JP5138292B2 - Air conditioner - Google Patents

Description

  The present invention is a multi-type air conditioner in which a plurality of indoor units are connected to a single outdoor unit, and in particular, the connected indoor units are diverse and the refrigerant pipe lengths also vary. The present invention relates to an air conditioner suitable for use in air conditioning for buildings.

  In the case of a multi-type air conditioner in which multiple indoor units are connected in parallel to one outdoor unit, the outdoor unit is shipped from the factory with a certain amount of refrigerant filled, and the indoor unit and the outdoor unit are locally installed. The units are installed and connected by refrigerant piping. In particular, what is used for air conditioning for buildings has various types and capacities of indoor units to be connected, and various refrigerant pipe lengths to which the indoor units are connected. For this reason, after installation at the site, an additional amount of refrigerant corresponding to the length of the refrigerant pipe, the model of the connected indoor unit, the capacity, and the like is added.

  As a result, the total amount of refrigerant in the air conditioner is the amount of refrigerant charged at the factory plus the amount of refrigerant additionally charged locally, but the technology to determine whether this is the appropriate amount of refrigerant is It is not well established yet. For this reason, troubles caused by excess or deficiency in the amount of refrigerant have occurred, such as air conditioning performance not being achieved as rated, or abnormal operation in which the pressure increases abnormally. In particular, the refrigerant that is additionally charged locally is the procedure to calculate the charging amount from the refrigerant pipe length and pipe size between the indoor unit and the outdoor unit, and charge the meter, but this is not protected, Or, the piping specifications are unclear and accurate calculations are not possible. Therefore, it is not easy to eliminate all excess and deficiency of the refrigerant charging amount.

Under such circumstances, on the assumption that the required refrigerant amount during cooling operation is larger than the required refrigerant amount during heating operation, all the usage units are cooled, superheat control by the use side expansion valve, and evaporation pressure by the compressor Patents that detect the degree of supercooling of the refrigerant at the outlet of the heat source side heat exchanger by the refrigerant quantity judgment operation mode for performing control, and thereby judge the suitability of the quantity of refrigerant charged in the refrigerant circuit. Proposed by reference 1.
Further, in Patent Document 2, the refrigerant amount is determined without stopping the operation of the refrigeration cycle, and the refrigerant filling operation and the inspection operation are facilitated by displaying the excessive amount and the insufficient amount of the refrigerant amount. What has been proposed is proposed.

JP 2006-23072 A Japanese Patent No. 2997487

  However, the thing of patent document 1 does not consider the influence which the volume of a heat exchanger has on a required refrigerant | coolant amount. Further, in the multi-type air conditioner, not only the refrigerant pipe length as described above, but also the types and capacities of the connected indoor units are various, so the required refrigerant amount in either cooling or heating is It becomes different depending on the combination of refrigerant pipe length / indoor / outdoor unit. Accordingly, there is a face that cannot be determined from the determination result alone that the refrigerant is always filled with an appropriate amount.

Patent Document 1 discloses that, as a result of determining whether or not the amount of refrigerant is appropriate, when the required amount of refrigerant has not been reached, an automatic charging operation is performed to additionally charge the refrigerant. However, nothing is said about what to do if the refrigerant is overfilled. Furthermore, there is no description on how to operate the air conditioner normally when the refrigerant is overfilled.
On the other hand, Patent Document 2 describes that, as a result of determination of the refrigerant amount, if there is an excess or deficiency, it is displayed, and the operator performs additional charging of refrigerant and extraction of refrigerant until the refrigerant reaches an appropriate amount. ing. However, it is not described at all how the air conditioner operates normally in the state when the refrigerant is excessively charged.

  As described above, in a multi-type air conditioner used for air conditioning of a building, various methods for determining the appropriateness of the refrigerant amount have been proposed, but there is no decisive factor, and the refrigerant amount is excessive or insufficient. Has not yet been resolved. In addition, in the case of an overcharge in which the refrigerant is excessively charged, there is currently no technology for operating the air conditioner normally in that state.

  The present invention has been made in view of such circumstances, and provides an air conditioner that can be operated normally as it is without causing an abnormal stop or insufficient capacity even when the refrigerant is overcharged. For the purpose.

In order to solve the above problems, the air conditioning apparatus of the present invention employs the following means.
That is, the air conditioner according to the present invention is for an outdoor unit including a compressor, an outdoor heat exchanger that functions as a condenser during cooling, and an evaporator during heating, and a second expansion valve for heating. A plurality of indoor units each having an indoor heat exchanger that functions as an evaporator during cooling and a condenser as a condenser during heating and a first expansion valve for cooling are connected in parallel, and the compressor, An accumulator is provided in the refrigerant suction piping line to the compressor of the refrigeration cycle including a heat exchanger and a plurality of the indoor heat exchangers, and the supercooling is provided in the liquid piping line of the refrigeration cycle A third part for supercooling is connected to a branch pipe line for allowing a part of the liquid refrigerant to flow through the heat exchanger from the liquid pipe line and to bypass the gasified refrigerant to the refrigerant inlet pipe line on the inlet side of the accumulator. In the air conditioner provided with a tension valve, the refrigerant subcooling degree at the outlet of the outdoor heat exchanger or the outlet of the indoor heat exchanger when functioning as a condenser, the refrigeration controlling the refrigerant subcooling degree The opening of the first expansion valve in the cycle, the high pressure in the refrigeration cycle, the number of rotations of the compressor controlling the high pressure, and the refrigerant liquid level of the receiver provided in the refrigeration cycle, Based on any one or a plurality of detection values, a refrigerant overcharge detection unit that detects that the refrigerant is excessively charged during the refrigeration cycle, and the refrigerant overcharge detection unit are in cooling or heating. when detecting overcharging of refrigerant, the time of cooling, the increase of the opening degree of the third expansion valve and the first expansion valve in the refrigeration cycle, during the heating, before in the refrigeration cycle It increases the opening degree of the third expansion valve and the second expansion valve, wherein to reduce the degree of superheat of the refrigerant returning to the refrigerant suction pipe line, save up the surplus refrigerant in the refrigeration cycle is moved to the accumulator excess And a refrigerant recovery unit.

If the refrigerant is excessively filled in the refrigeration cycle, (1) liquid refrigerant accumulates in the condenser and the refrigerant supercooling degree tends to increase, and (2) the refrigerant supercooling degree control valve. (3) The high pressure of the refrigeration cycle tends to increase, (4) The rotational speed of the compressor controlling the high pressure tends to decrease, (5) It is known that when a receiver is provided, the liquid level of the refrigerant tends to increase.
According to the present invention, at the time of cooling or heating, at least one of the above (1) to (5) is performed based on the detection value of the sensor or the control command value to the device, the refrigerant overcharge detection unit When detecting the charge, the surplus refrigerant recovery unit increases the opening degree of both the third expansion valve for supercooling and the first expansion valve for cooling when cooling, and when heating, The surplus refrigerant recovery unit increases the degree of opening of both the supercooling third expansion valve and the heating second expansion valve. This reduces the degree of superheat of the refrigerant that reaches the inlet side of the accumulator via the branch piping line and the refrigerant that returns to the refrigerant suction piping line via the indoor heat exchanger or the outdoor heat exchanger in both cases of cooling and heating. Thus, a so-called liquid back state is established, and the refrigerant that has been excessively charged during the refrigeration cycle can be sequentially moved to the accumulator and stored. As a result, the circulation amount of the refrigerant circulating in the refrigeration cycle is set to an appropriate circulation amount, and the refrigerant overcharge state is eliminated. Therefore, high pressure abnormal rise due to refrigerant overcharge, accompanying abnormal stop of air conditioner, cooling capacity , lack of heating capacity , etc. are resolved, and air conditioner operates normally despite refrigerant overcharge can do. In addition, when the refrigerant is overcharged, not only the third expansion valve, but also the first expansion valve for cooling during cooling and the second expansion valve for heating during heating are used together for liquid back-up, both during cooling and during heating. Since the refrigerant filled in is quickly moved to the accumulator, the influence on the cooling performance or the heating performance can be minimized and the deterioration of the air conditioning feeling can be suppressed.

Furthermore, in the air conditioner of the present invention, in the air conditioner described above , the non-heating that occurs when the refrigerant accumulates in a certain indoor unit due to the drift of the refrigerant or the like during heating is the first of the indoor unit. When the indoor unit non-warming avoidance control that avoids the opening of the expansion valve as the command opening is operating for a predetermined time or more, the third expansion is detected when the refrigerant overcharge detection unit detects refrigerant overcharge. The opening degree of the valve and the second expansion valve is increased, and excess refrigerant in the unheated indoor unit and the refrigeration cycle is moved to the accumulator.

When an indoor unit having a different capacity is connected to one outdoor unit, the expansion valve of the indoor unit is fixedly controlled. At this time, a refrigerant drift occurs and the refrigerant accumulates, which may result in non-heating. Therefore, there is an indoor unit non-warm avoidance control as a countermeasure. The non-warm avoidance control is to avoid the accumulation of refrigerant by issuing an opening degree command to the first expansion valve of the indoor unit from the outdoor unit side.
According to the present invention, when the indoor unit non-warming avoidance control is operating for a predetermined time or more during heating, when the refrigerant overcharge detection unit detects the refrigerant overcharge, the surplus refrigerant recovery unit causes the third expansion valve to And the opening degree of the second expansion valve is increased. As a result, the degree of superheat of the refrigerant returning to the refrigerant suction pipe line is reduced, so that a so-called liquid back state is established, and the surplus refrigerant including the above-mentioned accumulated refrigerant can be sequentially moved to the accumulator and accumulated. Therefore, the unheated indoor unit and the overcharged state of the refrigerant are eliminated, and the amount of refrigerant circulating in the refrigeration cycle is set to an appropriate amount of circulation so that the air conditioner can be operated normally.

  According to the present invention, even if the refrigerant is excessively charged in the refrigeration cycle, the refrigerant is sequentially moved to the accumulator and stored, so that the circulation amount of the refrigerant circulating in the refrigeration cycle is set to an appropriate circulation amount, and the refrigerant is excessive. The charge state can be eliminated. For this reason, the high pressure abnormal rise caused by the refrigerant overcharge, the accompanying abnormal stop of the air conditioner and the lack of cooling capacity and / or heating capacity are resolved, and even if the refrigerant remains overcharged, the air conditioning The device can be operated normally.

Embodiments according to the present invention will be described below with reference to the drawings.
[First Embodiment]
Hereinafter, a first embodiment of the present invention will be described with reference to FIGS. 1 and 2.
FIG. 1 shows a refrigeration cycle diagram of a multi-type air conditioner 1 according to the present embodiment. The air conditioner 1 includes one outdoor unit 2, a gas side pipe 4 and a liquid side pipe 5 led out from the outdoor unit 2, and a branching device 6 between the gas side pipe 4 and the liquid side pipe 5. And a plurality of indoor units 7A and 7B connected in parallel.

  The outdoor unit 2 heats an inverter-driven compressor 21 that compresses refrigerant, an oil separator 22 that separates lubricating oil from refrigerant gas, a four-way switching valve 23 that switches the circulation direction of refrigerant, and refrigerant and outside air. A plurality of outdoor heat exchangers 24A and 24B connected in parallel to be exchanged, outdoor expansion valves (EEVH; second expansion valves) 25A and 25B for heating, supercooling coils 26A and 26B, and liquid refrigerant are stored. Receiver 27, a supercooling heat exchanger 28 that supercools the liquid refrigerant, and a supercooling expansion valve (EEVSC; third expansion valve) 29 that controls the amount of refrigerant that is diverted to the supercooling heat exchanger 28 And an accumulator 30 that separates the liquid from the refrigerant gas sucked into the compressor 21 and stores the liquid refrigerant, a gas-side operation valve 31, and a liquid-side operation valve 32. Discharge piping 33A, gas Pipe 33B, the liquid pipe 33C, the gas pipe 33D, connected suction pipe 33E, and through the refrigerant pipe, such as a branch pipe 33F for supercooling, constitute the outdoor refrigerant circuit 34. The outdoor unit 2 is provided with outdoor fans 35A and 35B for blowing outside air to the outdoor heat exchangers 24A and 24B. The outdoor unit 2 is shipped in a state where a predetermined amount of refrigerant is filled in the refrigerant circuit 34 on the production factory side.

  The gas side pipe 4 and the liquid side pipe 5 are refrigerant pipes connected to the gas side operation valve 31 and the liquid side operation valve 32 of the outdoor unit 2, and are connected to the outdoor unit 2 and to it during installation on site. The length is appropriately determined according to the distance between the indoor units 7A and 7B. An appropriate number of branching devices 6 are provided in the middle of the gas side piping 4 and the liquid side piping 5, and an appropriate number of indoor units 7 </ b> A and 7 </ b> B are connected via the branching devices 6. Thereby, one sealed refrigeration cycle 3 is configured.

  The indoor units 7A and 7B include an indoor heat exchanger 71 that exchanges heat between the refrigerant and room air and supplies the air to the indoor air conditioner, an indoor expansion valve (EEVC; first expansion valve) 72 for cooling, and an indoor heat exchanger. And an indoor fan 73 that circulates the room air through 71, and is connected to the branching device 6 via the indoor branch gas pipe 4A and the branch liquid pipe 5A. In the present embodiment, an example in which two indoor units 7A and 7B are connected is shown, but the number of indoor units to be connected may be three or more. The stand is connected.

  The air conditioner 1 includes an outdoor unit 2, indoor units 7A and 7B, a gas side pipe 4, a liquid side pipe 5, branch gas pipes 4A, 4B and 4C, branch liquid pipes 5A, 5B and 5C, and a branching device. 6 and the like are separately carried into the installation site, and the outdoor unit 2 and the indoor units 7A and 7B are connected and constructed through the refrigerant piping at the site. In general, the outdoor unit 2 is installed on the rooftop or outside the building, and the indoor units 7A and 7B are individually arranged in each air conditioning zone or room. For this reason, the pipe lengths of the gas side pipe 4, the liquid side pipe 5, the branch gas pipes 4A, 4B, 4C, and the branch liquid pipes 5A, 5B, 5C that connect the outdoor unit 2 and the indoor units 7A, 7B are set up. It varies greatly depending on the environment. Also, indoor units 7A and 7B are often connected in a mixture of indoor units of different models and capacities. For this reason, in the multi-type air conditioner 1, after installation, an additional amount of refrigerant corresponding to the difference in refrigerant pipe length, indoor unit model, and capacity is charged locally, and an appropriate amount of refrigerant is stored in the refrigeration cycle 3. Is to be filled.

In the air conditioner 1, the cooling operation is performed as follows. In the cooling operation, the refrigerant is circulated in the direction of the solid line arrow shown in FIG.
The high-temperature and high-pressure refrigerant gas compressed by the compressor 21 is discharged to the discharge pipe 33A, and after the lubricating oil contained in the refrigerant is separated by the oil separator 22, it is circulated to the gas pipe 32B side by the four-way switching valve 23. In the outdoor heat exchangers 24A and 24B, heat is exchanged with the outside air blown by the outdoor fans 35A and 35B to be condensed and liquefied. This liquid refrigerant passes through the second expansion valves 25A and 25B for heating, is temporarily stored in the receiver 27 via the supercooling coils 26A and 26B, and the circulation amount is adjusted. The liquid refrigerant from the receiver 27 partially flows into the subcooling branch pipe 33F in the process of passing through the supercooling heat exchanger 28 via the liquid pipe 33C, and is insulated by the subcooling third expansion valve (EEVSC) 29. The refrigerant is cooled by exchanging heat with the expanded refrigerant and given a predetermined degree of supercooling, and then led out from the outdoor unit 2 to the liquid side pipe 5 via the liquid side operation valve 32. The liquid refrigerant led out to the liquid side pipe 5 is diverted by the branching device 6 to the branch liquid pipes 5A and 5B of the indoor units 7A and 7B.

  The liquid refrigerant divided into the branch liquid pipes 5A and 5B flows into the indoor units 7A and 7B, is adiabatically expanded by the cooling first expansion valve (EEVC) 72, becomes a gas-liquid two-phase flow, and heats the room. It flows into the exchanger 71. In the indoor heat exchanger 71, the indoor air circulated by the indoor fan 73 and the refrigerant are heat-exchanged, and the indoor air is cooled and provided for indoor cooling. On the other hand, the refrigerant is vaporized and reaches the branching device 6 through the branch gas pipes 4A and 4B, and merges with the refrigerant gas from the other indoor units in the gas side pipe 4. The refrigerant gas merged in the gas side pipe 4 returns to the outdoor unit 2 again, reaches the suction pipe 33E through the gas side operation valve 31, the gas pipe 33D, and the four-way switching valve 23, and is supplied from the subcooling branch pipe 33F. After being combined with the refrigerant gas, it is introduced into the accumulator 30. In the accumulator 30, the liquid component contained in the refrigerant gas is separated, only the gas component is sucked into the compressor 21, and the refrigerant is compressed again in the compressor 21. The cooling operation is performed by repeating the above cycle.

On the other hand, the heating operation is performed as follows. In addition, at the time of heating operation, the refrigerant is circulated in the direction of the broken arrow shown in FIG.
The high-temperature and high-pressure refrigerant gas compressed by the compressor 21 is discharged to the discharge pipe 33A, and after the lubricating oil contained in the refrigerant is separated by the oil separator 22, it is circulated to the gas pipe 33D side by the four-way switching valve 23. Is done. This refrigerant is led out from the outdoor unit 2 via the gas side operation valve 31 and the gas side pipe 4, and further introduced into the indoor units 7A and 7B via the branching device 6 and the branch gas pipes 4A and 4B on the indoor side. The high-temperature and high-pressure refrigerant gas introduced into the indoor units 7A and 7B is heat-exchanged with the indoor air circulated by the indoor fan 73 in the indoor heat exchanger 71, and the indoor air is heated and used for indoor heating. The liquid refrigerant condensed and liquefied here reaches the branching device 6 through the first expansion valve (EEVC) 72 for cooling and the branch liquid pipes 5A and 5B, and is merged with the refrigerant from other indoor units. It returns to the outdoor unit 2 through the side pipe 5. During heating, in the indoor units 7A and 7B, the first expansion valve (EEVC) 72 for cooling is opened so that the degree of supercooling of the refrigerant at the outlet of the indoor heat exchanger 71 functioning as a condenser becomes a constant value. The degree is controlled.

  The refrigerant that has returned to the outdoor unit 2 reaches the supercooling heat exchanger 28 via the liquid side operation valve 32 and the liquid pipe 33C, and after being given supercooling as in the case of cooling, flows into the receiver 27. It is stored and the amount of circulation is adjusted. The liquid refrigerant reaches the second expansion valves (EEVH) 25A and 25B for heating via the liquid pipe 33C and the supercooling coils 26A and 26B, where it is adiabatically expanded and flows into the outdoor heat exchangers 24A and 24B. In the outdoor heat exchangers 24A and 24B, heat is exchanged between the outside air blown by the outdoor fans 35A and 35B and the refrigerant, and the refrigerant absorbs heat from the outside air and is evaporated. This refrigerant merges with the refrigerant from the subcooling branch pipe 33F via the gas pipe 33B, the four-way switching valve 23, and the suction pipe 33E from the outdoor heat exchanger 24, and is introduced into the accumulator 30. In the accumulator 30, the liquid component contained in the refrigerant gas is separated and only the gas component is sucked into the compressor 21, and the refrigerant is compressed again by the compressor 21. A heating operation is performed by repeating the above cycle.

  Here, the refrigeration cycle 3 of the air conditioner 1 should be filled with an appropriate amount of refrigerant as described above, but sometimes the refrigerant is excessively filled (so-called overcharge state). ). When the refrigerant is overcharged, normally the pressure on the high pressure side abnormally rises, and accordingly, the air conditioner 1 stops abnormally, the cooling capability becomes insufficient due to the activation of the high pressure protection function, the refrigerant is on the evaporator side The problem that the heating capacity becomes insufficient due to the accumulation in the water occurs. In the present embodiment, the following configuration is adopted so that the air-conditioning apparatus 1 can be operated normally even when the refrigerant is overcharged.

First, overcharge countermeasure control start conditions during cooling and heating are as follows.
(When cooling; if the following conditions are satisfied)
(A1) During cooling operation (B1) Automatic recovery after abnormal stop due to high pressure abnormality (C1) The indoor unit operating capacity when abnormally stopped due to high pressure abnormality was 50% or less of the capacity of the outdoor unit 2 Case (when heating; if all of the following are satisfied)
(A2) Heating operation (B2) When the non-warming avoidance control is operating, for example, for 5 minutes or more (C2) When the gas low countermeasure control during heating is not operating

  In the above start condition, “50% or less of the capacity of the outdoor unit 2” at the time of cooling (C1) means that the operating capacity of the indoor units 7A and 7B is small, and the operating capacity of the indoor units 7A and 7B. If the required amount of refrigerant is small and the refrigerant is in an overcharged state, the receiver 27 becomes full and the high pressure is likely to rise.

The “non-warm avoidance control” during heating (B2) is the following control.
As described above, in the multi-type air conditioner 1, the indoor units 7A and 7B having various models and capacities are connected. As described above, when the indoor units 7A and 7B having different capacities are connected to one outdoor unit 2, the expansion valve 72 of the indoor unit is fixedly controlled. At this time, a refrigerant drift occurs and the refrigerant accumulates, which may result in non-heating. Therefore, indoor unit non-warm avoidance control is employed as a countermeasure. The non-warming avoidance control is to prevent the accumulation of refrigerant by issuing an opening degree command of the expansion valve 72 to the indoor units 7A and 7B from the outdoor unit 2 side. The details of the control will be described below with reference to the flowchart shown in FIG.

  When the outdoor unit 2 is operated, in step S1, an initial opening degree command is issued to the indoor units 7A and 7B in the indoor unit section <1> two minutes after the heating thermo-on. Next, in step S2, for example, when the high pressure HP is HP ≧ 2.5 MPa and the heating thermo-ON has elapsed for 5 minutes, the process proceeds to step S3, where non-warming determination is performed. This non-warming determination is, for example, 30 ° C. or lower when the heat exchanger temperature sensor (bend; Thi-R1) 41 or the heat exchanger temperature sensor (exit; Thi-R2) 42 of the indoor units 7A and 7B is lower. If this happens, the unit will not be warm. If there is no unwarmed unit, the process proceeds to step S4, where the high pressure target value is maintained, and in step S5, the opening command value of the expansion valve 72 of the heating indoor units 7A, 7B is maintained (<2> in the indoor unit section). If no command is issued at step S6, no warming avoidance control is terminated if an end condition (when defrost is established, when oil return control is established, when the compressor is stopped) is established in step S6.

  On the other hand, if it is determined in step S3 that there is an unwarmed indoor unit, the process proceeds to step S7, and it is determined whether or not the unwarmed indoor unit exists for, for example, 20 minutes or longer. If it is determined that there is an opening, the process proceeds to step S8, and the opening degree X is set to 80% of the current value (however, the lower limit) for the indoor units 7A and 7B whose opening degree is commanded in the indoor unit classification <2>. Value) and reset the 20-minute timer for determining whether there is no warming. If it is determined in step S7 that there is no presence, and if the process ends in step S8, the process proceeds to step S9, and the high pressure target value is increased to, for example, 3.15 MPa.

  The non-warm indoor unit proceeds to step S10, and for the indoor units 7A and 7B in the indoor unit section <1>, the opening of the expansion valve 72 is opened upward, and the indoor units 7A and 7A in the indoor unit section <2> are opened. 7B is not instructed to open the expansion valve 72 (cancel). When the process of step S10 is completed, if the end condition (when defrost is established, when oil return control is established, when the compressor is stopped) is established in step S6, the non-warm avoidance control is terminated. In addition, the indoor units 7A and 7B other than the unwarmed indoor unit proceed to step 11, and the indoor unit (<1>) in which the detected value of the heat exchanger temperature sensor (bend; Thi-R1) 41 is, for example, 40 ° C. or more. The expansion valve opening is on the upper side), the process proceeds to step S12. In step S13, the detected value of the heat exchanger temperature sensor 41 is the highest including the indoor units of the indoor unit sections <1> and <2>. The opening of the expansion valve 72 is throttled one by one in order from the indoor unit. In this case, a determination time of 5 minutes is provided after the opening degree of the expansion valve 72 is reduced.

In addition, the detected value of the heat exchanger temperature sensor (bend; Thi-R1) 41 is a unit of 40 ° C. or lower (<1> or the expansion valve opening is on the lower side), a unit of 40 ° C. or higher, and <2 >, The unit instructing the opening degree proceeds to step S14, and in step S15, the heating room unit expansion valve opening degree command value is maintained (if the opening degree command is not given in <2>, nothing is done). If the end condition (when defrost is established, when oil return control is established, when the compressor is stopped) is established in step S6, the non-warm avoidance control is terminated.
The non-warm avoidance control is performed by the non-warm avoidance control unit 52 provided in the controller 51.

In order to detect whether or not the refrigerant is in an overcharge state under the above-described start conditions of the overcharge countermeasure control, the controller 51 is provided with a refrigerant overcharge detection unit 53. The refrigerant overcharge detection unit 53 detects refrigerant overcharge from any one or a combination of detection values (1) to (5) below.
(1) The refrigerant supercooling degree at the outlet of the outdoor heat exchangers 24A and 24B (during cooling) or the indoor heat exchanger 71 (during heating) functioning as a condenser during cooling or heating is determined by the outlet of each heat exchanger. The heat exchanger temperature sensor (exit; Thi-R2) 42 and the heat exchanger temperature sensors (outlet; Tho-R1, Tho-R2) 43A, 43B, etc. provided in the 43b is detected. The refrigerant supercooling degrees 42a, 43a, and 43b tend to increase when the refrigerant is excessively filled in the refrigeration cycle 3 because liquid refrigerant accumulates in the condenser.

(2) The opening degree of the 1st expansion valve (EEVC) 72 which is performing refrigerant | coolant supercooling degree control in the exit of the indoor heat exchanger 71 which functions as a condenser at the time of heating is detected from the control command value 72a. The opening 72a of the first expansion valve 72 tends to increase when the refrigerant is excessively charged in the refrigeration cycle 3.
(3) The high pressure of the refrigeration cycle 3 is detected from the detected value 44a using the high pressure sensor 44 provided in the discharge pipe 33A. The high pressure 44a tends to increase when the refrigerant is excessively charged in the refrigeration cycle 3.

(4) The number of rotations of the compressor 21 performing high pressure control is detected from the control command value 21a. If the refrigerant is excessively charged in the refrigeration cycle 3, the compressor rotational speed 21a tends to decrease.
(5) The refrigerant liquid level height of the receiver 27 is detected from the detected value 44 a using the liquid level sensor 45 provided in the receiver 27. The refrigerant liquid level 45a tends to increase when the refrigerant is excessively filled in the refrigeration cycle 3.
The sensors 42, 43A, 43B, 44, 45 and the control command values 72a, 21a can use the existing sensors or the command values of the control that has already been performed.

  In addition, based on one or a plurality of the detection values 42a, 43a, 43b, 44a, 45a or the control command values 21a, 72a of the above (1) to (5), the refrigerant overcharge detecting unit 53 When overcharge is detected, an excess refrigerant recovery unit 54 is provided that increases the opening degree of the third expansion valve (EEVSC) 29 for supercooling to a predetermined opening degree based on the command. The surplus refrigerant recovery unit 54 has a refrigerant superheat degree (SHC) 46a of refrigerant reaching the outlet of the supercooling heat exchanger 28 detected by the branch pipe temperature sensor 46, that is, the inlet side of the accumulator 30 through the branch pipe 33F. The opening degree of the third expansion valve (EEVSC) 29 is controlled so as to achieve a target superheat degree (for example, 1 ° C.).

  As a result, the degree of superheat of the high-pressure liquid refrigerant on the high-pressure liquid pipe 33C side was lowered to 1 ° C. via the third expansion valve (EEVSC) 29 for supercooling, the supercooling heat exchanger 28, and the branch pipe 33F. The accumulator 30 can be so-called liquid-backed as a refrigerant in a wet gas state.

  Further, when the refrigerant overcharge detection unit 53 detects overcharge of the refrigerant during cooling, the surplus refrigerant recovery unit 54 simultaneously with the increase in the opening degree of the third cooling expansion valve (EEVSC) 29 for cooling, The opening of the expansion valve (EEVC) 72 can be increased. That is, the surplus refrigerant recovery unit 54 uses the degree of superheat (SHC) 48a of the refrigerant detected by the intake pipe temperature sensor 48 provided in the intake pipe 33E as the opening degree of the first expansion valve (EEVC) 72 as the target overheat. By controlling so as to be at a degree (for example, 1 ° C.), the excess refrigerant in the refrigeration cycle 3 is liquid-backed and actively moved to the accumulator 30, and the circulation amount of the refrigerant circulating in the refrigeration cycle 3 is set appropriately. The circulation amount is set so as to eliminate the overcharged state of the refrigerant.

  Similarly, when the refrigerant overcharge detection unit 53 detects refrigerant overcharge during heating, the surplus refrigerant recovery unit 54 increases the degree of opening of the third expansion valve (EEVSC) 29 for supercooling and simultaneously increases the first temperature for heating. It is set as the structure which can increase the opening degree of 2 expansion valves (EEVH) 25A, 25B. That is, the surplus refrigerant recovery unit 54 determines the degree of superheat (SHC) 48a of the refrigerant detected by the suction pipe temperature sensor 48 provided in the suction pipe 33E based on the opening degree of the second expansion valves (EEVH) 25A and 25B. By controlling so as to achieve a target superheat degree (for example, 1 ° C.), surplus refrigerant in the refrigeration cycle 3 is so-called liquid back and actively moved to the accumulator 30 to circulate the refrigerant circulating in the refrigeration cycle 3. The amount is set as an appropriate circulation amount, and the refrigerant overcharge state can be eliminated.

Thus, according to the present embodiment, the following operational effects are obtained.
If the refrigerant is overcharged during the refrigeration cycle 3, the outdoor heat exchangers 24A and 24B functioning as condensers (when cooling) or the indoor heat exchanger 71 (when heating) under the above-described conditions for starting overcharge countermeasure control. ), The refrigerant subcooling degree 42a, 43a, 43b, the opening degree 72a of the first expansion valve (EEVC) 72 controlling the refrigerant subcooling degree, the high pressure 44a in the refrigeration cycle 3, and the high pressure are controlled. The refrigerant overcharge detector 53 detects the refrigerant overcharge state based on detection values such as the rotational speed 21a of the compressor 21 and the refrigerant liquid level 45a of the receiver 27.

  When the refrigerant overcharge detection unit 53 detects the refrigerant overcharge, the surplus refrigerant recovery unit 54 increases the opening degree of the third expansion valve (EEVSC) 29 for supercooling. As a result, the refrigerant from the high pressure liquid pipe 33C side through the third expansion valve 29, the supercooling heat exchanger 28 and the branch pipe 33F to the inlet side suction pipe 33E of the accumulator 30 is reduced in superheat, and is a wet gas refrigerant. A so-called liquid back is performed on the accumulator 30. Therefore, the refrigerant that is excessively filled in the refrigeration cycle 3 is sequentially moved to the accumulator 30. The refrigerant moved to the accumulator 30 is separated into a liquid component and a gas component, and the liquid component remains in the accumulator 30.

  At the same time, the surplus refrigerant recovery unit 54 increases the opening degree of the first expansion valve 72 for cooling together with the third expansion valve 29 for supercooling during cooling, and the third expansion valve for supercooling during heating. 29, the opening degree of the second expansion valves 25A, 25B for heating is increased. As a result, the degree of superheat of the refrigerant that reaches the inlet side of the accumulator 30 via the branch pipe 33F and the refrigerant that returns to the refrigerant suction pipe 33E via the indoor heat exchanger 71 or the outdoor heat exchangers 24A and 25B is reduced. In this state, the refrigerant that is overfilled in the refrigeration cycle 3 can be quickly moved to the accumulator 30 sequentially from the two paths and stored.

As a result, the excessively charged refrigerant is stored in the accumulator 30, the amount of refrigerant circulating through the refrigeration cycle 3 is set to an appropriate amount of circulation, and the refrigerant overcharge state is eliminated. Then, the overcharge countermeasure control for moving the surplus refrigerant to the accumulator 30 is terminated under the following termination condition.
(When cooling)
(A1) When the compressor 21 is stopped (b1) The cooling high pressure protection control has not been continuously operated for 5 minutes, for example, after the cooling start control is finished. (C1) The abnormal stop due to the high pressure abnormality continues for 60 minutes, for example. (D1) The detected value 47a of the temperature sensor 47 under the dome provided at the bottom of the housing of the compressor 21 that is activated is below the set overheat temperature (SHT; for example, 20 ° C.), for example, for 10 seconds. If you continue

(When heating)
(A2) When the compressor 21 is stopped (b2) The non-warm avoidance control is not activated (c2) The detected value 47a of the temperature sensor 47 under the dome provided at the bottom of the housing of the compressor 21 that is activated is When the set superheat temperature (SHT; for example, 20 ° C.) or lower is continued for, for example, 10 seconds (d2) At the time of defrost control (e2) When the gas low countermeasure control at the time of heating is activated

  As described above, according to the present embodiment, when the refrigerant is overcharged, it is possible to eliminate the overcharged state of the refrigerant by moving the excessively charged refrigerant to the accumulator 30 and storing it. Therefore, an abnormal increase in high pressure due to refrigerant overcharge and the accompanying abnormal stop of the air conditioner 1 and lack of cooling capacity and heating capacity can be resolved, and the air conditioner is in spite of the refrigerant being overcharged. 1 can be operated normally.

Further, since the surplus refrigerant in the refrigeration cycle 3 can be stored in the accumulator 30 by using the branch pipe 33F and the third expansion valve (EEVSC) 29 provided for supercooling, either during cooling or heating Even in this case, the refrigerant overcharge state can be eliminated while cooling or heating without directly affecting the cooling performance or heating performance. Therefore, there is no worry that the air conditioning feeling is deteriorated.
During heating, the refrigerant condensed and liquefied in the indoor units 7A and 7B partially flashes due to pressure loss while being circulated in the liquid side pipe 5, but is supercooled again by the supercooling heat exchanger 28 and received by the receiver 27. Since the liquid phase is in the inlet portion, the liquid refrigerant can also be moved to the receiver 27. Therefore, the function of adjusting the original refrigerant circulation amount of the receiver 27 can be exhibited.

  Further, when the overheating of the refrigerant is detected when the indoor unit non-warming avoidance control is operated for a predetermined time or more, the surplus refrigerant including the refrigerant accumulated in the non-warm indoor unit is sequentially moved to the accumulator 30. Can be stored. Therefore, the non-heating state of the unheated indoor unit and the overcharge state of the refrigerant are eliminated, and the air circulation apparatus 1 can be operated normally by setting the circulation amount of the refrigerant circulating in the refrigeration cycle 3 to an appropriate circulation amount.

  The present invention is not limited to the invention according to the above-described embodiment, and can be appropriately modified without departing from the gist thereof. For example, the present invention is not necessarily based on non-warm avoidance control. Further, the outdoor heat exchangers 24A and 24B, the outdoor expansion valves 25A and 25B, and the supercooling coils 26A and 26B may be a single system of the outdoor unit 2. Furthermore, the supercooling heat exchanger 28 may be configured to function only during cooling.

It is a refrigerant circuit figure of the air harmony device concerning a 1st embodiment of the present invention. It is a flowchart figure of indoor unit unwarming avoidance control in the air conditioning apparatus concerning 1st Embodiment of this invention.

DESCRIPTION OF SYMBOLS 1 Air conditioning apparatus 2 Outdoor unit 3 Refrigeration cycle 7A, 7B Indoor unit 21 Compressor 24A, 24B Outdoor heat exchanger 25A, 25B Outdoor expansion valve (EEVH; 2nd expansion valve)
27 Receiver 28 Supercooling heat exchanger 29 Supercooling expansion valve (EEVSC; third expansion valve)
30 accumulator 33E suction pipe 33F branch pipe 52 non-warming avoidance control part 53 refrigerant overcharge detection part 54 surplus refrigerant recovery part 71 indoor heat exchanger 72 indoor expansion valve (EEVC; first expansion valve)

Claims (2)

For an outdoor unit including a compressor, a condenser during cooling, an outdoor heat exchanger that functions as an evaporator during heating, and a second expansion valve for heating, an evaporator during cooling and a heating during heating A plurality of indoor units including an indoor heat exchanger functioning as a condenser and a first expansion valve for cooling are connected in parallel,
An accumulator is provided in a refrigerant suction pipe line to the compressor of the refrigeration cycle configured to include the compressor, the outdoor heat exchanger, and a plurality of the indoor heat exchangers,
A part of the liquid refrigerant is branched and circulated from the liquid piping line to the supercooling heat exchanger provided in the liquid piping line of the refrigeration cycle, and the gasified refrigerant is bypassed to the refrigerant intake piping line on the inlet side of the accumulator In the air conditioner in which the third expansion valve for supercooling is provided in the branch piping line to be
The degree of refrigerant subcooling at the outlet of the outdoor heat exchanger or the outlet of the indoor heat exchanger when functioning as a condenser, the degree of opening of the first expansion valve in the refrigeration cycle controlling the degree of refrigerant subcooling, Based on one or a plurality of detected values of a high pressure in the refrigeration cycle, a rotation speed of the compressor controlling the high pressure, and a refrigerant liquid level of a receiver provided in the refrigeration cycle A refrigerant overcharge detection unit for detecting that the refrigerant is excessively charged during the refrigeration cycle;
When the refrigerant overcharge detection unit detects refrigerant overcharge during cooling or heating, during cooling, the third expansion valve and the first expansion valve in the refrigeration cycle are increased, and during heating. Increasing the degree of opening of the third expansion valve and the second expansion valve in the refrigeration cycle, reducing the degree of superheat of the refrigerant returning to the refrigerant suction pipe line, and removing excess refrigerant in the refrigeration cycle An air conditioner characterized by comprising: an excess refrigerant recovery unit that moves to an accumulator and accumulates. Indoor unit non-warm avoidance that avoids unheating, which occurs when refrigerant accumulates in a certain indoor unit due to drift of the refrigerant during heating, using the opening degree of the first expansion valve of the indoor unit as a command opening degree. When the control is operating for a predetermined time or more, and when the refrigerant overcharge detection unit detects the refrigerant overcharge, the openings of the third expansion valve and the second expansion valve are increased, and the non-heating is performed. The air conditioner according to claim 1 , wherein surplus refrigerant in the indoor unit and the refrigeration cycle is moved to the accumulator.

Images