361 is connected to the hot water channel 32 instead of the hot water storage unit 33. If so, water can be supplied to the hot water flow path 32 .

The hot water storage control section 30 controls the operation of the elements forming the hot water storage unit 3 . The hot water storage control unit 30 has, for example, a microcomputer, and controls the operation of the elements of the hot water storage unit 3 by executing a program stored in a storage medium such as a ROM. The hot water storage control unit 30 can control the power generation unit 31 to adjust the amount of heat generated per unit time in the power generation unit 31 . In addition, the hot water storage control unit 30 controls the conveying device 321 and the flow rate adjustment valve 322 provided in the hot water flow path 32 to execute and stop the flow of hot water flowing through the hot water flow path 32, and the flow rate of hot water. can be adjusted. In addition, the stored hot water control unit 30 can control the hot water supply amount adjustment unit 35 to adjust execution and stop of hot water supply and the hot water supply amount Qd. In addition, the hot water storage control unit 30 can control the hot water supply unit 36 to adjust execution and stop of water supply to the hot water storage unit 33 and the water supply amount Qs.

The hot water storage unit 3 includes a hot water storage operation section 37 (see FIG. 2) in the first embodiment. The user operates the hot water storage operation unit 37 to perform various settings such as the operation and stop of the power generation unit 31, the power generation amount, the hot water supply and stop, and the hot water supply amount Qd. Information input from the hot water storage operation unit 37 is received by the hot water storage control unit 30 .

The air conditioning system 1 further includes a communication device (not shown) that performs communication between the heat pump controller 20 and the hot water storage controller 30 . The communication device allows the heat pump control unit 20 and the hot water storage control unit 30 to mutually transmit and receive data wirelessly or by wire. Various conventionally known devices can be used as such a communication device, and there is no particular limitation.

In the first embodiment, the control unit 10 of the air conditioning system 1 is composed of a heat pump control unit 20 and a hot water storage control unit 30 . That is, the control section 10 controls the heat pump unit 2 and the hot water storage unit 3 . The heat pump control unit 20 and the hot water storage control unit 30 cooperate to function as a control unit 10 for the entire air conditioning system 1 . Note that the air conditioning system 1 may include a single controller 10 and the single controller 10 may control the entire air conditioning system 1 .

The air conditioning system 1 may also include an auxiliary heat source (not shown) for applying heat to hot water flowing through the hot water flow path 32 . In this case, the auxiliary heat source is controlled by the controller 10 .

Next, operation of the air conditioning system 1 will be described.

The air conditioning system 1 is capable of reheat dehumidifying operation (dry operation). In the reheat dehumidification operation, the air having the suction temperature Tr sucked from the suction port of the indoor unit 202 is cooled by the indoor refrigerant heat exchanger 24, thereby recovering the latent heat of the air and dehumidifying the air. Furthermore, the air that has passed through the indoor refrigerant heat exchanger 24 and has a temperature Te (° C.) is reheated by the hot water heat exchanger 4 to be blown out from the indoor unit 202 as air having a blowing temperature Ts (° C.). Blow out from your mouth. The blowout temperature Ts is preferably the same as the suction temperature Tr, but may be different from the suction temperature Tr.

The air conditioning system 1 can perform a hot water storage amount recovery operation. The stored hot water amount recovery operation is performed when the heat pump unit 2 and the hot water storage unit 3 are operated and the air heat-exchanged with the indoor refrigerant heat exchanger 24 and the hot water heat exchanger 4 is blown indoors. to be done. Specifically, when a predetermined condition is satisfied during the reheat dehumidification operation described above, the stored hot water amount recovery operation is performed in addition to the reheat dehumidification operation.

In the cogeneration system, when the amount of hot water stored in the hot water storage part 33 (hot water storage amount Q) becomes 0, the hot water heat exchanger 4 using hot water and other hot water terminals using hot water cannot be used. When the stored hot water amount Q decreases to the allowable lower limit value Ql, the control unit 10 controls the hot water supply unit 36 to start supplying water to the hot water storage unit 33 . The allowable lower limit value Ql may be a predetermined percentage of the capacity of the hot water storage unit 33, such as 0%, 5%, or 10% of the capacity of the hot water storage unit 33, or may be a specific value such as 10 liters. It is determined by design and is not particularly limited. When the hot water storage amount Q recovers, the hot water terminal using the hot water stored in the hot water storage unit 33 can be used again.

Further, in the cogeneration system, hot water is preferably discharged from the hot water storage unit 33 through the hot water outlet flow path 34 if there is a demand for hot water even while water is being supplied to the hot water storage unit 33 . As a result, hot water can be used continuously without being interrupted at the hot water terminal. When hot water is discharged from the hot water storage unit 33 while supplying water to the hot water storage unit 33, the stored hot water amount Q does not increase and the stored hot water amount does not increase unless the output hot water amount Qd is less than the water supply amount Qs (ie Qd<Qs) Q does not recover.

Therefore, during the reheat dehumidifying operation, when the stored hot water amount Q has decreased to the allowable lower limit value Ql, the control unit 10 controls the outlet hot water amount adjustment unit 35 to perform the stored hot water amount recovery operation to reduce the outlet hot water amount Qd. Water is supplied to the hot water storage unit 33 during the hot water recovery operation. The hot water supply unit 36 is supplied with water to the hot water storage unit 33 by the control unit 10. However, for example, a constant amount of water supply may be supplied to the hot water storage unit 33 without depending on the hot water supply unit 36. method is not limited.

A reduction width ΔQd of the output hot water amount Qd is calculated by the control unit 10 . Specifically, the reduction width ΔQd is the amount of heat generated in the power generation unit 31, the flow rate of hot water flowing through the hot water flow path 32, the amount of water supply Qs, and the increase in the amount of heat of the hot water stored in the hot water storage unit 33 (a value determined by design ), the time required for the amount of heat in hot water to increase by the above-mentioned amount (a value determined for design purposes), and the like. Various quantities other than those described above may be used to calculate the width of decrease ΔQd. Also, the reduction width ΔQd may be a predetermined value.

Since the stored hot water amount Qd is reduced by the stored hot water amount recovery operation, the decrease in the stored hot water amount Q is suppressed and the stored hot water amount Q can be easily increased. As a result, the amount of stored hot water Q becomes less than the allowable lower limit value Q1, hot water stored in the hot water storage part 33 cannot be discharged, and interruption of use of the hot water terminal such as the hot water heat exchanger 4 is suppressed. It is possible to use continuous hot water at the terminal. In addition, the continuous use of hot water at the hot water terminal means that the exhaust heat collected from the power generation unit 31 is continuously used, so energy saving is high.

Next, the air conditioning system of the second embodiment will be explained with reference to FIGS. 3 to 6. FIG. The air conditioning system of the second embodiment is slightly different from the air conditioning system of the first embodiment in hot water recovery control, but is otherwise the same (including the configuration shown in FIGS. 1 and 2). For this reason, explanations that overlap with the first embodiment will be omitted, and mainly different parts will be explained.

In the second embodiment, the control unit 10 stores the operating state of the heat pump unit 2 at this point in time when the hot water storage amount Q has decreased to the lower limit preliminary value Ql1 when the reheat dehumidifying operation is being performed. It differs from the first embodiment in that The lower limit preliminary value Ql1 is a value larger than the allowable lower limit value Ql by a predetermined amount, and the predetermined amount is determined in terms of design and is not particularly limited.

An operation example 1 of the air conditioning system 1 will be described below. FIG. 3 shows a flowchart of the stored hot water amount recovery control of the operation example 1. As shown in FIG. In operation example 1, the control unit 10 further adjusts the blowout temperature based on the operating state of the heat pump unit 2 stored when the stored hot water amount Q decreases to the lower limit preliminary value Q11 when the stored hot water amount Q1 decreases to the lower limit preliminary value Q11. The heat pump unit 2 is controlled so that Ts is maintained within a predetermined range.

The user operates the air conditioning operation unit 29 to set the set temperature (indoor target temperature Ta) and the set humidity, and the reheat dehumidification operation by the air conditioning system 1 is started. The controller 10 starts the stored hot water amount recovery control shown in FIG. 3 at the same time as the reheat dehumidification operation is started. In operation example 1, hot water heat exchanger 4 is the only hot water terminal that uses hot water discharged from hot water storage unit 33 .

In step S1, it is determined whether or not the stored hot water amount Q is equal to or less than the lower limit preliminary value Ql1 (Q≤Ql1). If it is determined in step S1 that the stored hot water amount Q is not equal to or less than the lower limit preliminary value Ql1, the process returns to step S1. When it is determined in step S1 that the stored hot water amount Q is equal to or less than the lower limit preliminary value Ql1, the process proceeds to step S2.

In step S<b>2 , the operating states of the heat pump unit 2 and the hot water storage unit 3 at this time are stored in a storage section (not shown) of the control section 10 . The storage unit is a nonvolatile memory such as an EEPROM (Electrically Erasable Programmable Read-Only Memory), but is not particularly limited. In addition, the operating state of the heat pump unit 2 includes various quantities such as the suction temperature Tr, the blowout temperature Ts, the rotation speed of the motor of the compressor 21, and the amount of refrigerant conveyed, which are detected by various sensors and controlled. Received by the unit 10 . Further, the operating state of the hot water storage unit 3 includes various amounts such as the power generation amount and heat generation amount in the power generation unit 31, the flow rate of hot water flowing through the hot water flow path 32, the hot water storage amount Q, and the hot water output Qd. It is detected by various sensors and received by the control unit 10 . After step S2, the process proceeds to step S3.

In step S3, it is determined whether or not the stored hot water amount Q is equal to or less than the allowable lower limit value Ql (Q≤Ql). If it is determined in step S3 that the stored hot water amount Q is not equal to or less than the allowable lower limit value Ql, the process returns to step S3. If it is determined in step S3 that the stored hot water amount Q is equal to or less than the allowable lower limit value Ql, the process proceeds to step S4.

In step S4, the controller 10 starts the stored hot water amount recovery operation. After step S4, the process proceeds to step S5.

In step S5, the reduction width ΔQd of the tapping amount Qd is calculated by the control unit 10 . In Operation Example 1, the reduction width ΔQd is the amount of heat generated in the power generation unit 31, the flow rate of hot water flowing through the hot water flow path 32, the amount of water supply Qs, and the amount of heat when the amount of stored hot water Q increases to the lower limit preliminary value Ql1. It is calculated from the time required to increase by this increment (a value determined by design). After step S5, the process proceeds to step S6.

In step S6, the operation is performed with the tapping amount Qd reduced by the reduction width ΔQd. After step S6, the process proceeds to step S7.

In step S7, it is determined whether or not a certain period of time has elapsed, and if it is not determined that the certain period of time has elapsed, the process returns to step S7. The certain period of time is set as appropriate and is not particularly limited. If it is determined in step S7 that the predetermined time has passed, the process proceeds to step S8.

In step S8, the blowing temperature Ts at this time is measured. Next, the process proceeds to step S9.

In step S9, it is determined whether the blowing temperature Ts measured in step S8 is outside a predetermined range based on the blowing temperature Ts stored in the storage unit. When it is determined in step S9 that the blowing temperature Ts measured in step S8 is outside the predetermined range (that is, when the blowing temperature Ts is higher than the predetermined range), the process proceeds to step S10.

In step S10, the controller 10 controls the heat pump unit 2 to lower the air cooling capacity of the indoor-side refrigerant heat exchanger 24 by one step. Specifically, the conveying amount of the refrigerant flowing through the refrigerant channel 27, the air volume flowing through the indoor channel and the outdoor air channel, and the like are decreased. Here, the amount of refrigerant transported, the amount of air flowing through the indoor channel and the outdoor air channel, and the like are tabulated. In other words, the amount of refrigerant transported, the amount of air flowing through the indoor flow path and the outdoor air flow path, etc. can originally take continuous values, but in terms of control, they are limited to a discrete finite number of values. Easy to control when aggregated. In operation example 1, a table is created in which the amount of refrigerant transported, the amount of air flowing through the indoor flow path and the outdoor air flow path, and the like are aggregated into a plurality of discrete values, and control is performed based on the values on this table. Is going. After step S10, the process proceeds to step S11.

Further, when it is determined in step S9 that the blowing temperature Ts measured in step S8 is not outside the predetermined range, the process proceeds to step S11.

In step S11, it is determined whether or not a certain period of time has elapsed, and if it is determined that the certain period of time has not elapsed, the process returns to step S11. The certain period of time is set as appropriate and is not particularly limited. If it is determined in step S11 that the predetermined time has passed, the process proceeds to step S12.

In step S12, it is determined whether or not the stored hot water amount Q is equal to or greater than the lower limit recovery value Q12 (Q≧Q12). Here, the lower limit recovery value Ql2 is equal to or greater than the lower limit preliminary value Ql1 (Ql2≧Ql1), and particularly preferably the lower limit recovery value Ql2 is greater than the lower limit preliminary value Ql1 (Ql2>Ql1). When it is determined in step S12 that the stored hot water amount Q is not equal to or greater than the lower limit recovery value Ql2, the process returns to step S8. If it is determined in step S12 that the stored hot water amount Q is equal to or greater than the lower limit recovery value Ql2, the process proceeds to step S13.

In step S13, the controller 10 terminates the stored hot water amount recovery operation. After step S13, the process returns to step S1.

In operation example 1 as well, when the stored hot water amount Q decreases to the allowable lower limit value Ql, the stored hot water amount recovery operation is performed. This prevents the hot water heat exchanger 4 from interrupting the use of the hot water heat exchanger 4 due to the stored hot water amount Q becoming less than the allowable lower limit value Ql, enabling continuous use of hot water in the hot water heat exchanger 4 and saving energy. is also expensive.

Further, in operation example 1, when the stored hot water amount Q has decreased to the lower limit preliminary value Ql1, the operating states of the heat pump unit 2 and the hot water storage unit 3 are stored (step S2). Based on the stored operating conditions, the heat pump unit 2 is controlled so that the blowing temperature Ts is maintained within a predetermined range (steps S8 to S10). As a result, even if the amount of hot water Qd decreases and the amount of heat imparted to the air by the hot water heat exchanger 4 decreases, the cooling capacity of the air in the indoor refrigerant heat exchanger 24 decreases, so the blowout temperature Ts remains within the predetermined range. easier to maintain.

Next, an operation example 2 of the air conditioning system 1 will be described. FIG. 4 shows a flowchart of the stored hot water amount recovery control in Operation Example 2. As shown in FIG. When the stored hot water amount Q has decreased to the allowable lower limit Ql, in the operation example 1, the blowout temperature Ts is maintained within a predetermined range based on the operating state stored when the stored hot water amount Q has decreased to the lower limit preliminary value Ql1. The heat pump unit 2 was controlled at the same time. On the other hand, in Operation Example 2, the ability of the indoor refrigerant heat exchanger 24 to cool air is maintained within a predetermined range based on the operating state stored when the hot water storage amount Q has decreased to the lower limit preliminary value Ql1. This differs from the operation example 1 in that the heat pump unit 2 is controlled as follows.

The user operates the air conditioning operation unit 29 to set the set temperature and set humidity, and the reheat dehumidification operation by the air conditioning system 1 is started. The controller 10 starts the stored hot water amount recovery control shown in FIG. 4 at the same time as the reheat dehumidification operation is started. Note that, even in Operation Example 2, the hot water heat exchanger 4 is the only hot water terminal that uses the hot water discharged from the hot water storage unit 33 .

In step S21, it is determined whether or not the stored hot water amount Q is equal to or less than the lower limit preliminary value Ql1 (Q≤Ql1). If it is determined in step S21 that the stored hot water amount Q is not equal to or less than the lower limit preliminary value Ql1, the process returns to step S21. When it is determined in step S21 that the stored hot water amount Q is equal to or less than the lower limit preliminary value Q11, the process proceeds to step S22.

In step S<b>22 , the operating states of the heat pump unit 2 and the hot water storage unit 3 at this time are stored in the storage section of the control section 10 . After step S22, the process proceeds to step S23.

In step S23, the control unit 10 starts refrigerating cycle optimum setting control. Before describing the refrigeration cycle optimum setting control, the relationship between the load W of the heat pump unit 2 and the coefficient of performance (hereinafter referred to as COP) in the refrigeration cycle will be described.

In the heat pump unit 2, the relationship shown in FIG. 5 exists between the load W and the COP. Here, Wmin(W) is the minimum value of the load W, which is the minimum throttling load that is determined mainly based on the minimum limit conveyed amount of refrigerant conveyed by the compressor 21 and the outside air temperature To. The minimum limit conveying amount is mainly determined by the lower limit value of the rotation speed per unit time of the motor of the compressor 21 .

Wmax(W) is the maximum value of the load W, and is mainly determined based on the maximum limit conveyed amount of refrigerant conveyed by the compressor 21 and the outside air temperature To. The maximum limit conveying amount is mainly determined by the upper limit of the rotation speed per unit time of the motor of the compressor 21 .

Since specific values of the load W and COP are determined for each heat pump unit 2, description of specific values is omitted.

Assuming that the load W at which the COP is maximum is Wcmax (W), the range in which the upper limit is Wcmax+α1 (W) and the lower limit is Wcmax−α2 (W) is defined as an optimized load range Z1. Here, α1 and α2 are appropriately determined depending on how wide various permissible ranges are to be taken from the viewpoint of COP, energy efficiency, and the like.

The refrigeration cycle is preferable for high COP and energy efficiency when the load W is within the optimized load range Z1. Also, the range of the load W outside the optimized load range Z1 is defined as a non-optimized load range Z2. In the optimized load range Z1, the area where the load W is less than Wcmax is defined as a range Z11, and the area where the load W is greater than or equal to Wcmax is defined as a range Z12. Further, in the non-optimized load range Z2, the area where the load W is less than Wcmax-α2 is defined as a range Z21, and the area where the load W is greater than or equal to Wcmax+α1 is defined as a range Z22.

The refrigerating cycle optimum setting control will be described based on the flowchart of the refrigerating cycle optimum control shown in FIG.

In step S41, it is determined whether or not the actual load W at this time is within the optimized load range Z1. If it is determined in step S41 that the load W is within the optimized load range Z1, the process proceeds to step S42.

In step S42, the actual load W at this time is stored in the storage unit as the load W of the heat pump unit 2 during hot water recovery operation, the refrigerating cycle optimum setting control is terminated, and the process proceeds to step S24.

Further, when it is determined in step S41 that the load W is not within the optimized load range Z1, the process proceeds to step S43.

In step S43, although it is known that the load W is in the non-optimized load range Z2, it is determined whether the load W is within the range Z21 of these. When it is determined in step S43 that the load W is within the range Z21, the process proceeds to step S44.

In step S44, the control unit 10 assumes that the load W is operated at Wcmax, and calculates the temperature Te of the air that has passed through the indoor-side refrigerant heat exchanger 24 in this case. The temperature Te is calculated by the controller 10 by performing a predetermined calculation based on various amounts that can be detected as the operating states of the heat pump unit 2 and the hot water storage unit 3 . After that, the process proceeds to step S45.

In step S45, it is determined whether the calculated temperature Te is within a predetermined range. If it is determined in step S45 that the calculated temperature Te is within the predetermined range, the process proceeds to step S46.

In step S46, Wcmax is stored in the storage unit as the load W of the heat pump unit 2 during hot water recovery operation, the refrigeration cycle optimum setting control is terminated, and the process proceeds to step S24.

Further, when it is determined in step S45 that the calculated temperature Te is not within the predetermined range, the process proceeds to step S47.

In step S47, the control unit 10 assumes that the load W is operated at Wcmax-α2, calculates the temperature Te of the air that has passed through the indoor refrigerant heat exchanger 24 in this case, and proceeds to step S48.

In step S48, it is determined whether the calculated temperature Te is within a predetermined range. If it is determined in step S48 that the calculated temperature Te is within the predetermined range, the process proceeds to step S49.

In step S49, Wcmax-α2 is stored in the storage unit as the load W of the heat pump unit 2 during hot water recovery operation, the refrigerating cycle optimum setting control is terminated, and the process proceeds to step S24.

Further, when it is determined in step S48 that the calculated temperature Te is not within the predetermined range, the process proceeds to step S42, where the actual load W at this time is calculated as the load W of the heat pump unit 2 during the hot water recovery operation. , the refrigerating cycle optimum setting control is terminated, and the process proceeds to step S24.

Further, when it is determined in step S43 that the load W is not within the range Z21, the process proceeds to step S50.

In step S50, it is known that the load W is in the range Z22, and the control unit 10 assumes that the load W is operated at Wcmax, and the temperature Te of the air that has passed through the indoor refrigerant heat exchanger 24 in this case Calculate After that, the process proceeds to step S51.

In step S51, it is determined whether the calculated temperature Te is within a predetermined range. When it is determined in step S51 that the calculated temperature Te is within the predetermined range, the process proceeds to step S46, Wcmax is set as the load W of the heat pump unit 2 during the hot water storage amount recovery operation, and the refrigeration cycle optimum setting control ends. and proceed to step S24.

Further, when it is determined in step S51 that the calculated temperature Te is not within the predetermined range, the process proceeds to step S52.

In step S52, the control unit 10 assumes that the load W is operated at Wcmax+α1, calculates the temperature Te of the air that has passed through the indoor-side refrigerant heat exchanger 24 in this case, and proceeds to step S53.

In step S53, it is determined whether the calculated temperature Te is within a predetermined range. If it is determined in step S53 that the calculated temperature Te is within the predetermined range, the process proceeds to step S54.

In step S54, Wcmax+α1 is stored in the storage unit as the load W of the heat pump unit 2 during hot water recovery operation, the refrigerating cycle optimum setting control is terminated, and the process proceeds to step S24.

Further, when it is determined in step S53 that the calculated temperature Te is not within the predetermined range, the process proceeds to step S42, where the actual load W at this time is calculated as the load W of the heat pump unit 2 during the hot water recovery operation. , the refrigerating cycle optimum setting control is terminated, and the process proceeds to step S24.

As shown in FIG. 4, in step S24, it is determined whether or not the stored hot water amount Q is equal to or less than the allowable lower limit value Ql (Q≤Ql). If it is determined in step S24 that the stored hot water amount Q is not equal to or less than the allowable lower limit value Ql, the process returns to step S23. If it is determined in step S24 that the stored hot water amount Q is equal to or less than the allowable lower limit value Ql, the process proceeds to step S25.

In step S25, the controller 10 starts the stored hot water amount recovery operation. In the stored hot water amount recovery operation, the heat pump unit 2 is operated with the load W set in the refrigeration cycle optimization control. After step S25, the process proceeds to step S26.

In step S26, the reduction width ΔQd of the tapping amount Qd is calculated by calculation. After step S26, the process proceeds to step S27.

In step S27, the operation is performed with the tapping amount Qd reduced by the reduction width ΔQd. After step S27, the process proceeds to step S28.

In step S28, it is determined whether or not the stored hot water amount Q is equal to or greater than the lower limit recovery value Q12 (Q≧Q12). If it is determined in step S28 that the stored hot water amount Q is not equal to or greater than the lower limit recovery value Ql2, the process returns to step S27. If it is determined in step S28 that the stored hot water amount Q is equal to or greater than the lower limit recovery value Ql2, the process proceeds to step S29.

In step S29, the controller 10 terminates the stored hot water amount recovery operation. After step S29, the process returns to step S21.

In the operation example 2 as well, when the stored hot water amount Q decreases to the allowable lower limit value Ql, the stored hot water amount recovery operation is performed. This prevents the hot water heat exchanger 4 from interrupting the use of the hot water heat exchanger 4 due to the stored hot water amount Q becoming less than the allowable lower limit value Ql, enabling continuous use of hot water in the hot water heat exchanger 4 and saving energy. is also expensive.

Further, in operation example 2, when the stored hot water amount Q has decreased to the lower limit preliminary value Ql1, the operating states of the heat pump unit 2 and the hot water storage unit 3 are stored (step S22). And the control part 10 performs refrigerating-cycle optimal setting control.

In the refrigerating cycle optimum setting control, if the actual load W is within the optimum load range Z1, the heat pump unit 2 is operated in this state during the hot water recovery operation (steps S41 and S42).

Further, if the actual load W is within the lower range Z21 of the non-optimized load range Z2, assuming that the load W is operated at the optimum Wcmax, the load W is set to Wcmax, and the heat pump unit 2 is operated during the hot water recovery operation (steps S44 to S46).

In addition, when the actual load W is within the lower range Z21 and the predetermined dehumidification capacity cannot be maintained assuming that the load W is operated at the optimum Wcmax, the load W is reduced to Wcmax- within the optimized load range Z1. Assume that the heat pump unit 2 is operated during the hot water recovery operation as α2 (step S47). Under this assumption, if the predetermined dehumidifying ability can be maintained, the load W is set to Wcmax-α2 and the heat pump unit 2 is operated during the hot water recovery operation (steps S48 and S49). In this assumption, if the predetermined dehumidification capacity cannot be maintained, the high COP operation is abandoned, and the heat pump unit 2 is operated under the current load W during the hot water recovery operation (step S42).

Further, if the actual load W is within the higher range Z22 of the non-optimized load range Z2, assuming that the load W is operated at the optimum Wcmax, the load W is set to Wcmax, and the heat pump unit 2 is operated during the hot water recovery operation (steps S50, S51, S46).

Further, when the actual load W is within the higher range Z22 and the predetermined dehumidification capacity cannot be maintained assuming that the load W is operated at the optimum Wcmax, the load W is set to Wcmax+α1 within the optimized load range Z1 and stored hot water. It is assumed that the heat pump unit 2 is operated during the amount recovery operation (step S52). Under this assumption, when the predetermined dehumidifying ability can be maintained, the load W is set to Wcmax+α1 and the heat pump unit 2 is operated during the hot water recovery operation (steps S53 and S54). In this assumption, if the predetermined dehumidification capacity cannot be maintained, the high COP operation is abandoned, and the heat pump unit 2 is operated under the current load W during the hot water recovery operation (step S42). Such refrigeration cycle optimum setting control allows the heat pump unit 2 to operate at the highest possible COP.

Various predetermined ranges (predetermined range of the blowing temperature Ts, predetermined range of the air cooling capacity of the indoor refrigerant heat exchanger 24, predetermined range of the temperature Te, etc.) are appropriately determined in terms of design, and are particularly limited. not.

REFERENCE SIGNS LIST 1 air conditioning system 10 control unit 2 heat pump unit 21 compressor 22 outdoor refrigerant heat exchanger 23 expansion mechanism 24 indoor refrigerant heat exchanger 3 hot water storage unit 31 power generation unit 32 hot water channel 33 hot water storage unit 34 hot water outlet channel 35 hot water output adjustment Part 36 Hot water supply part 4 Hot water heat exchanger

Claims (4)

a heat pump unit having a compressor, an outdoor refrigerant heat exchanger, an expansion mechanism, and an indoor refrigerant heat exchanger that exchanges heat with air blown into the room;
A power generation unit, a hot water channel through which hot water collected by exhaust heat from the power generation unit flows, a hot water storage unit provided in the hot water channel, a hot water outlet channel for delivering the hot water from the hot water storage unit, and the hot water outlet. a hot water storage unit comprising: a hot water supply amount adjusting section for adjusting the amount of hot water discharged from a flow path; and a hot water supply section for supplying hot water to the hot water flow path or the hot water storage section;
a hot water heat exchanger provided in the hot water outlet flow path for exchanging heat with the air that flows through the hot water and is blown out into the room;
a control unit that controls the heat pump unit and the hot water storage unit,
The control unit
When the heat pump unit and the hot water storage unit are operated and the air heat-exchanged with the indoor refrigerant heat exchanger and the hot water heat exchanger is blown indoors,
An air conditioning system comprising: when the amount of hot water stored in the hot water storage unit is reduced to an allowable lower limit, the hot water amount adjusting unit is controlled to perform a stored hot water amount recovery operation to reduce the amount of hot water output. The operation in which the air that has undergone heat exchange with the indoor refrigerant heat exchanger and the hot water heat exchanger is blown indoors is such that the air is cooled by the indoor refrigerant heat exchanger and heated by the hot water heat exchanger. is a reheat dehumidification operation that
The control unit
When the reheat dehumidification operation is being performed,
2. When the amount of hot water stored in the hot water storage unit decreases to a lower limit preliminary value larger than the allowable lower limit by a predetermined amount, the operating state of the heat pump unit at this time is stored. Air conditioning system as described. further comprising a blowout temperature detection unit that detects the blowout temperature of the air blown into the room;
The control unit
When the reheat dehumidification operation is being performed,
When the amount of hot water stored in the hot water storage unit decreases to the allowable lower limit, the heat pump maintains the outlet temperature within a predetermined range based on the stored operating state of the heat pump unit. 3. The air conditioning system of claim 2, wherein the air conditioning system controls the unit. The control unit
When the reheat dehumidification operation is being performed,
When the amount of hot water stored in the hot water storage unit decreases to the allowable lower limit, the indoor refrigerant heat exchanger loses its ability to cool the air based on the stored operating state of the heat pump unit. 3. The air conditioning system according to claim 2, wherein said heat pump unit is controlled so as to be maintained within a predetermined range.

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