KR100662115B1 - Regenerative Air Conditioning System - Google Patents

Abstract

The present invention relates to a heat storage air-conditioning system in which a plurality of heat storage exchangers are provided with measuring means for measuring an amount of heat storage (de-icing) and an expansion device for expanding a refrigerant.

The heat storage air-conditioning system according to the present invention includes an outdoor unit (100) having an outdoor heat exchanger (120) in which heat exchange occurs, and a compressor (110) for compressing a refrigerant; An indoor unit 400 having an indoor heat exchanger 420 through which heat exchange occurs; A plurality of heat storage exchanger 320, heat exchange occurs, a plurality of heat storage expansion devices (330, 332) for expanding each of the refrigerant flowing into the plurality of heat storage exchanger 320, and a plurality of measuring means for measuring the degree of heat storage (deicing) A heat storage unit 300 provided with (334, 334 '); It has a configuration including one or more functional units 200 for controlling the flow of the refrigerant in accordance with the operating conditions. The plurality of heat storage expansion devices 330 and 332 are controlled by the heat storage control unit 340. According to the present invention having such a configuration, there is an effect that the performance of the system is improved.

Description

Regenerative air conditioning system {Thermal storage airconditioner}

1 is a schematic configuration diagram of a conventional heat storage air conditioning system.

Figure 2 is a building bird's eye view showing a state of use of the preferred embodiment of the heat storage air-conditioning system according to the present invention.

3 is a block diagram of a preferred embodiment of the heat storage air conditioning system according to the present invention.

Figure 4 is a block diagram showing a connection state of the heat storage expansion device and the measuring means constituting a preferred embodiment of a heat storage air-conditioning system according to the present invention.

Figure 5a is a block diagram showing a refrigerant flow when the embodiment of the present invention is used in the 'heat storage mode'.

Figure 5b is a block diagram showing a refrigerant flow when the embodiment of the present invention is used in the 'heat storage cooling mode'.

Figure 5c is a block diagram showing a refrigerant flow when the embodiment of the present invention is used in the 'direct cooling mode'.

Explanation of symbols on the main parts of the drawings

100. Outdoor unit 110. Compressor

120. Outdoor Heat Exchanger 130. Accumulator

140. Four-way valve 150. Outdoor expansion device

200. Function unit 210. Auxiliary flow path

212. Auxiliary heat exchanger 214. Auxiliary pump

216. First valve 218. Second valve

220. Functional low voltage connection 222. Functional high pressure connection

240. Liquid flow path 244. Dryer

246.Pump 248. Receiver

250. High pressure heat storage connection 252. 5th valve

300. Heat storage unit 310. Heat storage tank

320. Heat storage exchanger 322. First heat exchanger

324. Second heat storage exchanger 330. First heat storage expansion device

332. Second heat storage expansion device 334. First measuring means

334 '. Second measuring means 340. Heat storage control unit

400. Indoor unit 410. Indoor high pressure flow path

412. Indoor low pressure oil passage 420. Indoor heat exchanger

430. Expansion device 450. Distribution head

The present invention relates to an air conditioner, and more particularly, to a regenerative air conditioner having a plurality of measuring means for measuring the amount of heat storage (de-icing) and an expansion device for expanding a refrigerant.

In general, an air conditioner includes a cooling / heating system that cools a room by a repetitive action of inhaling hot air in a room, exchanging heat with a low-temperature refrigerant, and then discharging it into the room. Mainly used, this air conditioner consists of a compressor-condenser-expansion-evaporator to form a series of cycles.

Recently, a regenerative air conditioning system is used to cool the room by using ice iced at night (when the power is low) as a condensation heat source during the daytime (when the power is used) to reduce electricity costs.

Figure 1 shows an example of a conventional heat storage air conditioning system.

As shown therein, an outdoor unit 3 having a compressor 1 for compressing a refrigerant and an outdoor heat exchanger 2 for providing heat exchange between the refrigerant compressed and flowed by the compressor 1 is provided on one side. do.

One side of the outdoor unit 3 is provided with a heat storage unit 10 for temporarily storing energy. The heat storage unit 10 includes a heat storage tank 11 in which heat storage material is stored, a water pump 12 for circulating water in the heat storage tank 11, and a heat exchanger 13 in which heat exchange between the water and the refrigerant occurs. And a refrigerant liquid pump 14 for forcing the flow of the liquid refrigerant. The heat storage tank 11 is provided with a heat storage exchanger (11 ') that heat exchange occurs.

Meanwhile, at least one indoor unit 20 is installed at one side of the heat storage unit 10. The indoor unit 20 is introduced into the indoor heat exchanger 21 and the indoor heat exchanger 21 where heat exchange occurs. An indoor expansion device 22 for expanding the refrigerant is provided.

In the conventional heat storage air-conditioning system having the above-described configuration, ice is frozen inside the heat storage tank 11 of the heat storage unit 10 at night, and then, during the day when power consumption is high (for example, 13:00 to 16:16). At 00 hours), indoor cooling is performed by using the ice deiced in the heat storage tank 11.

At this time, the compressor 1 is stopped and the refrigerant is circulated using the refrigerant liquid pump 14. Therefore, the refrigeration cycle at this time, the refrigerant is supplied by the refrigerant liquid pump 14, the heat exchange takes place in the indoor heat exchanger 21 which serves as an evaporator through the indoor expansion device (22). That is, since the indoor heat exchanger 21 absorbs heat of the indoor space, the room is cooled.

The refrigerant absorbing heat from the indoor heat exchanger 21 flows to the heat exchanger 13 to exchange heat with ice frozen in the heat storage tank 11 to become a cool refrigerant. The coolant is then moved to the coolant liquid pump 14 to complete the cycle.

Meanwhile, one end of the heat storage tank 11 is connected to the heat exchanger 13, and cold water inside the heat storage tank 11 is circulated by the water pump 12 to the heat exchanger 13.

However, the prior art as described above has the following problems.

In the heat storage air conditioning system according to the related art as described above, one heat storage exchanger 11 'is provided inside the heat storage tank 11. Therefore, there is a problem that it is difficult to evenly ice the water in the heat storage tank (11).

That is, since the heat storage exchanger 11 'is provided with one, the length thereof becomes long. Therefore, the temperature difference between the refrigerant at the inlet side and the outlet side of the heat storage exchanger 11 ′ is relatively large, and the water contacting the outlet side of the heat storage exchanger 11 ′ is relatively less in ice making than the water contacting the inlet side.

As described above, in the related art, the amount of ice making is different according to each part inside the heat storage tank 11, so that it is difficult to form an even amount of ice making, so that the performance of the heat storage air conditioning system is relatively low.

Accordingly, an object of the present invention is to solve the above problems, and to provide a regenerative air conditioning system having a plurality of regenerative heat exchangers.

Another object of the present invention is to provide a heat storage air conditioning system in which an expansion device for expanding a refrigerant in a plurality of heat storage exchangers is installed.

It is still another object of the present invention to provide a heat storage air conditioning system in which a plurality of heat storage exchangers are provided with measuring means for measuring the amount of heat storage (ice making).

The heat storage air-conditioning system according to the present invention for achieving the above object comprises an outdoor unit having an outdoor heat exchanger, and a compressor for compressing a refrigerant; An indoor unit having an indoor heat exchanger in which heat exchange occurs; A heat storage unit having a plurality of heat storage exchangers in which heat exchange takes place, and a plurality of heat storage expansion devices respectively expanding the refrigerant flowing into the plurality of heat storage exchangers; Characterized in that it has a configuration that includes; at least one functional unit for controlling the flow of the refrigerant in accordance with the operating conditions.

The heat storage unit is characterized in that each of the plurality of measuring means for measuring the degree of heat storage (de-icing) performed by the plurality of heat storage exchanger.

The plurality of heat storage expansion devices are controlled by a heat storage control unit to adjust the degree of expansion of the refrigerant.

The heat storage control unit is characterized in that for controlling the opening and closing of the plurality of heat storage expansion device according to the information measured by the plurality of measuring means.

The heat storage control unit controls the heat storage (de-icing) degree performed by the plurality of heat storage exchangers to be the same.

The measuring means is characterized in that it is installed in the heat storage exchanger.

According to the heat storage type air conditioning system according to the present invention having such a configuration, there is an advantage that the heat storage (ice making) performance is improved.

Hereinafter, exemplary embodiments of the present invention as described above will be described in detail with reference to the accompanying drawings.

2 is a bird's eye view of a schematic state in which a heat storage air conditioning system according to the present invention is installed in a building.

As shown in the figure, the outdoor unit 100, the functional unit 200, and the heat storage unit 300 constituting the present invention are separately installed on the outside of the building, and each of these units is installed inside the building. It is connected to the indoor unit 400.

The indoor unit 400 is provided with one or a plurality, the various types of indoor unit 400 is installed in each space of the room to operate individually or integrally. Therefore, the distribution head 450 may be built in the building to distribute the refrigerant to the plurality of indoor units 400 as described above.

3 is a configuration diagram of a heat storage air conditioning system according to the present invention, and FIG. 4 shows a state in which an expansion device and a measuring means inside the heat storage unit constituting the heat storage air conditioning system according to the present invention are controlled by a controller. A block diagram is shown.

As shown in the figure, the outdoor unit 100 includes a compressor 110 for compressing a refrigerant, and an outdoor heat exchanger 120 for exchanging heat with the refrigerant and ambient air.

The compressor 110 is to compress the refrigerant to be a high temperature and high pressure, one or more are provided. That is, one compressor 110 is installed to compress the refrigerant, and a constant speed compressor for constant speed operation and an inverter compressor that is a variable speed heat pump may be installed in pairs to operate according to the load.

An accumulator 130 is installed at one side of the compressor 110. The accumulator 130 accumulates liquid refrigerant among the refrigerant flowing into the compressor 110 so that only the gas refrigerant flows into the compressor 110.

In more detail, the refrigerant remaining in the liquid phase without being evaporated among the refrigerant introduced into the accumulator 130 is stored in the lower portion of the accumulator 130 because it is relatively heavier than the refrigerant in the gas phase, and only the gaseous refrigerant in the upper portion is It is introduced to the compressor (110).

As such, the reason for separating the gaseous refrigerant and the liquid refrigerant by the accumulator 130 is that, when the refrigerant remaining in the liquid phase without being evaporated into the gas in the refrigerant flows directly into the compressor 110, the refrigerant is heated at high temperature and high pressure. This is because the load on the compressor 110 that compresses the gaseous refrigerant of the gas is increased, resulting in damage to the compressor 110.

The outdoor unit 100 is provided with a four-way valve 140. The four-way valve 140 is installed in communication with a plurality of pipes. The four-way valve 140 is arranged to change the flow direction of the refrigerant according to the cooling and heating operation, each port is the outlet of the compressor 110, the inlet of the accumulator 130, the outdoor heat exchanger 120 and the function Connected to the unit 200 or the indoor unit 400, respectively.

An outdoor expansion device 150 is further provided at the outlet side of the outdoor heat exchanger 120 to control a movement amount of the refrigerant passing through the outdoor heat exchanger 120.

The outdoor unit 100 is combined with the functional unit 200. Accordingly, the outdoor low pressure connection unit 160 is formed in the pipe connected to the four-way valve 140, and the outdoor high pressure connection unit 162 is formed at one side of the outdoor expansion device 150.

Of course, it is also possible that the outdoor unit 100 is directly connected to the indoor unit 400. That is, the outdoor low pressure connection unit 160 may be connected to the indoor low pressure passage 412 to be described below, and the outdoor high pressure connection unit 162 may be connected to the indoor high pressure passage 410 to be described below.

The functional unit 200 is installed on one side of the outdoor unit 100, and controls the flow of the refrigerant in accordance with the operating conditions.

An auxiliary flow path 210 for guiding a coolant is formed in the functional unit 200, and the auxiliary flow path 210 is installed at one side of the auxiliary heat exchanger 212 and the auxiliary heat exchanger 212 through which heat exchange occurs. An auxiliary pump 214 for forcing the flow of the refrigerant is provided.

The auxiliary heat exchanger 212 is a heat exchange between the refrigerant and the outside air, such as the outdoor heat exchanger 120, and is selectively operated when the heat storage unit 300 is used. That is, when energy stored in the heat storage unit 300 is used, it is used only when necessary according to the capacity of the indoor unit 400 or the required temperature.

The auxiliary pump 214 forcibly flows the refrigerant so that the refrigerant flows into the auxiliary passage 210 and the auxiliary heat exchanger 212, and compresses the refrigerant. In addition, a first four-way valve 215 is installed between the auxiliary heat exchanger 212 and the auxiliary pump 214.

First and second valves 216 and 218 are provided at both ends of the auxiliary flow path 210, respectively, to open and close the auxiliary flow path 210.

One end of the functional unit 200 is connected in communication with the outdoor unit 100. In more detail, the functional low pressure connection unit 220 formed at one end of the functional unit 200 is connected to the outdoor low pressure connection unit 160 of the outdoor unit 100, and the functional high pressure connection unit of the functional unit 200 ( 222 are connected to the outdoor high voltage connection portion 162 of the outdoor unit 100, respectively.

The functional valve 200 is provided with a third valve 224 and a fourth valve 226, respectively. A liquid passage 240 is branched between the third valve 224 and the fourth valve 226. That is, the third valve 224 and the fourth valve 226 are respectively provided at both ends of the liquid passage 240 to control the flow of the refrigerant. The third valve 224 is connected to the functional high pressure connecting portion 222 is installed.

The liquid flow path 240 serves as a path for guiding the refrigerant flowing from the heat storage unit 300 when the air conditioner is operated using the heat storage unit 300. And the inlet and outlet side of the liquid flow path 240 is configured such that the flow path is controlled by the second four-way valve 242.

The liquid passage 240 is provided with a dryer 244. The dryer 244 is for removing moisture in the refrigerant flowing through the liquid passage 240.

A liquid pump 246 is installed at one side of the dryer 244. The liquid pump 246 forces the flow of the refrigerant flowing through the liquid flow path 240, and particularly, when the air conditioner is operated by the heat storage unit 300, the refrigerant flow.

The receiver 248 is installed at one side of the liquid pump 246. The receiver 248 separates the gas refrigerant and the liquid refrigerant.

More specifically, the receiver 248 stores the excess refrigerant among the refrigerant flowing from the outdoor unit 100 and at the same time allows only the liquid refrigerant to flow. That is, in the 'heat storage mode' only the liquid refrigerant is transferred to the heat storage unit 300.

One side of the fourth valve 226 is formed with a high pressure heat storage connection portion 250. Therefore, one end of the pipe of the heat storage unit 300 is connected to the high pressure heat storage connection unit 250.

On the other hand, the functional unit 200 is further provided with a fifth valve 252, the indoor high-pressure flow path 410 of the indoor unit 400 to be described later is branched to the fifth valve 252.

The functional unit 200 is also connected to the indoor unit 400. Therefore, at one end of the functional unit 200, the indoor low pressure connection part 260 and the indoor high pressure connection part 262 are formed, respectively.

The indoor low pressure connection part 260 is a part connected to the pipe of the indoor unit 400 in which the low pressure refrigerant flows in the cooling operation, and the indoor high pressure connection part 262 is a room in which the high pressure refrigerant flows in the cooling operation. It is a part connected to the piping of the unit 400.

One side of the indoor low pressure connection unit 260 is further provided with a shielding valve 270 for selectively blocking the refrigerant flowing between the indoor unit 400 and the functional unit 200.

The coolant flows into the functional unit 200 from the heat storage unit 300, and the coolant flowing from the heat storage unit 300 is connected to the second valve 218 through a low pressure storage connection part 272. It flows into the functional unit 200.

The heat storage unit 300 is installed and connected to the functional unit 200, the refrigerant flow between the heat storage unit 300 and the functional unit 200 is the second valve 218 and the fourth valve 226. Controlled by

The heat storage unit 300 is provided with a heat storage tank 310 in which heat storage material is stored. Therefore, the heat storage material stored in the heat storage tank 310 is heated or cooled to store heat. The heat storage material stored in the heat storage tank 310 accumulates (heat) energy, and is preferably made of water (H ₂ O) having a high specific gravity.

The heat storage tank 310 is provided with a heat storage exchanger (320). The heat storage exchanger 320 is provided with two, heat exchange between the refrigerant flowing through the inside and the heat storage material of the outside, it is preferable that a plurality is provided. That is, the heat storage exchanger 320 is composed of a first heat exchanger 322 and a second heat exchanger 324, the heat storage material stored in the heat storage tank 310 according to the refrigerant temperature in the heat storage exchanger 320 is heated. You will lose or cool down.

A first heat storage expansion device 330 is installed at an inlet (refrigerant inlet) side of the first heat exchanger 322, and a second storage outlet (outlet at which refrigerant is discharged) of the second heat exchanger 324. The heat storage expansion device 332 is installed. The first heat storage expansion device 330 and the second heat storage expansion device 332 adjust the amount of refrigerant flowing into the heat storage unit 300 and allow the refrigerant to be in a low temperature low pressure state by expansion.

As the first thermal expansion device 330 and the second thermal expansion device 332, various valves such as an electronic expansion valve or a solenoid valve, also called a linear expansion valve (LEV), may be used.

Accordingly, the first heat storage expansion device 330 and the second heat storage expansion device 332 thermally expand the refrigerant condensed in the outdoor heat exchanger 120 in the 'heat storage mode' to lower the temperature and pressure of the refrigerant. Or, it serves to send the amount of refrigerant suitable for the load to the heat storage exchanger (320).

The first heat storage expansion device 330 and the second heat storage expansion device 332 are controlled by the heat storage control unit 340 to be described below to adjust the degree of expansion of the refrigerant flowing into each of the heat storage exchanger (320). do. That is, each of the heat storage expansion devices 330 and 332 adjusts the valve opening degree under the control of the heat storage control unit 340 to actively control the amount of refrigerant discharged into the heat storage exchanger 320 and to reduce the refrigerant pressure.

The heat storage unit 300 is provided with a plurality of measuring means (334, 334 '). The measuring means (334, 334 ') is to measure the degree of heat storage (de-icing) performed by the plurality of heat storage exchanger (320). In more detail, the measuring means 334 and 334 'are installed in each of the plurality of heat storage exchangers 320. That is, the first measurement means 334 is installed in the first heat exchanger 322, and the second measurement means 334 ′ are respectively installed in the second heat exchanger 324.

The measuring means 334, 334 'may be configured in various forms as long as it has a function of measuring the amount of heat storage (ice making). The measuring means 334 and 334 'may be installed inside or outside the heat storage exchanger 320 having a pipe shape. The measuring means 334 and 334' may be formed in various shapes, respectively, by various methods. It may be configured to measure the heat storage (deicing) degree by the heat storage exchanger (320) of.

For example, the heat storage (deicing) degree of the heat storage exchanger 320 is indirectly measured by measuring the temperature of the refrigerant that is installed inside the pipe of the heat storage exchanger 320 and expanded by the heat storage expansion devices 330 and 332. Various methods such as measuring the temperature of the heat storage material (water) or the temperature change of the heat storage material (water) by measuring the temperature of the heat storage material (water) or the solid material by measuring the thickness of the solid may be performed. It will be possible.

As shown in FIG. 5, the measuring means 334 and 334 ′ and the heat storage expansion devices 330 and 332 are connected to the heat storage control unit 340. The heat storage control unit 340 controls the heat storage expansion devices 330 and 332 by collecting the heat storage (de-icing) degree of each heat storage exchanger 320 sensed by the measurement means 334 and 334 '. That is, the heat storage control unit 340 controls the opening and closing of the heat storage expansion devices 330 and 332 according to the information measured by the plurality of measurement means 334 and 334 '.

In more detail, the heat storage control unit 340 preferably controls the heat storage (de-icing) degree performed by the plurality of heat storage exchangers 320 to be the same.

Therefore, when the amount of ice making (de-icing degree) in the second heat storage exchanger 324 is smaller than the amount of ice making (de-icing degree) in the first heat storage exchanger 322, the control of the heat storage control unit 340 is performed. The expansion of the refrigerant in the second heat storage expansion device 332 is increased, and conversely, the amount of ice making (ice level) in the first heat storage exchanger 322 is larger than the amount of ice making (ice level) in the second heat exchanger 324. In this small case, the expansion of the refrigerant in the first heat storage expansion device 330 is increased by the control of the heat storage control unit 340.

The indoor unit 400 is connected to the functional unit 200. In more detail, the indoor high pressure connecting portion 262 of the functional unit 200 is connected to the indoor high pressure passage 410 of the indoor unit 400, and the indoor low pressure connecting portion 260 of the functional unit 200 is an indoor unit. It is connected to the indoor low pressure passage 412 of (400).

The indoor unit 400 includes an indoor heat exchanger 420 through which heat exchange occurs, and an indoor expansion device 430 for expanding the refrigerant and controlling the amount of refrigerant.

The indoor unit 400 is provided with one or two or more, each having a capacity suitable for cooling or heating of the indoor space.

The indoor expansion device 430 is formed of an electronic expansion device (LEV) like the first thermal expansion device 330 and the second thermal expansion device 332. Therefore, the indoor expansion device 430 thermally expands the refrigerant condensed in the outdoor heat exchanger 120 in the 'direct cooling mode' to lower the temperature and pressure of the refrigerant, and the amount of refrigerant suitable for the load is the indoor heat exchange. It serves to send to the flag (420).

Hereinafter, the operation of the regenerative air conditioning system having the configuration as described above will be described taking an example for cooling.

First, a case in which the heat storage air conditioning system according to the present invention operates in the 'heat storage mode' will be described with reference to FIG. 5A.

The 'heat storage mode' is to store energy in the heat storage unit 300 in advance at night, that is, when the power consumption is low, specifically, the heat storage material stored in the heat storage tank 310 of the heat storage unit 300. Phase change (de-icing if the heat storage material is water).

At this time, the outdoor unit 100, the functional unit 200 and the heat storage unit 300 is operated. That is, at this time, the outdoor unit 100 and the heat storage unit 300 communicate with each other in the functional unit 200, and the flow of the refrigerant is blocked by the indoor unit 400.

In more detail, the flow of the refrigerant is blocked by the shielding valve 270 and the fifth valve 252 to stop the refrigerant flow between the indoor unit 400 and the functional unit 200.

Therefore, by the action of the compressor 110, the refrigerant is compressed to high pressure and flows into the outdoor heat exchanger 120 via the four-way valve 140, as shown by the arrow.

Since the outdoor heat exchanger 120 is generally installed outdoors, the refrigerant flowing inside the outdoor heat exchanger 120 causes heat exchange with air outside the building.

At this time, since the heat storage mode, the refrigerant inside the outdoor heat exchanger 120 is deprived of heat to the outside. That is, since the outdoor heat exchanger 120 acts as a condenser, the refrigerant is cooled through heat exchange with external air, thereby becoming a liquid refrigerant (of course, not a complete liquid refrigerant).

The refrigerant discharged from the outdoor heat exchanger 120 passes through the outdoor expansion device 150 and flows into the functional unit 200.

The refrigerant introduced into the functional unit 200 again flows into the heat storage unit 300. That is, since the liquid flow path 240 is blocked by the third valve 224 and the fourth valve 226, the refrigerant flowing into the functional unit 200 is directly through the high pressure heat storage connection unit 250. It flows to the heat storage unit 300.

The refrigerant introduced into the heat storage unit 300 is divided into two branches and passes through the first heat storage expansion device 330 and the second heat storage expansion device 332. The refrigerant passing through the first heat storage expansion device 330 and the second heat storage expansion device 332 becomes a refrigerant having a relatively low temperature and low pressure by expansion, and more preferably, the temperature of the coolant becomes below zero.

The refrigerant passing through the first heat storage expansion device 330 and the second heat storage expansion device 332 undergoes heat exchange while passing through the first heat storage heat exchanger 322 and the second heat storage heat exchanger 324. At this time, the first heat storage exchanger 322 and the second heat storage exchanger 324 act as an evaporator, thereby lowering the temperature of the heat storage material stored in the heat storage tank 310, and eventually, inside the heat storage tank 310. The heat storage material changes phase (de-ice). That is, the heat storage material inside the heat storage tank 310 is gradually changed in phase from the periphery of the heat exchanger 320 due to a decrease in temperature.

The refrigerant deprived of heat while passing through the heat storage exchanger 320 becomes a gas state by evaporation, and the refrigerant flows into the functional unit 200 through the low pressure heat storage connection unit 272. At this time, the second valve 218 blocks the refrigerant from flowing into the auxiliary flow path 210.

The refrigerant introduced into the functional unit 200 is introduced into the outdoor unit 100 through the functional low pressure connection unit 220 and the outdoor low pressure connection unit 160. The refrigerant introduced into the outdoor unit 100 is guided to the accumulator 130 via the four-way valve 140.

In the accumulator 130, the liquid refrigerant is filtered. Therefore, only the gaseous refrigerant flows into the compressor 110.

The cycle of the 'heat storage mode' is completed by this process, and the phase change proceeds to the heat storage tank 310 inside the heat storage unit 300 by the 'heat storage mode' (if the heat storage material is water, ice is frozen. do).

On the other hand, during the cycle as described above, the respective measuring means (334, 334 ') measures the amount of heat storage (deicing) in the respective heat storage exchanger (320). In addition, the measured values of the measuring means 334 and 334 'are transmitted to the heat storage control unit 340. In this case, the heat storage control unit 340 controls the opening and closing of the plurality of heat storage expansion devices (330,332) according to the information measured by the plurality of measuring means (334,334 '). That is, the heat storage controller 340 controls the heat storage (de-icing) degree performed by the plurality of heat storage exchangers 320 to be the same.

Therefore, when the amount of ice making (de-icing degree) in the second heat storage exchanger 324 is smaller than the amount of ice making (de-icing degree) in the first heat storage exchanger 322, the second heat storage expansion device 332 is further added. On the contrary, when the amount of ice making (de-icing degree) in the first heat storage exchanger 322 is smaller than the amount of ice making (de-icing degree) in the second heat storage exchanger 324, the first heat storage expansion device 330 To further open to increase refrigerant expansion. By the above process, the heat storage material (water) inside the heat storage tank 310 has a uniform phase change (ice making) as a whole.

5B shows a refrigerant flow state in the 'heat storage cooling mode'. That is, the process of cooling the room using the energy stored by the 'heat storage mode' as shown above is shown.

The 'regenerative cooling mode' is mainly used during the daytime, that is, during the daytime when the power usage is high, and the cooling is performed by using the stored energy at night.

At this time, the refrigerant flows through the functional unit 200, the heat storage unit 300, and the indoor unit 400, and the refrigerant flow in the outdoor unit 100 is stopped. That is, the refrigerant flow to the outdoor unit 100 is blocked by the first valve 216 and the third valve 224.

First, the refrigerant flowing into the functional unit 200 through the high pressure heat storage connection unit 250 will be described.

At this time, the liquid flow path 240 is opened by the third valve 224 and the fourth valve 226. Therefore, the refrigerant flowing into the functional unit 200 from the heat storage unit 300 flows through the liquid flow path 240.

The refrigerant flowing in the liquid passage 240 is forced by the liquid pump 246. Therefore, the refrigerant flowing through the liquid passage 240 passes through the receiver 248 and the liquid pump 246 to remove moisture and gas refrigerant.

In more detail, the gas coolant is filtered in the receiver 248, and the moisture in the coolant is removed from the dryer 244.

Therefore, the liquid refrigerant passing through the liquid passage 240 passes through the second four-way valve 242, the third valve 224, and the fifth valve 252, and then through the indoor high pressure connection part 262. It is introduced into the indoor unit 400.

Since the indoor unit 400 is provided in plural numbers, the refrigerant supplied from the functional unit 200 is distributed to each indoor unit 400. The refrigerant introduced into the indoor unit 400 passes through the plurality of indoor expansion devices 430.

The refrigerant passing through the indoor expansion device 430 becomes low pressure and flows into the indoor heat exchanger 420, and heat exchange occurs in the indoor heat exchanger 420. That is, heat exchange occurs between the refrigerant flowing in the indoor heat exchanger 420 and the air in the indoor space. At this time, the indoor heat exchanger 420 serves as an evaporator, so that the refrigerant deprives heat of the indoor air. It becomes.

As such, while passing through the indoor heat exchanger 420, the refrigerant evaporates to a gaseous state, and the indoor space is deprived of heat and cooled.

The refrigerant discharged from the indoor heat exchanger 420 is guided by the indoor low pressure passage 412 and flows into the functional unit 200 through the indoor low pressure connection unit 260. At this time, the shielding valve 270 is open, and the first valve 216 blocks the refrigerant from entering the outdoor unit 100.

Therefore, the refrigerant introduced into the functional unit 200 flows through the auxiliary passage 210. The refrigerant flowing into the auxiliary flow path 210 is forced by the auxiliary pump 214 and flows into the auxiliary heat exchanger 212.

The auxiliary heat exchanger 212 consists of a small heat exchanger, and serves as a condenser. Therefore, the refrigerant passing through the auxiliary heat exchanger 212 is lowered in temperature by the auxiliary heat exchanger 212.

The refrigerant passing through the subsidiary heat exchanger 212 is introduced into the heat storage unit 300 through the low compression storage connection 272. The refrigerant introduced into the heat storage unit 300 passes through the heat storage exchanger 320.

Heat exchange occurs in the heat storage exchanger (320). That is, heat exchange occurs between the refrigerant in the heat storage exchanger 320 and the heat storage material (ice) in the heat storage tank 310. Therefore, the heat storage material (ice) inside the heat storage tank 310 takes heat away from the refrigerant inside the heat storage exchanger 320 and melts, and by this process, the refrigerant passing through the heat storage exchanger 320 becomes low temperature.

The refrigerant discharged from the heat storage exchanger 320 is introduced into the functional unit 200 through the high pressure heat storage connection unit 250.

By the above process, the cycle of the 'heat storage cooling mode' is completed, and the room is cooled.

5c shows a general cooling mode. That is, the 'direct cooling mode' is shown in which the cooling of the room is performed by a general air conditioner in which the heat storage unit 300 is not used.

The high pressure refrigerant is introduced into the outdoor heat exchanger 120 through the four-way valve 140 by the operation of the compressor 110. Since the outdoor heat exchanger 120 acts as a condenser, the heat is taken away by the outdoor air so that the refrigerant becomes a low temperature liquid refrigerant.

The refrigerant passing through the outdoor heat exchanger 120 is introduced into the functional unit 200 via the outdoor expansion device 150.

The refrigerant introduced into the functional unit 200 flows directly to the indoor unit 400. That is, the inflow of the refrigerant into the heat storage unit 300 is blocked by the third valve 224 and the fifth valve 252. Therefore, the refrigerant introduced into the functional unit 200 flows into the indoor unit 400 through the indoor high pressure connection part 262 via the fifth valve 252.

Since the indoor unit 400 is provided in plural numbers, the refrigerant supplied from the functional unit 200 is distributed to each indoor unit 400. The refrigerant introduced into the indoor unit 400 passes through the plurality of indoor expansion devices 430.

The refrigerant passing through the indoor expansion device 430 becomes low pressure and flows into the indoor heat exchanger 420, and heat exchange occurs in the indoor heat exchanger 420. That is, heat exchange occurs between the refrigerant flowing in the indoor heat exchanger 420 and the air in the indoor space. At this time, the indoor heat exchanger 420 serves as an evaporator, so that the refrigerant deprives heat of the indoor air. It becomes.

As such, while passing through the indoor heat exchanger 420, the refrigerant evaporates to a gaseous state, and the indoor space is deprived of heat and cooled. This is the same as the operation in the indoor unit 400 in the 'heat storage cooling mode' described above.

The refrigerant discharged from the indoor heat exchanger 420 is guided by the indoor low pressure passage 412 and flows into the functional unit 200 through the indoor low pressure connection unit 260.

In this case, the shielding valve 270 is open, and the first valve 216 blocks the refrigerant from flowing into the auxiliary flow path 210. Therefore, the refrigerant introduced into the functional unit 200 is introduced into the outdoor unit 100 through the functional low pressure connection unit 220 and the outdoor low pressure connection unit 160.

The refrigerant introduced into the outdoor unit 100 is guided to the accumulator 130 via the four-way valve 140. In the accumulator 130, the liquid refrigerant is filtered. Therefore, only the gaseous refrigerant flows into the compressor 110.

By this process, the cycle of 'direct cooling mode' is completed.

On the other hand, in the above description has been described a case where the heat storage air-conditioning system according to the present invention is used for cooling, it can be used for heating in addition to the case for such cooling.

That is, the above example illustrates the case where the phase change (de-icing) of the heat storage material is performed by using the heat storage tank 310 of the heat storage unit 300 as a cooling heat storage tank at night for cooling, but the flow of the refrigerant is reversed. 310 may be used as a heating heat storage tank.

In this case, the heat storage material inside the heat storage tank 310 is heated to a high temperature at night to accumulate thermal energy, and during the day it is used to heat the indoor space using this heat energy.

In addition, the heat storage tank 310 may be installed separately for cooling and heating, and then may be configured to use a cooling heat storage tank for cooling and use a heating output heat tank for heating.

As such, the operating principle of the cooling and heating system is the same as the principle of use of a general air-conditioning air conditioner, and thus detailed description thereof will be omitted.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

For example, in the above embodiment, but the case that the heat storage exchanger 320 is provided with two, it is apparent that three or more may be provided in addition to the configuration. In addition, when three or more heat storage exchangers 320 are provided, three or more heat storage expansion devices and measuring means are also provided in each heat storage exchanger 320.

As described above, in the heat storage air conditioning system according to the present invention, the heat storage unit includes a plurality of heat storage exchangers. In addition, at the inlet side of the plurality of heat storage exchangers, a heat storage expansion device for expanding the refrigerant flowing into each heat storage exchanger and a measuring means for measuring the degree of heat storage (ice making) in each heat storage exchanger are respectively provided, and the heat storage expansion device has a heat storage expansion device. It is automatically adjusted by the control unit.

Therefore, according to the present invention, an even amount of ice making is formed in a plurality of heat storage exchangers. That is, since the heat storage control unit controls the heat storage (even ice) in the heat storage tank as a whole, it is possible to improve the performance of the heat storage air-conditioning system.

Claims (6)

An outdoor unit having an outdoor heat exchanger through which heat exchange occurs, and a compressor for compressing a refrigerant; An indoor unit having an indoor heat exchanger in which heat exchange occurs; A heat storage unit having a plurality of heat storage exchangers in which heat exchange takes place, and a plurality of heat storage expansion devices respectively expanding the refrigerant flowing into the plurality of heat storage exchangers; And at least one functional unit for controlling the flow of the refrigerant in accordance with the operating conditions. The heat storage air conditioning system according to claim 1, wherein the heat storage unit is provided with a plurality of measuring means for measuring a degree of heat storage (ice making) performed by the plurality of heat storage exchangers. The heat storage air conditioning system according to claim 2, wherein the plurality of heat storage expansion devices are controlled by a heat storage control unit to adjust the degree of expansion of the refrigerant. According to claim 3, wherein the heat storage control unit, Regenerative air conditioning system, characterized in that for controlling the opening and closing of the plurality of heat storage expansion device according to the information measured by the plurality of measuring means. The method of claim 4, wherein the heat storage control unit, Regenerative air conditioning system characterized in that the control is performed so that the degree of heat storage (deicing) performed by the plurality of heat storage exchangers are equal to each other. The regenerative air conditioning system according to any one of claims 2 to 5, wherein the measuring means is installed in the regenerative heat exchanger.

Images