JP2004293889A - Ice thermal storage unit, ice thermal storage type air conditioner and its operating method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an ice thermal storage unit not needing an exclusive outdoor machine unit and having high versatility. <P>SOLUTION: This ice thermal storage unit comprises a thermal storage medium circulating system 31 for storing and circulating the water as a thermal storage medium, and a thermal storage refrigerant circulating system 40 generating the cold heat by circulating the thermal storage refrigerant, and further comprises a water/refrigerant heat exchanger 50 storing the cold heat generated by the thermal storage refrigerant circulating system 40 in the water, and over-cooling the air conditioning refrigerant by the cold heat kept in the water or the thermal storage refrigerant. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to an ice heat storage unit, an ice heat storage type air conditioner, and an operation method thereof, which store cold heat at night or the like and use it effectively during a cooling operation.
[0002]
[Prior art]
2. Description of the Related Art There is known an ice storage type air conditioner configured to store cold heat by effectively using inexpensive nighttime electric power and use the cold heat during a cooling operation.
The conventional ice storage type air conditioner includes, in addition to an outdoor unit and an indoor unit that constitute a normal air conditioner, an ice storage unit for storing cold heat in the form of, for example, cold water or ice. It is provided as a configuration in which the machine unit and the refrigerant system are integrated.
[0003]
That is, the conventional ice storage air conditioner includes a heat exchanger that cools the refrigerant supplied from the compressor of the outdoor unit by exchanging heat with a heat storage medium such as water stored in the ice heat storage unit. By flowing a liquid refrigerant through the heat exchanger, heat is absorbed from water in the heat storage tank, and cold water or ice is formed and stored in the heat storage tank. During the cooling operation, the cold water supplied from the heat storage tank and the liquid refrigerant sent from the outdoor unit are introduced into a water heat exchanger to exchange heat, and the liquid refrigerant to which supercooling is added by cooling is applied to the indoor unit. Supplied to the unit. Therefore, the maximum load on the compressor is reduced, and the compressor can be downsized to perform a highly efficient cooling operation with low power consumption. (For example, see Patent Document 1)
[0004]
[Patent Document 1]
JP-A-2002-372260 (page 3-5, FIG. 1)
[0005]
[Problems to be solved by the invention]
By the way, in the above-mentioned conventional ice thermal storage type air conditioner, the refrigerant used by the ice thermal storage unit for cooling the heat storage medium and the refrigerant used for air conditioning (cooling / heating and dehumidification) in the outdoor unit and the indoor unit are separated. Since the same refrigerant system is formed, it has the following problems.
(1) An outdoor unit dedicated to the ice storage type air conditioner is required. That is, it is difficult to combine with a general air conditioner having no ice heat storage unit, and it is necessary to newly develop a dedicated outdoor unit which is disadvantageous in cost. In addition, since a dedicated outdoor unit is required, it is necessary to replace the outdoor unit or significantly reduce the outdoor unit in order to retrofit the ice storage unit with a general existing air conditioner. Remodeling is required.
[0006]
(2) It is difficult to simultaneously perform the cold storage operation for storing cold heat in the ice heat storage unit and the cooling and heating operation.
(3) The amount of refrigerant required for operation increases.
(4) If one unit breaks down, it is necessary to stop and repair the entire air conditioning system, so that air conditioning operation becomes impossible.
[0007]
The present invention has been made in view of the above circumstances, and an object of the present invention is to provide a highly versatile ice storage unit, an ice storage air conditioner, and an operation method thereof that do not require a dedicated outdoor unit. It is.
[0008]
[Means for Solving the Problems]
The present invention employs the following means in order to solve the above problems.
The ice heat storage unit according to claim 1, comprising a heat storage medium circulation system that stores and circulates the heat storage medium, and a heat storage refrigerant circulation system that circulates the heat storage refrigerant to generate cold heat. A heat storage medium / refrigerant heat exchanger for storing heat in the heat storage medium with the cold generated in the system, and adding supercooling to the air conditioning refrigerant of the air conditioner with the cold stored by the heat storage medium or the heat storage refrigerant. It is characterized by having.
[0009]
According to such an ice heat storage unit according to claim 1, a heat storage refrigerant circulation system dedicated to heat storage that circulates the heat storage refrigerant to generate cold heat is provided, and the cold generated by the heat storage refrigerant circulation system is provided. The air conditioner is equipped with a heat storage medium / refrigerant heat exchanger that stores heat in the heat storage medium and adds supercooling to the air-conditioning refrigerant of the air conditioner with the cold heat held by the heat storage medium or the heat storage refrigerant. It is possible to store cold heat by operating the ice heat storage unit independent of the heat storage unit, or to stop the operation of the ice heat storage unit and operate the air conditioner independently having the independent refrigerant circulation system. Further, in the heat storage medium / refrigerant heat exchanger, the supercooling addition to the air conditioning refrigerant by the heat storage medium and the supercooling addition to the air conditioning refrigerant by the heat storage refrigerant can be selectively performed.
[0010]
The ice heat storage unit according to claim 2, wherein the heat storage tank stores a heat storage medium, a heat storage medium pipe that introduces the heat storage medium from a lower part of the heat storage tank and returns the heat storage medium to an upper part, and heat storage provided in the heat storage medium pipe. A heat storage medium circulation system comprising a medium circulation pump,
A compressor that compresses the heat storage refrigerant, a heat radiation heat exchanger that performs heat exchange between the heat storage refrigerant and the outside air, and a heat exchanger that is installed in the heat storage tank and that is between the heat storage refrigerant and the heat storage medium. A heat storage heat exchanger for exchanging heat with the heat storage medium, a heat storage medium / refrigerant heat exchanger for adding supercooling to the air conditioning refrigerant of the air conditioner with the cold stored by the heat storage medium or the heat storage refrigerant, and the heat release heat Downstream of the exchanger, a heat storage flow path returning to the compressor via a first throttle means and the heat storage heat exchanger via a flow path selection means, a second throttle means and the heat storage medium / refrigerant A heat storage refrigerant circulation system comprising: a heat storage refrigerant pipe branched to an air conditioning refrigerant cooling flow path returning to the compressor via a heat exchanger;
It is characterized by having.
[0011]
According to the ice heat storage unit of the second aspect, the heat storage refrigerant circulation system dedicated to heat storage includes a compressor, a heat radiation heat exchanger, a heat storage heat exchanger, a heat storage medium / refrigerant heat exchanger, and a heat storage flow. Since the heat storage refrigerant pipe is branched to the passage and the air conditioning refrigerant cooling flow path, a dedicated refrigerant circuit and a refrigeration cycle for circulating the heat storage refrigerant to generate cold heat are formed. Therefore, it is possible to store the cold heat by the independent operation of the ice heat storage unit in which the refrigerant circulation system is independent of the air conditioner, or to stop the operation of the ice heat storage unit and operate the air conditioner in which the refrigerant circulation system is independent by itself. Will be possible. Further, in the heat storage medium / refrigerant heat exchanger, the supercooling addition to the air conditioning refrigerant by the heat storage medium and the supercooling addition to the air conditioning refrigerant by the heat storage refrigerant can be selectively performed.
[0012]
In the ice heat storage unit according to claim 1 or 2, the heat storage medium / refrigerant heat exchanger flows three kinds of fluids of the heat storage medium, the heat storage refrigerant, and the air conditioning refrigerant to exchange heat. It is preferable to use a three-pass type, whereby the supercooling addition of the heat storage medium to the air conditioning refrigerant and the supercooling addition of the heat storage refrigerant to the air conditioning refrigerant can be easily performed by one heat exchanger. (Claim 3)
[0013]
The ice storage type air conditioner according to claim 4 includes a compressor for compressing an air conditioning refrigerant and an outdoor heat exchanger for performing heat exchange between the air conditioning refrigerant and outdoor air. Outdoor unit,
A suction port for taking in indoor air, an indoor heat exchanger for cooling or heating by exchanging heat between the air taken in from the suction port and the air conditioning refrigerant, and heat exchanged in the indoor heat exchanger. An air outlet for returning the air to the room, and an indoor unit comprising: an indoor air blower for blowing air that has been heat-exchanged by taking in the air from the air inlet into the room from the air outlet;
The ice heat storage unit according to any one of claims 1 to 3, further comprising a heat storage refrigerant circulating system independent of the air conditioning refrigerant circulating system.
A refrigerant pipe for circulating the air conditioning refrigerant by connecting the outdoor unit, the indoor unit and the ice heat storage unit,
It is characterized by having.
[0014]
According to such an ice storage type air conditioner according to claim 4, since the ice storage unit is provided with the heat storage refrigerant circulation system independent of the air conditioning refrigerant circulation system, the cold heat is generated by the ice storage unit operating alone. The cooling operation or the heating operation can be performed by the air conditioner alone by storing the heat or stopping the operation of the ice heat storage unit.
[0015]
In the ice regenerative air conditioner according to claim 4, the auxiliary heat pump for flowing the heat storage refrigerant to the heat storage medium / refrigerant heat exchanger and adding supercooling to the air conditioning refrigerant with the cold heat held by the heat storage refrigerant. It is preferable to have a use cooling operation mode, whereby the capacity of the compressor for compressing the air conditioning refrigerant can be suppressed. (Claim 5)
[0016]
In the ice storage type air conditioner according to claim 5, in the heat storage medium / refrigerant heat exchanger, the heat storage refrigerant preferably adds supercooling to the air conditioning refrigerant via the heat storage medium, Accordingly, it is possible to add supercooling to the air-conditioning refrigerant in a state where the temperature fluctuation of the heat storage refrigerant due to the fluctuation of the operating point of the compressor that compresses the heat storage refrigerant is suppressed. At this time, it is preferable that the heat storage medium has a higher specific heat than the heat storage refrigerant. (Claim 6)
[0017]
The method for operating an ice storage air conditioner according to claim 7 is the method for operating an ice storage air conditioner according to any one of claims 4 to 6,
A cooling heat storage operation mode in which the ice heat storage unit is operated independently to circulate the heat storage refrigerant, and cools and stores heat in the heat storage medium with the heat storage refrigerant;
By operating the ice heat storage unit to circulate the heat storage medium and operating the outdoor unit and the indoor unit, supercooling is added to the air-conditioning refrigerant with the cold stored by the heat storage medium to perform a cooling operation. A heat storage cooling operation mode to be performed;
The ice heat storage unit is operated to circulate the heat storage refrigerant, and the outdoor unit and the indoor unit are operated, and supercooling is added to the air conditioning refrigerant with the cold stored by the heat storage refrigerant to perform cooling. A cooling operation mode using an auxiliary heat pump for operation,
A normal operation cooling mode in which the operation of the ice heat storage unit is stopped and the outdoor unit and the indoor unit are operated to perform a cooling operation;
A heating operation mode in which the operation of the ice heat storage unit is stopped and the outdoor unit and the indoor unit are driven and
It is characterized in that any one of the above operation modes is selected for operation.
[0018]
According to such an operation method of the ice storage type air conditioner according to the seventh aspect, the operation mode of the ice heat storage unit in the single operation and the air conditioner including the ice storage unit, the outdoor unit and the indoor unit are both operated. The operation mode in which the air conditioner including the outdoor unit and the indoor unit is operated independently can be selectively implemented.
[0019]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, an embodiment of an ice heat storage unit, an ice heat storage type air conditioner, and an operation method thereof according to the present invention will be described with reference to the drawings.
1 to 5, reference numeral 1 in the figures denotes a multi-type ice storage type air conditioner having a plurality of indoor unit units. The ice storage type air conditioner 1 includes an outdoor unit 10, a plurality of indoor units 20, and an ice storage unit 30. The outdoor unit 10 and the indoor unit 20 are connected by the refrigerant pipe 2 for circulating the air-conditioning refrigerant, so that a known air-conditioning apparatus capable of performing a cooling and heating operation by a heat pump is provided.
[0020]
The outdoor unit 10 includes an air-conditioning compressor 11 for compressing the air-conditioning refrigerant, a four-way valve 12 for selectively switching the circulation direction of the air-conditioning refrigerant in accordance with an operation mode, and an outdoor air / air-conditioning refrigerant. It is a well-known structure including an outdoor heat exchanger 13 for performing heat exchange between the two, and an outdoor unit expansion valve 14 provided as a throttling means.
Reference numeral 15 in the figure denotes an accumulator, 16 denotes a check valve, and further includes an outdoor unit fan and a receiver (not shown).
[0021]
The indoor unit 20 is a well-known unit including an indoor heat exchanger 21 and an indoor unit expansion valve 22, and a wall-mounted type or a ceiling-mounted type is appropriately used depending on the installation location. Further, the indoor unit 20 includes a check valve 23, a suction port, an air outlet, and a fan of indoor blowing means (not shown) in addition to the indoor heat exchanger 21 and the indoor unit expansion valve 22 described above. I have.
A plurality of indoor units 20 (not shown) are connected in parallel by the refrigerant pipe 2.
[0022]
The indoor heat exchanger 21 is a heat exchanger that performs heat exchange between indoor air taken in from a suction port by operation of a fan and air conditioning refrigerant supplied from the outdoor unit 10. The indoor air is taken into the indoor unit 20 from the suction port by the operation of the fan, passes through the indoor heat exchanger 21, exchanges heat with the air-conditioning refrigerant, and then becomes air-conditioned air and blows out from the outlet into the room. Is done.
Note that the air-conditioning refrigerant flowing through the refrigerant pipe 2 connecting the outdoor unit 10 and the indoor unit 20 is cooled by ice (described later) before being throttled (expanded) by the outdoor expansion valve 14 or the indoor expansion valve 22 of the throttle means. The water (heat storage medium) provided in the heat storage unit 30 flows through the refrigerant heat exchanger 50.
The indoor unit expansion valve 22 is a throttling unit used during cooling (including dehumidification) operation, and is provided for each indoor unit 20.
[0023]
The ice heat storage unit 30 includes, for example, a heat storage medium circulation system 31 that stores and circulates a heat storage medium C such as water, and a heat storage refrigerant circulation system 40 that circulates the heat storage refrigerant C to generate cold heat. You. Further, in order to store the cold heat generated in the heat storage refrigerant circulation system 40 in the heat storage medium C, and to add supercooling to the air conditioning refrigerant of the air conditioner with the cold stored by the heat storage medium C or the heat storage refrigerant, A three-pass water (heat storage medium) / refrigerant heat exchanger 50 is provided.
In the following description, it is assumed that water that is easily available at hand, most versatile and easy to handle is the heat storage medium C. In addition, brine such as calcium chloride, paraffin, and ethylene glycol is used. Can be used as a heat storage medium.
[0024]
The heat storage medium circulation system 31 includes a heat storage tank 32 that stores water of the heat storage medium C, a heat storage medium pipe 33 that introduces water of the heat storage medium C from a lower part of the heat storage tank 32 and returns the water to an upper part, and a heat storage medium pipe 33. The heat storage medium circulation pump 34 is provided.
The water flowing through the heat storage medium circulation system 31 is one of the fluids flowing through a three-pass water / refrigerant heat exchanger 50 that introduces three types of fluids. The water / refrigerant heat exchanger 50 is connected to the downstream side of the heat storage medium circulation pump 34 via a heat storage medium pipe 33.
[0025]
In the heat storage medium circulation system 31, by operating the heat storage medium circulation pump 34, the liquid water stored in the heat storage tank 32 is sucked and sent out to the water / refrigerant heat exchanger 50 via the heat storage medium pipe 33. This water exchanges heat with the water / refrigerant heat exchanger 50, and then is guided to the heat storage medium pipe 33 and flows down from the upper opening of the heat storage tank 32.
In addition, such circulation of water is performed when cold heat is stored in the heat storage tank 32. Therefore, in order to detect the state of water stored in the heat storage tank 32, the heat storage tank 32 is provided with a float switch (not shown) and a water temperature sensor (not shown). The float switch detects the state of heat storage upper limit (ice is full), and the water temperature sensor detects the heat storage lower limit (state of no ice). Used for operation control of components.
[0026]
The heat storage refrigerant circulation system 40 is provided in the heat storage tank 32, a heat storage compressor 41 that compresses the heat storage refrigerant, a heat radiation heat exchanger 42 that performs heat exchange between the heat storage refrigerant and the outside air. A heat storage heat exchanger 43 for exchanging heat between the heat storage refrigerant and water (heat storage medium C), and a first electromagnetic valve 44 and a second electromagnetic valve of flow path selection means downstream of the heat radiation heat exchanger 42. A heat storage flow path 48A returning to the heat storage compressor 41 via a first expansion valve (first throttle means) 46 and a heat storage heat exchanger 43 via a valve 45, and a second expansion valve (second throttle). Means) and a heat storage refrigerant pipe 48 branched to an air conditioning refrigerant cooling flow path 48B returning to the compressor 41 via the water / refrigerant heat exchanger 50.
It should be noted that a three-way switching valve may be employed as the flow path switching means instead of the illustrated first electromagnetic valve 44 and second electromagnetic valve 45.
[0027]
Further, the heat storage refrigerant circulation system 40 includes a water / refrigerant heat exchanger 50 that adds supercooling to the air conditioning refrigerant of the air conditioner using the water of the heat storage medium or the cold stored by the heat storage refrigerant.
The water / refrigerant heat exchanger 50 is a three-pass type in which heat is exchanged by passing three kinds of fluids, a heat storage refrigerant, water of the heat storage medium C, and an air conditioning refrigerant used in an air conditioner. Is a plate-type heat exchanger. Therefore, the water / refrigerant heat exchanger 50 is connected to the refrigerant pipe 2, the heat storage medium pipe 33, and the air-conditioning refrigerant cooling flow path 48 </ b> B of the heat storage refrigerant pipe 48. Are configured to pass through.
The heat storage refrigerant circulation system 40 further includes a check valve 49 and a heat exchanger fan (not shown).
[0028]
The heat storage refrigerant circulation system 40 configures a refrigeration cycle in which the heat storage refrigerant circulates in one direction by operating the heat storage compressor 40.
That is, by operating the heat storage compressor 40, the high-pressure gas refrigerant is sent to the heat radiation heat exchanger 42 to radiate the heat of condensation to the outside air, so that the gas refrigerant is condensed and the liquid refrigerant is condensed. It becomes. The flow path of the liquid refrigerant is switched according to the open / close state of the first solenoid valve 44 or the second solenoid valve 45.
[0029]
When the first solenoid valve 44 is opened and the second solenoid valve 45 is closed, the liquid-phase heat storage refrigerant flowing out of the heat-radiating heat exchanger 42 branches off from the heat-storage refrigerant pipe 48. It is led to the heat storage channel 48A. The heat storage refrigerant is decompressed by the first expansion valve 46, then guided to the heat storage heat exchanger 43 in the heat storage tank 32, and evaporated by absorbing heat from water in the heat exchanger. Therefore, the heat storage heat exchanger 43 functions as a cooler (evaporator) that cools water and converts it to ice, and cool heat is stored in the heat storage tank 32 in the form of ice.
The heat storage refrigerant that has absorbed heat from water in this way becomes a gaseous refrigerant from a liquid phase to a gaseous phase, passes through the check valve 49, and is sucked into the heat storage compressor 41 again. Then, the heat storage refrigerant circulates in the same route as described above, and repeatedly changes the state of gas and liquid, and stores cold heat in the heat storage tank 32.
[0030]
When the second solenoid valve 45 is opened and the first solenoid valve 44 is closed, the liquid-phase heat storage refrigerant flowing out of the heat-radiating heat exchanger 42 branches off from the heat-storage refrigerant pipe 48. Then, it is guided to the air conditioning refrigerant cooling channel 48B. The heat storage refrigerant is decompressed by the second expansion valve 47 and then guided to the water / refrigerant heat exchanger 50, which cools the air conditioning refrigerant to add supercooling. As a result, the heat storage refrigerant evaporates by absorbing heat from the air conditioning refrigerant, and thus the water / refrigerant heat exchanger 50 functions as a cooler (evaporator) that cools the air conditioning refrigerant and adds supercooling.
The heat storage refrigerant that has absorbed heat from the air conditioning refrigerant in this way becomes a gaseous refrigerant from a liquid phase to a gaseous phase, and is sucked into the heat storage compressor 41 again. Then, the heat storage refrigerant circulates in the same path as described below, and repeatedly changes the gas-liquid state, thereby adding supercooling to the air conditioning refrigerant.
[0031]
By the way, at the time of supercooling addition by the refrigerant in the water / refrigerant heat exchanger 50 described above, the heat storage refrigerant and the air conditioning refrigerant may be directly heat-exchanged, but the air conditioning refrigerant may be cooled via water. preferable. In other words, if the water of the heat storage medium having a specific heat greater than that of the heat storage refrigerant is cooled, and the cold water in the heat exchanger thus generated and the air conditioning refrigerant are heat-exchanged to add supercooling, Even if the operation of the heat storage compressor 41 fluctuates due to temperature, protection control, etc., and the evaporation temperature of the heat storage refrigerant fluctuates somewhat, the air conditioning refrigerant can be cooled in a state where the fluctuation is controlled. Supercooling ability is obtained.
[0032]
In order to allow the heat storage refrigerant to supercool the air conditioning refrigerant via the water, the present embodiment employs a plate heat exchanger as described above, and uses a heat storage medium / refrigerant heat exchanger (water). The refrigerant heat exchanger) 50 has a function of exchanging heat between the heat storage refrigerant and the water as the heat storage medium, and between the water as the heat storage medium and the air conditioning refrigerant to perform supercooling by the heat storage refrigerant. The supercooling by water as a heat storage medium can be realized by one heat exchanger.
[0033]
Subsequently, an operation method of the above-described ice regenerative air conditioner will be described together with a flow and a state change of the air conditioning refrigerant and the heat storage refrigerant.
The ice storage type air conditioner operates by selecting one of at least five operation modes described below according to various conditions such as an operation time zone.
[0034]
First, the cooling heat storage operation mode shown in FIG. 1 will be described.
This operation mode is an operation mode in which the ice heat storage unit 30 is operated alone to circulate the heat storage refrigerant, and the water for the heat storage medium is cooled by the heat storage refrigerant to store heat in the form of ice (cool storage). In this case, the operation of the air conditioner including the outdoor unit 10 and the indoor unit 20 is stopped.
[0035]
In the cooling heat storage operation mode, the first electromagnetic valve 44 is opened and the second electromagnetic valve 45 is closed, and the heat storage compressor 41 of the ice heat storage unit 30 is operated. Note that the heat storage medium circulation pump 34 is stopped.
As a result, the heat storage refrigerant is sent from the heat storage compressor 41 through the heat storage refrigerant pipe 48 to the heat radiation heat exchanger 42 as a high-temperature and high-pressure gas refrigerant, and the heat exchanger radiates heat to the outside air and condenses. , Becomes a high-pressure liquid refrigerant. This liquid refrigerant is guided to the first expansion valve 46 through the heat storage flow path 48A in which the first solenoid valve 44 is opened, and is decompressed by the first expansion valve 46 and then to the heat storage heat exchanger 43. Supplied.
[0036]
The liquid refrigerant supplied to the heat storage heat exchanger 43 absorbs heat from water in the heat storage tank 32 and cools. As a result, the liquid refrigerant is vaporized to become a low-pressure gas refrigerant, and the water becomes ice and cool heat is stored. Such cooling of the water by the heat storage heat exchanger 43 is normally continued until a float switch (not shown) provided in the heat storage tank 32 detects a rise in water level and outputs a signal to the control unit. That is, it is detected that the water in the heat storage tank 32 has become a predetermined amount of ice and the water level has risen, and the operation of the heat storage compressor 41 is stopped using this as the heat storage upper limit.
[0037]
The heat storage refrigerant thus converted into a gas refrigerant passes through the check valve 49 and is sucked into the heat storage compressor 41 again, and thereafter circulates through the heat storage refrigerant pipe 48 and the heat storage flow path 48A while repeating the same state change. .
By the way, in such a cooling heat storage operation mode, heat can be stored by the operation of the relatively small heat storage compressor 41, and there is no cooling load, and a time zone (for example, late at night, etc.) in which the electricity rate is cheap is selected and executed. Is preferred.
[0038]
Next, the cooling operation mode using heat storage shown in FIG. 2 will be described.
This operation mode is preferably performed in a time period when the cooling load is large and the power consumption for which it is desired to suppress the power consumption is at a peak (for example, about 13:00 to 16:00), and the air conditioning including the outdoor unit 10 and the indoor unit 20 is performed. The apparatus and the heat storage medium circulation pump 34 of the ice heat storage unit 30 are operated.
[0039]
On the side of the air conditioner, the refrigerant for air conditioning circulates as follows, and changes in gas-liquid state are repeated. The high-temperature and high-pressure gas refrigerant delivered by operating the air conditioning compressor 11 is supplied to the outdoor heat exchanger 13 through the refrigerant pipe 2 by setting the four-way valve 12. The outdoor heat exchanger 13 functions as a condenser that causes heat exchange between the outside air and the air conditioning refrigerant to radiate heat to the outside air and condense the gas refrigerant. The liquid refrigerant condensed here passes through the check valve 16 and is guided to the water / refrigerant heat exchanger 50. Since the outdoor unit expansion valve 14 has a large flow path resistance, most of the liquid refrigerant flows through the check valve 16.
[0040]
The liquid-phase air-conditioning refrigerant flowing through the water-refrigerant heat exchanger 50 is cooled by exchanging heat with water (cold water) as a heat storage medium, and is added with supercooling.
More specifically, on the ice heat storage unit 30 side, the water stored in the heat storage tank 32 passes through the heat storage medium pipe 33 and the water / refrigerant heat exchanger 50 by operating the heat storage medium circulation pump 34. Circulate. This water is cold water having a very low temperature because a predetermined amount of the water is ice in the above-mentioned cooling heat storage operation mode. Accordingly, the liquid refrigerant having a relatively high temperature condensed in the outdoor heat exchanger 13 is absorbed by the cold water and added with supercooling.
In the present embodiment, the flow direction of the refrigerant for air conditioning in the water / refrigerant heat exchanger 50 and the flow direction of the chilled water are opposite, that is, the pressure direction of the heat storage medium circulating pump is defined so as to be the counterflow. I have. By using the counter flow, the heat exchange efficiency in the water / refrigerant heat exchanger 50 can be made higher than in the case of using the parallel flow.
[0041]
Thus, the liquid refrigerant having a relatively low temperature is supplied to the indoor unit 20 and the pressure is reduced by the indoor unit expansion valve 22, and then the indoor heat exchanger 21 exchanges heat with indoor air. At this time, the liquid refrigerant takes vaporization heat from the indoor air to evaporate, so that the liquid refrigerant becomes a low-pressure gas refrigerant, and the indoor air is cooled and dehumidified and blown into the room as conditioned air.
The air-conditioning refrigerant, which has become a gas refrigerant in the indoor heat exchanger 21, returns to the outdoor unit 10 through the refrigerant pipe 2, and is again sucked into the air-conditioning compressor 11 via the accumulator 15 by setting the four-way valve 12. You. Then, it circulates through the refrigerant pipe 2 while repeating the same state change.
[0042]
On the other hand, the chilled water whose temperature has been increased by adding supercooling to the air conditioning refrigerant in the water / refrigerant heat exchanger 50 is returned to the heat storage tank 32 again. Since ice remains in the heat storage tank 32, the temperature of the cold water is maintained by melting the ice. The cold water thus maintained at a low temperature circulates in the heat storage medium circulation system 31 through the heat storage medium pipe 33, the heat storage medium pump 34, and the water / refrigerant heat exchanger 50.
In addition, when there is no ice in the heat storage tank 32, that is, when the heat storage is exhausted, the temperature of the water rises. Therefore, when the water temperature sensor detects that the water temperature has risen to a predetermined value or more, this signal is output. The operation is sent to the control unit to stop the operation in the heat storage cooling operation mode.
[0043]
By employing such a heat storage cooling operation mode, supercooling can be added to the liquid-phase air-conditioning refrigerant in the water / refrigerant heat exchanger 50, and the capacity of the air-conditioning compressor 11 is reduced accordingly. Can be driven. That is, the power consumption of the air-conditioning compressor 11 is suppressed, and a high-efficiency cooling operation with low power consumption becomes possible. The power consumption of the air conditioning compressor 11 that can be reduced here is considerably larger than the power consumption required for the operation of the heat storage medium circulating pump 34. Therefore, the ice storage type air conditioner 1 consumes as a whole. The power can be reduced.
[0044]
Next, the cooling operation mode using the auxiliary heat pump shown in FIG. 3 will be described.
This operation mode is preferably performed in a time zone in which the power consumption of the cooling operation is to be suppressed, for example, before and after a time zone in which the power consumption peaks (for example, about 8:00 to 13:00 and about 16:00 to 18:00). The air conditioner including the outdoor unit 10 and the indoor unit 20 and the heat storage compressor 41 of the ice heat storage unit 30 are operated.
[0045]
On the air conditioner side, the air-conditioning refrigerant circulates as follows, and the gas-liquid state changes are repeated, similarly to the above-described cooling operation mode using heat storage.
The high-temperature and high-pressure gas refrigerant delivered by operating the air conditioning compressor 11 is supplied to the outdoor heat exchanger 13 through the refrigerant pipe 2 by setting the four-way valve 12. The outdoor heat exchanger 13 functions as a condenser that causes heat exchange between the outside air and the air conditioning refrigerant to radiate heat to the outside air and condense the gas refrigerant. The liquid refrigerant condensed here passes through the check valve 16 and is guided to the water / refrigerant heat exchanger 50. Since the outdoor unit expansion valve 14 has a large flow path resistance, most of the liquid refrigerant flows through the check valve 16.
[0046]
The liquid-phase air-conditioning refrigerant flowing through the water / heat storage unit 50 is cooled by exchanging heat with the heat-storage refrigerant here, and is added with supercooling.
To explain this in detail, on the ice heat storage unit 30 side, by operating the heat storage compressor 41, the heat storage refrigerant circulation system 40 is operated as described below, similarly to the heat storage in the cooling heat storage operation mode. Circulate and repeat state changes.
[0047]
In this operation mode, the second electromagnetic valve 45 is opened and the first electromagnetic valve 44 is closed, and the heat storage compressor 41 of the ice heat storage unit 30 is operated. Note that the heat storage medium circulation pump 34 is stopped.
As a result, the heat storage refrigerant is sent from the heat storage compressor 41 through the heat storage refrigerant pipe 48 to the heat radiation heat exchanger 42 as a high-temperature and high-pressure gas refrigerant, and the heat exchanger radiates heat to the outside air and condenses. , Becomes a high-pressure liquid refrigerant. This liquid refrigerant is guided to the second expansion valve 47 through the air-conditioning refrigerant cooling channel 48B in which the second solenoid valve 45 is opened. It is supplied to the exchanger 50.
[0048]
The liquid-phase heat storage refrigerant supplied to the water / refrigerant heat exchanger 50 absorbs heat from the liquid-phase air-conditioning refrigerant sent from the outdoor unit 10 and cools it. As a result, the liquid-phase heat storage refrigerant is vaporized into a low-pressure gas refrigerant, and the liquid-phase air-conditioning refrigerant is also supercooled. At this time, it is preferable to suppress the input of the heat storage compressor 41 by setting the evaporation temperature of the heat storage refrigerant in the water / refrigerant heat exchanger 50 to be relatively high (for example, about 10 ° C. to 15 ° C.).
The heat storage refrigerant thus converted into a gas refrigerant is sucked into the heat storage compressor 41 again, and circulates through the heat storage refrigerant pipe 48 and the air conditioning refrigerant cooling passage 48B while repeating the same state change.
[0049]
Thus, the liquid refrigerant having a relatively low temperature is supplied to the indoor unit 20 and the pressure is reduced by the indoor unit expansion valve 22, and then the indoor heat exchanger 21 exchanges heat with indoor air. At this time, the liquid refrigerant takes vaporization heat from the indoor air to evaporate, so that the liquid refrigerant becomes a low-pressure gas refrigerant, and the indoor air is cooled and dehumidified and blown into the room as conditioned air.
The air-conditioning refrigerant, which has become a gas refrigerant in the indoor heat exchanger 21, returns to the outdoor unit 10 through the refrigerant pipe 2, and is again sucked into the air-conditioning compressor 11 via the accumulator 15 by setting the four-way valve 12. You. Then, it circulates through the refrigerant pipe 2 while repeating the same state change.
[0050]
By employing such a heat storage cooling operation mode, supercooling can be added to the liquid-phase air-conditioning refrigerant in the water / refrigerant heat exchanger 50, and the capacity of the air-conditioning compressor 11 is reduced accordingly. Can be driven. That is, the power consumption of the air-conditioning compressor 11 is suppressed, and a high-efficiency cooling operation with low power consumption becomes possible. The power consumption of the air conditioning compressor 11 that can be reduced here is considerably larger than the power consumption required for the operation of the heat storage compressor 41, so that the ice storage type air conditioner 1 consumes as a whole. The power can be reduced.
[0051]
Incidentally, the heat exchange between the heat storage refrigerant and the air conditioning refrigerant in the water / refrigerant heat exchanger 50 described above is preferably performed with the water of the heat storage medium interposed. That is, the liquid-phase heat storage refrigerant evaporates, first cooling the water in the heat exchanger, exchanging heat between the cold water and the air-conditioning refrigerant, and cooling the air-conditioning refrigerant with cold water to add supercooling. By doing so, it is possible to add a stable supercooling capacity that is hardly affected by the operation fluctuation of the heat storage compressor 41.
[0052]
Next, the normal (non-heat storage use) cooling operation mode shown in FIG. 4 will be described.
This operation mode is a normal cooling operation in which the ice heat storage unit 30 is not used at all. The ice heat storage unit 30 is completely stopped, and only the outdoor unit 10 and the indoor unit 20 are operated. That is, the operation is the same as the cooling operation of a general air conditioner except that the liquid refrigerant simply passes through the water / refrigerant heat exchanger 50.
[0053]
That is, on the air conditioner side, the air conditioning refrigerant circulates as follows, and the gas-liquid state changes are repeated. The high-temperature and high-pressure gas refrigerant delivered by operating the air conditioning compressor 11 is supplied to the outdoor heat exchanger 13 through the refrigerant pipe 2 by setting the four-way valve 12. The outdoor heat exchanger 13 functions as a condenser that causes heat exchange between the outside air and the air conditioning refrigerant to radiate heat to the outside air and condense the gas refrigerant. The liquid refrigerant condensed here passes through the check valve 16 and is guided to the water / refrigerant heat exchanger 50. Since the outdoor unit expansion valve 14 has a large flow path resistance, most of the liquid refrigerant flows through the check valve 16.
[0054]
The liquid-phase air-conditioning refrigerant flowing through the water / heat storage unit 50 has no circulation of the water of the heat storage medium or the heat storage refrigerant because the ice heat storage unit 30 is stopped, and therefore, only passes through the heat exchanger. Become.
When the air-conditioning refrigerant in the liquid phase is thus supplied to the indoor unit 20, the pressure is reduced by the indoor unit expansion valve 22, and the indoor heat exchanger 21 exchanges heat with indoor air. Here, the liquid refrigerant evaporates by taking heat of vaporization from the indoor air, so that the liquid-phase refrigerant becomes a low-pressure gas refrigerant, and the indoor air is cooled and dehumidified and blown into the room as conditioned air.
The air-conditioning refrigerant, which has become a gas refrigerant in the indoor heat exchanger 21, returns to the outdoor unit 10 through the refrigerant pipe 2, and is again sucked into the air-conditioning compressor 11 via the accumulator 15 by setting the four-way valve 12. You. Then, it circulates through the refrigerant pipe 2 while repeating the same state change.
[0055]
Finally, the heating operation mode shown in FIG. 5 will be described.
This operation mode is the same as the heating operation in a normal air conditioner that does not use the ice heat storage unit 30 at all. The ice heat storage unit 30 is completely stopped, and only the outdoor unit 10 and the indoor unit 20 are operated. . That is, the only difference is that the liquid refrigerant simply passes through the water / refrigerant heat exchanger 50.
[0056]
That is, on the air conditioner side, the air conditioning refrigerant circulates as follows, and the gas-liquid state changes are repeated. The high-temperature and high-pressure gas refrigerant delivered by operating the air conditioning compressor 11 is supplied to the indoor heat exchanger 21 of the indoor unit 20 through the refrigerant pipe 2 by setting the four-way valve 12. The indoor heat exchanger 21 functions as a condenser (radiator) for exchanging heat between the indoor air and the air conditioning refrigerant to radiate heat to the inside air and condense the gas refrigerant. For this reason, the inside air becomes heated conditioned air and is blown out toward the room.
[0057]
On the other hand, the liquid refrigerant condensed in the indoor heat exchanger 21 passes through the check valve 23 and is guided to the water / refrigerant heat exchanger 50. Since the indoor unit expansion valve 22 has a large flow path resistance, most of the liquid refrigerant flows through the check valve 23.
The liquid-phase air-conditioning refrigerant flowing through the water / heat storage unit 50 has no circulation of the water of the heat storage medium or the heat storage refrigerant because the ice heat storage unit 30 is stopped, and therefore, only passes through the heat exchanger. Become.
[0058]
When the air-conditioning refrigerant in the liquid phase is returned to the outdoor unit 10 in this way, the pressure is reduced by the outdoor unit expansion valve 14, and the outdoor heat exchanger 13 exchanges heat with the outside air. Here, the liquid refrigerant takes vaporization heat from the outside air and evaporates, so that the liquid-phase refrigerant becomes a low-pressure gas refrigerant, and the outside air lowers in temperature and is blown out of the room.
The air-conditioning refrigerant, which has become a gas refrigerant in the outdoor heat exchanger 13, is sucked into the air-conditioning compressor 11 again through the accumulator 15 by setting the four-way valve 12. Then, it circulates through the refrigerant pipe 2 while repeating the same state change.
[0059]
As described above, in the ice heat storage air conditioner 1 of the present invention, the heat storage refrigerant system used in the ice heat storage unit 30 and the air conditioning refrigerant system used in the air conditioner independently form a refrigeration cycle. Therefore, the air conditioning operation for cooling and heating for operating the outdoor unit 10 and the indoor unit 20 can be performed simultaneously with the execution of the cooling heat storage operation mode in which the ice heat storage unit 30 is operated alone. That is, since only the air-conditioning refrigerant passes through the water / refrigerant heat exchanger 50, the cold heat storage by the heat storage refrigerant and the air-conditioning by the air-conditioning refrigerant can be operated by independent control without being affected by each other. it can.
[0060]
Therefore, for example, an ice heat storage unit 30 can be provided as a retrofit to an existing air conditioner including the outdoor unit 10 and the indoor unit 20. In other words, there is no need to separately develop the outdoor unit 10 and the indoor unit 20 dedicated for connecting the ice heat storage unit 30, and the standardized outdoor unit 10 and the indoor unit 20 used for a normal air conditioner are: It is possible to easily combine the ice heat storage units 30 as needed.
Further, even if one of the air conditioner and the ice heat storage unit 30 fails, the entire ice heat storage type air conditioner 1 can be repaired without stopping. That is, even if a failure occurs on the ice heat storage unit 30 side, normal cooling and heating operation can be continued.
[0061]
In addition, it is not necessary to use the same type of refrigerant as the air-conditioning refrigerant and the heat storage refrigerant. For example, a general R407C is used as the air-conditioning refrigerant, and R410C that is effective for improving the COP is used as the heat storage refrigerant. Is also possible.
[0062]
By the way, in order to use R410C as a refrigerant for air conditioning, a significant improvement is required, such as changing the pressure resistance performance of various components such as compressors, valves and pipes because of the high pressure resistance refrigerant, resulting in an increase in cost. . However, if the refrigerant system is independent as in the configuration of the present invention, it is possible to use R410C only for the heat storage refrigerant on the ice heat storage unit 30 side, and the air conditioner side remains unchanged without significant improvement. However, it is possible to improve the COP of the entire ice regenerative air conditioner and achieve high efficiency.
[0063]
The configuration of the present invention is not limited to the above-described embodiment, and can be appropriately changed without departing from the gist of the present invention.
[0064]
【The invention's effect】
According to the ice heat storage unit, the ice heat storage type air conditioner, and the operation method of the present invention described above, the following effects can be obtained.
According to the ice heat storage unit of the first and second aspects, the refrigerant circulation system stores the cold heat by operating the ice heat storage unit independently of the air conditioner, or stops the operation of the ice heat storage unit and operates the refrigerant circulation system. Can operate an independent air conditioner independently.In addition, in the heat storage medium / refrigerant heat exchanger, supercooling is added to the air conditioning refrigerant by the heat storage medium, and superheat is added to the air conditioning refrigerant by the heat storage medium. The cooling addition can be performed selectively.
This makes it easy to retrofit existing air conditioners and to combine them with standard air conditioners, and to use unique refrigerants. There is no need to develop a new unit or indoor unit, which makes the ice storage unit highly versatile.
[0065]
According to the ice heat storage type air conditioner of the fourth aspect, since the ice heat storage unit is provided with the heat storage refrigerant circulation system independent of the air conditioning refrigerant circulation system, the ice heat storage unit can store cold heat by independent operation. Alternatively, the operation of the ice heat storage unit is stopped, and the cooling operation or the heating operation can be performed by the air conditioner alone. Also, the amount of refrigerant required for operation can be suppressed.
For this reason, it becomes easy to retrofit an existing air conditioner with an ice heat storage unit or to provide an ice heat storage unit in combination with a standardized normal air conditioner. Also, since it is possible to use a unique refrigerant for the air conditioner and the heat storage refrigerant unit, there is no need to newly develop an outdoor unit or an indoor unit dedicated to the ice storage type air conditioner. It becomes a highly versatile ice storage air conditioner.
[0066]
In addition, an auxiliary heat pump-based cooling operation mode is provided, in which the heat storage refrigerant flows through the heat storage medium / refrigerant heat exchanger and supercooling is added to the air conditioning refrigerant using the cold heat of the heat storage refrigerant. , The COP can be improved by downsizing the compressor and reducing the power consumption, and the production and operation costs can be greatly reduced.
In this case, in the heat storage medium / refrigerant heat exchanger, if the heat storage refrigerant adds supercooling to the air conditioning refrigerant via the heat storage medium, the air conditioning refrigerant is supercooled by the heat storage medium having small temperature fluctuations. Can be added, so that a remarkable effect of adding a stable supercooling ability can be obtained.
[0067]
According to the operation method of the ice storage type air conditioner according to claim 7, an operation mode in which the ice storage unit is operated alone and an operation mode in which the ice storage unit and the air conditioner including the outdoor unit and the indoor unit are operated together And an operation mode in which an air conditioner including an outdoor unit and an indoor unit is independently operated, so that an ice heat storage unit can be retrofitted or operated in combination with a normal air conditioner. Is easier to do.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing an embodiment of an ice storage air conditioner according to the present invention, and shows a state of a cooling heat storage operation mode.
FIG. 2 is a configuration diagram showing an embodiment of an ice storage type air conditioner according to the present invention, and shows a state of a cooling operation mode using heat storage.
FIG. 3 is a configuration diagram showing an embodiment of an ice storage type air conditioner according to the present invention, showing a state of a cooling operation mode using an auxiliary heat pump.
FIG. 4 is a configuration diagram showing one embodiment of an ice storage type air conditioner according to the present invention, and shows a state of a normal (non-heat storage use) cooling operation mode.
FIG. 5 is a configuration diagram showing one embodiment of an ice storage type air conditioner according to the present invention, showing a state of a heating operation mode.
[Explanation of symbols]
1 Ice storage air conditioner
2 Refrigerant piping (air conditioning refrigerant piping)
10. Outdoor unit
11 Compressor for air conditioning
12 Four-way valve
13 outdoor heat exchanger
14. Outdoor expansion valve (throttle means)
15 Accumulator
16, 23, 49 Check valve
20 indoor unit
21 Indoor heat exchanger
22 Indoor expansion valve (throttle means)
30 Ice heat storage unit
31 Heat storage medium circulation system
32 thermal storage tank
33 Heat storage medium piping
34 Heat storage medium circulation pump
40 Refrigerant circulation system for heat storage
41 Compressor for heat storage
42 Heat exchanger for heat dissipation
43 Heat exchanger for heat storage
44 first solenoid valve (flow path selecting means)
45 second solenoid valve (flow path selecting means)
46 first expansion valve (first throttle means)
47 Second expansion valve (second throttle means)
48 Heat storage refrigerant piping
48A heat storage channel
48B Refrigerant cooling channel for air conditioning
50 Water (heat storage medium) / refrigerant heat exchanger
C heat storage medium

Claims (7)

A heat storage medium circulating system that stores and circulates the heat storage medium, and a heat storage refrigerant circulating system that circulates the heat storage refrigerant to generate cold heat, and cools the heat generated by the heat storage refrigerant circulating system to the heat storage medium. An ice heat storage unit, comprising: a heat storage medium / refrigerant heat exchanger that stores heat and adds supercooling to the air-conditioning refrigerant of an air conditioner using the cold stored by the heat storage medium or the heat storage refrigerant. A heat storage medium comprising: a heat storage tank that stores a heat storage medium; a heat storage medium pipe that introduces the heat storage medium from a lower part of the heat storage tank and returns the heat storage medium to an upper part; and a heat storage medium circulation pump provided in the heat storage medium pipe. Circulatory system,
A compressor that compresses the heat storage refrigerant, a heat radiation heat exchanger that performs heat exchange between the heat storage refrigerant and the outside air, and a heat exchanger that is installed in the heat storage tank and that is between the heat storage refrigerant and the heat storage medium. A heat storage heat exchanger for exchanging heat with the heat storage medium, a heat storage medium / refrigerant heat exchanger for adding supercooling to the air conditioning refrigerant of the air conditioner with the cold stored by the heat storage medium or the heat storage refrigerant, and the heat release heat Downstream of the exchanger, a heat storage flow path returning to the compressor via a first throttle means and the heat storage heat exchanger via a flow path selection means, a second throttle means and the heat storage medium / refrigerant A heat storage refrigerant circulation system comprising: a heat storage refrigerant pipe branched to an air conditioning refrigerant cooling flow path returning to the compressor via a heat exchanger;
An ice heat storage unit comprising: The heat storage medium / refrigerant heat exchanger is a three-pass type in which three kinds of fluids, that is, the heat storage medium, the heat storage refrigerant, and the air conditioning refrigerant, flow to exchange heat. Or the ice heat storage unit of 2. An outdoor unit including a compressor for compressing the air-conditioning refrigerant and an outdoor heat exchanger for causing heat exchange between the air-conditioning refrigerant and outdoor air,
A suction port for taking in indoor air, an indoor heat exchanger for cooling or heating by exchanging heat between the air taken in from the suction port and the air conditioning refrigerant, and heat exchanged in the indoor heat exchanger. An air outlet for returning the air to the room, and an indoor unit comprising: an indoor air blower for blowing air that has been heat-exchanged by taking in the air from the air inlet into the room from the air outlet;
The ice heat storage unit according to any one of claims 1 to 3, further comprising a heat storage refrigerant circulating system independent of the air conditioning refrigerant circulating system.
A refrigerant pipe for circulating the air conditioning refrigerant by connecting the outdoor unit, the indoor unit and the ice heat storage unit,
An ice storage air conditioner comprising: An auxiliary heat pump-based cooling operation mode is provided in which the heat storage refrigerant is caused to flow through the heat storage medium / refrigerant heat exchanger, and supercooling is added to the air conditioning refrigerant with the cold heat held by the heat storage refrigerant. The ice storage type air conditioner according to claim 4. The ice storage type air conditioner according to claim 5, wherein in the heat storage medium / refrigerant heat exchanger, the heat storage refrigerant adds supercooling to the air conditioning refrigerant via the heat storage medium. It is an operating method of the ice storage type air conditioner according to any one of claims 4 to 6,
A cooling heat storage operation mode in which the ice heat storage unit is operated independently to circulate the heat storage refrigerant, and cools and stores heat in the heat storage medium with the heat storage refrigerant;
By operating the ice heat storage unit to circulate the heat storage medium and operating the outdoor unit and the indoor unit, supercooling is added to the air-conditioning refrigerant with the cold stored by the heat storage medium to perform a cooling operation. A heat storage cooling operation mode to be performed;
The ice heat storage unit is operated to circulate the heat storage refrigerant, and the outdoor unit and the indoor unit are operated, and supercooling is added to the air conditioning refrigerant with the cold stored by the heat storage refrigerant to perform cooling. A cooling operation mode using an auxiliary heat pump for operation,
A normal operation cooling mode in which the operation of the ice heat storage unit is stopped and the outdoor unit and the indoor unit are operated to perform a cooling operation;
A heating operation mode in which the operation of the ice heat storage unit is stopped and the outdoor unit and the indoor unit are driven and
An operation method for an ice storage air conditioner, wherein one of the above operation modes is selected for operation.

Images