JP4736970B2 - Air conditioner - Google Patents

Description

  The present invention relates to control of an air conditioner.

In a conventional air conditioner, the amount of heat generated is controlled by controlling the energization time of the electric heater according to the outdoor air temperature (see, for example, Patent Document 1).
JP 7-43027 A

  However, in the conventional air conditioner, it is possible to control to low power by controlling the energization time, but in order to increase the temperature of the cryogenic compressor, the output of the electric heater must be increased. In this case, the watt density of the heater is limited in terms of the reliability of the electric heater (for example, 40 W / m), and it is necessary to lengthen the heater when raising the temperature. In this case, the heater length becomes extremely longer than the outer peripheral length of the compressor, so that the installation becomes complicated, or the electric heater having a special length is required because it is out of the standard specification. In addition, there are disadvantages such as complicated equipment and high price due to the addition of an energization time control circuit.

  The present invention solves the above-mentioned conventional problems, and is effective by providing a plurality of electric heaters in the compressor and changing the number of electric heaters to be energized according to the value of the compressor outer temperature when the compressor is stopped. Another object of the present invention is to provide an air conditioner that can prevent liquid refrigerant from accumulating inside the compressor and that is not complicated and expensive.

In order to solve the conventional problems, an air conditioner of the present invention has a compressor, an outdoor heat exchanger, an outdoor fan, a four-way valve, an outdoor unit having a throttle device, an indoor heat exchanger, and an indoor fan. An air conditioner connected to an indoor unit, the discharge temperature detecting device provided outside the compressor for detecting the discharge temperature, the compressor includes a first crankcase heater and a second crankcase heater; A first heater temperature setting device and a second heater temperature setting device in which temperatures for determining energization of the first crankcase heater and the second crankcase heater are set, and are second than the first crankcase heater. The crankcase heater is attached to the upper part, and the temperature detected by the discharge temperature detection device is lower than the temperature set in the first heater temperature setting device while the compressor is stopped. If the temperature detected by the discharge temperature detection device is lower than the temperature set in the second heater temperature setting device, the first crankcase heater and the second crankcase heater are energized. By energizing the crankcase heater, liquid refrigerant is effectively prevented from accumulating inside the compressor.

The air conditioner of the present invention increases the number of electric heaters that are energized when the compressor outer temperature is low while the compressor is stopped, and effectively prevents liquid refrigerant from accumulating inside the compressor. to prevent the damage can improve reliability, along with if high temperature can be reduced power consumption by reducing the number of energizing the heater, the temperature rise of the electrical components and the like disposed around the compressor The reliability and life are improved, and the use of standard electric heaters prevents the air conditioner from becoming complicated and expensive.

1st invention is an air conditioning apparatus which connected the outdoor unit which has a compressor, an outdoor heat exchanger, an outdoor air blower, a 4-way valve, an expansion device, and an indoor unit which has an indoor heat exchanger and an indoor air blower. A discharge temperature detecting device for detecting a discharge temperature provided outside the compressor, a first crankcase heater, a second crankcase heater, a first crankcase heater, and a second crankcase in the compressor A first heater temperature setting device and a second heater temperature setting device in which a temperature for determining energization of the heater is set, and a second crankcase heater is attached to the upper portion of the compressor rather than the first crankcase heater. When the temperature detected by the discharge temperature detection device is lower than the temperature set in the first heater temperature setting device, the first crankcase heater is energized. Lower than the temperature at which the temperature detected by the discharge temperature detector is set in the second heater temperature setting device, a first crank case heater and a second
When the compressor outer temperature is low while the compressor is stopped, the number of electric heaters to be energized is increased, effectively preventing liquid refrigerant from accumulating inside the compressor, Damage to the compressor can be prevented and reliability can be improved. In addition, when the temperature is high, power consumption can be reduced by reducing the number of energized heaters, and an increase in the temperature of electrical components and the like arranged around the compressor can be suppressed, improving reliability and life.

In the second invention, in particular in the first invention, the first crankcase heater is always energized when the compressor is stopped, so that the electric heater is reliably energized when the compressor is stopped even when the sensor fails. By preventing liquid refrigerant from accumulating inside the machine, damage to the compressor can be prevented and reliability can be improved. Further, by using the B contact of the compressor relay for this always-on circuit, the cost can be reduced.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the present embodiment.

(Embodiment 1)
1 is a refrigeration cycle diagram of an air-conditioning apparatus according to Embodiment 1 of the present invention, FIG. 2 is a control block diagram, and FIG. 3 is a flowchart of crankcase energization.

  In FIG. 1, the outdoor unit 1 includes a compressor 2, an outdoor heat exchanger 3, an outdoor blower 4, a refrigerant liquid pipe 5a, a refrigerant gas pipe 6a, a cooling / heating switching four-way valve 7, and a throttle device 8. Is provided. The outdoor unit 1 includes an outdoor heat exchanger temperature detection device 9 that detects the temperature of the outdoor heat exchanger 3, a discharge temperature detection device 10 that detects the discharge temperature of the compressor 2, and a first electric power supply to the compressor 2. A plurality of heaters (hereinafter referred to as first crankcase heaters) 11a and second electric heaters (hereinafter referred to as second crankcase heaters) 11b are provided (for example, two here).

  On the other hand, the indoor unit 12 includes an indoor blower 13, an indoor heat exchanger 14, an indoor heat exchanger temperature detecting device 15 for detecting the temperature of the indoor heat exchanger 14, and an indoor suction temperature detecting device for detecting the room temperature of the room. 16 and an operation setting device 17 capable of setting an operation mode (cooling, dehumidification or heating) desired by a resident, room temperature, operation or stop, air volume and direction. And the outdoor unit 1 and the indoor unit 12 are connected by the connection piping 5b and 6b, and the refrigerating cycle is comprised.

  In the refrigeration cycle, during cooling or dehumidifying operation, the refrigerant discharged from the compressor 2 flows to the outdoor heat exchanger 3 through the four-way valve 7, and exchanges heat with outdoor air by the outdoor heat exchanger 3 by the outdoor fan 4. The refrigerant is condensed and liquefied, and then decompressed by passing through the expansion device 8 through the refrigerant liquid pipe 5a, evaporates in the indoor heat exchanger 14, passes through the refrigerant gas pipe 6a, and passes through the four-way valve 7. It is sucked into the compressor 2 again. During the heating operation, the refrigerant discharged from the compressor 2 flows to the indoor heat exchanger 14 via the four-way valve 7, and heat is exchanged with the indoor air in the indoor heat exchanger 14 by the indoor blower 13 to be condensed and liquefied. Then, the refrigerant depressurized by passing through the expansion device 8 evaporates in the outdoor heat exchanger 3 and then is sucked into the compressor 2 again through the four-way valve 7.

Next, the control of the present invention will be described with reference to FIGS. In FIG. 2, the control device 18 of the air conditioner of the present invention includes an operation mode changeover switch 19 (cooling, dehumidification or heating) desired by a resident, an indoor temperature setting switch 20, an operation stop switch 21, and an air volume setting switch 22. And an operation mode storage device 24 that stores signals of the operation setting device 17 constituted by the wind direction setting switch 23, an indoor heat exchanger temperature detection device 15, an indoor suction temperature detection device 16, and an outdoor heat exchanger detection device 9. A compressor discharge temperature detecting device 10, a first heater temperature setting device 25a for determining energization of each of the first crankcase heater 11a and the second crankcase heater 11b, a second heater temperature setting device 25b, A determination device 26 that receives the above signals every sampling time and determines the operation of the compressor 2, the indoor fan 12, the outdoor fan 4, and the like; The signal of the constant unit 26, the compressor 2 and the first crank case heater 11a, a second crank case heater 11b and the indoor blower 13, and an output relay circuit 27 for driving the outdoor blower 4 and the like.

  When the resident selects cooling, dehumidification or heating with the operation mode changeover switch 19 and starts operation, the output relay circuit 27 is driven by the signals from the operation mode storage device 24, the indoor suction temperature detection device 16, and the indoor temperature setting device 20. In FIG. 3, when the compressor 2 is stopped (Y in S2), the detection Td (S3) of the compressor discharge temperature detection device 10 is set in the first heater temperature setting device 25a. If the temperature is lower (here, for example, Td <20 ° C.) (Y in S4), the first crankcase heater 11a is energized (S6), and the detection Td (S3) of the compressor discharge temperature detecting device 10 is the second. When the temperature is lower than the temperature set in the heater temperature setting device 25b (here, for example, Td <0 ° C.) (Y in S5), the first crankcase heater 11a and the second crankcase Energizing the heater 11b (S6, S7). When the compressor 2 starts operation, the heater is deenergized.

  According to the above configuration, when the compressor outer temperature when the compressor is stopped is low, power consumption can be reduced by increasing the number of energized crancase heaters and decreasing the number of energized heaters as the temperature increases. It is possible to effectively prevent liquid refrigerant from accumulating inside the compressor, and it is possible to prevent damage to the compressor and improve reliability. In addition, when the temperature is high, by reducing the number of energized heaters, it is possible to suppress an increase in the temperature of electrical components and the like arranged around the compressor, and the reliability and life are improved. Further, when the amount of heat required for the crankcase heater is large, it is possible to suppress an increase in price by using a plurality of standard specifications without setting a particularly large specification.

  Here, the compressor outer temperature is substituted and controlled by the compressor discharge temperature, but a temperature detection device may be directly attached to the compressor outer wall, or it is judged not by the compressor outer temperature but by the outdoor air temperature. But it has the same effect.

(Embodiment 2)
Since the refrigeration cycle diagram of the air-conditioning apparatus according to Embodiment 2 of the present invention is the same as that of Embodiment 1, description thereof is omitted. FIG. 4 is a control block diagram of the air conditioner according to Embodiment 2, and FIG. 5 is a relay circuit diagram of the compressor and a schematic external view of the compressor, and also shows a function of energizing the crankcase heater. FIG. 6 is a flowchart of crankcase energization.

  4, the control device 18 of the air conditioner of the present invention includes an operation mode changeover switch 19 (cooling, dehumidification or heating) desired by a resident, an indoor temperature setting switch 20, an operation stop switch 21, and an air volume setting switch 22. And an operation mode storage device 24 that stores signals of the operation setting device 17 constituted by the wind direction setting switch 23, an indoor heat exchanger temperature detection device 15, an indoor suction temperature detection device 16, and an outdoor heat exchanger detection device 9. The compressor discharge temperature detecting device 10, the second heater temperature setting device 25b for determining the energization of the second crankcase heater 11b, the compressor 2, the indoor blower 12, The determination device 26 that determines the operation of the outdoor blower 4 and the like, and the signal from the determination device 26, the compressor 2, the second crankcase heater 11 b, Wind machine 13 has an output relay circuit 27 for driving the outdoor blower 4 and the like. As shown in FIG. 5, the first crankcase heater 11a is connected to the B contact of the relay 27a of the compressor 2 (the B contact side is on when the compressor relay A contact is off), and when the compressor 2 is turned off. The first crankcase heater 11a is configured to be energized.

When the resident selects cooling, dehumidification or heating with the operation mode changeover switch 19 and starts operation, the output relay circuit 27 is driven by the signals from the operation mode storage device 24, the indoor suction temperature detection device 16, and the indoor temperature setting device 20. 6, when the compressor 2 is stopped (Y in S9), the first crankcase heater 11a is energized (S10), and the detection Td ( When S11) is lower than the temperature set in the second heater temperature setting device 25b (here, for example, Td <0 ° C.) (Y in S12), the second crankcase heater 11b is also energized (S13). When the compressor 2 starts operation, the heater is deenergized.

  According to the above configuration, when the compressor outer temperature when the compressor is stopped is low, power consumption can be reduced by increasing the number of energized crancase heaters and decreasing the number of energized heaters as the temperature increases. It is possible to effectively prevent liquid refrigerant from accumulating inside the compressor, and it is possible to prevent damage to the compressor and improve reliability. In addition, when the temperature is high, by reducing the number of energized heaters, it is possible to suppress an increase in the temperature of electrical components and the like arranged around the compressor, and the reliability and life are improved.

In addition, by connecting one Crancase heater to the B contact of the relay of the compressor, the circuit configuration is simplified and the cost can be reduced, and the compressor can be energized even when the compressor temperature sensor fails. Damage to the machine can be prevented and reliability can be improved.

(Embodiment 3)
The refrigeration cycle diagram of the air-conditioning apparatus according to Embodiment 3 of the present invention is the same as that in Embodiment 1 shown in FIG. The control block diagram of FIG. 4 and the flowchart of FIG. 6 are the same. FIG. 7 is a relay circuit diagram of the compressor and a schematic external view of the compressor.

  The control of the present invention will be described with reference to FIG. 4, the control device 18 of the air conditioner of the present invention includes an operation mode changeover switch 19 (cooling, dehumidification or heating) desired by a resident, an indoor temperature setting switch 20, an operation stop switch 21, and an air volume setting switch 22. And an operation mode storage device 24 that stores signals of the operation setting device 17 constituted by the wind direction setting switch 23, an indoor heat exchanger temperature detection device 15, an indoor suction temperature detection device 16, and an outdoor heat exchanger detection device 9. The compressor discharge temperature detecting device 10, the second heater temperature setting device 25b for determining the energization of the second crankcase heater 11b, the compressor 2, the indoor blower 12, The determination device 26 that determines the operation of the outdoor blower 4 and the like, and the signal from the determination device 26, the compressor 2, the second crankcase heater 11 b, Wind machine 13 has an output relay circuit 27 for driving the outdoor blower 4 and the like. As shown in FIG. 7, the first crankcase heater 11 a is connected to the B contact of the relay 27 a of the compressor 2, and the first crankcase heater 11 a is energized when the compressor 2 is turned off. Has been.

The compressor 2 is provided with a first crankcase heater 11a and a second crankcase heater 11b. Since the compressor 2 has an accumulator 28, one must be placed above the accumulator 28. The first crankcase heater 11 a is attached below the accumulator 28, and the second crankcase heater 11 b is attached above the accumulator 28.

When the resident selects cooling, dehumidification or heating with the operation mode changeover switch 19 and starts operation, the output relay circuit 27 is driven by the signals from the operation mode storage device 24, the indoor suction temperature detection device 16, and the indoor temperature setting device 20. 6, when the compressor 2 is stopped (Y in S9), the first crankcase heater 11a is energized (S10), and the detection Td ( When S11) is lower than the temperature set in the second heater temperature setting device 25b (here, for example, Td <0 ° C.) (Y in S12), the second crankcase heater 11b is also energized (S13). When the compressor 2 starts operation, the heater is deenergized.

  According to the above configuration, when the compressor outer temperature when the compressor is stopped is low, power consumption can be reduced by increasing the number of energized crancase heaters and decreasing the number of energized heaters as the temperature increases. It is possible to effectively prevent liquid refrigerant from accumulating inside the compressor, and it is possible to prevent damage to the compressor and improve reliability. In addition, since the liquid refrigerant is stored below the low-temperature compressor refrigerator oil, the liquid refrigerant can be more effectively prevented from accumulating inside the compressor by attaching the energized clan case heater downward. In addition, when the temperature is high, by reducing the number of energized heaters, it is possible to suppress an increase in the temperature of electrical components and the like arranged around the compressor, and the reliability and life are improved.

In addition, by connecting one Crancase heater to the B contact of the relay of the compressor, the circuit configuration is simplified and the cost can be reduced, and the compressor can be energized even when the compressor temperature sensor fails. Damage to the machine can be prevented and reliability can be improved.

  As described above, the air conditioner according to the present invention controls the heater energization amount to the compressor and prevents liquid refrigerant from accumulating inside the compressor, and therefore can be applied to a multi-chamber air conditioner.

Refrigeration cycle diagram in the first to third embodiments of the air-conditioning apparatus of the present invention Control block diagram in the first embodiment Flowchart of crankcase energization in the first embodiment Control block diagram in the second and third embodiments Compressor appearance schematic diagram in the second embodiment Flow chart of crankcase energization in the second and third embodiments Compressor appearance schematic diagram in the third embodiment

DESCRIPTION OF SYMBOLS 1 Outdoor unit 2 Compressor 3 Outdoor heat exchanger 4 Outdoor blower 5 Refrigerant liquid pipe 6 Refrigerant gas pipe 7 Four-way valve 8 Throttle device 9 Outdoor heat exchanger temperature detection device 10 Compressor discharge temperature detection device 11 Indoor unit 12 Indoor blower

Claims (2)

An air conditioner in which an outdoor unit having a compressor, an outdoor heat exchanger, an outdoor fan, a four-way valve, a throttle device, and an indoor unit having an indoor heat exchanger and an indoor fan are connected . A discharge temperature detecting device for detecting a discharge temperature provided in an outer shell; a first crankcase heater and a second crankcase heater in the compressor; the first crankcase heater and the second crankcase heater; A first heater temperature setting device and a second heater temperature setting device in which a temperature for determining energization of the first crankcase heater is set, and the second crankcase heater is attached to an upper portion than the first crankcase heater, and When the compressor is stopped and the temperature detected by the discharge temperature detecting device is lower than the temperature set in the first heater temperature setting device, the first clan When the case heater is energized and the temperature detected by the discharge temperature detection device is lower than the temperature set in the second heater temperature setting device, the first crankcase heater and the second crankcase heater An air conditioner characterized by energizing the air. The compressor Oite at shutdown, air conditioner location according to claim 1, wherein the first crank case heater is always be energized.