JP3972139B2 - Refrigeration equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a refrigeration apparatus, and particularly relates to a refrigeration apparatus that circulates a refrigerant and conveys and uses cold heat on the heat source side to the utilization side.
[0002]
[Prior art]
  Conventionally, as a refrigeration apparatus, a refrigeration apparatus that includes a closed circuit in which a refrigerant circulates, imparts cold heat from a cold heat source to the circulating refrigerant, and conveys the refrigerant to a user side is known. For example, Japanese Patent Laid-Open No. 11-281174 discloses a refrigeration apparatus of this type applied to an air conditioner.
[0003]
  The refrigeration apparatus disclosed in the above publication includes a primary side circuit and a secondary side circuit through which refrigerant circulates. In the primary circuit, the refrigerant circulates to perform a vapor compression refrigeration cycle. The primary side refrigerant in the primary side circuit evaporates by absorbing heat from the secondary side refrigerant in the secondary side circuit in the main heat exchanger, while the secondary side refrigerant in the secondary side circuit is 1 in the main heat exchanger. It dissipates heat and condenses to the primary refrigerant of the secondary circuit. That is, in the main heat exchanger, the cold of the primary circuit is imparted to the secondary refrigerant.
[0004]
  A secondary side circuit conveys the cold provided by the main heat exchanger to the indoor heat exchanger on the use side by circulation of the secondary side refrigerant. Specifically, the secondary side refrigerant condensed in the main heat exchanger is sent to the indoor heat exchanger. In the indoor heat exchanger, the secondary-side refrigerant absorbs heat from the object and evaporates, thereby cooling the object. The evaporated secondary side refrigerant is sent to the main heat exchanger and condensed again, and this circulation is repeated.
[0005]
  At that time, in the secondary side circuit of the refrigeration apparatus, the refrigerant is circulated by a so-called heat-driven pump. That is, a pair of tanks for storing liquid refrigerant are provided, and liquid refrigerant is recovered from one tank at the same time as liquid refrigerant is pushed out from the one tank, and this operation gives a circulation driving force to the secondary refrigerant. ing.
[0006]
[Problems to be solved by the invention]
  However, in the refrigeration apparatus, when the liquid refrigerant is sent from the main heat exchanger on the heat source side to the indoor heat exchanger on the usage side, the low-temperature liquid refrigerant is circulated in the pipe. As a result, there was a problem that condensation occurred on the surface.
[0007]
  For example, when the refrigeration apparatus is an air conditioner, the indoor heat exchanger is usually provided in the indoor unit, while the main heat exchanger and the primary circuit are usually provided in the outdoor unit. Accordingly, the outdoor main heat exchanger and the indoor indoor heat exchanger must be connected by a relatively long communication pipe. For example, when installing in a building, communication piping is often provided from an outdoor unit provided on the roof to an indoor unit on each floor. For this reason, when a low-temperature liquid refrigerant flows through the connecting pipe and condensation occurs on the pipe surface, it may cause troubles such as water leakage into the room.
[0008]
  For the above problem, it is conceivable to take measures to provide heat insulation to the connecting pipe such as wrapping a heat insulating material around the connecting pipe. However, this increases the number of man-hours for the installation work and causes a problem of increasing costs.
[0009]
  Moreover, when updating an air conditioner, the air conditioner comprised with the said freezing apparatus may be installed using the existing refrigerant | coolant piping in a building. In such a case, heat insulation may not be applied to the existing piping. If heat insulation is applied again, the installation work becomes complicated and the cost required for this increases. In addition, it is often difficult to heat-protect pipes that have already been laid. Therefore, in this case, there is a problem that it is impossible to take a measure of heat insulation to the connecting pipe, and the above-mentioned problem of condensation cannot be avoided.
[0010]
  The present invention has been made in view of such points, and an object of the present invention is to provide a refrigeration apparatus that avoids the problem of dew condensation without performing heat insulation on the piping, and that can also meet the demand for renewal. There is to do.
[0011]
[Means for Solving the Problems]
  The first solution provided by the present invention is that the main heat exchanger (HEX2), the refrigerant conveying means (30), the expansion mechanism (EV), and the use side heat exchanger (HEX1) are connected by piping to convey refrigerant. A refrigeration system comprising a heat transfer circuit (20) that circulates the heat and a heat source (10) that is connected to the main heat exchanger (HEX2) and applies cold heat to the transfer refrigerant of the heat transfer circuit (20) It is said. The heat transfer circuit (20) is a reheat unit for heating the liquid-phase transfer refrigerant supplied to the expansion mechanism (EV) to the predetermined temperature by being supplied with a circulation driving force by the transfer unit (30). (HEX7), and the supply refrigerant heated by the reheating means (HEX7) is depressurized by the expansion mechanism (EV) and then supplied to the use-side heat exchanger (HEX1).
[0012]
  In the first solution, the heat source ( Ten ) Is a heat source circuit that performs a vapor compression refrigeration cycle by circulating the heat source side refrigerant ( Ten ) And the reheating means ( HEX7 ) Heat transfer circuit ( 20 ) Transfer refrigerant to the heat source circuit ( Ten ) Reheat heat exchanger that exchanges heat with the high pressure heat source side refrigerant ( HEX7 ) And the above heat source circuit ( Ten ) Is a heat transfer circuit ( 20 ) Is also configured to serve as a heat source for imparting heat to the transport refrigerant, and the heat transport circuit ( 20 ) Transport means ( 30 ) From the expansion mechanism ( EV ) After passing the use side heat exchanger ( HEX1 ) And main heat exchanger ( HEX2 ) Passes through the conveying means ( 30 ) And the conveying means ( 30 ) From the main heat exchanger ( HEX2 ) And use side heat exchanger ( HEX1 ) And expansion mechanism ( EV ) Pass through the transport means ( 30 ) Four-way selector valve for switching the state of flowing into twenty three ) And the heat transfer circuit ( 20 ) The main heat exchanger ( HEX2 ) To user side heat exchanger ( HEX1 The cooling heat transfer operation for transferring the cold heat to the main heat exchanger (reversing the circulation direction of the refrigerant for transfer) HEX2 ) To user side heat exchanger ( HEX1 Heat transfer operation to transfer the heat to the four-way selector valve ( twenty three ), While the reheat heat exchanger ( HEX7 ) Heat transfer circuit ( 20 ) Four-way selector valve ( twenty three ) And expansion mechanism ( EV ) And the above reheat heat exchanger ( HEX7 ) Heat transfer circuit ( 20 ) During heat transfer operation, use side heat exchanger ( HEX1 ) Transport refrigerant from the heat source circuit ( Ten ) To exchange heat with the low-pressure heat source side refrigerant, 30 ) Also serves as a liquid phase maintaining means for maintaining the transporting refrigerant sent to the liquid phase.
[0013]
  The second solving means taken by the present invention is the same as the first solving means described above, the outdoor unit (29) provided with the main heat exchanger (HEX2), the conveying means (30) and the reheating means (HEX7). And an indoor unit (22) provided with an expansion mechanism (EV) and a use side heat exchanger (HEX1), and between the reheating means (HEX7) and the expansion mechanism (EV), and a use side heat exchanger (HEX1) and the main heat exchanger (HEX2) are each provided with connecting pipes (27, 28) to constitute a heat transfer circuit (20).
[0014]
  The third solution provided by the present invention is that the existing liquid side communication pipe (27) and gas side communication pipe for the indoor unit (22) having the use side heat exchanger (HEX1) and the expansion mechanism (EV). The refrigeration equipment connected by (28) is targeted. And it has a main heat exchanger (HEX2) and a refrigerant conveying means (30), the conveying means (30) side is via a liquid side communication pipe (27) and the main heat exchanger (HEX2) side is a gas side communication pipe ( 28) a heat transfer circuit (20) connected to the indoor unit (22) via the main heat exchanger (HEX2) and the indoor unit (22) via the heat transfer circuit (20), and the main heat exchange A heat source (10) that is connected to the heat exchanger (HEX2) and applies cold heat to the refrigerant for conveyance of the heat conveyance circuit (20), and a circulation driving force is imparted by the conveying means (30) to the liquid side communication pipe (27) And a reheating means (HEX7) for heating the refrigerant for transportation to a predetermined temperature.
[0015]
  In the third solution, the heat source ( Ten ) Is a heat source circuit that performs a vapor compression refrigeration cycle by circulating the heat source side refrigerant ( Ten ) And the reheating means ( HEX7 ) Heat transfer circuit ( 20 ) Transfer refrigerant to the heat source circuit ( Ten ) Reheat heat exchanger that exchanges heat with the high pressure heat source side refrigerant ( HEX7 ) And the above heat source circuit ( Ten ) Is a heat transfer circuit ( 20 ) Is also configured to serve as a heat source for imparting heat to the transport refrigerant, and the heat transport circuit ( 20 ) Transport means ( 30 ) To liquid side communication tube ( 27 ) And the main heat exchanger ( HEX2 ) To transport means ( 30 ) And the conveying means ( 30 ) To main heat exchanger ( HEX2 ) And the liquid side communication pipe ( 27 ) To transport means ( 30 ) Four-way selector valve for switching the state of flowing into twenty three ) And the heat transfer circuit ( 20 ) The main heat exchanger ( HEX2 ) To user side heat exchanger ( HEX1 The cooling heat transfer operation for transferring the cold heat to the main heat exchanger (reversing the circulation direction of the refrigerant for transfer) HEX2 ) To user side heat exchanger ( HEX1 Heat transfer operation to transfer the heat to the four-way selector valve ( twenty three ), While the reheat heat exchanger ( HEX7 ) Heat transfer circuit ( 20 ) Four-way selector valve ( twenty three ) And liquid side communication tube ( 27 )the aboveReheat heat exchanger ( HEX7 ) Heat transfer circuit ( 20 ) During heat transfer operation, use side heat exchanger ( HEX1 ) Transport refrigerant from the heat source circuit ( Ten ) Low pressure heat source Heat exchange with the side refrigerant, 30 ) Also serves as a liquid phase maintaining means for maintaining the transporting refrigerant sent to the liquid phase.
[0016]
  According to a fourth solving means of the present invention, in the first, second or third solving means, the conveying means (30) is connected to the heat conveying circuit (20) to store the refrigerant for conveyance. A pair of tanks (T1, T2), a high-pressure part (HEX3) for supplying the evaporated gas refrigerant to the tank (T1) and pressurizing the tank (T1), and suction from the tank (T2) And a low pressure part (HEX4) for depressurizing the tank (T2) by condensing the gas refrigerant, and pressurizing one of the tanks (T1) to push out the transport refrigerant from the tank (T1), The other tank (T2) is depressurized and an operation of collecting the transporting refrigerant in the tank (T2) is performed to apply a circulation driving force to the transporting refrigerant.
[0017]
  The fifth solution taken by the present invention is as described above.Any one of the first to fourthIn this solution, the heat source side refrigerant of the heat source circuit (10) is a non-azeotropic refrigerant mixture.
[0018]
      -Action-
  In the first solution means, the heat transfer circuit (20) pipe-connects the main heat exchanger (HEX2), the refrigerant transfer means (30), the expansion mechanism (EV), and the use side heat exchanger (HEX1). Configured. The heat transfer circuit (20) is filled with a transfer refrigerant, and the transfer refrigerant circulates in the heat transfer circuit (20). The heat source (10) imparts cold heat to the transfer refrigerant in the main heat exchanger (HEX2). That is, in the main heat exchanger (HEX2), the heat source (10) absorbs heat from the transfer refrigerant, and the transfer refrigerant dissipates heat and condenses. The refrigerant for transportation, which has been condensed into a liquid phase, is given a circulation driving force by the transportation means (30), and after being decompressed by the expansion mechanism (EV), is introduced into the use side heat exchanger (HEX1).
[0019]
  At that time, the transfer refrigerant from the transfer means (30) is heated to a predetermined temperature by the reheating means (HEX7) and then sent to the expansion mechanism (EV). For example, in the reheating means (HEX7), the transporting refrigerant is heated to a temperature substantially equal to or slightly higher than the dew point temperature of the outside air. Then, in the piping from the reheating means (HEX7) to the expansion mechanism (EV), the heated transfer refrigerant at a predetermined temperature flows.
[0020]
  In the use side heat exchanger (HEX1), the transporting refrigerant after decompression absorbs heat from the object and evaporates. Thereby, the object is cooled. The transporting refrigerant evaporated is sent to the main heat exchanger (HEX2) and condensed again. In the heat transfer circuit (20), the transfer refrigerant repeats this circulation and transfers the cold heat of the heat source (10) to the use side heat exchanger (HEX1) to cool the object.
[0021]
  In the second solving means, an outdoor unit (29) and an indoor unit (22) are provided. In the outdoor unit (29), a main heat exchanger (HEX2) of the heat transfer circuit (20), a transfer means (30), and a reheat means (HEX7) are installed. In the indoor unit (22), an expansion mechanism (EV) of the heat transfer circuit (20) and a use side heat exchanger (HEX1) are installed. The outdoor unit (29) and the indoor unit (22) are connected by a pair of connecting pipes (27, 28). Specifically, the reheating means (HEX7) of the outdoor unit (29) and the expansion mechanism (EV) of the indoor unit (22) are connected via one communication pipe (27). Further, the use side heat exchanger (HEX1) of the indoor unit (22) and the main heat exchanger (HEX2) of the outdoor unit (29) are connected via the other connecting pipe (28).
[0022]
  In the third solution means, the heat transfer circuit (20), the heat source (10), and the reheat means (HEX7) are provided in the refrigeration apparatus. This refrigeration apparatus is connected to the indoor unit (22) via a liquid side communication pipe (27) and a gas side communication pipe (28) that are already installed in a building or the like. The indoor unit (22) may be an existing one or a new one.
[0023]
  The heat transfer circuit (20) is provided with a main heat exchanger (HEX2) and a refrigerant transfer means (30). The heat transfer circuit (20) is connected to the indoor unit (22) via the liquid side communication pipe (27) on the transfer means (30) side, and the gas side communication pipe (28) on the main heat exchanger (HEX2) side. To the indoor unit (22). And a closed circuit is comprised by the heat transfer circuit (20), the liquid side connecting pipe (27), the indoor unit (22), and the gas side connecting pipe (28), and the refrigerant | coolant for conveyance circulates in this closed circuit.
[0024]
  The heat source (10) imparts cold heat to the transfer refrigerant in the main heat exchanger (HEX2). That is, in the main heat exchanger (HEX2), the heat source (10) absorbs heat from the transfer refrigerant, and the transfer refrigerant dissipates heat and condenses. The transport refrigerant that has condensed into a liquid phase is supplied with a circulation driving force by the transport means (30) and is sent to the liquid side communication pipe (27).
[0025]
  At that time, the transfer refrigerant from the transfer means (30) is heated to a predetermined temperature by the reheating means (HEX7) and then introduced into the liquid side communication pipe (27). For example, in the reheating means (HEX7), the transporting refrigerant is heated to a temperature substantially equal to or slightly higher than the dew point temperature of the outside air. Then, in the liquid side communication pipe (27) extending from the reheating means (HEX7) to the indoor unit (22), the transporting refrigerant having a predetermined temperature due to heating flows.
[0026]
  In the indoor unit (22), the transporting refrigerant supplied through the liquid side communication pipe (27) is decompressed by the expansion mechanism (EV), and then introduced into the use side heat exchanger (HEX1). In the use side heat exchanger (HEX1), the transporting refrigerant after decompression absorbs heat from the object and evaporates. Thereby, the object is cooled. The transporting refrigerant evaporated is sent to the main heat exchanger (HEX2) through the gas side communication pipe (28) and condensed again.
[0027]
  In the fourth solution means, the conveying means (30) is constituted by a so-called heat-driven pump instead of a general mechanical pump. Specifically, a pair of tanks (T1, T2) are provided, and each tank (T1, T2) is connected to the heat transfer circuit (20). First, one tank (T1) is communicated with the high pressure section (HEX3), and the high pressure gas refrigerant in the high pressure section (HEX3) is introduced to pressurize the tank (T1). At the same time, the other tank (T2) is communicated with the low pressure part (HEX4), and the gas refrigerant is sucked into the low pressure part (HEX4) to decompress the tank (T2). Then, the transfer refrigerant stored in one tank (T1) is pushed out to the heat transfer circuit (20), and the transfer refrigerant from the heat transfer circuit (20) is collected in the other tank (T2).
[0028]
  Subsequently, on the contrary, one tank (T1) is communicated with the low pressure part (HEX4) to depressurize, and at the same time, the other tank (T2) is communicated with the high pressure part (HEX3) and pressurized. As a result, the transfer refrigerant collected in the other tank (T2) is pushed out again to the heat transfer circuit (20), and the transfer refrigerant is recovered from the heat transfer circuit (20) in one tank (T1). . The conveying means (30) of the present solving means imparts a circulation driving force to the refrigerant for conveyance of the heat conveying circuit (20) by alternately performing the above operations.
[0029]
  the aboveFirst and third solving meansThen, the heat source (10) is constituted by a heat source circuit (10). In the heat source circuit (10), the heat source side refrigerant circulates to perform a vapor compression refrigeration cycle. Specifically, in the heat source circuit (10), the heat source side refrigerant repeats a cycle of compression, condensation, expansion, and evaporation to generate cold. At that time, the heat source side refrigerant absorbs heat from the transfer refrigerant in the heat transfer circuit (20) and evaporates in the main heat exchanger (HEX2).
[0030]
  Further, the reheating means (HEX7) is constituted by a reheat heat exchanger (HEX7). The reheat heat exchanger (HEX7) is connected to both the heat transfer circuit (20) and the heat source circuit (10). In the reheat heat exchanger (HEX7), the transfer refrigerant radiated by the main heat exchanger (HEX2) and the high-pressure heat source side refrigerant in the heat source circuit (10) exchange heat. By the heat exchange in the reheat heat exchanger (HEX7), the transfer refrigerant is heated to a predetermined temperature.
[0031]
  the above5thIn this solution, a non-azeotropic refrigerant mixture is used as the heat source side refrigerant of the heat source circuit (10). This non-azeotropic refrigerant mixture is a mixture of a plurality of refrigerants having different boiling points. For example, R407C corresponds to this non-azeotropic refrigerant mixture.
[0032]
  the aboveFirst and third solving meansThen, the heat source circuit (10) switches between the refrigeration cycle and the heat pump cycle, and the heat transfer circuit (20) switches between the cold transfer operation and the heat transfer operation. The heat transfer circuit (20) switches the refrigerant circulation direction between the cold transfer operation and the hot transfer operation. That is, the transfer refrigerant is given warm temperature by the main heat exchanger (HEX2) and evaporates, and is then sent to the use side heat exchanger (HEX1). In the usage-side heat exchanger (HEX1), the carrier refrigerant dissipates heat and condenses, thereby heating the object. The condensed conveying refrigerant flows to the conveying means (30), is given a circulation driving force, and is sent again to the main heat exchanger (HEX2).
[0033]
  When flowing from the usage-side heat exchanger (HEX1) to the transport means (30), the transport refrigerant passes through the reheat heat exchanger (HEX7). During the heat transfer operation of the heat transfer circuit (20), the reheat heat exchanger (HEX7) is supplied with the low-pressure heat source side refrigerant of the heat source circuit (10) and functions as a liquid phase maintaining means. That is, in the reheat heat exchanger (HEX7), the transfer refrigerant from the use side heat exchanger (HEX1) exchanges heat with the heat source side refrigerant in the heat source circuit (10), and the transfer refrigerant is cooled and is supercooled. It becomes. For this reason, the transport refrigerant flowing to the transport means (30) is always maintained in the liquid phase and does not flash.
[0034]
【The invention's effect】
  In the present invention, the reheating means (HEX7) is provided, and the transfer refrigerant to which the cold heat is applied in the main heat exchanger (HEX2) is heated to a predetermined temperature, and the transfer refrigerant having reached the predetermined temperature is reheated. It is made to circulate through the piping from (HEX7) to the expansion mechanism (EV). Specifically, in the second solving means, the refrigerant for conveyance after heating in the connecting pipe (27) from the reheating means (HEX7) of the outdoor unit (29) to the expansion mechanism (EV) of the indoor unit (22). Flows. In the third solution, the heated transport refrigerant flows in the liquid side communication pipe (27) from the reheating means (HEX7) of the outdoor unit (29) to the indoor unit (22).
[0035]
  Therefore, the temperature of the transfer refrigerant flowing through the communication pipe (27) and the liquid side communication pipe (27) can be increased as compared with the conventional one having no reheating means (HEX7). For this reason, it is possible to make the temperature of the piping of the communication piping (27) and the liquid side communication piping (27) higher than the dew point temperature of the air around the piping, and reliably prevent condensation on the surface of the piping. Can do. As a result, the problem of dew condensation can be avoided without heat-insulating the pipe. Furthermore, even when installing a refrigeration system using existing piping that is not heat-insulated, it is possible to avoid problems such as condensation and prevent problems such as water leakage. It is possible to sufficiently cope with this.
[0036]
  Further, according to the fourth solution means, the conveying means (30) can be configured without using a general mechanical pump. For this reason, it is possible to reliably circulate the transport refrigerant in the heat transfer circuit (20) while avoiding troubles such as seizure due to poor lubrication of the bearing, which is a problem with mechanical pumps, and refrigerant leakage due to defective refrigerant seals. It becomes.
[0037]
  Also,The present inventionThen, the reheating means (HEX7) is constituted by a reheat heat exchanger (HEX7), and the transport refrigerant is heated by heat exchange with the heat source side refrigerant of the heat source circuit (10). For this reason, heating of the refrigerant for conveyance in the reheating means (HEX7) can be performed without newly inputting energy. Hereinafter, this point will be described with reference to FIG. FIG. 8 shows cycles in the heat source circuit (10) and the heat transfer circuit (20) on the Mollier diagram (pressure-enthalpy diagram) of the refrigerant.
[0038]
  A cycle in the heat source circuit (10) is indicated by a line connecting points A, B, C, and D in order. Specifically, the refrigerant at point A is compressed into a state at point B. The refrigerant at point B is condensed and further subcooled to be in the state of point C. The refrigerant at point C is depressurized to a point D state. The refrigerant at point D evaporates and is further heated to return to the state at point A.
[0039]
  On the other hand, the cycle in the heat transfer circuit (20) is indicated by a line connecting points a, b, c, d, e, and f in order. Specifically, the refrigerant at point a is condensed in the main heat exchanger (HEX2) and further subcooled to be in the state at point b. The refrigerant at the point b is given a circulation driving force by the conveying means (30), and the pressure rises to a state at the point c. The refrigerant at the point c is overheated by the reheating means (HEX7) to be in the state at the point d. The refrigerant at the point d is depressurized by the expansion mechanism (EV) and becomes the state at the point e. The refrigerant at the point e evaporates in the use side heat exchanger (HEX1) and is further heated to a state at the point f. The refrigerant at point f returns to the state at point a with a slight decrease in pressure before reaching the main heat exchanger (HEX2).
[0040]
  In the reheat heat exchanger (HEX7), a predetermined amount of heat is given to the conveying refrigerant. This amount of heat is a value obtained by multiplying the enthalpy difference Δh2 between the points d and c by the circulation amount Gr2 of the transporting refrigerant, that is, (Δh2 × Gr2). In addition, in order to maintain the heat absorption amount (the value obtained by multiplying the enthalpy difference between the points f and e by the circulation amount Gr2 of the conveying refrigerant) in the use side heat exchanger (HEX1), in the main heat exchanger (HEX2) It is necessary to dissipate heat from the transport refrigerant. The amount of heat to be radiated excessively is a value obtained by multiplying the enthalpy difference Δh2 between the points b ′ and b by the circulation amount Gr2 of the conveying refrigerant, that is, (Δh2 × Gr2).
[0041]
  However, in the reheat heat exchanger (HEX7), the transfer refrigerant exchanges heat with the heat source side refrigerant. For this reason, the amount of heat released from the heat-source-side refrigerant increases by the heat absorption amount (Δh2 × Gr2) of the carrier-use refrigerant, and the enthalpy of the heat-source-side refrigerant decreases from point C ′ to point C. The increase in the heat radiation amount is a value obtained by multiplying the enthalpy difference Δh1 between the points C ′ and C by the circulation amount Gr1 of the heat source side refrigerant, that is, (Δh1 × Gr1). The relationship (Δh1 × Gr1) = (Δh2 × Gr2) is established.
[0042]
  For this reason, in the main heat exchanger (HEX2), the amount of heat absorbed by the heat source side refrigerant from the transfer refrigerant is a value obtained by multiplying Δh1 which is the enthalpy difference between the points D and D ′ by the circulation amount Gr1 of the heat source side refrigerant. It increases by Δh1 × Gr1). Accordingly, the reheat heat exchanger (10) is increased without increasing the energy required for the compression of the heat source side refrigerant in the heat source circuit (10), that is, the value obtained by multiplying the enthalpy difference between points B and A by the circulation amount Gr1 of the heat source side refrigerant. Heating of the refrigerant for transportation in HEX7) becomes possible.
[0043]
  As mentioned above,The present inventionThen, in order to heat the refrigerant for conveyance in the reheat heat exchanger (HEX7), new energy is unnecessary. Accordingly, it is possible to reduce the temperature difference between the internal transfer refrigerant and the external air in the pipe from the reheat heat exchanger (HEX7) to the expansion mechanism (EV) without separately supplying energy. As a result, it is possible to reduce a loss due to heat intrusion while flowing in the pipe, and to improve energy efficiency.
[0044]
  the above5thIn this solution, a non-azeotropic refrigerant mixture is used as the heat source side refrigerant of the heat source circuit (10), and this heat source side refrigerant is sent to the reheat heat exchanger (HEX7) and used for heating the refrigerant for conveyance. For this reason, the temperature of the heat-source-side refrigerant when introduced into the main heat exchanger (HEX2) can be lowered, and thereby the cooling capacity can be improved.
[0045]
  Hereinafter, this point will be described with reference to FIG. FIG. 9 shows cycles in the heat source circuit (10) and the heat transfer circuit (20) on the Mollier diagram (pressure-enthalpy diagram) of the refrigerant, as in FIG. Each point corresponds to that in FIG. However, in FIG. 9, only a part of the cycle in the heat transfer circuit (20) is shown.
[0046]
  In the present solution, since the heat source side refrigerant exchanges heat with the transfer refrigerant in the reheat heat exchanger (HEX7), the heat release amount of the high pressure heat source side refrigerant increases as described above. Therefore, the high-pressure heat source side refrigerant before decompression is in the state of point C ′ when heat exchange is not performed in the reheat heat exchanger (HEX7), but in this solution, the enthalpy is further reduced. Then, the state of point C is obtained. Along with this, the heat-source-side refrigerant after decompression is in the state of point D having a lower enthalpy than the state of point D ′.
[0047]
  Here, the non-azeotropic refrigerant mixture has a characteristic of causing a temperature change even when the phase changes under the same pressure. For example, when evaporating, since the low boiling point component evaporates first, the evaporation temperature gradually increases. For this reason, the isotherm on the Mollier diagram is inclined downward to the right with respect to the isobaric line, as shown by a one-dot chain line in FIG. Therefore, when the state of the heat source refrigerant after depressurization moves from the point D ′ to the point D, the temperature decreases from t1 to t2.
[0048]
  When the temperature of the heat source side refrigerant after decompression decreases, the temperature of the heat source side refrigerant flowing into the main heat exchanger (HEX2) decreases. For this reason, the temperature difference between the heat source side refrigerant and the transfer refrigerant in the main heat exchanger (HEX2) can be expanded, and the temperature and pressure of the transfer refrigerant flowing out of the main heat exchanger (HEX2) can be reduced. It becomes possible. As a result, it is possible to lower the evaporation temperature and the evaporation pressure of the transport refrigerant in the use side heat exchanger (HEX1), thereby increasing the cooling capacity.
[0049]
  In addition, the present inventionThen, when the heat transfer circuit (20) also transfers heat, the transfer refrigerant flowing from the use side heat exchanger (HEX1) to the transfer means (30) is converted into a reheat heat exchanger ( HEX7) is used for cooling. For this reason, it is possible to prevent the transport refrigerant flowing into the transport means (30) from being flushed and reliably maintain the liquid phase, and to reliably apply the circulation driving force to the transport refrigerant in the transport means (30). It becomes possible. Further, the reheat heat exchanger (HEX7) that functions as the reheating means (HEX7) during the cold transfer operation is caused to function as the liquid phase maintaining means during the hot transfer operation. For this reason, it is not necessary to add a structure separately as a liquid phase maintenance means, and the above-described effects can be obtained without complicating the structure.
[0050]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
[0051]
    << Reference Technology 1 >>
  Reference technique 1 will be described.
[0052]
      <Overall configuration of air conditioner>
  As shown in FIG.Reference technologyOne air conditioner has a so-called multi-type configuration in which a plurality of indoor units (22) are connected to one outdoor unit (29). The outdoor unit (29) and each indoor unit (22) are connected by a pair of communication pipes including a liquid side communication pipe (27) and a gas side communication pipe (28).
[0053]
  Here, when the air conditioner is installed in a building or the like, the existing communication pipes (27, 28) may be used. In other words, an air conditioner already installed in a building etc.Reference technologyWhen upgrading to air conditioner 1, remove the existing air conditioner, leaving only the connection pipe (27, 28).Reference technologyConnect the outdoor unit (29) and indoor unit (22) according to 1 to the existing communication pipe (27, 28)Reference technologyIt is also possible to configure one air conditioner. Furthermore, it is possible to divert existing units for the indoor unit (22).
[0054]
  The air conditioner is provided with a primary side circuit (10) and a secondary side circuit (20). The secondary circuit (20) is provided with a pump circuit (30). The primary side circuit (10) and the pump circuit (30) are accommodated in the outdoor unit (29). On the other hand, the secondary side circuit (20) is provided from the outdoor unit (29) to the indoor unit (22).
[0055]
  The said primary side circuit (10) is a closed circuit provided with a primary side compressor (11) etc., Comprising: A refrigerant | coolant circulates and is comprised so that a vapor | steam compression refrigeration cycle may be performed. The primary side circuit (10) is also configured to perform an operation for driving the pump circuit (30). The primary side circuit (10) will be described later.
[0056]
      <Configuration of secondary circuit>
  The secondary side circuit (20) constitutes a heat transfer circuit. The secondary side circuit (20) includes a secondary side four-way switching valve (23), a reheat heat exchanger (HEX7) as reheating means (HEX7), and an indoor expansion valve (EV) as an expansion mechanism. The indoor heat exchanger (HEX1), which is a use side heat exchanger, and the main heat exchanger (HEX2) are connected in order by piping. Of the secondary circuit (20), the secondary four-way selector valve (23), the reheat heat exchanger (HEX7), and the main heat exchanger (HEX2) are housed in the outdoor unit (29). ing. On the other hand, the indoor expansion valve (EV) and the indoor heat exchanger (HEX1) are housed one by one in the plurality of indoor units (22).
[0057]
  A main liquid pipe (25) is provided between the secondary side four-way selector valve (23) and the indoor expansion valve (EV), and a reheat heat exchanger (HEX7) is placed in the middle of the main liquid pipe (25). Is provided. One end of the main liquid pipe (25) is connected to the first port of the secondary side four-way selector valve (23), and the other end is branched and connected to each indoor expansion valve (EV). Moreover, the part ranging from the outdoor unit (29) to each indoor unit (22) in the main liquid pipe (25) constitutes the liquid side communication pipe (27).
[0058]
  A main gas pipe (24) is provided between the indoor heat exchanger (HEX1) and the main heat exchanger (HEX2). One end of the main gas pipe (24) is branched and connected to each indoor heat exchanger (HEX1), and the other end is connected to the upper end of the main heat exchanger (HEX2). Moreover, the part ranging from each indoor unit (22) to the outdoor unit (29) in the main gas pipe (24) constitutes a gas side communication pipe (28).
[0059]
  A main liquid pipe (26) is provided between the main heat exchanger (HEX2) and the secondary side four-way selector valve (23). One end of the main liquid pipe (26) is connected to the lower end of the main heat exchanger (HEX2), and the other end is connected to the second port of the secondary side four-way selector valve (23).
[0060]
  The secondary circuit (20) is filled with R22 as a secondary refrigerant. In the secondary circuit (20), the secondary refrigerant, which is the refrigerant for conveyance, circulates and changes phase, and conveys cold heat or heat from the main heat exchanger (HEX2) to the indoor heat exchanger (HEX1).
[0061]
      <Pump circuit configuration>
  The said pump circuit (30) comprises the conveyance means which consists of what is called a heat drive pump. The pump circuit (30) includes a heating heat exchanger (HEX3) that is a high pressure part, a cooling heat exchanger (HEX4) that is a low pressure part, a first main tank (T1), and a second main tank (T2). And. This pump circuit (30) allows both main tanks (T1, T2) connected to the secondary circuit (20) to communicate alternately with the heating heat exchanger (HEX3) and the cooling heat exchanger (HEX4). Thus, the inside of the tank is pressurized and depressurized, whereby a circulation driving force is applied to the secondary side refrigerant of the secondary side circuit (20). The pump circuit (30) includes a tank pre-heat exchanger (HEX5), a sub tank (ST), and a buffer tank (BT) that are liquid phase maintaining means.
[0062]
  A recovery liquid pipe (38) and an extrusion liquid pipe (37) are connected to the first main tank (T1) and the second main tank (T2), respectively.
[0063]
  The extrusion liquid pipe (37) has one end branched into three branch pipes (37a, 37b, 37c) and the other end connected to the third port of the secondary side four-way selector valve (23). Yes. The branch pipes (37a, 37b, 37c) of the extrusion liquid pipe (37) are connected to the lower ends of the first and second main tanks (T1, T2) and the sub tank (ST). Of these branch pipes (37a-37c), the branch pipes (37a, 37b) connected to the first and second main tanks (T1, T2) receive only the refrigerant outflow from the main tanks (T1, T2). An allowable check valve (CV-3) is provided. The branch pipe (37c) connected to the sub tank (ST) is provided with a check valve (CV-4) that allows only the refrigerant to flow into the sub tank (ST).
[0064]
  The recovery liquid pipe (38) has one end connected to the fourth port of the secondary side four-way switching valve (23) and the other end branched to two branch pipes (38a, 38b). The branch pipes (38a, 38b) of the recovery liquid pipe (38) are connected to the lower ends of the first and second main tanks (T1, T2). These branch pipes (38a, 38b) are provided with check valves (CV-5) that allow only the refrigerant to flow into the main tanks (T1, T2). A tank pre-heat exchanger (HEX5) is provided in the middle of the recovery liquid pipe (38).
[0065]
  In the secondary side four-way selector valve (23), the extrusion liquid pipe (37) communicates with the main liquid pipe (25) on the indoor unit (22) side, and the recovery liquid pipe (38) and the main heat exchanger. The main liquid pipe (26) on the (HEX2) side is in communication (state shown by the solid line in Fig. 1), the liquid pipe for extrusion (37), and the main liquid pipe (26) on the main heat exchanger (HEX2) side The communication liquid pipe (38) for communication and the main liquid pipe (25) on the indoor unit (22) side communicate with each other (a state indicated by a broken line in FIG. 1). By switching the secondary side four-way selector valve (23), the circulation direction of the secondary side refrigerant in the secondary side circuit (20) is switched.
[0066]
  The heating heat exchanger (HEX3) is for pressurizing the first and second main tanks (T1, T2) and the sub tank (ST). The heating heat exchanger (HEX3) is connected to the first and second main tanks (T1, T2) and the sub tank (ST) via the gas supply pipe (31). The gas supply pipe (31) has one end connected to the upper end of the heating heat exchanger (HEX3) and the other end branched into three branch pipes (31a, 31b, 31c). The branch pipes (31a to 31c) of the gas supply pipe (31) are connected to the upper ends of the first and second main tanks (T1, T2) and the sub tank (ST). Each of the branch pipes (31a to 31c) is provided with first to third tank pressurizing solenoid valves (SV-P1, SV-P2, SV-P3).
[0067]
  The heating heat exchanger (HEX3) is connected to the sub tank (ST) through the liquid recovery pipe (34). One end of the liquid recovery pipe (34) is connected to the lower end of the sub tank (ST), and the other end is connected to the lower end of the heating heat exchanger (HEX3). The liquid recovery pipe (34) includes a check valve (CV-1) that allows only refrigerant to flow out of the sub tank (ST) and a buffer tank (BT) from the sub tank (ST) to the heating heat exchanger. It is provided in order toward (HEX3).
[0068]
  In the heating heat exchanger (HEX3), the liquid refrigerant supplied through the liquid recovery pipe (34) evaporates. The gas refrigerant of the heating heat exchanger (HEX3) is supplied to the first and second main tanks (T1, T2) and the sub tank (ST) through the gas supply pipe (31). Thereby, these tanks (T1, T2, ST) are pressurized.
[0069]
  Further, the buffer tank (BT) and the heating heat exchanger (HEX3) are communicated with each other by a pressure equalizing pipe (39). One end of the pressure equalizing pipe (39) is connected to the upper end of the buffer tank (BT) via the liquid recovery pipe (34), and the other end is connected to the heating heat exchanger (HEX3) via the gas supply pipe (31). It is connected to the upper end.
[0070]
  The cooling heat exchanger (HEX4) is for depressurizing the first and second main tanks (T1, T2) and the sub tank (ST). The cooling heat exchanger (HEX4) is connected to the first and second main tanks (T1, T2) and the sub tank (ST) via the gas recovery pipe (32). The gas recovery pipe (32) has one end branched into three branch pipes (32a, 32b, 32c) and the other end connected to the upper end of the cooling heat exchanger (HEX4). The branch pipes (32a to 32c) of the gas recovery pipe (32) are connected to the upper ends of the first and second main tanks (T1, T2) and the sub tank (ST). These branch pipes (32a to 32c) are provided with first to third tank pressure reducing solenoid valves (SV-V1, SV-V2, SV-V3).
[0071]
  The cooling heat exchanger (HEX4) is connected to the first and second main tanks (T1, T2) via the liquid supply pipe (33). One end of the liquid supply pipe (33) is connected to the lower end of the cooling heat exchanger (HEX4), and the other end is branched into two branch pipes (33a, 33b). The branch pipes (33a, 33b) of the liquid supply pipe (33) are connected to the lower ends of the first and second main tanks (T1, T2). These branch pipes (33a, 33b) are provided with check valves (CV-2) that allow only the flow of refrigerant toward the main tanks (T1, T2).
[0072]
  The cooling heat exchanger (HEX4) sucks the gas refrigerant from the first and second main tanks (T1, T2) and the sub tank (ST) through the gas recovery pipe (32) and condenses them. As a result, the tanks (T1, T2, ST) are depressurized. The condensed refrigerant is returned to the first and second main tanks (T1, T2) through the liquid supply pipe (33).
[0073]
  Each main tank (T1, T2) is installed at a position lower than the cooling heat exchanger (HEX4). The sub tank (ST) is installed at a position higher than the heating heat exchanger (HEX3). Further, the buffer tank (BT) is disposed above the heating heat exchanger (HEX3) and below the sub tank (ST). The buffer tank (BT) is provided to stably supply the liquid refrigerant to the heating heat exchanger (HEX3) during operation and startup.
[0074]
      <Primary circuit configuration>
  The primary side circuit (10) constitutes a heat source circuit. The primary circuit (10) includes a main circuit (15) and first to seventh branch pipes (51 to 57).
[0075]
  The main circuit (15) includes a primary compressor (11), a primary four-way selector valve (12), an outdoor heat exchanger (HEX6), a receiver (13), a heating heat exchanger (HEX3), A heat heat exchanger (HEX7) and a main heat exchanger (HEX2) are connected in order by piping. The main circuit (15) is filled with R22 as a primary refrigerant. In this main circuit (15), the circulation direction of the primary side refrigerant that is the heat source side refrigerant is reversed by switching the primary side four-way selector valve (12), and the refrigeration cycle operation and the heat pump cycle operation are switched. .
[0076]
  The main circuit (15) is provided with a check valve, a solenoid valve, and the like. Specifically, a check valve (CV-6) is provided between the outdoor heat exchanger (HEX6) and the receiver (13) that allows only the refrigerant to flow toward the receiver (13). Between the receiver (13) and the heating heat exchanger (HEX3), a first solenoid valve (SV-1) and a check valve (CV-7) are installed in order toward the heating heat exchanger (HEX3). It has been. This check valve (CV-7) only allows the refrigerant to flow to the heating heat exchanger (HEX3). Between the reheat heat exchanger (HEX7) and the main heat exchanger (HEX2), there is an electric valve (EV-F), first expansion valve (EV-1), and check valve (CV-8) in sequence. Is provided. This check valve (CV-8) only allows the refrigerant to flow to the main heat exchanger (HEX2).
[0077]
  The first branch pipe (51) has one end connected between the motor-operated valve (EV-F) and the first expansion valve (EV-1) in the main circuit (15), and the other end in the main circuit (15). The primary side four-way selector valve (12) is connected between the suction side of the primary side compressor (11). The first branch pipe (51) is provided with a second expansion valve (EV-2) and a cooling heat exchanger (HEX4) in order from one end to the other end.
[0078]
  One end of the second branch pipe (52) is connected between the heating heat exchanger (HEX3) and the reheat heat exchanger (HEX7) in the main circuit (15), and the other end is the first branch pipe (51). Is connected closer to one end than the second expansion valve (EV-2). The second branch pipe (52) is provided with a second solenoid valve (SV-2).
[0079]
  One end of the third branch pipe (53) is connected between the connection portion of the second branch pipe (52) in the first branch pipe (51) and the second expansion valve (EV-2), and the other end is the first branch pipe (53). The one branch pipe (51) is connected closer to the other end than the cooling heat exchanger (HEX4). The third branch pipe (53) is provided with a third expansion valve (EV-3) and a tank pre-heat exchanger (HEX5) in order from one end to the other end.
[0080]
  The fourth branch pipe (54) has one end connected between the first expansion valve (EV-1) and the check valve (CV-8) in the main circuit (15), and the other end connected to the main circuit (15). Is connected between the outdoor heat exchanger (HEX6) and the check valve (CV-6). The fourth branch pipe (54) is provided with a check valve (CV-10) that allows only the refrigerant to flow from one end to the other end.
[0081]
  The fifth branch pipe (55) has one end connected between the check valve (CV-8) and the main heat exchanger (HEX2) in the main circuit (15), and the other end connected to the reverse in the main circuit (15). It is connected between the stop valve (CV-6) and the receiver (13). The fifth branch pipe (55) is provided with a check valve (CV-9) that allows only the refrigerant to flow from one end to the other end.
[0082]
  The sixth branch pipe (56) has one end connected between the discharge side of the primary compressor (11) in the main circuit (15) and the primary side four-way selector valve (12), and the other end is main. The circuit (15) is connected between the check valve (CV-7) and the heating heat exchanger (HEX3). The sixth branch pipe (56) is provided with a fourth solenoid valve (SV-4).
[0083]
  The seventh branch pipe (57) has one end connected between the receiver (13) and the first solenoid valve (SV-1) in the main circuit (15), and the other end connected to the motor-operated valve ( EV-F) and the first expansion valve (EV-1) are connected. The seventh branch pipe (57) is provided with a third solenoid valve (SV-3).
[0084]
      -Driving action-
      <Cooling operation>
  The operation during cooling operation in which the cold generated in the primary circuit (10) is transferred to the indoor unit (22) will be described with reference to FIG.
[0085]
  In the primary side circuit (10), the primary side four-way selector valve (12) is switched as shown by a solid line in FIG. 1, and the first solenoid valve (SV-1) is opened, and the motor operated valve (EV- F) The first expansion valve (EV-1) and the second expansion valve (EV-2) are adjusted to a predetermined opening degree. In the primary circuit (10), the third expansion valve (EV-3), the second solenoid valve (SV-2), the third solenoid valve (SV-3), and the fourth solenoid valve (SV-4) Is closed. When the primary-side compressor (11) is operated in this state, the primary-side refrigerant circulates in the primary-side circuit (10) as shown by the one-dot chain line arrow in FIG. 1, and the refrigeration cycle operation is performed.
[0086]
  Specifically, the primary refrigerant discharged from the primary side compressor (11) flows to the outdoor heat exchanger (HEX6) through the primary side four-way switching valve (12). In the outdoor heat exchanger (HEX6), the primary refrigerant is condensed by exchanging heat with the outside air. The condensed primary refrigerant flows through the receiver (13) to the heating heat exchanger (HEX3).
[0087]
  In the heating heat exchanger (HEX3), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the secondary refrigerant evaporates, and the heating heat exchanger (HEX3) is maintained in a high pressure state. In addition, when the heating amount with respect to the secondary side refrigerant | coolant in a heating heat exchanger (HEX3) is insufficient, the discharge gas of a primary side compressor (11) is suitably introduce | transduced into a heating heat exchanger (HEX3). Specifically, the fourth solenoid valve (SV-4) is opened, and the discharge gas is sent through the sixth branch pipe (56).
[0088]
  The primary refrigerant from the heating heat exchanger (HEX3) flows to the reheat heat exchanger (HEX7). In the reheat heat exchanger (HEX7), the primary refrigerant exchanges heat with the secondary refrigerant flowing through the main liquid pipe (25) of the secondary circuit (20). By this heat exchange, the secondary side refrigerant sent to the liquid side communication pipe (27) is heated to a predetermined temperature.
[0089]
  The primary refrigerant from the reheat heat exchanger (HEX7) is split into two hands after passing through the electric valve (EV-F). Of the divided primary refrigerant, one flows toward the cooling heat exchanger (HEX4) and the other flows toward the main heat exchanger (HEX2).
[0090]
  The primary-side refrigerant heading for the cooling heat exchanger (HEX4) flows into the first branch pipe (51), is decompressed by the second expansion valve (EV-2), and then flows into the cooling heat exchanger (HEX4). . In the cooling heat exchanger (HEX4), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the primary side refrigerant evaporates and at the same time the secondary side refrigerant condenses, and the cooling heat exchanger (HEX4) is maintained in a low pressure state. The primary-side refrigerant evaporated in the cooling heat exchanger (HEX4) flows through the first branch pipe (51) and is sucked into the primary-side compressor (11).
[0091]
  The primary-side refrigerant directed to the main heat exchanger (HEX2) flows through the main circuit (15) as it is, is decompressed by the first expansion valve (EV-1), and then flows into the main heat exchanger (HEX2). In the main heat exchanger (HEX2), the primary refrigerant exchanges heat with the secondary refrigerant of the secondary circuit (20). By this heat exchange, the primary side refrigerant evaporates and at the same time the secondary side refrigerant condenses, and cold heat is given to the secondary side refrigerant. The primary refrigerant evaporated in the main heat exchanger (HEX2) passes through the primary four-way switching valve (12) and is sucked into the primary compressor (11).
[0092]
  In the secondary side circuit (20), the secondary side four-way switching valve (23) is switched as shown by a solid line in FIG. 1, and the indoor expansion valve (EV) is adjusted to a predetermined opening. In this state, open and close each pressurization solenoid valve (SV-P1, SV-P2, SV-P3) and each decompression solenoid valve (SV-V1, SV-V2, SV-V3) of the pump circuit (30), A circulation driving force is applied to the secondary refrigerant. In the secondary circuit (20), the secondary refrigerant circulates while changing phase between the main heat exchanger (HEX2) and the indoor heat exchanger (HEX1), and in the primary circuit (10). The generated cold energy is transferred to the indoor heat exchanger (HEX1).
[0093]
  Specifically, description will be made from the state where each solenoid valve (SV-P1, SV-V2, SV-P3) of the pump circuit (30) is in the following state. That is, the pressurization solenoid valve (SV-P1) of the first main tank (T1), the pressurization solenoid valve (SV-P3) of the sub tank (ST), the decompression solenoid valve (SV-V2) of the second main tank (T2) ) Is open. On the other hand, the pressure solenoid valve (SV-P2) of the second main tank (T2), the pressure reducing solenoid valve (SV-V1) of the first main tank (T1), the pressure reducing solenoid valve (SV-V3) of the sub tank (ST) Is closed.
[0094]
  In this state, the first main tank (T1) communicates with the heating heat exchanger (HEX3). As described above, the heating heat exchanger (HEX3) is maintained in a high pressure state by evaporation of the refrigerant. Therefore, the high pressure gas refrigerant of the heating heat exchanger (HEX3) is supplied to the first main tank (T1) through the gas supply pipe (31), thereby pressurizing the first main tank (T1). When the first main tank (T1) is pressurized, the stored liquid refrigerant is pushed out of the first main tank (T1). The liquid refrigerant pushed out from the first main tank (T1) flows from the branch pipe (37a) of the extrusion liquid pipe (37) to the extrusion liquid pipe (37) as shown by the solid line arrow in FIG. It flows through the secondary side four-way selector valve (23) to the main liquid pipe (25) of the secondary side circuit (20).
[0095]
  On the other hand, the second main tank (T2) communicates with the cooling heat exchanger (HEX4). As described above, the cooling heat exchanger (HEX4) is maintained in a low pressure state by the condensation of the refrigerant. Accordingly, the gas refrigerant in the second main tank (T2) is sucked into the cooling heat exchanger (HEX4) through the gas recovery pipe (32), whereby the second main tank (T2) is decompressed. When the second main tank (T2) is depressurized, the liquid refrigerant in the secondary circuit (20) is recovered in the second main tank (T2). That is, as indicated by the solid line arrow in FIG. 1, the liquid refrigerant in the main liquid pipe (26) is sucked and the secondary side four-way switching valve (23), the recovery liquid pipe (38), the recovery liquid pipe ( It flows through the branch pipe (38b) of 38) in order and is collected in the second main tank (T2).
[0096]
  The sub tank (ST) communicates with the heating heat exchanger (HEX3). Therefore, the gas refrigerant of the heating heat exchanger (HEX3) is also supplied to the sub tank (ST), and thereby the sub tank (ST) is pressurized. The liquid refrigerant is pushed out from the pressurized sub tank (ST). This liquid refrigerant is a liquid recovery pipe as shown by the broken arrow in FIG.( 34 )And is sent to the heating heat exchanger (HEX3) and used to maintain the heating heat exchanger (HEX3) at a high pressure.
[0097]
  Thereafter, when the sub tank (ST) is almost empty, the pressurization solenoid valve (SV-P3) of the sub tank (ST) is closed and the decompression solenoid valve (SV-V3) is opened. In this state, the sub tank (ST) communicates with the cooling heat exchanger (HEX4), and the sub tank (ST) is depressurized. In the decompressed sub tank (ST), a part of the refrigerant flowing through the extrusion liquid pipe (37) is collected through the branch pipe (37c).
[0098]
  When the sub-tank (ST) is filled with liquid refrigerant, the pressurization solenoid valve (SV-P3) of the sub-tank (ST) is opened again and the pressure-reduction solenoid valve (SV-V3) is closed to heat the sub-tank (ST). Liquid refrigerant is sent to the exchanger (HEX3). Repeatedly pressurizing and depressurizing the sub-tank (ST) as described above to continuously supply liquid refrigerant to the heating heat exchanger (HEX3).
[0099]
  In the secondary side circuit (20), the secondary side refrigerant circulates by pushing out the liquid refrigerant from the first main tank (T1) and collecting the liquid refrigerant to the second main tank (T2) as described above. To do.
[0100]
  Specifically, the liquid refrigerant (secondary refrigerant) pushed out from the first main tank (T1) is sent to the indoor heat exchanger (HEX1) of each indoor unit (22) through the main liquid pipe (25). . At that time, the liquid refrigerant flowing through the main liquid pipe (25) is heated by exchanging heat with the primary refrigerant in the reheat heat exchanger (HEX7). In the reheat heat exchanger (HEX7), the secondary side refrigerant is heated to a temperature slightly higher than the dew point temperature of air around the liquid side communication pipe (27). That is, the liquid refrigerant from the first main tank (T1) is heated to a predetermined temperature by the reheat heat exchanger (HEX7) and then flows into the liquid side communication pipe (27). Therefore, no condensation occurs outside the liquid side communication pipe (27).
[0101]
  The liquid refrigerant distributed to each indoor unit (22) through the liquid side connecting pipe (27) is decompressed by the indoor expansion valve (EV) and then introduced into the indoor heat exchanger (HEX1). In the indoor heat exchanger (HEX1), the decompressed secondary-side refrigerant exchanges heat with room air, absorbs heat from the room air, and evaporates. As a result, the room air is cooled, and the low-temperature room air is supplied to the room again to perform cooling. The refrigerant evaporated in each indoor heat exchanger (HEX1) flows to the main heat exchanger (HEX2) through the main gas pipe (24).
[0102]
  In the main heat exchanger (HEX2), the secondary refrigerant exchanges heat with the primary refrigerant of the primary circuit (10). By this heat exchange, the secondary side refrigerant releases heat to the primary side refrigerant and condenses. The secondary refrigerant condensed in the main heat exchanger (HEX2) flows through the main liquid pipe (26), and is collected in the second main tank (T2) through the collection liquid pipe (38).
[0103]
  After performing such an operation for a predetermined time, the solenoid valves (SV-P1, SV-P2,...) Of the pump circuit (30) are switched. In other words, the pressurization solenoid valve (SV-P1) of the first main tank (T1) and the decompression solenoid valve (SV-V2) of the second main tank (T2) are closed to pressurize the second main tank (T2). Open the solenoid valve (SV-P2) and the decompression solenoid valve (SV-V1) of the first main tank (T1). As a result, the first main tank (T1) is depressurized and, conversely, the second main tank (T2) is pressurized. For this reason, the liquid refrigerant pushed out from the second main tank (T2) circulates as described above and is collected in the first main tank (T1).
[0104]
  As described above, each solenoid valve (SV-P1, SV-P2,...) Performs a switching operation to continuously circulate the secondary side refrigerant in the secondary side circuit (20). As a result, the cold heat of the primary circuit (10) is transferred to the indoor heat exchanger (HEX1) to cool the room. Note that the solenoid valve (SV-P1, SV) of the main tank (T1, T2) can be opened and closed at its own timing for the opening and closing of the pressurization solenoid valve (SV-P3) and decompression solenoid valve (SV-V3) of the sub tank (ST). -P2, SV-V1, SV-V2) are performed regardless of opening and closing.
[0105]
      <Heating operation>
  The operation during heating operation in which the heat generated in the primary circuit (10) is transferred to the indoor unit (22) will be described with reference to FIG.
[0106]
  In the primary side circuit (10), the primary side four-way switching valve (12) is switched as shown by a broken line in FIG. 2, and the second solenoid valve (SV-2) and the third solenoid valve (SV-3) are switched. ) And the fourth solenoid valve (SV-4) are opened, and the first expansion valve (EV-1), the second expansion valve (EV-2) and the third expansion valve (EV-3) are adjusted to a predetermined opening degree. Is done. In the primary circuit (10), the motor-operated valve (EV-F) and the first electromagnetic valve (SV-1) are closed. When the primary side compressor (11) is operated in this state, the primary side refrigerant circulates in the primary side circuit (10) as shown by the one-dot chain line arrow in FIG. 2, and the heat pump cycle operation is performed.
[0107]
  Specifically, the primary side refrigerant discharged from the primary side compressor (11) is divided into two hands and flows toward the main heat exchanger (HEX2) and the heating heat exchanger (HEX3).
[0108]
  The primary refrigerant directed to the main heat exchanger (HEX2) flows into the main heat exchanger (HEX2) through the primary side four-way switching valve (12). In the main heat exchanger (HEX2), the primary refrigerant exchanges heat with the secondary refrigerant of the secondary circuit (20). As a result of this heat exchange, the primary side refrigerant condenses, and at the same time, the secondary side refrigerant evaporates and heat is given to the secondary side refrigerant. The primary refrigerant condensed in the main heat exchanger (HEX2) once flows into the receiver (13) through the fifth branch pipe (55). The primary refrigerant from the receiver (13) flows through the seventh branch pipe (57) and then returns to the main circuit (15). The primary refrigerant that has returned to the main circuit (15) is divided into two branches and flows toward the outdoor heat exchanger (HEX6) and the first branch pipe (51).
[0109]
  The primary-side refrigerant going to the outdoor heat exchanger (HEX6) is decompressed by the first expansion valve (EV-1), and then flows into the outdoor heat exchanger (HEX6) through the fourth branch pipe (54). . In the outdoor heat exchanger (HEX6), heat is exchanged with the outside air, and the primary refrigerant evaporates. The primary side refrigerant evaporated in the outdoor heat exchanger (HEX6) is sucked into the primary side compressor (11) through the primary side four-way switching valve (12).
[0110]
  The primary side refrigerant discharged from the primary side compressor (11) and going to the heating heat exchanger (HEX3) flows into the heating heat exchanger (HEX3) through the sixth branch pipe (56). In the heating heat exchanger (HEX3), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the primary side refrigerant condenses and the secondary side refrigerant evaporates, and the heating heat exchanger (HEX3) is maintained in a high pressure state. The primary refrigerant condensed in the heating heat exchanger (HEX3) flows into the second branch pipe (52). The primary refrigerant that has exited from the second branch pipe (52) merges with the primary refrigerant that exits from the seventh branch pipe (57) and goes to the first branch pipe (51), and is then split into two hands. It flows toward the cooling heat exchanger (HEX4) and the tank front heat exchanger (HEX5).
[0111]
  The primary-side refrigerant heading for the cooling heat exchanger (HEX4) flows into the first branch pipe (51), is decompressed by the second expansion valve (EV-2), and then flows into the cooling heat exchanger (HEX4). . In the cooling heat exchanger (HEX4), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the primary side refrigerant evaporates and at the same time the secondary side refrigerant condenses, and the cooling heat exchanger (HEX4) is maintained in a low pressure state. The primary-side refrigerant evaporated in the cooling heat exchanger (HEX4) flows through the first branch pipe (51) and is sucked into the primary-side compressor (11).
[0112]
  The primary refrigerant going to the tank pre-heat exchanger (HEX5) flows from the first branch pipe (51) to the third branch pipe (53) and is decompressed by the third expansion valve (EV-3), and then the tank It flows into the front heat exchanger (HEX5). In the tank front heat exchanger (HEX5), the primary refrigerant exchanges heat with the secondary refrigerant flowing in the recovery liquid pipe (38) of the pump circuit (30). That is, in the tank pre-heat exchanger (HEX5), the secondary refrigerant recovered from the main liquid pipe (25) of the secondary circuit (20) to the main tank (T1, T2) is heated with the primary refrigerant and heat. It is cooled after replacement. By this heat exchange, the secondary refrigerant recovered in the main tanks (T1, T2) is maintained in the liquid phase. Further, the primary refrigerant evaporated by this heat exchange is again sucked into the primary compressor (11) through the first branch pipe (51).
[0113]
  In the secondary side circuit (20), the secondary side four-way switching valve (23) is switched as indicated by a broken line in FIG. 2, and the indoor expansion valve (EV) is adjusted to a predetermined opening. In this state, open and close each pressurization solenoid valve (SV-P1, SV-P2, SV-P3) and each decompression solenoid valve (SV-V1, SV-V2, SV-V3) of the pump circuit (30), A circulation driving force is applied to the secondary refrigerant. 2 indicate the flow of the refrigerant when the liquid refrigerant is pushed out from the second main tank (T2) and the liquid refrigerant is recovered into the first main tank (T1).
[0114]
  The operation of the pump circuit (30) is the same as that during the cooling operation. In the secondary circuit (20), the secondary refrigerant circulates while changing phase between the main heat exchanger (HEX2) and the indoor heat exchanger (HEX1), and in the primary circuit (10). The generated heat is transferred to the indoor heat exchanger (HEX1).
[0115]
  Specifically, the liquid refrigerant pushed out from one of the main tanks (T1, T2) flows through the extrusion liquid pipe (37) and the secondary side four-way switching valve (23), and enters the secondary side circuit (20). It is sent to the main heat exchanger (HEX2) through the main liquid pipe (26). In the main heat exchanger (HEX2), the secondary side refrigerant exchanges heat with the primary side refrigerant of the primary side circuit (10), and is heated and evaporated by the primary side refrigerant. Thereby, the heat of the primary side circuit (10) is given to the secondary side refrigerant of the secondary side circuit (20).
[0116]
  The gas refrigerant evaporated in the main heat exchanger (HEX2) flows through the main gas pipe (24) and is distributed to the indoor heat exchanger (HEX1) of each indoor unit (22). In the indoor heat exchanger (HEX1), the secondary refrigerant exchanges heat with room air. By this heat exchange, the secondary side refrigerant dissipates heat to the room air and condenses, and the room air is heated. Then, the heated room air is supplied again into the room for heating.
[0117]
  The secondary refrigerant condensed in the indoor heat exchanger (HEX1) flows into the main liquid pipe (25) through the indoor expansion valve (EV). Thereafter, the secondary refrigerant is recovered from the main liquid pipe (25) to the other main tank (T1, T2) through the secondary side four-way switching valve (23) and the recovery liquid pipe (38). .
[0118]
      −Reference technology1 effect-
  BookReference technology1, a reheat heat exchanger (HEX7) is provided to reheat (heat) the secondary refrigerant flowing through the main liquid pipe (25) to a predetermined temperature. That is, the secondary side refrigerant, which has been cooled by the main heat exchanger (HEX2) and cooled to a low temperature, is heated in the reheat heat exchanger (HEX7) to a predetermined temperature corresponding to the dew point temperature of the air. It is made to flow into the side connection piping. Accordingly, in the liquid side communication pipe (27) from the outdoor unit (29) to the indoor unit (22), the secondary side refrigerant heated by the reheat heat exchanger (HEX7) can be circulated, and the liquid side The temperature of the surface of the connecting pipe (27) can be made higher than the dew point temperature of the air around it. For this reason, the dew condensation on the surface of the liquid side communication pipe (27) can be surely prevented.
[0119]
  As a result, the problem of dew condensation can be avoided without applying heat insulation to the liquid side communication pipe (27), such as adding a heat insulating material to the liquid side communication pipe (27). Furthermore, even when installing refrigeration equipment using existing connection pipes that are not heat-insulated, it is possible to avoid problems such as condensation and prevent problems such as water leakage. It is possible to sufficiently cope with this.
[0120]
  Also bookReference technology1, the high-pressure primary refrigerant of the primary circuit (10) is introduced into the reheat heat exchanger (HEX7), and the secondary refrigerant is reheated by heat exchange with the primary refrigerant. Yes. For this reason, as above-mentioned, the heating of the secondary side refrigerant | coolant in a reheat heat exchanger (HEX7) can be performed without supplying energy newly (refer FIG. 8). Therefore, no new energy is required to prevent condensation in the liquid side communication pipe (27).
[0121]
  Like thisReference technologyAccording to 1, the temperature difference between the surface of the liquid side communication pipe (27) and the air around the liquid side communication pipe (27) can be reduced without supplying energy separately. As a result, it is possible to reduce loss due to heat intrusion during the flow through the liquid side communication pipe (27), thereby improving the cooling capacity and improving the energy efficiency.
[0122]
  Also bookReference technologyIn 1, the pre-tank heat exchanger (HEX5) is provided to cool the secondary-side refrigerant flowing through the recovery liquid pipe (38) during the heating operation, and maintain the liquid phase as a supercooled state. For this reason, the secondary side refrigerant | coolant collect | recovered by the main tank (T1, T2) can be reliably made into a liquid phase, and the circulation drive force provided with a pump circuit (30) falls because a refrigerant | coolant flushes. Can be prevented. For this reason, at the time of heating operation, the circulation amount of the secondary side refrigerant in the secondary side circuit (20) can be secured, and the heating capacity can be sufficiently exhibited.
[0123]
    << Reference Technology 2 >>
  Reference technique 2 will be described. This reference technology2 aboveReference technology1, the configuration of the primary circuit (10) is changed. Specifically,Reference technologyIn the primary side circuit (10) according to No. 1, the heating heat exchanger (HEX3) and the reheat heat exchanger (HEX7) are provided in series.Reference technologyIn the primary side circuit (10) according to the above, the heating heat exchanger (HEX3) and the reheat heat exchanger (HEX7) are provided in parallel. BookReference technologyThe configuration of the secondary circuit (20) and the pump circuit (30) in FIG.Reference technology1 is the same. Less than,Reference technologyA configuration different from 1 will be described.
[0124]
  As shown in FIG. 3, the primary circuit (10) includes a main circuit (15) and first to eighth branch pipes (51 to 58).
[0125]
  The main circuit (15) includes a primary compressor (11), a primary four-way selector valve (12), an outdoor heat exchanger (HEX6), a receiver (13), a heating heat exchanger (HEX3), and a main circuit. The heat exchanger (HEX2) is connected by piping in order. The main circuit (15) is filled with R22 as a primary refrigerant. In the main circuit (15), the refrigerant circulation direction is reversed by switching the primary side four-way switching valve (12), and the refrigeration cycle operation and the heat pump cycle operation are switched.
[0126]
  The main circuit (15) is provided with a check valve, a solenoid valve, and the like. Specifically, a check valve (CV-6) is provided between the outdoor heat exchanger (HEX6) and the receiver (13) that allows only the refrigerant to flow toward the receiver (13). Between the receiver (13) and the heating heat exchanger (HEX3), a first solenoid valve (SV-1) and a check valve (CV-7) are installed in order toward the heating heat exchanger (HEX3). It has been. This check valve (CV-7) only allows the refrigerant to flow to the heating heat exchanger (HEX3). Between the heating heat exchanger (HEX3) and the main heat exchanger (HEX2), in order toward the main heat exchanger (HEX2), the first expansion valve (EV-1) and the check valve (CV-8) And are provided. This check valve (CV-8) only allows the refrigerant to flow to the main heat exchanger (HEX2).
[0127]
  The first branch pipe (51) has one end connected between the heating heat exchanger (HEX3) and the first expansion valve (EV-1) in the main circuit (15), and the other end in the main circuit (15). The primary side four-way selector valve (12) is connected between the suction side of the primary side compressor (11). The first branch pipe (51) is provided with a second expansion valve (EV-2) and a cooling heat exchanger (HEX4) in order from one end to the other end.
[0128]
  One end of the second branch pipe (52) is connected between the receiver (13) and the first solenoid valve (SV-1) in the main circuit (15), and the other end is heated and exchanged in the main circuit (15). Connected between the container (HEX3) and the first expansion valve (EV-1). The second branch pipe (52) includes a fifth solenoid valve (SV-5), a check valve (CV-11), a reheat heat exchanger (HEX7), and an electric valve in order from one end to the other end. (EV-F) is provided. This check valve (CV-11) only allows the refrigerant to flow to the reheat heat exchanger (HEX7).
[0129]
  One end of the third branch pipe (53) is connected closer to one end than the second expansion valve (EV-2) in the first branch pipe (51), and the other end is cooling heat exchange in the first branch pipe (51). It is connected closer to the other end than the vessel (HEX4). The third branch pipe (53) is provided with a third expansion valve (EV-3) and a tank pre-heat exchanger (HEX5) in order from one end to the other end.
[0130]
  The fourth branch pipe (54) has one end connected between the first expansion valve (EV-1) and the check valve (CV-8) in the main circuit (15), and the other end connected to the main circuit (15). Is connected between the outdoor heat exchanger (HEX6) and the check valve (CV-6). The fourth branch pipe (54) is provided with a check valve (CV-10) that allows only the refrigerant to flow from one end to the other end.
[0131]
  The fifth branch pipe (55) has one end connected between the check valve (CV-8) and the main heat exchanger (HEX2) in the main circuit (15), and the other end connected to the reverse in the main circuit (15). It is connected between the stop valve (CV-6) and the receiver (13). The fifth branch pipe (55) is provided with a check valve (CV-9) that allows only the refrigerant to flow from one end to the other end.
[0132]
  The sixth branch pipe (56) has one end connected between the discharge side of the primary compressor (11) in the main circuit (15) and the primary side four-way selector valve (12), and the other end is main. The circuit (15) is connected between the check valve (CV-7) and the heating heat exchanger (HEX3). The sixth branch pipe (56) is provided with a fourth solenoid valve (SV-4).
[0133]
  The seventh branch pipe (57) has one end connected between the receiver (13) and the first solenoid valve (SV-1) in the main circuit (15), and the other end connected to the heating heat exchanger (HEX3) and the first It is connected closer to the first expansion valve (EV-1) than the connection portion of the second branch pipe (52) to the main circuit (15) between the first expansion valve (EV-1). The seventh branch pipe (57) is provided with a third solenoid valve (SV-3).
[0134]
  The eighth branch pipe (58) has one end connected closer to one end than the fourth solenoid valve (SV-4) in the sixth branch pipe (56) and the other end connected to the check valve in the second branch pipe (52). (CV-11) and reheat heat exchanger (HEX7). The eighth branch pipe (58) is provided with a sixth solenoid valve (SV-6).
[0135]
      -Driving action-
  BookReference technologyThe operation of the air conditioner according to 2 will be described. In this air conditioner, the operation of the secondary circuit (20) and the pump circuit (30)Reference technology1 is the same. The bookthree TechnologyThe operation of the primary side circuit (10) according to 2 will be described.
[0136]
      <Cooling operation>
  The operation of the primary side circuit (10) during the cooling operation will be described with reference to FIG. In the primary side circuit (10), the primary side four-way switching valve (12) is switched as shown by a solid line in FIG. 3, and the first solenoid valve (SV-1) and the fifth solenoid valve (SV-5). ) Is opened, and the electric valve (EV-F), the first expansion valve (EV-1), and the second expansion valve (EV-2) are adjusted to a predetermined opening degree. In the primary circuit (10), the third expansion valve (EV-3), the third solenoid valve (SV-3), the fourth solenoid valve (SV-4), and the sixth solenoid valve (SV-6) Is closed. When the primary-side compressor (11) is operated in this state, the primary-side refrigerant circulates in the primary-side circuit (10) as shown by the one-dot chain line arrow in FIG. 3, and the refrigeration cycle operation is performed.
[0137]
  Specifically, the primary refrigerant discharged from the primary side compressor (11) flows to the outdoor heat exchanger (HEX6) through the primary side four-way switching valve (12). In the outdoor heat exchanger (HEX6), the primary refrigerant is condensed by exchanging heat with the outside air. The condensed primary-side refrigerant passes through the receiver (13) and is then divided into two hands. One of the divided primary refrigerant flows to the heating heat exchanger (HEX3), and the other flows to the reheat heat exchanger (HEX7).
[0138]
  The primary refrigerant directed to the heating heat exchanger (HEX3) flows through the main circuit (15) as it is and flows into the heating heat exchanger (HEX3). In the heating heat exchanger (HEX3), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the secondary refrigerant evaporates, and the heating heat exchanger (HEX3) is maintained in a high pressure state. In addition, when the heating amount with respect to the secondary side refrigerant | coolant in a heating heat exchanger (HEX3) is insufficient, the discharge gas of a primary side compressor (11) is suitably introduce | transduced into a heating heat exchanger (HEX3). Specifically, the fourth solenoid valve (SV-4) is opened, and the discharge gas is sent through the sixth branch pipe (56).
[0139]
  On the other hand, the primary refrigerant directed to the reheat heat exchanger (HEX7) flows through the second branch pipe (52) and flows into the reheat heat exchanger (HEX7). In the reheat heat exchanger (HEX7), the primary refrigerant exchanges heat with the secondary refrigerant flowing through the main liquid pipe (25) of the secondary circuit (20). By this heat exchange, the secondary side refrigerant sent to the liquid side communication pipe (27) is heated to a predetermined temperature. In addition, when the heating amount with respect to the secondary side refrigerant in the reheat heat exchanger (HEX7) is insufficient, the discharge gas of the primary side compressor (11) is appropriately introduced into the reheat heat exchanger (HEX7). . Specifically, the sixth solenoid valve (SV-6) is opened, and the discharge gas is sent through the eighth branch pipe (58).
[0140]
  The primary side refrigerant from the heating heat exchanger (HEX3) is divided into two, and one of the refrigerant flows toward the cooling heat exchanger (HEX4). The primary-side refrigerant heading for the cooling heat exchanger (HEX4) flows into the first branch pipe (51), is decompressed by the second expansion valve (EV-2), and then flows into the cooling heat exchanger (HEX4). . In the cooling heat exchanger (HEX4), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the primary side refrigerant evaporates and at the same time the secondary side refrigerant condenses, and the cooling heat exchanger (HEX4) is maintained in a low pressure state. The primary-side refrigerant evaporated in the cooling heat exchanger (HEX4) flows through the first branch pipe (51) and is sucked into the primary-side compressor (11).
[0141]
  Of the primary refrigerant from the divided heating heat exchanger (HEX3), the other flows through the main circuit (15) as it is. The primary side refrigerant flowing through the main circuit (15) joins with the primary side refrigerant from the reheat heat exchanger (HEX7), and then sent to the main heat exchanger (HEX2). The primary refrigerant directed to the main heat exchanger (HEX2) is decompressed by the first expansion valve (EV-1) and then flows into the main heat exchanger (HEX2). In the main heat exchanger (HEX2), the primary refrigerant exchanges heat with the secondary refrigerant of the secondary circuit (20). By this heat exchange, the primary side refrigerant evaporates and at the same time the secondary side refrigerant condenses, and cold heat is given to the secondary side refrigerant. The primary refrigerant evaporated in the main heat exchanger (HEX2) passes through the primary four-way switching valve (12) and is sucked into the primary compressor (11).
[0142]
      <Heating operation>
  The operation of the primary side circuit (10) during the heating operation will be described with reference to FIG. In the primary side circuit (10), the primary side four-way selector valve (12) is switched as shown by a broken line in FIG. 4, and the third solenoid valve (SV-3) and the fourth solenoid valve (SV-4) are switched. ) Is opened, and the first expansion valve (EV-1), the second expansion valve (EV-2), and the third expansion valve (EV-3) are adjusted to a predetermined opening degree. In the primary circuit (10), the motor operated valve (EV-F), the first solenoid valve (SV-1), the fifth solenoid valve (SV-5) and the sixth solenoid valve (SV-6) are closed. Is done. When the primary-side compressor (11) is operated in this state, the primary-side refrigerant circulates in the primary-side circuit (10) as shown by the one-dot chain line arrow in FIG. 4, and the heat pump cycle operation is performed.
[0143]
  Specifically, the primary side refrigerant discharged from the primary side compressor (11) is divided into two hands and flows toward the main heat exchanger (HEX2) and the heating heat exchanger (HEX3).
[0144]
  The primary refrigerant directed to the main heat exchanger (HEX2) flows to the main heat exchanger (HEX2) through the primary side four-way switching valve (12). In the main heat exchanger (HEX2), the primary refrigerant exchanges heat with the secondary refrigerant of the secondary circuit (20). As a result of this heat exchange, the primary side refrigerant condenses, and at the same time, the secondary side refrigerant evaporates and heat is given to the secondary side refrigerant. The primary refrigerant condensed in the main heat exchanger (HEX2) once flows into the receiver (13) through the fifth branch pipe (55). The primary refrigerant from the receiver (13) flows through the seventh branch pipe (57) and then returns to the main circuit (15). The primary refrigerant that has returned to the main circuit (15) is divided into two branches and flows toward the outdoor heat exchanger (HEX6) and the first branch pipe (51).
[0145]
  The primary-side refrigerant going to the outdoor heat exchanger (HEX6) is decompressed by the first expansion valve (EV-1), and then flows into the outdoor heat exchanger (HEX6) through the fourth branch pipe (54). . In the outdoor heat exchanger (HEX6), heat is exchanged with the outside air, and the primary refrigerant evaporates. The primary side refrigerant evaporated in the outdoor heat exchanger (HEX6) is sucked into the primary side compressor (11) through the primary side four-way switching valve (12).
[0146]
  The primary side refrigerant discharged from the primary side compressor (11) and going to the heating heat exchanger (HEX3) flows into the heating heat exchanger (HEX3) through the sixth branch pipe (56). In the heating heat exchanger (HEX3), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the primary side refrigerant condenses and the secondary side refrigerant evaporates, and the heating heat exchanger (HEX3) is maintained in a high pressure state. The primary refrigerant condensed in the heating heat exchanger (HEX3) merges with the primary refrigerant going out of the seventh branch pipe (57) and going to the first branch pipe (51), and then split into two hands. It flows toward the cooling heat exchanger (HEX4) and the tank front heat exchanger (HEX5).
[0147]
  The primary-side refrigerant heading for the cooling heat exchanger (HEX4) flows into the first branch pipe (51), is decompressed by the second expansion valve (EV-2), and then flows into the cooling heat exchanger (HEX4). . In the cooling heat exchanger (HEX4), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the primary side refrigerant evaporates and at the same time the secondary side refrigerant condenses, and the cooling heat exchanger (HEX4) is maintained in a low pressure state. The primary-side refrigerant evaporated in the cooling heat exchanger (HEX4) flows through the first branch pipe (51) and is sucked into the primary-side compressor (11).
[0148]
  The primary refrigerant going to the tank pre-heat exchanger (HEX5) flows from the first branch pipe (51) to the third branch pipe (53) and is decompressed by the third expansion valve (EV-3), and then the tank It flows into the front heat exchanger (HEX5). In the tank front heat exchanger (HEX5), the primary refrigerant exchanges heat with the secondary refrigerant flowing in the recovery liquid pipe (38) of the pump circuit (30). That is, in the tank pre-heat exchanger (HEX5), the secondary refrigerant recovered from the main liquid pipe (25) of the secondary circuit (20) to the main tank (T1, T2) is heated with the primary refrigerant and heat. It is cooled after replacement. By this heat exchange, the secondary refrigerant recovered in the main tanks (T1, T2) is maintained in the liquid phase. Further, the primary refrigerant evaporated by this heat exchange is again sucked into the primary compressor (11) through the first branch pipe (51).
[0149]
    << Embodiment of the Invention >>
  An embodiment of the present invention will be described. In the present embodiment, the refrigeration apparatus according to the present invention is configured as an air conditioner.
[0150]
  This embodiment is the aboveReference technology1, the configuration of the pump circuit (30) and the primary circuit (10) is changed. Specifically, during cooling,Reference technologyThe function of the cooling heat exchanger (HEX4) in No. 1 is also used by the main heat exchanger (HEX2) of the secondary circuit (20).Reference technologyThe reheat heat exchanger (HEX7) also functions as the cooling heat exchanger (HEX4) and the tank front heat exchanger (HEX5) in FIG. Less than,Reference technologyA configuration different from 1 will be described.
[0151]
      <Pump circuit configuration>
  As shown in FIG. 5, in the pump circuit (30) of this embodiment, the above-mentionedReference technologyThe cooling heat exchanger (HEX4) and the tank front heat exchanger (HEX5) in Fig. 1 are omitted (see Fig. 1). Along with this, in the pump circuit (30),Reference technologyIn place of the gas recovery pipe (32) in FIG. 1, first, second and third gas recovery pipes (41, 42, 43) are provided. Specifically, a first gas recovery pipe (41) is connected to the first main tank (T1), and a second gas recovery pipe (42) is connected to the second main tank (T2). A third gas recovery pipe (43) is connected to the sub tank (ST).
[0152]
  The first gas recovery pipe (41) has one end connected to the upper end of the first main tank (T1) and the other end branched into two branch pipes (41a, 41b). The first gas recovery pipe (41) is provided with a first tank pressure reducing solenoid valve (SV-V1). On the other hand, the second gas recovery pipe (42) has one end connected to the upper end of the second main tank (T2) and the other end branched to two branch pipes (42a, 42b). The second gas recovery pipe (42) is provided with a second tank pressure reducing solenoid valve (SV-V2).
[0153]
  One branch pipe (41a, 42a) of the first and second gas recovery pipes (41, 42) is connected to the main gas pipe (24) of the secondary side circuit (20). Each of these branch pipes (41a, 42a) is provided with a check valve (CV-15). Each check valve (CV-15) only allows refrigerant to flow to the main gas pipe (24).
[0154]
  The other branch pipes (41b, 42b) of the first and second gas recovery pipes (41, 42) are respectively connected to the reheat heat exchanger (HEX7) in the main liquid pipe (25) of the secondary side circuit (20). Connected to the indoor expansion valve (EV). Each of these branch pipes (41b, 42b) is provided with a check valve (CV-16). Each check valve (CV-16) only allows the refrigerant to flow to the main liquid pipe (25).
[0155]
  The third gas recovery pipe (43) has one end connected to the upper end of the sub tank (ST) and the other end branched into two branch pipes (43a, 43b). One branch pipe (43a) of the third gas recovery pipe (43) is connected to the main gas pipe (24) of the secondary circuit (20). The branch pipe (43a) is provided with a third tank pressure reducing solenoid valve (SV-V3) and a check valve (CV-17) in order toward the main gas pipe (24). This check valve (CV-17) only allows the refrigerant to flow to the main gas pipe (24). The other branch pipe (43b) of the third gas recovery pipe (43) is connected between the reheat heat exchanger (HEX7) and the indoor expansion valve (EV) in the main liquid pipe (25) of the secondary circuit (20). Connected between. The branch pipe (43b) is provided with a fourth tank pressure reducing solenoid valve (SV-V4).
[0156]
      <Primary circuit configuration>
    As shown in FIG. 5, the primary side circuit (10) of this embodiment includes a main circuit (15), fourth to seventh, ninth and tenth branch pipes (54 to 57, 59, 60). It is constituted by.
[0157]
  The main circuit (15) includes a primary compressor (11), a primary four-way selector valve (12), an outdoor heat exchanger (HEX6), a receiver (13), a heating heat exchanger (HEX3), A heat heat exchanger (HEX7) and a main heat exchanger (HEX2) are connected in order by piping. The main circuit (15) is filled with R22 as a primary refrigerant. In the main circuit (15), the refrigerant circulation direction is reversed by switching the primary side four-way switching valve (12), and the refrigeration cycle operation and the heat pump cycle operation are switched.
[0158]
  The main circuit (15) is provided with a check valve, a solenoid valve, and the like. Specifically, a check valve (CV-6) is provided between the outdoor heat exchanger (HEX6) and the receiver (13) that allows only the refrigerant to flow toward the receiver (13). Between the receiver (13) and the heating heat exchanger (HEX3), a first solenoid valve (SV-1) and a check valve (CV-7) are installed in order toward the heating heat exchanger (HEX3). It has been. This check valve (CV-7) only allows the refrigerant to flow to the heating heat exchanger (HEX3). A fourth expansion valve (EV-4) is provided between the heating heat exchanger (HEX3) and the reheat heat exchanger (HEX7). Between the reheat heat exchanger (HEX7) and the main heat exchanger (HEX2), in order toward the main heat exchanger (HEX2), the 8th solenoid valve (SV-8) and check valve (CV-12) ), A first expansion valve (EV-1), and a check valve (CV-8). These two check valves (CV-8, CV-12) allow only the flow of refrigerant toward the main heat exchanger (HEX2).
[0159]
  The fourth branch pipe (54) has one end connected between the first expansion valve (EV-1) and the check valve (CV-8) in the main circuit (15), and the other end connected to the main circuit (15). Is connected between the outdoor heat exchanger (HEX6) and the check valve (CV-6). The fourth branch pipe (54) is provided with a check valve (CV-10) that allows only the refrigerant to flow from one end to the other end.
[0160]
  The fifth branch pipe (55) has one end connected between the check valve (CV-8) and the main heat exchanger (HEX2) in the main circuit (15), and the other end connected to the reverse in the main circuit (15). It is connected between the stop valve (CV-6) and the receiver (13). The fifth branch pipe (55) is provided with a check valve (CV-9) that allows only the refrigerant to flow from one end to the other end.
[0161]
  The sixth branch pipe (56) has one end connected between the discharge side of the primary compressor (11) in the main circuit (15) and the primary side four-way selector valve (12), and the other end is main. The circuit (15) is connected between the check valve (CV-7) and the heating heat exchanger (HEX3). The sixth branch pipe (56) is provided with a fourth solenoid valve (SV-4).
[0162]
  One end of the seventh branch pipe (57) is connected between the receiver (13) and the first solenoid valve (SV-1) in the main circuit (15), and the other end is a check valve in the main circuit (15). (CV-12) and the first expansion valve (EV-1). The seventh branch pipe (57) is provided with a third solenoid valve (SV-3).
[0163]
  The ninth branch pipe (59) has one end connected between the heating heat exchanger (HEX3) and the fourth expansion valve (EV-4) in the main circuit (15), and the other end in the main circuit (15). It is connected between the check valve (CV-12) and the first expansion valve (EV-1). The ninth branch pipe (59) is provided with a seventh solenoid valve (SV-7).
[0164]
  The tenth branch pipe (60) has one end connected between the reheat heat exchanger (HEX7) and the eighth solenoid valve (SV-8) in the main circuit (15), and the other end connected to the main circuit (15). Is connected between the primary four-way switching valve (12) and the suction side of the primary compressor (11). The tenth branch pipe (60) is provided with a ninth solenoid valve (SV-9).
[0165]
      -Driving action-
      <Cooling operation>
  An operation during the cooling operation of the air conditioner according to the present embodiment will be described with reference to FIG.
[0166]
  In the primary side circuit (10), the primary side four-way selector valve (12) is switched as shown by a solid line in FIG. 5, and the first solenoid valve (SV-1) and the eighth solenoid valve (SV-8). ) Is opened and the fourth expansion valve (EV-4) is adjusted to fully open, while the first expansion valve (EV-1) is adjusted to a predetermined opening. In the primary circuit (10), the third solenoid valve (SV-3), the fourth solenoid valve (SV-4), the seventh solenoid valve (SV-7) and the ninth solenoid valve (SV-9) Is closed. When the primary side compressor (11) is operated in this state, the primary side refrigerant circulates in the primary side circuit (10) as shown by the one-dot chain line arrow in FIG. 5, and the refrigeration cycle operation is performed.
[0167]
  Specifically, the primary refrigerant discharged from the primary side compressor (11) flows to the outdoor heat exchanger (HEX6) through the primary side four-way switching valve (12). In the outdoor heat exchanger (HEX6), the primary refrigerant is condensed by exchanging heat with the outside air. The condensed primary refrigerant flows through the receiver (13) to the heating heat exchanger (HEX3).
[0168]
  In the heating heat exchanger (HEX3), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the secondary refrigerant evaporates, and the heating heat exchanger (HEX3) is maintained in a high pressure state. In addition, when the heating amount with respect to the secondary side refrigerant | coolant in a heating heat exchanger (HEX3) is insufficient, the discharge gas of a primary side compressor (11) is suitably introduce | transduced into a heating heat exchanger (HEX3). Specifically, the fourth solenoid valve (SV-4) is opened, and the discharge gas is sent through the sixth branch pipe (56).
[0169]
  The primary refrigerant from the heating heat exchanger (HEX3) flows to the reheat heat exchanger (HEX7). In the reheat heat exchanger (HEX7), the primary refrigerant exchanges heat with the secondary refrigerant flowing through the main liquid pipe (25) of the secondary circuit (20). By this heat exchange, the secondary side refrigerant sent to the liquid side communication pipe (27) is heated to a predetermined temperature.
[0170]
  The primary side refrigerant from the reheat heat exchanger (HEX7) flows through the main circuit (15) as it is, and is decompressed by the first expansion valve (EV-1) and then flows into the main heat exchanger (HEX2). In the main heat exchanger (HEX2), the primary refrigerant exchanges heat with the secondary refrigerant of the secondary circuit (20). By this heat exchange, the primary side refrigerant evaporates and at the same time the secondary side refrigerant condenses, and cold heat is given to the secondary side refrigerant. The primary refrigerant evaporated in the main heat exchanger (HEX2) passes through the primary four-way switching valve (12) and is sucked into the primary compressor (11).
[0171]
  In the secondary side circuit (20), the secondary side four-way switching valve (23) is switched as shown by a solid line in FIG. 5, and the indoor expansion valve (EV) is adjusted to a predetermined opening. In this state, open and close each pressurization solenoid valve (SV-P1, SV-P2, SV-P3) and each decompression solenoid valve (SV-V1, SV-V2, SV-V3) of the pump circuit (30), A circulation driving force is applied to the secondary refrigerant. During the cooling operation, the fourth tank pressure reducing solenoid valve (SV-V4) is always closed.
[0172]
  In the secondary circuit (20), the secondary refrigerant circulates while changing phase between the main heat exchanger (HEX2) and the indoor heat exchanger (HEX1), and in the primary circuit (10). The generated cold energy is transferred to the indoor heat exchanger (HEX1). The operation in the secondary side circuit (20) is as described above.Reference technology1 is the same.
[0173]
  The operation of the pump circuit (30) according to this embodiment is basically as described above.Reference technologyThe operation is the same as that of No. 1 except that both main tanks (T1, T2) and sub-tanks (ST) are depressurized.
[0174]
  For example, when depressurizing the first main tank (T1), the first tank depressurizing solenoid valve (SV-V1) is opened. In this state, the first main tank (T1) communicates with the main heat exchanger (HEX2) via the branch pipe (41a) and the main gas pipe (24) of the secondary circuit (20). Here, in the main heat exchanger (HEX2), the secondary side refrigerant is cooled and condensed by heat exchange with the primary side refrigerant of the primary side circuit (10). Therefore, the main heat exchanger (HEX2) is maintained at a low pressure. For this reason, the gas refrigerant in the first main tank (T1) is sucked into the main heat exchanger (HEX2), and the first main tank (T1) is decompressed.
[0175]
  Similarly, when depressurizing the second main tank (T2), the second tank depressurizing solenoid valve (SV-V2) is opened. Further, when depressurizing the sub tank (ST), the third tank depressurizing solenoid valve (SV-V3) is opened. That is, during the cooling operation, the main heat exchanger (HEX2) according to the present embodiment not only applies cooling to the secondary-side refrigerant, but alsoReference technologyIt also functions as a cooling heat exchanger (HEX4) in No. 1.
[0176]
      <Heating operation>
  The operation at the time of heating operation of the air conditioner according to the present embodiment will be described with reference to FIG.
[0177]
  In the primary side circuit (10) of the present embodiment, the primary side four-way switching valve (12) is switched as indicated by a broken line in FIG. 6, and the third solenoid valve (SV-3) and the fourth solenoid valve are switched. (SV-4), 7th solenoid valve (SV-7) and 9th solenoid valve (SV-9) are opened, 1st expansion valve (EV-1) and 4th expansion valve (EV-4) are predetermined It is adjusted to the opening. In the primary circuit (10), the first solenoid valve (SV-1) and the eighth solenoid valve (SV-8) are closed. When the primary side compressor (11) is operated in this state, the primary side refrigerant circulates in the primary side circuit (10) as shown by the dashed-dotted arrow in FIG. 6, and the heat pump cycle operation is performed.
[0178]
  Specifically, the primary side refrigerant discharged from the primary side compressor (11) is divided into two hands and flows toward the main heat exchanger (HEX2) and the heating heat exchanger (HEX3).
[0179]
  The primary refrigerant directed to the main heat exchanger (HEX2) flows to the main heat exchanger (HEX2) through the primary side four-way switching valve (12). In the main heat exchanger (HEX2), the primary refrigerant exchanges heat with the secondary refrigerant of the secondary circuit (20). As a result of this heat exchange, the primary side refrigerant condenses, and at the same time, the secondary side refrigerant evaporates and heat is given to the secondary side refrigerant. The primary refrigerant condensed in the main heat exchanger (HEX2) once flows into the receiver (13) through the fifth branch pipe (55). The primary refrigerant from the receiver (13) flows through the seventh branch pipe (57) and then returns to the main circuit (15). The primary refrigerant that has returned to the main circuit (15) is split into two hands and flows toward the outdoor heat exchanger (HEX6) and the ninth branch pipe (59).
[0180]
  The primary-side refrigerant going to the outdoor heat exchanger (HEX6) is decompressed by the first expansion valve (EV-1), and then flows into the outdoor heat exchanger (HEX6) through the fourth branch pipe (54). . In the outdoor heat exchanger (HEX6), heat is exchanged with the outside air, and the primary refrigerant evaporates. The primary side refrigerant evaporated in the outdoor heat exchanger (HEX6) is sucked into the primary side compressor (11) through the primary side four-way switching valve (12).
[0181]
  The primary side refrigerant discharged from the primary side compressor (11) and going to the heating heat exchanger (HEX3) flows into the heating heat exchanger (HEX3) through the sixth branch pipe (56). In the heating heat exchanger (HEX3), the primary refrigerant exchanges heat with the secondary refrigerant of the pump circuit (30). By this heat exchange, the primary side refrigerant condenses and the secondary side refrigerant evaporates, and the heating heat exchanger (HEX3) is maintained in a high pressure state. The primary refrigerant condensed in the heating heat exchanger (HEX3) merges with the primary refrigerant flowing through the ninth branch pipe (59) after being separated from the seventh branch pipe (57). The merged primary refrigerant flows through the main circuit (15) as it is to the reheat heat exchanger (HEX7).
[0182]
  The primary refrigerant directed to the reheat heat exchanger (HEX7) is decompressed by the fourth expansion valve (EV-4) and then flows into the reheat heat exchanger (HEX7). In the reheat heat exchanger (HEX7), the secondary refrigerant recovered from the main liquid pipe (25) through the recovery liquid pipe (38) to the main tank (T1, T2) is the primary refrigerant. It is cooled by heat exchange. By this heat exchange, the secondary refrigerant recovered in the main tanks (T1, T2) is maintained in the liquid phase. That is, the reheat heat exchanger (HEX7) of the present embodiment has the above-mentioned during heating operation.Reference technology1 fulfills the function of the tank front heat exchanger (HEX5). The primary refrigerant from the reheat heat exchanger (HEX7) is sucked into the primary compressor (11) through the tenth branch pipe (60).
[0183]
  In the secondary side circuit (20), the secondary side four-way switching valve (23) is switched as indicated by a broken line in FIG. 6, and the indoor expansion valve (EV) is adjusted to a predetermined opening. In this state, open and close each pressurization solenoid valve (SV-P1, SV-P2, SV-P3) and each decompression solenoid valve (SV-V1, SV-V2, SV-V3) of the pump circuit (30), A circulation driving force is applied to the secondary refrigerant. During the heating operation, the third tank pressure reducing solenoid valve (SV-V3) is always closed.
[0184]
  In the secondary circuit (20), the secondary refrigerant circulates while changing phase between the main heat exchanger (HEX2) and the indoor heat exchanger (HEX1), and in the primary circuit (10). The generated heat is transferred to the indoor heat exchanger (HEX1). The operation in the secondary side circuit (20) is as described above.Reference technology1 is the same.
[0185]
  The operation of the pump circuit (30) according to this embodiment is basically as described above.Reference technologyThe operation is the same as that of No. 1 except that both main tanks (T1, T2) and sub-tanks (ST) are depressurized.
[0186]
  For example, when depressurizing the first main tank (T1), the first tank depressurizing solenoid valve (SV-V1) is opened. In this state, the first main tank (T1) communicates with the reheat heat exchanger (HEX7) through the branch pipe (41b) and the main liquid pipe (25) of the secondary circuit (20). Here, in the reheat heat exchanger (HEX7), the low-pressure secondary refrigerant flowing through the main liquid pipe (25) is cooled by heat exchange with the primary refrigerant in the primary circuit (10) and is supercooled. It is in a state. Therefore, the reheat heat exchanger (HEX7) is maintained at a low pressure. For this reason, the gas refrigerant in the first main tank (T1) is sucked into the main liquid pipe (25), flows into the reheat heat exchanger (HEX7), and is condensed. As a result, the first main tank (T1) is depressurized.
[0187]
  Similarly, when depressurizing the second main tank (T2), the second tank depressurizing solenoid valve (SV-V2) is opened. Further, when depressurizing the sub tank (ST), the fourth tank depressurizing solenoid valve (SV-V4) is opened. That is, at the time of heating operation, the reheat heat exchanger (HEX7) according to the present embodiment is as described above.Reference technologyAs well as fulfilling the function of the tank front heat exchanger (HEX5) in 1Reference technologyIt also functions as a cooling heat exchanger (HEX4) in No. 1.
[0188]
      -Effect of the embodiment-
  According to this embodiment, the aboveReference technologyIn addition to the effect 1, the following effects can be obtained. That is, in the present embodiment, during the cooling operation, the main heat exchanger (HEX2) of the secondary side circuit (20)Reference technologyIt also functions as a cooling heat exchanger (HEX4) in No. 1. During heating operation, the reheat heat exchanger (HEX7)Reference technology1 functions as both the cooling heat exchanger (HEX4) and the tank front heat exchanger (HEX5). Therefore,Reference technology 1Than above while reducing the number of heat exchangersReference technologyThe function equivalent to 1 air conditioner can be obtained. For this reason, it is possible to simplify the configuration and reduce the cost without any loss of function.
[0189]
      -Modification of the embodiment-
  In the above embodiment, the sub tank (ST) and the buffer tank (BT) can be omitted.
[0190]
  That is, as shown in FIG. 7, the sub tank (ST), the buffer tank (BT) and the pipes (31c, 37c, 39, 43) connected to these are omitted from the air conditioner of the embodiment (see FIG. 5). Then, the configuration of the liquid recovery pipe (34) is changed. The liquid recovery pipe (34) of this modification has one end connected to the lower end of the heating heat exchanger (HEX3) and the other end branched to two branch pipes (34a, 34b). Of these branch pipes (34a, 34b), one branch pipe (34a) is connected to one branch pipe (37a) of the extrusion liquid pipe (37), and the other branch pipe (34b) is the extrusion liquid pipe. (37) is connected to the other branch pipe (37b). Each branch pipe (34a, 34b) is provided with a check valve (CV-18) that allows only the flow of refrigerant toward the heating heat exchanger (HEX3).
[0191]
  During the operation of the air conditioner, a part of the secondary side refrigerant pushed out from the main tank (T1, T2) flows into the branch pipes (34a, 34b) of the liquid recovery pipe (34). Is supplied to the heating heat exchanger (HEX3). In the heating heat exchanger (HEX3), the supplied secondary-side refrigerant evaporates to maintain the inside at a high pressure.
[0192]
Other Embodiments of the Invention
  Embodiment aboveAnd each reference technologyThen, a pump circuit (30) constituting a so-called heat-driven pump is connected to the secondary circuit (20), and the secondary refrigerant is circulated by the pump circuit (30). On the other hand, a general mechanical pump (such as a centrifugal pump) may be provided in the secondary circuit (20).
[0193]
  In addition, the above embodimentAnd each reference technologyIn this case, the primary side circuit (10) is filled with R22, which is a single composition refrigerant, as the primary side refrigerant. Instead, R407C, which is a non-azeotropic refrigerant mixture, is filled as the primary side refrigerant. May be.
[0194]
  Embodiment aboveAnd each reference technologyIn a configuration in which a high-pressure primary refrigerant is introduced into the reheat heat exchanger (HEX7) during refrigerating operation to reheat the secondary refrigerant, a non-azeotropic refrigerant mixture is used as the primary refrigerant. And it becomes possible to reduce the temperature of the primary side refrigerant | coolant at the time of introduce | transducing into a main heat exchanger (HEX2) (refer FIG. 9). For this reason, the temperature of the secondary-side refrigerant after being cooled by the main heat exchanger (HEX2) can be lowered, and the cooling capacity can be improved.
[0195]
  In addition, the above embodimentAnd each reference technologyIn this case, the secondary circuit (20) is filled with R22, which is a single composition refrigerant, as a secondary refrigerant, but instead, is filled with R407C, which is a non-azeotropic refrigerant, as a secondary refrigerant. May be.
[Brief description of the drawings]
[Figure 1]Reference technology2 is a piping system diagram illustrating a refrigerant flow during a cooling operation of the air conditioner according to FIG.
[Figure 2]Reference technology2 is a piping system diagram showing a refrigerant flow during heating operation of the air conditioner according to FIG.
[Fig. 3]Reference technology2 is a piping system diagram showing a refrigerant flow during a cooling operation of an air conditioner according to FIG.
[Fig. 4]Reference technologyIt is a piping system diagram which shows the flow of the refrigerant | coolant at the time of the heating operation of the air conditioner which concerns on 2. FIG.
FIG. 5 is a piping system diagram showing a refrigerant flow during cooling operation of the air conditioner according to the embodiment.
FIG. 6 is a piping system diagram showing a refrigerant flow during heating operation of the air conditioner according to the embodiment.
FIG. 7 is a piping system diagram of an air conditioner according to a modification of the embodiment.
FIG. 8 is a Mollier diagram of a refrigerant for explaining the effect of the present invention.
FIG. 9 is a Mollier diagram of a refrigerant for explaining the effect of the present invention.
[Explanation of symbols]
  (10) Primary circuit (heat source, heat source circuit)
  (20) Secondary circuit (heat transfer circuit)
  (22) Indoor unit
  (27) Liquid side communication pipe (communication piping)
  (28) Gas side communication pipe (communication piping)
  (29) Outdoor unit
  (30) Pump circuit (conveying means)
  (T1) 1st main tank
  (T2) Second main tank
  (HEX1) Indoor heat exchanger (use side heat exchanger)
  (HEX2) Main heat exchanger
  (HEX3) Heating heat exchanger (high pressure section)
  (HEX4) Cooling heat exchanger (low pressure part)
  (HEX7) Reheat heat exchanger (reheat means)
  (EV) Indoor expansion valve (expansion mechanism)

Claims (5)

A heat transfer circuit (20) in which a main heat exchanger (HEX2), a refrigerant transfer means (30), an expansion mechanism (EV) and a use-side heat exchanger (HEX1) are connected by piping to circulate the transfer refrigerant;
A refrigeration apparatus comprising a heat source (10) connected to the main heat exchanger (HEX2) and imparting cold to the refrigerant for conveyance of the heat conveyance circuit (20),
The heat transfer circuit (20) includes a reheating unit (HEX7) for heating the liquid-phase transfer refrigerant supplied to the expansion mechanism (EV) to the predetermined temperature by being supplied with a circulation driving force by the transfer unit (30). ), And is configured to supply the refrigerant for transportation heated by the reheating means (HEX7) to the use side heat exchanger (HEX1) after depressurizing by the expansion mechanism (EV) ,
The heat source ( 10 ) includes a heat source circuit ( 10 ) that performs a vapor compression refrigeration cycle by circulating the heat source side refrigerant ,
The reheating means ( HEX7 ) includes a reheat heat exchanger ( HEX7 ) that exchanges heat between the refrigerant for conveyance of the heat conveyance circuit ( 20 ) and the high-pressure heat source side refrigerant of the heat source circuit ( 10 ) .
The heat source circuit ( 10 ) is configured to also serve as a heat source that performs heat pump cycles and imparts heat to the transport refrigerant in the heat transport circuit ( 20 ),
The heat carrier circuit (20), the refrigerant in which the refrigerant flowing out from the conveying means (30) passes through the expansion mechanism main heat exchanger with are sent to after passing through the (EV) to the utilization side heat exchanger (HEX 1) (HEX 2) pass but a state of flowing to the transfer means (30), the utilization-side heat exchanger with the refrigerant flowing out from the conveying means (30) is sent to the main heat exchanger (HEX 2) (HEX 1) and the expansion mechanism (EV) in order Provided with a four-way selector valve ( 23 ) for switching between the state in which the refrigerant flows into the conveying means ( 30 ) ,
In the heat transfer circuit ( 20 ), the cooling heat transfer operation for transferring cold heat from the main heat exchanger ( HEX2 ) to the user side heat exchanger ( HEX1 ) and the circulation direction of the refrigerant for transfer are reversed during the cold heat transfer operation. The four-way switching valve ( 23 ) switches the heat transfer operation to transfer heat from the main heat exchanger ( HEX2 ) to the user-side heat exchanger ( HEX1 ) .
The reheat heat exchanger ( HEX7 ) is connected between the four-way selector valve ( 23 ) and the expansion mechanism ( EV ) in the heat transfer circuit ( 20 ) ,
The re-heat exchanger (HEX7), at the time of heat transport operation of the heat carrier circuit (20), the low pressure of the heat-source side refrigerant and the heat of the heat source circuit carrying refrigerant from the usage-side heat exchanger (HEX 1) (10) A refrigeration apparatus that also serves as a liquid phase maintaining means for maintaining the transport refrigerant that is exchanged and sent to the transport means ( 30 ) in the liquid phase . The refrigeration apparatus according to claim 1, wherein
An outdoor unit (29) provided with a main heat exchanger (HEX2), a conveying means (30) and a reheating means (HEX7);
While having an indoor unit (22) provided with an expansion mechanism (EV) and a use side heat exchanger (HEX1),
A heat transfer circuit (27, 28) is provided between the reheating means (HEX7) and the expansion mechanism (EV), and between the use side heat exchanger (HEX1) and the main heat exchanger (HEX2). 20) Refrigeration equipment that is configured. A refrigeration system connected to an indoor unit (22) having a use side heat exchanger (HEX1) and an expansion mechanism (EV) by an existing liquid side communication pipe (27) and gas side communication pipe (28). ,
It has a main heat exchanger (HEX2) and refrigerant conveying means (30), the conveying means (30) side is via the liquid side communication pipe (27), and the main heat exchanger (HEX2) side is the gas side communication pipe (28) A heat transfer circuit (20) connected to the indoor unit (22) via the main heat exchanger (HEX2) and circulating the transfer refrigerant between the indoor unit (22),
A heat source (10) connected to the main heat exchanger (HEX2) to apply cold to the refrigerant for conveyance of the heat conveyance circuit (20);
Reheating means (HEX7) for heating the conveying refrigerant to which the circulation driving force is given by the conveying means (30) and sent to the liquid side connecting pipe (27) to a predetermined temperature ,
The heat source ( 10 ) includes a heat source circuit ( 10 ) that performs a vapor compression refrigeration cycle by circulating the heat source side refrigerant ,
The reheating means ( HEX7 ) includes a reheat heat exchanger ( HEX7 ) that exchanges heat between the refrigerant for conveyance of the heat conveyance circuit ( 20 ) and the high-pressure heat source side refrigerant of the heat source circuit ( 10 ) .
The heat source circuit ( 10 ) is configured to also serve as a heat source that performs heat pump cycles and imparts heat to the transport refrigerant in the heat transport circuit ( 20 ),
The heat carrier circuit (20) includes a state in which the refrigerant to transport means (30) from the main heat exchanger (HEX 2) together with the refrigerant is sent from the transport means (30) the liquid side communication pipe (27) flows, the transport A four-way switching valve ( 23 ) for switching between a state in which the refrigerant is sent from the means ( 30 ) to the main heat exchanger ( HEX2 ) and flows into the conveying means ( 30 ) from the liquid side communication pipe ( 27 ) ,
The heat transfer circuit ( 20 ) reverses the circulation direction of the transfer refrigerant between the cold heat transfer operation for transferring cold heat from the main heat exchanger ( HEX2 ) to the user side heat exchanger ( HEX1 ), and during the cold heat transfer operation. On the other hand, the four-way switching valve ( 23 ) switches the heat transfer operation to transfer heat from the main heat exchanger ( HEX2 ) to the user-side heat exchanger ( HEX1 ) .
The reheat heat exchanger ( HEX7 ) is connected between the four-way switching valve ( 23 ) and the liquid side communication pipe ( 27 ) in the heat transfer circuit ( 20 ) ,
The re-heat exchanger (HEX7), at the time of heat transport operation of the heat carrier circuit (20), the low pressure of the heat-source side refrigerant and the heat of the heat source circuit carrying refrigerant from the usage-side heat exchanger (HEX 1) (10) A refrigeration apparatus that also serves as a liquid phase maintaining means for maintaining the refrigerant for transportation sent to the transportation means ( 30 ) in the liquid phase after being exchanged . The refrigeration apparatus according to claim 1, 2, or 3,
The transport means (30)
A pair of tanks (T1, T2) for connecting the heat transfer circuit (20) and storing the transfer refrigerant;
A high pressure section (HEX3) for supplying the evaporated gas refrigerant to the tank (T1) and pressurizing the tank (T1);
A low-pressure part (HEX4) for condensing the gas refrigerant sucked from the tank (T2) to decompress the tank (T2),
Pressurize one tank (T1) to push out the transport refrigerant from the tank (T1), and simultaneously depressurize the other tank (T2) to recover the transport refrigerant to the tank (T2) A refrigeration apparatus configured to apply a circulation driving force to a conveying refrigerant. The refrigeration apparatus according to claim 1, 2, 3, or 4 ,
The heat source side refrigerant of the heat source circuit (10) is a refrigeration apparatus that is a non-azeotropic refrigerant mixture.

Images