JP4111246B2 - Refrigeration equipment - Google Patents

Description

  The present invention relates to control of means for heating a compressor while the refrigeration apparatus is stopped.

  In the refrigeration apparatus, the refrigerant may accumulate in the compressor during the stoppage. For example, when the compressor is accommodated in an outdoor unit installed outdoors, the temperature of the compressor also decreases in winter when the outside air temperature is low, so that the refrigerant in the refrigerant circuit may condense and accumulate in the compressor. is there. When the refrigerant accumulates in the compressor, the refrigerant dissolves in the lubricating oil stored in the compressor and the viscosity of the lubricating oil decreases. And if a compressor is started in this state, low-viscosity lubricating oil will be supplied to the sliding part of a compressor, and there exists a danger of resulting in the seizing by poor lubrication. In addition, the refrigerant dissolved in the lubricating oil after the start of the compressor may be gasified at a stretch, and the lubricating oil may be in a foamed state, making it impossible to supply sufficient oil.

  In order to solve this problem, measures are taken to prevent the refrigerant from accumulating in the compressor by heating the compressor while the refrigeration system is stopped. For example, Patent Document 1 discloses that an electric heater is attached to a compressor, and the electric heater is energized to heat the compressor. Patent Document 2 discloses that a high-frequency low voltage is applied to a coil of an electric motor installed in a compressor and Joule heat is generated by the coil without rotating the electric motor to heat the compressor. ing.

When the compressor is heated while the refrigeration apparatus is stopped, energy such as electric power is consumed even when the refrigeration apparatus is stopped. As a countermeasure against this problem, Patent Document 1 determines whether or not to energize the electric heater based on the outdoor temperature and the indoor temperature, and when it is determined that heating of the compressor is unnecessary, It is disclosed to stop energization. Specifically, in Patent Document 1, when the temperature difference between the room and the outside is a predetermined value or more and the outside air temperature is also a predetermined value or more, it is determined that the amount of refrigerant accumulated in the compressor is not so much. The power supply to is stopped.
JP 2002-106981 A JP 2002-031386 A

  Here, the refrigerant circuit of the refrigeration apparatus connects the outdoor unit provided with the compressor and the heat source side heat exchanger and the indoor unit provided with the use side heat exchanger by connecting piping. Often formed. When the outside air temperature is lower than the room temperature, the refrigerant accumulates in the outdoor unit.

  However, even in a state where the refrigerant is accumulated in the outdoor unit, the refrigerant is not necessarily accumulated in the compressor. In other words, since the outdoor unit is provided with a heat source side heat exchanger in addition to the compressor, refrigerant may accumulate in the heat source side heat exchanger instead of the compressor. In such a case, the compressor There is no need to heat.

  However, as disclosed in Patent Document 1, even if the indoor / outdoor air temperature is taken into account, it can be determined whether the refrigerant is accumulated in the indoor side or the outdoor side, but the refrigerant is accumulated in the compressor. It is not possible to judge whether it is in a state to obtain. For this reason, even if the amount of refrigerant accumulated in the compressor is not so large, the compressor is heated, and there is a possibility that useless energy is consumed.

  The present invention has been made in view of such a point, and an object of the present invention is to appropriately determine whether or not a large amount of refrigerant can accumulate in the compressor, and to reduce energy consumption when the refrigeration apparatus is stopped. There is.

  1st invention has a heat source side circuit (21) which has a compressor (30) and a heat source side heat exchanger (34), and is installed outdoors, and has a utilization side heat exchanger (37) A refrigeration apparatus including a refrigerant circuit (20) connected to a use side circuit (22) installed indoors and performing a refrigeration cycle by circulating refrigerant in the refrigerant circuit (20) is intended. And while the heat source side heat exchanger (34) is configured to exchange heat between the refrigerant and outdoor air, heating means (80) for heating the compressor (30) while the refrigeration apparatus is stopped, The outside air temperature detecting means (72) for detecting the outdoor air temperature and the heating means (80) while the detected value of the outside air temperature detecting means (72) is lowered even when the refrigeration apparatus is stopped. And a control means (91) for maintaining heating of the compressor (30) in a stopped state.

  In the first invention, the heating means (80) heats the compressor (30) while the refrigeration apparatus (10) is stopped, so that the refrigerant in the refrigerant circuit (20) flows into the compressor (30) and condenses. To prevent it. In the present invention, while the detection value of the outside air temperature detection means (72) is decreasing, the control means (91) is compressed by the heating means (80) even when the refrigeration apparatus (10) is stopped. Hold the heating of the machine (30) stopped.

  Here, in a state where the refrigeration apparatus (10) is stopped, the temperatures of the compressor (30) and the heat source side heat exchanger (34) change as the outside air temperature changes. Further, the heat capacity of the compressor (30) is usually larger than the heat capacity of the heat source side heat exchanger (34) for exchanging heat between the outdoor air and the refrigerant. For this reason, the time delay of the temperature change with respect to the change of the outside air temperature is longer in the compressor (30) than in the heat source side heat exchanger (34). Therefore, for example, in the process where the outside air temperature gradually decreases from noon to night, the temperature of the heat source side heat exchanger (34) becomes almost the same value as the outside air temperature, but the temperature of the compressor (30) is higher than the outside air temperature. Is also somewhat higher. That is, while the outside air temperature gradually decreases, the temperature of the compressor (30) becomes higher than the temperature of the heat source side heat exchanger (34).

  On the other hand, while the refrigeration apparatus (10) is stopped, the refrigerant charged in the refrigerant circuit (20) condenses in the portion of the refrigerant circuit (20) where the temperature is the lowest and accumulates in that portion. For this reason, while the outside air temperature gradually decreases, the refrigerant accumulates in the heat source side heat exchanger (34), which has a lower temperature than the compressor (30), and so much refrigerant is compressed. It can be estimated that it does not accumulate in the machine (30).

  Therefore, the control means (91) of the first invention determines that the amount of refrigerant accumulated in the compressor (30) does not increase so much while the detection value of the outside air temperature detection means (72) is decreasing. The heating of the compressor (30) by the heating means (80) is kept stopped.

In a second aspect based on the first aspect , the use side heat exchanger (37) is configured so that the refrigerant exchanges heat with the room air, and the room temperature detection means (75) for detecting the room temperature is provided. The control means (91) includes the compressor by the heating means (80) while the detected value of the inside air temperature detecting means (75) is lower than the detected value of the outside air temperature detecting means (72). The heating of (30) is configured to be held in a stopped state.

In the second invention, while the detected value of the inside air temperature detecting means (75) is higher than the detected value of the outside air temperature detecting means (72), even if the refrigeration apparatus (10) is stopped, the control means (91) Holds the heating of the compressor (30) by the heating means (80) in a stopped state.

  As described above, when the refrigeration apparatus (10) is stopped, the refrigerant charged in the refrigerant circuit (20) condenses at the lowest temperature portion of the refrigerant circuit (20) and accumulates in that portion. . For this reason, when the refrigeration apparatus (10) is stopped and the room temperature is lower than the outside air temperature, the refrigerant charged in the refrigerant circuit (20) It collects in the direction of the use side circuit (22) installed indoors rather than the circuit (21). That is, in this state, it can be estimated that the amount of refrigerant that accumulates in the heat source side circuit (21) provided with the compressor (30) is not so much.

Therefore, the control means (91) of the second aspect of the present invention is configured to reduce the amount of refrigerant accumulated in the compressor (30) while the detected value of the inside air temperature detecting means (75) is lower than the detected value of the outside air temperature detecting means (72). It is judged that the amount is not so large, and heating of the compressor (30) by the heating means (80) is kept stopped.

3rd invention has a heat source side circuit (21) installed in the outdoors which has a compressor (30) and a heat source side heat exchanger (34), and a utilization side heat exchanger (37). A refrigeration apparatus including a refrigerant circuit (20) connected to a use side circuit (22) installed indoors and performing a refrigeration cycle by circulating refrigerant in the refrigerant circuit (20) is intended. And while the heat source side heat exchanger (34) is configured to exchange heat between the refrigerant and outdoor air, heating means (80) for heating the compressor (30) while the refrigeration apparatus is stopped, The heat exchanger temperature detecting means (73) for detecting the temperature of the heat source side heat exchanger (34), and the detected value of the heat exchanger temperature detecting means (73) is lowered even when the refrigeration apparatus is stopped. During the operation, the control means (91) for holding the heating of the compressor (30) by the heating means (80) in a stopped state is provided.

In the third invention, the heating means (80) heats the compressor (30) while the refrigeration apparatus (10) is stopped, so that the refrigerant in the refrigerant circuit (20) flows into the compressor (30) and condenses. To prevent it. Further, in the present invention, while the detection value of the heat exchanger temperature detection means (73) is decreasing, the control means (91) is also heated by the heating means (80) even when the refrigeration apparatus (10) is stopped. Hold the compressor (30) heated by.

  Here, in a state where the refrigeration apparatus (10) is stopped, the temperatures of the compressor (30) and the heat source side heat exchanger (34) change as the outside air temperature changes. Further, the heat capacity of the compressor (30) is usually larger than the heat capacity of the heat source side heat exchanger (34) for exchanging heat between the outdoor air and the refrigerant. For this reason, the time delay of the temperature change with respect to the change of the outside air temperature is longer in the compressor (30) than in the heat source side heat exchanger (34). Therefore, for example, in the process where the outside air temperature gradually decreases from noon to night, the temperature of the heat source side heat exchanger (34) becomes almost the same value as the outside air temperature, but the temperature of the compressor (30) is higher than the outside air temperature. Is also somewhat higher. That is, while the temperature of the heat source side heat exchanger (34) gradually decreases as the outside air temperature decreases, the temperature of the compressor (30) becomes higher than the temperature of the heat source side heat exchanger (34). .

  On the other hand, while the refrigeration apparatus (10) is stopped, the refrigerant charged in the refrigerant circuit (20) condenses in the portion of the refrigerant circuit (20) where the temperature is the lowest and accumulates in that portion. For this reason, while the temperature of the heat source side heat exchanger (34) gradually decreases, the refrigerant accumulates in the heat source side heat exchanger (34) having a lower temperature than the compressor (30). Therefore, it can be estimated that such a large amount of refrigerant does not accumulate in the compressor (30).

Therefore, the control means (91) of the third invention requires that the amount of refrigerant accumulated in the compressor (30) does not increase so much while the detection value of the heat exchanger temperature detection means (73) is decreasing. Judgment is made and the heating of the compressor (30) by the heating means (80) is kept stopped.

In a fourth aspect based on the third aspect , the use side heat exchanger (37) is configured so that the refrigerant exchanges heat with the room air, and the room temperature detection means (75) for detecting the room temperature is provided. The control means (91) is provided with the heating means (80) by the heating means (80) while the detected value of the inside air temperature detecting means (75) is lower than the detected value of the heat exchanger temperature detecting means (73). The compressor (30) is configured to keep heating in a stopped state.

In the fourth invention, while the detected value of the inside air temperature detecting means (75) is higher than the detected value of the heat exchanger temperature detecting means (73), even if the refrigeration apparatus (10) is stopped, the control means (91) holds the heating of the compressor (30) by the heating means (80) in a stopped state.

  As described above, when the refrigeration apparatus (10) is stopped, the refrigerant charged in the refrigerant circuit (20) condenses at the lowest temperature portion of the refrigerant circuit (20) and accumulates in that portion. . For this reason, when the refrigeration apparatus (10) is stopped and the room temperature is lower than the outside air temperature, the refrigerant charged in the refrigerant circuit (20) It collects in the direction of the use side circuit (22) installed indoors rather than the circuit (21). That is, in this state, it can be estimated that the amount of refrigerant that accumulates in the heat source side circuit (21) provided with the compressor (30) is not so much. Further, as described above, it can be estimated that the temperature of the heat source side heat exchanger (34) is substantially the same value as the outside air temperature.

Therefore, the control means (91) of the fourth invention accumulates in the compressor (30) while the detected value of the inside air temperature detecting means (75) is lower than the detected value of the heat exchanger temperature detecting means (73). It is determined that the amount of the refrigerant does not increase so much, and the heating of the compressor (30) by the heating means (80) is kept stopped.

According to a fifth invention, in any one of the first to fourth inventions, the heating means (80) is an electric heater (55) attached to the compressor (30).

In the fifth invention, the electric heater (55) constitutes the heating means (80). When the electric heater (55) is energized while the refrigeration apparatus (10) is stopped, the compressor (30) is heated by the generated Joule heat.

In a sixth aspect based on any one of the first to fourth aspects, the compressor (30) includes a compression mechanism (61) for compressing the refrigerant and an electric motor (62) for driving the compression mechanism (61). ) Is a hermetic compressor housed in one casing (63), while the heating means (80) energizes the electric motor (62) in an open-phase state by energizing the electric motor (62). ) To generate Joule heat in the electric motor (62) without rotating.

In the sixth invention, the heating means (80) energizes the motor (62) of the compressor (30) in an open phase state. For example, when the motor (62) of the compressor (30) is a three-phase motor (62), the heating means (80) supplies AC power to the motor (62) in a state where one of the three phases is missing. . When the motor (62) of the compressor (30) is energized in an open phase state, the motor (62) does not rotate and only Joule heat is generated. The compressor (30) is heated by Joule heat generated by the electric motor (62) in the casing (63).

  In the present invention, it is determined whether or not more refrigerant is accumulated in the heat source side heat exchanger (34) than in the compressor (30) while the refrigeration apparatus (10) is stopped. If so, the heating of the compressor (30) by the heating means (80) is kept in a stopped state. That is, in the present invention, even when the refrigeration apparatus (10) is stopped, when it can be estimated that there is not much refrigerant accumulated in the compressor (30), the compressor (30) by the heating means (80) The heating is not performed. For this reason, according to the present invention, it is possible to prevent the compressor (30) from being heated in spite of the fact that the refrigerant collected in the compressor (30) is not so much, and the refrigeration apparatus (10) It is possible to reduce the energy required to heat the compressor (30) while the engine is stopped. As a result, according to the present invention, the energy consumption of the refrigeration apparatus (10) while the refrigeration apparatus (10) is stopped can be reduced.

Further, in the second and fourth inventions, it is determined whether or not more refrigerant is accumulated in the utilization side circuit (22) than in the heat source side circuit (21) while the refrigeration apparatus (10) is stopped. Judging, if it is in such a state, the heating of the compressor (30) by the heating means (80) is kept in a stopped state. That is, in these inventions, even when the refrigeration apparatus (10) is stopped, when it can be estimated that there is not much refrigerant accumulated in the heat source side circuit (21) provided with the compressor (30), The compressor (30) is not heated by the heating means (80). Therefore, according to these inventions, it is possible to more reliably avoid a situation where the compressor (30) is heated although it is not necessary, and the refrigeration apparatus (10) while the refrigeration apparatus (10) is stopped ( The energy consumption of 10) can be further reduced.

<< Embodiment of the Invention >>
Describing the embodiments of the present invention. The present embodiment is an air conditioner (10) configured by a refrigeration apparatus according to the present invention.

  As shown in FIG. 1, the air conditioner (10) includes a refrigerant circuit (20). The refrigerant circuit (20) includes an outdoor circuit (21) that is a heat source side circuit, an indoor circuit (22) that is a use side circuit, a liquid side connection pipe (23), and a gas side connection pipe (24). It is configured. The outdoor circuit (21) is accommodated in an outdoor unit (11) installed outdoors. The outdoor unit (11) is provided with an outdoor fan (12). On the other hand, the indoor circuit (22) is accommodated in an indoor unit (13) installed indoors. The indoor unit (13) is provided with an indoor fan (14).

  The outdoor circuit (21) includes a compressor (30), a four-way switching valve (33), an outdoor heat exchanger (34), a receiver (35), and an electric expansion valve (36). Yes. The outdoor circuit (21) is provided with a bridge circuit (40), a liquid side closing valve (25), and a gas side closing valve (26).

  In the outdoor circuit (21), the discharge pipe (32) of the compressor (30) is connected to the first port of the four-way switching valve (33). A high pressure switch (71) is provided on the pipe connecting the discharge pipe (32) and the four-way switching valve (33) of the compressor (30). The suction pipe (31) of the compressor (30) is connected to the second port of the four-way switching valve (33). A third port of the four-way switching valve (33) is connected to one end of the outdoor heat exchanger (34). The other end of the outdoor heat exchanger (34) is connected to the bridge circuit (40). The bridge circuit (40) is connected to a receiver (35), an electric expansion valve (36), and a liquid side closing valve (25). This point will be described later. The fourth port of the four-way switching valve (33) is connected to the gas side closing valve (26).

  The bridge circuit (40) includes four check valves (41 to 44). In this bridge circuit (40), the outflow side of the first check valve (41) and the outflow side of the second check valve (42) are connected to each other, and the inflow side of the second check valve (42) The third check valve (43) is connected to the outflow side, the third check valve (43) is connected to the inflow side of the fourth check valve (44), and the fourth check valve (43) is connected to the outflow side. The outflow side of (44) and the inflow side of the first check valve (41) are connected to each other.

  The other end of the outdoor heat exchanger (34) is connected between the first check valve (41) and the fourth check valve (44) in the bridge circuit (40). A liquid side closing valve (25) is connected between the second check valve (42) and the third check valve (43) in the bridge circuit (40).

  The receiver (35) is a sealed container member formed in a vertically long cylindrical shape. The upper end of the receiver (35) is connected between the first check valve (41) and the second check valve (42) in the bridge circuit (40). The lower end of the receiver (35) is connected between the third check valve (43) and the fourth check valve (44) in the bridge circuit (40) via the electric expansion valve (36).

  The outdoor circuit (21) is provided with a pressure equalizing pipe (50). One end of the pressure equalizing pipe (50) is connected to the receiver (35), and the other end is connected between the outdoor heat exchanger (34) and the bridge circuit (40). The pressure equalizing pipe (50) is provided with a capillary tube (51).

  The indoor circuit (22) is provided with an indoor heat exchanger (37). One end of the indoor circuit (22) is connected to the liquid side shut-off valve (25) via the liquid side communication pipe (23). The other end of the indoor circuit (22) is connected to the gas side shutoff valve (26) via the gas side communication pipe (24). After the installation of the air conditioner (10), the liquid side closing valve (25) and the gas side closing valve (26) are always opened.

  The compressor (30) is a high-pressure dome type hermetic compressor. Specifically, in the compressor (30), a compression mechanism (61) that is a scroll type fluid machine and an electric motor (62) that drives the compression mechanism (61) are in a vertically long and cylindrical sealed container shape. It is stored in the formed casing (63). The refrigerant sucked from the suction pipe (31) is directly introduced into the compression mechanism (61). The refrigerant compressed by the compression mechanism (61) is once discharged into the casing (63) and then sent out from the discharge pipe (32).

  The electric motor (62) of the compressor (30) is constituted by a three-phase synchronous motor which is a kind of AC electric motor (62). Electric power is supplied to the electric motor (62) through an inverter (not shown). When the output frequency of the inverter is changed, the rotation speed of the electric motor (62) changes and the capacity of the compressor (30) changes.

  Both the outdoor heat exchanger (34) and the indoor heat exchanger (37) are cross-fin type fin-and-tube heat exchangers. The outdoor heat exchanger (34) forms a heat source side heat exchanger, and exchanges heat between the refrigerant in the refrigerant circuit (20) and outdoor air supplied by the outdoor fan (12). On the other hand, the indoor heat exchanger (37) constitutes a use side heat exchanger, and exchanges heat between the refrigerant in the refrigerant circuit (20) and the indoor air supplied by the indoor fan (14).

  The four-way switching valve (33) includes a state in which the first port and the third port communicate with each other and a state in which the second port and the fourth port communicate with each other (state indicated by a solid line in FIG. 1), and the first port And the fourth port communicate with each other and the second port and the third port communicate with each other (state indicated by a broken line in FIG. 1).

  The air conditioner (10) is provided with various temperature sensors. The detection value of each temperature sensor is input to the controller (90) and used for operation control of the air conditioner (10).

  Specifically, the outdoor unit (11) is provided with an outdoor air temperature sensor (72) for detecting the temperature of the outdoor air. The outside air temperature sensor (72) constitutes outside air temperature detecting means. The outdoor heat exchanger (34) is provided with an outdoor heat exchanger temperature sensor (73) for detecting the heat transfer tube temperature. The outdoor heat exchanger temperature sensor (73) constitutes an outdoor heat exchange temperature detecting means. The discharge pipe (32) of the compressor (30) is provided with a discharge pipe temperature sensor (74) for detecting the discharge refrigerant temperature of the compressor (30). The indoor unit (13) is provided with an internal air temperature sensor (75) for detecting the temperature of the indoor air. The inside air temperature sensor (75) constitutes an inside air temperature detecting means. The indoor heat exchanger (37) is provided with an indoor heat exchanger temperature sensor (76) for detecting the heat transfer tube temperature. The indoor heat exchanger temperature sensor (76) constitutes an indoor heat exchange temperature detecting means.

  The air conditioner (10) of the present embodiment includes a controller (90). The controller (90) performs capacity control of the compressor (30), opening degree control of the electric expansion valve (36), and the like based on detection values obtained by the temperature sensors.

  The controller (90) includes a heating control unit (91). The heating control unit (91) energizes the motor (62) of the compressor (30) in an open phase state while the air conditioner (10) is stopped (ie, the power is turned off by an input from a remote controller or the like). Is configured to do. Specifically, the AC power with one phase missing is supplied to the electric motor (62). When the electric motor (62) is energized in an open phase, the electric motor (62) does not rotate, but Joule heat is generated by the current flowing through the coil of the electric motor (62). That is, in the air conditioner (10) of the present embodiment, the heating control unit (91) and the electric motor (62) of the compressor (30) constitute the heating means (80).

  Further, the heating control unit (91) constitutes a control means, and whether or not to energize the electric motor (62) while the air conditioner (10) is stopped is determined based on the detected value of the outside air temperature sensor (72). The operation to judge is performed. This operation in the heating control section (91) will be described later.

-Air conditioner operation-
The operation of the air conditioner (10) will be described. The air conditioner (10) performs switching between a cooling operation in which the indoor air is cooled by the indoor heat exchanger (37) and a heating operation in which the indoor air is heated by the indoor heat exchanger (37).

<Cooling operation>
During the cooling operation, the four-way switching valve (33) is switched to the state shown by the solid line in FIG. 1, and the electric expansion valve (36) is adjusted to a predetermined opening. In addition, the outdoor fan (12) and the indoor fan (14) are operated. In this state, the refrigerant circuit (20) performs a refrigeration cycle by circulating the refrigerant.

  The refrigerant discharged from the compressor (30) dissipates heat to the outdoor air in the outdoor heat exchanger (34), condenses, passes through the first check valve (41) of the bridge circuit (40), and receives the receiver (35). Flow into. The refrigerant flowing out of the receiver (35) is depressurized when passing through the electric expansion valve (36), and then passes through the third check valve (43) of the bridge circuit (40) to be connected to the liquid side communication pipe (23 ) To the indoor heat exchanger (37).

  In the indoor heat exchanger (37), the refrigerant absorbs heat from the indoor air and evaporates. The indoor air taken into the indoor unit (13) is cooled by the indoor heat exchanger (37) and then sent back into the room. The refrigerant evaporated in the indoor heat exchanger (37) sequentially passes through the gas side communication pipe (24) and the four-way switching valve (33) and is sucked into the compressor (30). The compressor (30) compresses and discharges the sucked refrigerant.

<Heating operation>
During the heating operation, the four-way switching valve (33) is switched to the state shown by the broken line in FIG. 1, and the electric expansion valve (36) is adjusted to a predetermined opening. In addition, the outdoor fan (12) and the indoor fan (14) are operated. In this state, the refrigerant circuit (20) performs a refrigeration cycle by circulating the refrigerant.

  The refrigerant discharged from the compressor (30) flows into the indoor heat exchanger (37) through the four-way switching valve (33) and the gas side connection pipe (24). In the indoor heat exchanger (37), the refrigerant dissipates heat to the indoor air and condenses. The indoor air taken into the indoor unit (13) is heated by the indoor heat exchanger (37) and then sent back into the room.

  The refrigerant condensed in the indoor heat exchanger (37) sequentially passes through the liquid side connection pipe (23) and the second check valve (42) of the bridge circuit (40) and flows into the receiver (35). The refrigerant flowing out of the receiver (35) is decompressed when passing through the electric expansion valve (36), and then passes through the fourth check valve (44) of the bridge circuit (40) to the outdoor heat exchanger (34). Flow into. The refrigerant flowing into the outdoor heat exchanger (34) absorbs heat from the outdoor air and evaporates, and then is sucked into the compressor (30). The compressor (30) compresses and discharges the sucked refrigerant.

-Control operation of the heating controller-
While the air conditioner (10) is stopped, the heating control unit (91) of the controller (90) energizes the motor (62) of the compressor (30) in an open phase state to heat the compressor (30). Perform the action.

  Here, while the air conditioner (10) is stopped, the refrigerant in the refrigerant circuit (20) condenses and accumulates at the lowest temperature in the refrigerant circuit (20). For this reason, in some cases, the liquid refrigerant accumulates in the casing (63) of the compressor (30).

  On the other hand, the compressor (30) is a hermetic compressor. That is, in the compressor (30), refrigeration oil is stored in the casing (63). During operation of the compressor (30), the refrigeration oil stored in the casing (63) is supplied to the compression mechanism (61) and used for lubrication. If the refrigerant accumulates in the casing (63) while the compressor (30) is stopped, the refrigerant dissolves in the refrigeration oil and the viscosity of the refrigeration oil decreases. When the compressor (30) is started in this state, refrigeration oil having a low viscosity is supplied to the compression mechanism (61), which may cause troubles such as seizure. In addition, the refrigerating machine oil dissolved in the refrigerating machine oil may rapidly evaporate, and the refrigerating machine oil may be in a foamed state and a sufficient amount of refrigerating machine oil may not be supplied to the compression mechanism (61).

  Therefore, the heating control unit (91) performs an operation of energizing the motor (62) of the compressor (30) in an open phase state while the air conditioner (10) is stopped. When the motor (62) of the compressor (30) is energized in an open phase state, the motor (62) does not rotate, but current flows through the coil of the motor (62), and Joule heat is generated and compressed by the Joule heat. The machine (30) is warmed. As a result, the amount of refrigerant that flows into the compressor (30) and dissolves in the refrigerating machine oil while the air conditioner (10) is stopped is reduced, and a decrease in the viscosity of the refrigerating machine oil is suppressed.

  Moreover, a heating control part (91) judges whether it energizes to an electric motor (62) during the stop of an air conditioner (10) based on the detected value of an external temperature sensor (72). The operation of the heating control unit (91) will be described.

A heating control part (91) will monitor the detected value (namely, outside temperature) of an outside temperature sensor (72), if an air conditioner (10) will be in a halt condition. Specifically, the heating control unit (91) samples the detection value of the outside air temperature sensor (72) every predetermined time, the latest detection value T ₀ (that is, the current outside air temperature) and the previous detection value T _1. (I.e., the outside temperature before a predetermined time). Then, the heating control unit (91) performs the operation on the electric motor (62) of the compressor (30) while the latest detection value is lower than the previous detection value (that is, while T ₀ <T ₁ ). While the energization is stopped, the motor of the compressor (30) while the latest detection value is equal to or higher than the previous detection value (that is, while T ₀ ≧ T ₁ ). Execute energization in the open phase state for (62). That is, the heating control unit (91) keeps the energization of the motor (62) of the compressor (30) in a stopped state while the detection value of the outside air temperature sensor (72) continues to decrease, and the outside air temperature sensor (72) ) Is energized to the motor (62) of the compressor (30) while the detected value is constant or increased.

  The operation of the heating control unit (91) will be specifically described by taking as an example a case where the air conditioner (10) is stopped all day in an intermediate period such as spring or final period.

  As indicated by the solid line in FIG. 2, the outside air temperature changes approximately periodically. That is, the outside temperature gradually decreases from noon to midnight, while the outside temperature gradually increases from midnight to noon.

  The outdoor heat exchanger (34) is a heat exchanger that exchanges heat between the refrigerant and the outdoor air, and thus has a large surface area in contact with the outdoor air. The outdoor heat exchanger (34) is usually composed of a member made of a metal having a relatively high thermal conductivity, such as aluminum or copper, and has a relatively small heat capacity. For this reason, when the outside air temperature changes, the temperature of the outdoor heat exchanger (34) also changes almost simultaneously. That is, the temperature of the outdoor heat exchanger (34) is approximately the same value as the outside air temperature.

  On the other hand, the mass of the compressor (30) is significantly larger than the mass of the outdoor heat exchanger (34), and the surface area of the compressor (30) is significantly smaller than the surface area of the outdoor heat exchanger (34). In addition, many members constituting the compressor (30) are made of steel or cast iron having a relatively low thermal conductivity. Therefore, the heat capacity of the compressor (30) is usually much larger than the heat capacity of the outdoor heat exchanger (34). Furthermore, the compressor (30) is often covered with a heat insulating material such as glass wool. For this reason, the temperature change of the compressor (30) follows the change in the outside air temperature with a delay, as shown by a one-dot chain line in FIG. That is, while the outside air temperature gradually decreases, the temperature of the compressor (30) becomes higher than the temperature of the outdoor heat exchanger (34) (≈outside air temperature).

  As described above, while the air conditioner (10) is stopped, the refrigerant in the refrigerant circuit (20) condenses and accumulates at the lowest temperature in the refrigerant circuit (20). For this reason, while the outside air temperature gradually decreases, the refrigerant accumulates in the outdoor heat exchanger (34) having a temperature lower than that of the compressor (30). That is, while the outside air temperature gradually decreases, the amount of refrigerant entering the compressor (30) does not increase so much even if the compressor (30) is not heated. Therefore, the heating control unit (91) keeps the energization of the compressor (30) to the electric motor (62) until the time t1 in FIG. 2 is reached.

  Since the temperature change of the compressor (30) follows the change of the outside air temperature, while the outside air temperature gradually rises, the temperature of the compressor (30) becomes the temperature of the outdoor heat exchanger (34) (≒ It becomes lower than outside temperature. In such a state, the refrigerant in the refrigerant circuit (20) may accumulate in the compressor (30), not in the outdoor heat exchanger (34), so the heating control unit (91) is not connected to the compressor (30). Energization of the electric motor (62) in a phase-losing state is executed. In the example of FIG. 2, the heating control unit (91) starts energizing the electric motor (62) of the compressor (30) at time t1, and the electric motor of the compressor (30) while the outside air temperature continues to rise. Continue energizing to (62). When the outside air temperature begins to decrease again at time t2, the heating control unit stops energization of the electric motor (62) of the compressor (30).

  If the air conditioner (10) is turned on while the motor (62) of the compressor (30) is energized in an open phase, the heating controller (91) compresses Immediately stop energization of the machine (30) in the open phase with respect to the motor (62). And a controller (90) starts supply of the three-phase alternating current with respect to the electric motor (62) of a compressor (30), drives a compression mechanism (61) with an electric motor (62), and starts the refrigerating cycle operation | movement of a refrigerant circuit. .

-Effect of the embodiment-
In this embodiment, it is determined whether or not more refrigerant is accumulated in the outdoor heat exchanger (34) than in the compressor (30) while the air conditioner (10) is stopped. Then, the heating control unit (91) keeps the energization of the compressor (30) to the electric motor (62) in a stopped state. That is, in this embodiment, even when the air conditioner (10) is stopped, when it can be estimated that there is not much refrigerant accumulated in the compressor (30), the electric motor (62) of the compressor (30) The energization in the open phase state is stopped. Therefore, according to the present embodiment, the compressor (30) is heated even though the compressor (30) is not heated so that the amount of refrigerant accumulated therein is not so much. This can prevent the electric power required to heat the compressor (30) while the air conditioner (10) is stopped. Therefore, according to the present embodiment, power consumption (so-called standby power) while the air conditioner (10) is stopped can be reduced.

-Modification 1 of embodiment-
In the heating control unit (91) of the present embodiment, the detected value of the outdoor heat exchanger temperature sensor (73) is used instead of the detected value of the outside air temperature sensor (72) to the electric motor (62) of the compressor (30). It may be determined whether or not energization is performed.

  While the air conditioner (10) is stopped, the heating control unit (91) of the present modification monitors the detection value of the outdoor heat exchanger temperature sensor (73). And a heating control part (91) stops electricity supply in the open phase state with respect to the electric motor (62) of a compressor (30), while the detected value of an outdoor heat exchanger temperature sensor (73) continues falling. On the other hand, while the detected value of the outdoor heat exchanger temperature sensor (73) remains constant or continues to rise, energization of the compressor (30) to the electric motor (62) is performed in an open phase state.

  As described above, while the air conditioner (10) is stopped, the temperature of the outdoor heat exchanger (34) becomes substantially the same value as the outside air temperature. For this reason, when the temperature of the outdoor heat exchanger (34) continues to decrease gradually, the outside air temperature continues to decrease. In such a state, the temperature of the compressor (30) decreases to the outdoor heat exchanger (34). It can be inferred that it is higher than the temperature in (34). Therefore, the heating control unit (91) of this modification determines that a large amount of refrigerant does not accumulate in the compressor (30) while the temperature of the outdoor heat exchanger (34) continues to decrease gradually. The energization of the compressor (30) to the electric motor (62) is held in a stopped state to avoid unnecessary power consumption.

-Modification 2 of embodiment-
In the heating control unit (91) of the present embodiment, the compression is performed while the latest detection value is lower than the previous detection value or when both are the same value (that is, T ₀ ≦ T ₁ ). While the power supply to the motor (62) of the machine (30) is stopped, compression is performed while the latest detection value is higher than the previous detection value (that is, T ₀ > T ₁ ). The energization of the machine (30) with respect to the electric motor (62) in an open phase state may be executed. In other words, the heating control unit (91) of the present modified example is in a state where energization to the electric motor (62) of the compressor (30) is stopped while the detected value of the outside air temperature sensor (72) is lowered or constant. The electric power to the electric motor (62) of the compressor (30) is executed while the detected value of the outside air temperature sensor (72) is increasing.

《 Reference technology 》
Reference technology will be described. Here, about an air conditioner (10) of this reference technology, a different point from the embodiment of the present invention is explained.

As shown in FIG. 3, in the air conditioner (10) of the present reference technology , the compressor temperature sensor (77) is attached to the casing (63) of the compressor (30). The compressor temperature sensor (77) constitutes compressor temperature detecting means for detecting the temperature of the compressor (30).

The heating control unit (91) of this reference technology determines whether the electric motor (62) is energized while the air conditioner (10) is stopped, whether the detected value of the outside air temperature sensor (72) and the compressor temperature sensor (77). An operation is performed based on the detected value. The operation of the heating control unit (91) will be described.

When the air conditioner (10) is stopped, the heating control unit (91) detects the detected value of the outside air temperature sensor (72) (that is, the outside temperature) and the detected value of the compressor temperature sensor (77) (that is, the compressor). (30) temperature).
Specifically, the heating control section (91), the the detection value T _OA of the outdoor air temperature sensor (72) and the detection value T _C of the compressor temperature sensor (77) is sampled at predetermined time intervals, comparing both values To do. Then, the heating control section (91) while the detection value _{T OA} of the outdoor air temperature sensor (72) is below the detection value _{T C} of the compressor temperature sensor (77) _(i.e., becomes T OA _{<T C} while while) is to stop the energization of the electric motor (62) of the compressor (30) are the detected value T _OA of the outdoor air temperature sensor (72) is it equal to the detection value T _C of the compressor temperature sensor (77) while above (i.e., while a T _OA ≧ T _C) performs the energization in the open phase state to the electric motor (62) of the compressor (30).

  The operation of the heating control unit (91) will be specifically described by taking as an example a case where the air conditioner (10) is stopped all day in an intermediate period such as spring or final period.

  As indicated by the solid line in FIG. 4, the outside air temperature changes approximately periodically. And since the heat capacity of the outdoor heat exchanger (34) is relatively small and the surface area in contact with the outdoor air is large, the temperature thereof is substantially the same as the outside air temperature. On the other hand, while the air conditioner (10) is stopped, the refrigerant accumulates in the outdoor circuit (21) toward the lower temperature of the outdoor heat exchanger (34) and the compressor (30). Therefore, the heating control unit (91) keeps the energization of the compressor (30) to the electric motor (62) until the time t1 in FIG. 4 is reached.

  When the temperature of the compressor (30) becomes the same as the temperature of the outdoor heat exchanger (34) at time t1, the heating control unit (91) energizes the compressor (30) in the open phase state with respect to the electric motor (62). To start. Since the temperature of the compressor (30) continues to be lower than the temperature of the outdoor heat exchanger (34) while the outside air temperature gradually increases thereafter, the heating control unit (91) is connected to the compressor (30). Continue energizing the motor (62). When the temperature of the compressor (30) exceeds the temperature of the outdoor heat exchanger (34) at time t2, the heating control unit (91) stops energization of the electric motor (62) of the compressor (30).

As described above, the heating control unit (91) of the present reference technology is configured so that the electric motor of the compressor (30) is used only when the amount of refrigerant accumulated in the compressor (30) is estimated to increase in the outdoor circuit (21). Energization is performed in an open phase state with respect to (62). Therefore, according to the present reference technique , as in the case of the embodiment of the present invention, useless heating of the compressor (30) can be avoided, and electric power consumed while the air conditioner (10) is stopped ( That is, standby power) can be reduced.

-Modification of reference technology 1-
In the heating control unit (91) of this reference technology , the detected value of the outdoor heat exchanger temperature sensor (73) is used instead of the detected value of the outside air temperature sensor (72) to the electric motor (62) of the compressor (30). It may be determined whether or not energization is performed.

  While the air conditioner (10) is stopped, the heating control unit (91) of the present modification monitors the detection value of the outdoor heat exchanger temperature sensor (73) and the detection value of the compressor temperature sensor (77). Then, the heating control unit (91) performs the operation on the electric motor (62) of the compressor (30) while the detected value of the compressor temperature sensor (77) exceeds the detected value of the outdoor heat exchanger temperature sensor (73). While the energization in the open phase state is stopped, while the detected value of the compressor temperature sensor (77) is equal to or lower than the detected value of the outdoor heat exchanger temperature sensor (73), the compressor (30) Energization of the electric motor (62) in a phase-open state is executed.

  As described above, while the air conditioner (10) is stopped, the refrigerant accumulates in the outdoor circuit (21) toward the lower temperature of the outdoor heat exchanger (34) and the compressor (30). Therefore, the heating control unit (91) of the present modification has a large amount in the compressor (30) while the detected value of the compressor temperature sensor (77) exceeds the detected value of the outdoor heat exchanger temperature sensor (73). It is determined that the refrigerant does not accumulate, and energization of the compressor (30) to the electric motor (62) is held in a stopped state, thereby avoiding unnecessary power consumption.

<< Other Embodiments >>
In the above embodiment and the reference technique , the following configuration may be adopted.

-First modification-
In the above embodiment and the reference technique , the compressor (30) is heated by energizing the electric motor (62) of the compressor (30) in an open phase state, but instead, the compressor (30) An electric heater (55) may be attached to the compressor and the compressor (30) may be heated by energizing the electric heater (55). In this modification, the electric heater (55) and the heating control unit (91) of the controller (90) constitute the heating means (80).

  As shown in FIG. 5, the electric heater (55) is wound around the lower part of the casing (63) of the compressor (30). When the electric heater (55) is energized, Joule heat is generated and the compressor (30) is warmed. In this modification, the heating control unit (91) of the controller (90) performs an operation of supplying electric power to the electric heater (55) while the air conditioner (10) is stopped.

As described above, the heating control unit (91) of the embodiment and the reference technology determines whether the compressor (30) needs to be heated while the air conditioner (10) is stopped, based on the outside air temperature sensor (72). This is performed based on the change tendency of the detected value and the relationship between the detected value of the outside air temperature sensor (72) and the detected value of the compressor temperature sensor (77). When the heating control unit (91) of this modification makes the same determination as in the above embodiment and the reference technique, and it is determined that the compressor (30) needs to be heated while the air conditioner (10) is stopped Energize the electric heater (55).

-Second modification-
In the embodiment, the reference technique, and the first modification, the heating control unit (91) of the controller (90) determines whether the compressor (30) needs to be heated while the air conditioner (10) is stopped. In doing so, the detected value of the internal air temperature sensor (75) may be further taken into consideration.

  Specifically, the heating control unit (91) of the present modification compares the detected value of the inside air temperature sensor (75) with the detected value of the outside air temperature sensor (72) while the air conditioner (10) is stopped. Even when the detected value of the air temperature sensor (72) is equal to or higher than the detected value of the internal air temperature sensor (75), the heating of the compressor (30) is held in a stopped state.

For example, when this modification is applied to the above-described embodiment , the heating control unit (91) has a first condition that the detected value of the inside air temperature sensor (75) is lower than the detected value of the outside air temperature sensor (72), If any one of the second conditions that the detected value of the outside air temperature sensor (72) continues to decrease is established while the air conditioner (10) is stopped, the motor (62) of the compressor (30) ) Keep the energization in the open phase state for) in a stopped state.

In addition, when the present modification is applied to the above-described reference technique , the heating control unit (91) includes a first condition that the detected value of the inside air temperature sensor (75) is lower than the detected value of the outside air temperature sensor (72), and the outside condition. If any one of the second conditions that the detected value of the air temperature sensor (72) is lower than the detected value of the compressor temperature sensor (77) is established while the air conditioner (10) is stopped, the compressor ( 30) Stop energization of the motor (62) in the open phase state in the stopped state.

  As described above, while the air conditioner (10) is stopped, the refrigerant in the refrigerant circuit (20) condenses and accumulates at the lowest temperature in the refrigerant circuit (20). Then, in a state where the detected value of the internal air temperature sensor (75) (that is, the indoor air temperature) is lower than the detected value of the outdoor air temperature sensor (72) (that is, the outdoor air temperature), the indoor circuit (22) is connected to the outdoor circuit (21 ), The refrigerant flows into the indoor circuit (22) and accumulates. That is, in this state, it can be estimated that so much refrigerant does not accumulate in the outdoor circuit (21) where the compressor (30) is installed. Therefore, in this modification, the compressor (30) is stopped and compressed even when the detected value of the internal air temperature sensor (75) falls below the detected value of the external air temperature sensor (72) while the air conditioner (10) is stopped. The machine (30) is not heated unnecessarily.

  In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

  As described above, the present invention is useful for a refrigeration apparatus provided with means for heating a compressor during stoppage.

It is a refrigerant circuit figure which shows the structure of the air conditioner in embodiment . It is a time and relational diagram temperature for explaining a control operation the heating control unit in the implementation form performed. It is a refrigerant circuit figure which shows the structure of the air conditioner in a reference technique . It is a relationship diagram of the time and temperature for demonstrating the control operation | movement which the heating control part in a reference technique performs. It is a refrigerant circuit figure which shows the structure of the air conditioner in the 1st modification of other embodiment.

Explanation of symbols

10 Air conditioner (refrigeration equipment)
20 Refrigerant circuit
21 Outdoor circuit (heat source side circuit)
22 Indoor circuit (use side circuit)
30 Compressor
34 Outdoor heat exchanger (heat source side heat exchanger)
37 Indoor heat exchanger (use side heat exchanger)
55 Electric heater
61 Compression mechanism
62 Electric motor
63 Casing
72 Outside temperature sensor (outside temperature detection means)
73 Outdoor heat exchanger temperature sensor (heat exchanger temperature detection means)
75 Inside air temperature sensor
77 Compressor temperature sensor (Compressor temperature detection means)
80 Heating means
91 Heating control unit (control means)

Claims (4)

Heat source side circuit (21) installed outdoors with compressor (30) and heat source side heat exchanger (34), and use installed indoors with use side heat exchanger (37) A refrigeration apparatus comprising a refrigerant circuit (20) connected to a side circuit (22) and performing a refrigeration cycle by circulating refrigerant in the refrigerant circuit (20),
While the heat source side heat exchanger (34) is configured to exchange heat between the refrigerant and outdoor air,
Heating means (80) for heating the compressor (30) while the refrigeration apparatus is stopped;
Outdoor temperature detection means (72) for detecting outdoor air temperature;
Control for maintaining heating of the compressor (30) by the heating means (80) in a stopped state while the detected value of the outside air temperature detecting means (72) is decreasing even when the refrigeration apparatus is stopped Means (91). In claim 1 ,
The use side heat exchanger (37) is configured to exchange heat between the refrigerant and room air,
Inside air temperature detecting means (75) for detecting the indoor air temperature is provided,
While the detected value of the inside air temperature detecting means (75) is lower than the detected value of the outside air temperature detecting means (72), the control means (91) heats the compressor (30) by the heating means (80). The refrigeration apparatus is configured to hold the battery in a stopped state. Heat source side circuit (21) installed outdoors with compressor (30) and heat source side heat exchanger (34), and use installed indoors with use side heat exchanger (37) A refrigeration apparatus comprising a refrigerant circuit (20) connected to a side circuit (22) and performing a refrigeration cycle by circulating refrigerant in the refrigerant circuit (20),
While the heat source side heat exchanger (34) is configured to exchange heat between the refrigerant and outdoor air,
Heating means (80) for heating the compressor (30) while the refrigeration apparatus is stopped;
Heat exchanger temperature detecting means (73) for detecting the temperature of the heat source side heat exchanger (34);
Even when the refrigeration system is stopped, heating of the compressor (30) by the heating means (80) is held in a stopped state while the detection value of the heat exchanger temperature detection means (73) is decreasing. And a control means (91). In claim 3 ,
The use side heat exchanger (37) is configured to exchange heat between the refrigerant and room air,
Inside air temperature detecting means (75) for detecting the indoor air temperature is provided,
While the detected value of the inside air temperature detecting means (75) is lower than the detected value of the heat exchanger temperature detecting means (73), the control means (91) is configured to compress the compressor (30) by the heating means (80). The refrigeration apparatus is configured to hold the heating in a stopped state.

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