JP2012137207A - Refrigerating cycle apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a refrigerating cycle apparatus that performs an operation mode depending on conditions to maintain a high-efficiency operation over a wide range.SOLUTION: The refrigerating cycle apparatus 100 includes: an injection operation mode; a capacity-control operation mode; a normal operation mode; and a suction-pipe injection operation mode, which are performed by the apparatus controlling a fist flow-rate adjusting device 7, a second flow-rate adjusting device 8, and an opening and closing device 10.

Description

  The present invention relates to a refrigeration cycle apparatus in which a compressor capable of supercharging (injecting) refrigerant into a compression chamber in the middle of compression is mounted as an element of a refrigeration cycle.

  There has been proposed a refrigeration cycle apparatus that is configured such that gas fluid separated in the middle of a refrigeration cycle can be injected into a compression chamber and is intended to improve the efficiency during low-load operation (see, for example, Patent Document 1). ). The injection device mounted on the refrigeration cycle apparatus opens and closes the injection path by controlling a switching valve that switches between blocking and canceling the injection path. That is, by controlling the switching valve, an injection state in which the injection path is opened and the injection is executed, and an injection cutoff state in which the upstream side of the injection path is closed and the injection is blocked are switched. This injection device further allows the downstream side of the injection path to communicate with the suction path to the compression chamber when the injection is cut off.

  In the configuration described in Patent Document 1, the high load operation can be made highly efficient by switching to the injection state at the time of high load operation, supercharging the refrigerant to the compression chamber, and increasing the refrigerant circulation amount. In addition, during low-load operation, it is switched to the injection cutoff state, and in addition to eliminating supercharging due to injection, a part of the refrigerant in the compression chamber is bypassed to the suction path of the compressor through the downstream side of the injection path. Since the volume of the refrigerant is kept as it is, the circulation amount of the refrigerant is smaller than that, so that the operation can be performed with high efficiency even during low load operation.

JP-A-11-107968 (3rd, 4th page, FIG. 1 etc.)

  The technique described in Patent Document 1 can switch only between two operations, an injection operation (operation in an injection state) and a capacity control operation (operation in an injection cutoff state). However, the technique described in Patent Document 1 does not disclose or suggest any operation when neither injection operation nor capacity control operation is performed. Further, there is no disclosure or suggestion about the adjustment of the injection flow rate during the injection operation.

  Furthermore, in recent years, efforts to combat global warming have been strengthened, and the transition to refrigerants with low global warming potential (GWP) has been considered. In order to achieve both high efficiency equal to or higher than the conventional one and low GWP, it is necessary to cope with each refrigerant. Currently, refrigerants that are used as substitutes for R410A refrigerants used in home and commercial air conditioners are CFC-based low GWP refrigerants such as R32 and HFO1234yf, and hydrocarbon-based natural refrigerants such as propane. . In order to obtain refrigeration capacity, heating capacity, or efficiency equivalent to or higher than those of conventional refrigerants, it is necessary to take a wide range of refrigerant compression rates. In addition, when a refrigerant whose discharge temperature is likely to increase is used, the injection operation is effective in order to suppress an excessive increase in the discharge temperature.

  In the technique described in Patent Document 1, since only two operations, that is, an injection operation and a capacity control operation, can be performed, it is not possible to meet recent demands. In addition, since there is no reference in the technique described in Patent Document 1, it is not known how to adjust the injection flow rate and injection pressure. As a result, high-efficiency operation can be performed only under certain conditions.

  The present invention has been made to solve the above-described problems, and provides a refrigeration cycle apparatus capable of maintaining high-efficiency operation over a wide range by executing an operation mode according to the situation. It is an object.

  A refrigeration cycle apparatus according to the present invention includes a compressor that compresses and discharges a refrigerant, a radiator that exchanges heat between the refrigerant discharged from the compressor and a heat medium, and a decompression mechanism that depressurizes the refrigerant flowing out of the radiator And a refrigeration cycle in which an evaporator that exchanges heat between the refrigerant decompressed by the decompression mechanism and the heat medium is connected by piping, a pipe between the radiator and the decompression mechanism, and a process in the middle of compression in the compressor An injection circuit connected to the compression chamber, a bypass circuit connecting the suction pipe of the compressor and the injection circuit, and a connection point connecting the bypass circuit of the injection circuit to the radiator side. A second flow rate adjusting device installed on the compressor side from a connection point where the bypass circuit of the injection circuit is connected; An opening / closing device installed in a path circuit, the first flow rate adjusting device, the second flow rate adjusting device, and an injection operation mode executed by controlling the switch device, a capacity control operation mode, A normal operation mode and a suction pipe injection operation mode, wherein the injection operation mode circulates the refrigerant in the refrigeration cycle, and passes the refrigerant into the compression chamber in the middle of the compression in the compressor via the injection circuit. In the capacity control operation mode, the refrigerant is circulated in the refrigeration cycle, the second flow rate adjusting device is installed in the injection circuit, and the compressor is in the middle of compression in the compressor. The compressor via the connected injection circuit and bypass circuit The normal operation mode circulates the refrigerant in the refrigeration cycle without using the injection circuit and the bypass circuit in the normal operation mode. In the suction pipe injection operation mode, the refrigerant is circulated in the refrigeration cycle, the first flow rate adjusting device is installed in the injection circuit, and the pipe between the radiator and the pressure reducing mechanism is installed. This is executed by injecting a refrigerant into the suction side of the compressor via the injection circuit connected to the bypass circuit and the bypass circuit.

  According to the refrigeration cycle apparatus according to the present invention, a compressor capable of injection, an injection circuit, a bypass circuit, a first flow rate adjustment device, a second flow rate adjustment device, and a switching device are provided, and the first flow rate adjustment device and the second flow rate adjustment are provided. Since the four operation modes executed by controlling the device and the switchgear are provided, it is possible to maintain highly efficient operation over a wide range.

It is a circuit block diagram which shows roughly the refrigerant circuit structure of the refrigerating-cycle apparatus which concerns on embodiment of this invention. It is the schematic which shows the structural example of the compressor mounted in the refrigeration cycle apparatus which concerns on embodiment of this invention. It is a circuit block diagram which shows the cycle state at the time of the injection operation mode of the refrigerating-cycle apparatus which concerns on embodiment of this invention. It is a circuit block diagram which shows the cycle state at the time of the capacity | capacitance control operation mode of the refrigerating-cycle apparatus which concerns on embodiment of this invention. It is a circuit block diagram which shows the cycle state at the time of the normal operation mode of the refrigerating-cycle apparatus which concerns on embodiment of this invention. It is a circuit block diagram which shows the cycle state at the time of the suction pipe injection operation mode of the refrigeration cycle apparatus which concerns on embodiment of this invention.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a circuit configuration diagram schematically showing a refrigerant circuit configuration of a refrigeration cycle apparatus 100 according to an embodiment of the present invention. FIG. 2 is a schematic diagram illustrating a configuration example of the compressor 1. Based on FIG.1 and FIG.2, the structure and operation | movement of the refrigerating-cycle apparatus 100 are demonstrated. In addition, in the following drawings including FIG. 1, the relationship of the size of each component may be different from the actual one. Further, in the following drawings including FIG. 1, the same reference numerals denote the same or equivalent parts, and this is common throughout the entire specification. Furthermore, the forms of the constituent elements shown in the entire specification are merely examples, and are not limited to these descriptions.

  The refrigeration cycle apparatus 100 according to the embodiment is used for, for example, a refrigerator, a freezer, a vending machine, an air conditioner, a showcase, a heat pump water heater, and the like. The refrigeration cycle apparatus 100 includes a compressor 1, a condenser (radiator) 2, a decompression mechanism 3, and an evaporator 4 that are basic components of the refrigeration cycle. It is designed to circulate. The pipe 5 includes a pipe 5a connecting the compressor 1 and the condenser 2, a pipe 5b connecting the condenser 2 and the decompression mechanism 3, a pipe 5c connecting the decompression mechanism 3 and the evaporator 4, and an evaporator. 4 and a pipe 5 d connecting the compressor 1.

  Further, the discharge pipe 1a through which the refrigerant discharged from the compressor 1 conducts passes through the pipe 5a, the suction pipe 1b through which the refrigerant sucked into the compressor 1 conducts through the pipe 5d, and the compression chamber in the middle of compression of the compressor 1 passes through the compression chamber. The injection pipe 1c through which the supplied (injected) refrigerant is conducted is connected to the injection circuit 6 of the pipe 5b. That is, the pipe 5 b and the injection pipe 1 c are connected by the injection circuit 6. Further, the refrigeration cycle apparatus 100 is provided with a bypass circuit 9 that connects the suction side of the compressor 1 and the injection circuit 6. The discharge pipe 1a, the suction pipe 1b, and the injection pipe 1c are each independently connected to the compressor 1. The compressor 1 may select any of a rotary method, a screw method, a reciprocating method, and a scroll method.

  The compressor 1 compresses the refrigerant sucked from the suction pipe 1b and the injection pipe 1c to a high temperature / high pressure state and discharges the refrigerant from the discharge pipe 1a. The compressor 1 has a structure in which refrigerant flowing through the injection pipe 1c can be injected (injected) into a compression chamber in the compressor 1. The compressor 1 is configured by a capacity control type in which the rotation speed can be controlled by an inverter, for example. The condenser 2 condenses and liquefies the refrigerant by exchanging heat between the refrigerant discharged from the compressor 1 and a heat medium such as air or water. The decompression mechanism 3 decompresses and expands the refrigerant that has flowed out of the condenser 2. The decompression mechanism 3 may be constituted by an electronic expansion valve or the like whose opening degree can be variably controlled, for example. The evaporator 4 performs heat exchange between the refrigerant decompressed by the decompression mechanism 3 and a heat medium such as air or water to evaporate the refrigerant.

  The injection circuit 6 is provided with a first flow rate adjusting device 7 and a second flow rate adjusting device 8 from the pipe 5b side. Both the first flow rate adjusting device 7 and the second flow rate adjusting device 8 are configured to have an opening degree that can be adjusted to 0 to 100% (for example, an electromagnetic expansion valve). In addition, it can also serve as a decompression adjustment and an on-off valve. In the following description, the second flow rate from the position where the first injection circuit 6a and the bypass circuit 9 are connected to the injection circuit 6 on the side where the first flow rate adjustment device 7 is installed from the position where the bypass circuit 9 is connected. The injection circuit 6 on the side where the adjusting device 8 is installed will be referred to as a second injection circuit 6b. Further, an opening / closing device 10 is installed in the bypass circuit 9. The opening / closing device 10 may be configured by a device that can open and close the bypass circuit 9 electromagnetically (for example, an electromagnetic valve).

  The refrigeration cycle apparatus 100 is equipped with a control device (not shown) composed of a microcomputer or the like that can control the entire system. The control device includes a drive frequency control of the compressor 1, an opening control of the pressure reducing mechanism 3, an opening control of the first flow rate adjusting device 7, an opening control of the second flow rate adjusting device 8, an opening / closing control of the opening / closing device 10, and the like. It has a function to perform. The control device controls these actuators (for example, the compressor 1, the pressure reducing mechanism 3, the first flow rate adjusting device 7, the second flow rate adjusting device 8, the opening / closing device 10, etc.) to execute each operation described below. It has become.

  In addition, it is good to install the oil separator which isolate | separates the refrigerant | coolant discharged from the compressor 1 and refrigeration oil in the middle of the piping 5a connected to the discharge pipe 1a and the condenser 2. FIG. However, in the refrigeration cycle apparatus 100, the presence and absence of an oil separator does not have a significant effect, and thus description and description are omitted. A gas-liquid separator for preventing liquid refrigerant from being directly sucked into the compressor 1 in the middle of the bypass circuit 9 and the evaporator 4 side in the pipe 5d connected to the evaporator 4 and the suction pipe 1b. It is good to install. However, in the refrigeration cycle apparatus 100, the presence and absence of a gas-liquid separator does not have a significant effect, and therefore description and description are omitted. Furthermore, it goes without saying that the condenser 2 plays the role of a gas cooler in an operation that does not condense even a refrigerant that does not condense or a refrigerant that condenses.

The refrigerant flow during basic operation of the refrigeration cycle apparatus 100 will be described.
The high-temperature and high-pressure gas refrigerant compressed by the compressor 1 flows into the condenser 2, dissipates heat by heat exchange with the heat medium supplied to the condenser 2, becomes high-pressure liquid refrigerant, and flows out of the condenser 2. . The high-pressure liquid refrigerant that has flowed out of the condenser 2 flows into the decompression mechanism 3 and is decompressed to become a low-pressure two-phase refrigerant or a low-pressure liquid refrigerant. The low-pressure refrigerant that has flowed out of the decompression mechanism 3 flows into the evaporator 4, evaporates by heat exchange with the heat medium supplied to the evaporator 4, becomes a low-pressure gas refrigerant, and flows out of the evaporator 4. The low-pressure gas refrigerant that has flowed out of the evaporator 4 is sucked into the compressor 1 again.

  Here, the specific structural example of the compressor 1 is demonstrated based on FIG. FIG. 2 shows an example of a compressor using a scroll method in which the compression rate is determined by the scroll shape. As described above, the compressor 1 sucks the refrigerant circulating in the refrigeration cycle, compresses the refrigerant, and discharges it as a high-temperature and high-pressure state. As described above, the method of the compressor 1 is not particularly limited.

  The compressor 1 houses a compression mechanism unit 50 and an electric motor 60 in an airtight container (shell) 22. Connected to the sealed container 22 are a suction pipe 1b that is connected to the pipe 5d and takes the refrigerant into the sealed container 22, and a discharge pipe 1a that is connected to the pipe 5a and discharges the refrigerant out of the sealed container 22. The sealed container 22 is connected to an injection pipe 1c that takes in the refrigerant into the compression chamber 23 in the course of compression. The injection pipe 1c is connected to the injection port 24. The compression mechanism unit 50 is disposed on the upper side of the sealed container 22, and the electric motor 60 is disposed on the lower side (low pressure space) of the sealed container 22. The bottom of the sealed container 22 is an oil sump 19 for storing refrigeration oil. Further, the frame 13 is fixedly supported at the upper portion, the motor stator 21 is fixed at the middle portion, and the subframe 16 is fixed at the lower portion of the sealed container 22.

  The compression mechanism 50 is driven by the electric motor 60 and has a function of compressing the refrigerant gas sucked from the suction pipe 1 b and discharging it to the discharge space 33 in the sealed container 22. The compression mechanism unit 50 is roughly configured by a fixed scroll 11 and an orbiting scroll 12. The discharge space 33 is formed in an upper space inside the compressor 1 and is a high-pressure space. Then, the refrigerant gas discharged to the discharge space 33 is discharged from the discharge pipe 1a communicating with the discharge space 33 to the outside of the compressor 1, that is, the pipe 5a.

  The fixed scroll 11 is fixed to a frame 13 fixedly supported in the sealed container 22 by bolts or the like (not shown). Moreover, the fixed scroll 11 has the end plate 11a and the lap | wrap part 11b which is the spiral protrusion of the involute curve shape erected on one surface (for example, the surface below paper surface) of the end plate 11a. Further, a discharge port 11c for discharging the compressed and high-pressure refrigerant gas is formed at the center of the fixed scroll 11.

  The orbiting scroll 12 performs a revolving orbiting motion without rotating with respect to the fixed scroll 11. The orbiting scroll 12 includes an end plate 12a and a wrap portion 12b that is a spiral protrusion having an involute curve shape that is erected on one surface of the end plate 12a (the upper surface on the paper surface). A hollow cylindrical oscillating scroll boss 12c is formed at a substantially central portion of a surface (hereinafter referred to as a thrust surface) opposite to the surface on which the wrap portion 12b of the oscillating scroll 12 is formed. An eccentric pin portion 14a provided at the upper end of the rotation main shaft 14 to be described later is fitted (engaged) with the swing scroll boss portion 12c.

  The fixed scroll 11 and the orbiting scroll 12 are mounted in the sealed container 22 with the wrap portion 11b and the wrap portion 12b meshing with each other. And between the lap | wrap part 11b and the lap | wrap part 12b, the compression chamber 23 from which a volume changes relatively is formed. An Oldham ring 15 is disposed between the orbiting scroll 12 and the fixed scroll 11 for preventing the orbiting scroll 12 from rotating during an eccentric orbiting motion. The Oldham ring 15 functions to prevent the orbiting scroll 12 from rotating and to enable a revolving orbiting motion.

  The electric motor 60 has a function of driving the orbiting scroll 12 constituting the compression mechanism unit 50 so as to compress the refrigerant gas by the compression mechanism unit 50. That is, when the electric motor 60 drives the orbiting scroll 12 via the rotary main shaft 14, the compression mechanism unit 50 compresses the refrigerant gas. The electric motor 60 is generally configured by an electric motor rotor 20 fixed to the rotary main shaft 14 and an electric motor stator 21 fixedly held by the sealed container 22. The electric motor rotor 20 is fixed to the rotating main shaft 14 and is driven to rotate when the electric current to the electric motor stator 21 is started to rotate the rotating main shaft 14. Further, the outer peripheral surface of the motor stator 21 is fixedly supported on the sealed container 22 by shrink fitting or the like.

  The rotation main shaft 14 may be configured by selecting a material that has rigidity capable of securing an allowable deflection amount with respect to an acting gas load, has good machinability, and can reduce costs. An upper end portion of the rotary main shaft 14 is formed with an eccentric pin portion 14 a that is rotatably fitted to the swing scroll boss portion 12 c of the swing scroll 12. In addition, an oil supply passage 14 b serving as a passage for refrigerating machine oil stored in an oil sump 19 is formed inside the rotary main shaft 14. Then, the refrigerating machine oil collected in the oil sump 19 can be sucked up along with the rotation of the rotary main shaft 14 and supplied to the compression mechanism unit 50.

  The frame 13 has an outer peripheral surface fixed to the inner peripheral surface of the sealed container 22 by shrink fitting, welding, or the like, supports the fixed scroll 11, and can rotate the rotary main shaft 14 through a through hole formed in the center portion. It is something to support. A main bearing 36 that rotatably supports the rotary main shaft 14 is provided in the through hole. The frame 13 is installed above the sealed container 22 and supports the upper portion of the rotary main shaft 14.

  The subframe 16 has an outer peripheral surface fixed to the inner peripheral surface of the hermetic container 22 by shrink fitting, welding, or the like, and rotatably supports the rotary main shaft 14 through a through hole formed in the center portion. In this through hole, a ball bearing 17 is press-fitted and fixed in order to rotatably support the rotary spindle 14. The subframe 16 is installed below the sealed container 22 and supports the lower part of the rotary main shaft 14. Further, the subframe 16 is provided with a positive displacement oil pump 18 and is driven by the rotary main shaft 14. That is, the refrigerating machine oil stored in the oil sump 19 is sucked into the oil supply passage 14b by the oil pump 18 driven by the rotation of the rotary main shaft 14 and supplied to the compression mechanism 50 and each bearing. .

The operation of the compressor 1 will be briefly described.
When power is applied to the motor stator 21, the motor rotor 20 rotates in response to the rotational force from the rotating magnetic field generated by the motor stator 21. Along with this, the rotary main shaft 14 fixed to the motor rotor 20 and supported by the main bearing of the frame 13 and the ball bearing 17 of the sub-frame 16 is driven to rotate. A general commercial power supply of 50 Hz or 60 Hz is used as the power supply, but an inverter power supply is also used so that the drive rotational speed can be driven in the range of 600 rpm to 10,000 rpm in order to vary the refrigerant circulation amount.

  The rotational motion of the rotary main shaft 14 is transmitted to the swing scroll 12 through the eccentric pin portion 14a and the swing scroll boss portion 12c of the rotary main shaft 14. At this time, the orbiting scroll 12 is revolved while the rotation is restricted by the Oldham ring 15. That is, the Oldham ring 15 reciprocates between the Oldham groove (not shown) of the orbiting scroll 12 that houses the key portion (not shown) of the Oldham ring 15 and the Oldham groove (not shown) of the frame 13. By moving, the rotation of the rocking scroll 12 is suppressed, and rocking motion is enabled.

  As the electric motor 60 is driven, the refrigerant flowing through the pipe 5d is sucked into the sealed container 22 from the suction pipe 1b and is formed on the outer peripheral side formed by the wrap portion 12b of the swing scroll 12 and the wrap portion 11b of the fixed scroll 11. It is taken into the compression chamber 23. The refrigerant taken into the compression chamber 23 moves to the center of the orbiting scroll 12 by the orbiting motion of the orbiting scroll 12, and is compressed by further reducing the volume. At this time, the compression ratio is geometrically determined by the shape of the scroll wrap. An injection port 24 is disposed in the compression chamber 23 in the compression process in the middle of moving to the center, and the injection pipe 1c is connected to the injection port 24.

  The refrigerant sucked from the suction pipe 1b and the refrigerant supercharged via the injection port 24 are gradually compressed and become a high pressure state through the discharge port 11c formed in the end plate 11a of the fixed scroll 11, The discharge valve 25 is pushed open, flows through the discharge space 33 formed above the sealed container 22, flows through the discharge pipe 1 a, and flows out of the compressor 1. The compressed high-pressure refrigerant flows out from the discharge pipe 1a to the outside of the sealed container 22 and circulates in the refrigeration cycle.

  In the series of operations as described above, the refrigerating machine oil is supplied to the sliding portion and the bearing. For example, the wrap portion 12b and the wrap portion 11b, the seal 26 disposed on the tip surface of the wrap portion 11b and the tooth bottom surface on the wrap portion side of the end plate 12a, and the seal 26 and end plate disposed on the end surface of the wrap portion 12b. 11a, the dent portion on the lap portion side, the Oldham groove provided on the back surface opposite to the forming side of the end plate 12a and the key portion of the Oldham ring 15, the Oldham groove provided on the frame 13 in the vicinity of the main bearing, and Oldham Refrigerating machine oil is supplied to a rocking bearing (thrust bearing) provided at the center of the back surface opposite the forming side of the key portion of the ring 15 and the lap portion of the end plate 12a, the frame bearing provided at the center of the frame 13, and the like. The

  Moreover, since these sliding parts become high temperature, they are the same atmosphere as the comparatively low temperature refrigerant | coolant suck | inhaled in the airtight container 22, and are cooled. In addition, the refrigerant having a relatively low temperature sucked into the sealed container 22 has an effect of cooling the motor rotor 20 and the motor stator 21, and the suction pipe 1 b for taking in the refrigerant from the refrigerant circuit includes the frame 13 and the motor stator 21. It may be designed to be in the vicinity of each of the above.

In the refrigeration cycle apparatus 100, R410A, R407C, R404A, etc., which are commonly used HFC refrigerants having an ozone depletion coefficient of zero, can be used as the refrigerant. Recently, R32 having a small global warming potential and a mixed refrigerant containing the same may be used. When using R32 or carbon dioxide (CO ₂ ) as a refrigerant, the temperature of the refrigerant discharged from the compressor 1 is higher than that of R410A, R407C, and R404A, and the resin used as a sealing material in the refrigerant circuit Since the refrigeration oil may be deteriorated, according to the refrigeration cycle apparatus 100, the discharge temperature can be lowered using the injection mechanism.

  The injection mechanism has the effect of lowering the gas temperature during compression by injecting a liquid refrigerant or gas refrigerant having a high pressure and a low temperature into the compression chamber 23 during compression in the compression process, that is, cooled by the condenser 2. is there. At the same time, injecting a high-pressure and high-density refrigerant increases the mass in the compression chamber 23 and increases the amount of refrigerant in the compressor 1.

  Also, in recent years, halogenated hydrocarbons having a carbon double bond in the composition such as HFO1234yf, HFO1234ze, and HFO1243zf, which are called Freon-based low GWP refrigerants, hydrocarbons such as propane and propylene, which are natural refrigerants, or When a mixture containing them is used as a refrigerant, it is necessary to increase the circulation amount of the refrigerant, which is a response to a large capacity compressor. With a large-capacity compressor, when operating with a small load, that is, when operating with a small amount of refrigerant circulation, it is possible to reduce the drive speed, but it is possible to supply the minimum required lubricating oil for each bearing The drive speed can only be reduced to the limit. Therefore, the capacity control operation, which will be described below in detail, bypassing the compression chamber 23 and the suction pipe 1b side of the compressor 1 is effective for reducing the refrigerant circulation amount.

  From here, the operation mode which the refrigerating cycle apparatus 100 performs is demonstrated in detail. The refrigeration cycle apparatus 100 can select and execute an injection operation mode, a capacity control operation mode, a normal operation mode, and a suction pipe injection operation mode according to conditions. FIG. 3 is a circuit configuration diagram showing a cycle state when the refrigeration cycle apparatus 100 is in the injection operation mode. FIG. 4 is a circuit configuration diagram showing a cycle state of the refrigeration cycle apparatus 100 in the capacity control operation mode. FIG. 5 is a circuit configuration diagram showing a cycle state of the refrigeration cycle apparatus 100 in the normal operation mode. FIG. 6 is a circuit configuration diagram showing a cycle state when the refrigeration cycle apparatus 100 is in the suction pipe injection operation mode. In addition, in FIGS. 3-6, piping which does not conduct a refrigerant | coolant is represented with the broken line.

  In the injection operation mode shown in FIG. 3, the control device closes the opening / closing device 10 and closes the bypass circuit 9. That is, the control device executes the injection operation mode so that the refrigerant is not conducted to the bypass circuit 9. In the injection operation mode, the relatively cool high-pressure refrigerant that has flowed out of the condenser 2 is divided into the refrigerant that flows into the decompression mechanism 3 and the refrigerant that flows into the injection circuit 6. The refrigerant flowing into the injection circuit 6 passes through the injection circuit 6, passes through the injection pipe 1 c connected to the compressor 1, and is supercharged from the injection port 24 of the compressor 1 to the compression chamber 23 in the intermediate compression process. .

  At this time, the first flow rate adjusting device 7 and the second flow rate adjusting device 8 installed in the injection circuit 6 are controlled to open together. Then, one of the first flow rate adjusting device 7 and the second flow rate adjusting device 8 adjusts the pressure of the high-pressure refrigerant, and the other adjusts the injection amount. One guideline for adjusting the injection amount is to allow the temperature of the discharge pipe 1a of the compressor 1 to be sensed, and to prevent the deterioration of the resin used as the sealing material in the refrigerant circuit and the refrigerating machine oil. For example, it is good to adjust so that it may not exceed 100-150 degreeC. Further, in order to adjust the temperature of the refrigerant to be injected, it is possible to take measures to improve the cycle efficiency by exchanging heat with the refrigerant flowing through the injection circuit 6 and somewhere in the refrigeration cycle circuit.

  In the capacity control operation mode shown in FIG. 4, the control device closes the first flow rate adjusting device 7 and closes the first injection circuit 6a. Further, the control device forms the capacity control circuit using the second injection circuit 6b and the bypass circuit 9 by fully opening the second flow rate adjusting device 8 and opening the opening / closing device 10. That is, the control device executes the capacity control operation mode such that the refrigerant is not conducted to the first injection circuit 6a but the refrigerant being compressed flows into the bypass circuit 9 via the injection pipe 1c.

  In the capacity control operation mode, the refrigerant gas taken into the compression chamber 23 in the compressor 1 is equalized with the suction pipe 1b outside the compressor 1 via the injection port 24, so that the compression chamber 23 communicates with the injection port 24. During this time, compression is disabled. In other words, the capacity control operation mode is realized by performing the refrigerant compression operation of the compressor 1 on the center side of the scroll with respect to the injection port 24.

  At this time, the pressure loss between the second injection circuit 6b and the bypass circuit 9 needs to be minimized. This is because if the pressure loss between the second injection circuit 6b and the bypass circuit 9 is large, the resistance of the refrigerant flowing through the bypass circuit 9 increases, and the expected bypass amount cannot be obtained. If this happens, the pressure in the bypass circuit 9 will be increased, leading to waste of extra power for compressing the refrigerant that does not contribute to refrigeration on the refrigeration cycle, and reducing the efficiency of the refrigeration cycle.

  In order to avoid such a situation, it is preferable to configure the distance between the second injection circuit 6b and the bypass circuit 9 as short as possible. Therefore, it is desirable that the connection point between the bypass circuit 9 and the injection circuit 6 be located as close to the second flow rate adjusting device 8 as possible. Similarly, it is desirable that the connection point between the bypass circuit 9 and the pipe 5d is located as close as possible to the suction pipe 1b.

  Moreover, the pressure loss of the refrigerant passing through the second flow rate adjusting device 8 can be reduced by selecting the second flow rate adjusting device 8 that can increase the opening of the second flow rate adjusting device 8. In this case, heat exchange between the second injection circuit 6b and the bypass circuit 9 and somewhere in the refrigeration cycle circuit may increase the intake refrigerant temperature of the compressor 1 and should be avoided. is there. This is because when the intake refrigerant temperature of the compressor 1 increases, the intake refrigerant density decreases and the efficiency of the refrigeration cycle decreases.

  In the injection operation mode shown in FIG. 5, the control device closes both the first flow rate adjustment device 7 and the second flow rate adjustment device 8, closes the opening / closing device 10, and closes the injection circuit 6 and the bypass circuit 9. That is, the control device executes the normal operation mode so that the refrigerant is not conducted to the injection circuit 6 and the bypass circuit 9. In other words, the normal operation mode is the basic operation mode described above in which neither the injection operation mode nor the capacity control operation mode is performed.

  In the normal operation mode, it is the same as the refrigerant circuit having neither the injection circuit 6 nor the bypass circuit 9, and a very simple and highly efficient operation can be realized. In addition to the injection circuit 6 and the bypass circuit 9, the refrigerant flowing in any of the piping 5a, piping 5b, piping 5c, and piping 5d in the refrigeration cycle circuit is used for heat exchange to improve cycle efficiency. It is also possible to take measures.

  In the suction pipe injection operation mode shown in FIG. 6, the control device opens the first flow rate adjusting device 7, closes the second flow rate adjusting device 8, and closes the second injection circuit 6b. Further, the control device opens the opening / closing device 10 and forms a suction pipe injection circuit using the first injection circuit 6 a and the bypass circuit 9. That is, the control device does not conduct the refrigerant to the second injection circuit 6b, and causes the refrigerant that has flowed out of the condenser 2 to flow into the suction pipe 1b of the compressor 1 via the first injection circuit 6a and the bypass circuit 9. To execute the suction pipe injection operation mode.

  In the suction pipe injection operation mode, a relatively cool high-pressure refrigerant that has flowed out of the condenser 2 is divided into a refrigerant that flows into the decompression mechanism 3 and a refrigerant that flows into the injection circuit 6. The refrigerant flowing into the injection circuit 6 is supercharged through the first injection circuit 6 a and the bypass circuit 9 through the suction pipe 1 b connected to the compressor 1 to the hermetic container 22 of the compressor 1. At this time, the first flow rate adjusting device 7 adjusts the pressure and flow rate of the refrigerant to adjust the injection amount.

  One guideline for adjusting the injection amount is to sense the surface temperature of the hermetic container 22 of the compressor 1 and prevent deterioration of the resin and refrigerating machine oil used as the insulating material of the motor (electric motor 60). It may be adjusted so as not to exceed an allowable temperature, for example, 80 to 140 ° C. Further, in order to adjust the temperature of the refrigerant to be injected, it is possible to take measures to improve cycle efficiency by exchanging heat between the refrigerant flowing through the first injection circuit 6a and somewhere in the refrigeration cycle circuit.

Next, an example of the switching of each operation mode performed by the refrigeration cycle apparatus 100 will be described.
(1) Normal Operation Mode In the refrigeration cycle apparatus 100, the operation is normally performed in the normal operation mode including when the refrigeration cycle apparatus 100 is activated.

(2) Injection operation mode This mode is operated at the time when high pressure differential operation is required, for example, during refrigeration / freezing or heating / hot water supply operation. Under such conditions, the low-pressure pressure is relatively low and the refrigerant circulation rate is reduced. At this time, in the refrigeration cycle apparatus 100, the rotational speed of the compressor 1 increases to increase the refrigerant circulation amount, and the discharge temperature increases due to the high compression ratio operation. Therefore, the refrigeration cycle apparatus 100 selects and executes the injection operation mode.

  In the injection operation mode, in order to prevent the discharged refrigerant temperature from the compressor 1 from exceeding 100 to 150 ° C., a refrigerant having a high density and a low temperature is supercharged in the compression chamber 23 in the middle of the compression process. By doing so, the discharge temperature and the refrigerant circulation amount can be optimally adjusted. In addition, what is necessary is just to detect the refrigerant | coolant temperature discharged from the compressor 1 with the temperature sensor (not shown) etc. which were attached to the vicinity of the discharge pipe 1a.

(3) Capacity control operation mode When the required load is very small (the required load is smaller than a predetermined value set in advance), for example, a plurality of indoor units are connected to one outdoor unit. This is a mode that is operated when only one indoor unit is operated in a connected multi-air conditioner or the like. Under such conditions, the compression ratio decreases, the relatively low pressure increases, and the refrigerant circulation rate increases. At this time, in the refrigeration cycle apparatus 100, the drive rotational speed of the compressor 1 is reduced in order to reduce the refrigerant circulation amount. However, the drive rotational speed of the compressor 1 can be reduced only to the extent that the minimum required lubricating oil can be supplied at each bearing of the compressor 1. Moreover, if the compressor 1 is stopped in order to avoid it, it will be necessary to continue operation as much as possible because it takes a long time to start up or power consumption at the time of startup is large.

  Therefore, the refrigeration cycle apparatus 100 selects and executes the capacity control operation mode. By selecting the capacity control operation mode, the refrigerant is compressed from the middle of the compression chamber 23, and the refrigerant circulation amount is reduced while the operation of the compressor 1 is continued even when the load is very small. Will be able to.

(4) Suction pipe injection operation mode When a high pressure differential operation is required and the refrigerant circulation amount is very small (the refrigerant circulation amount is smaller than a predetermined value set in advance), for example, one outdoor unit On the other hand, in a multi-air conditioner or the like to which a plurality of indoor units are connected, this mode is operated when only one indoor unit is heated. Under such conditions, the load becomes high, the relatively low pressure is lowered, and the refrigerant circulation amount is reduced. At this time, in the refrigeration cycle apparatus 100, the rotational speed of the compressor 1 remains small, but the motor temperature becomes high due to the high load operation. However, since the refrigerant circulation amount is small, the motor cannot be cooled efficiently.

  Therefore, the refrigeration cycle apparatus 100 selects and executes the suction pipe injection operation mode. By selecting the suction pipe injection operation mode, a refrigerant having a high density and a low temperature can be injected into the suction pipe 1b, and the temperature around the motor can be deteriorated as a resin or refrigeration oil used as an insulating material for the motor. It is possible to adjust the temperature so as not to exceed an allowable temperature that can be prevented, for example, 80 to 140 ° C.

  As described above, according to the refrigeration cycle apparatus 100 according to the embodiment of the present invention, the compressor 1 that can be injected, the injection circuit 6, the bypass circuit 9, the first flow rate adjustment device 7, the second flow rate adjustment device 8, Since the switchgear 10 is provided, four operation modes can be selected and executed according to conditions, so that highly efficient operation can be maintained over a wide range. That is, according to the refrigeration cycle apparatus 100, it is possible to easily obtain the optimum operation state corresponding to various loads.

  Further, if the compressor 1 is configured by an inverter compressor capable of inverter control, the operating load range is further expanded, and therefore the effect exhibited by the refrigeration cycle apparatus 100 can be further enhanced. Furthermore, if the structure of the compressor 1 is a low-pressure vessel type, the motor disposed in the low-pressure space can be cooled in the suction pipe injection operation mode, and a highly efficient and long-life compressor 1 is obtained. As a result, the refrigeration cycle apparatus 100 with high efficiency and long life can be obtained.

  By the way, although the case where the compressor 1 was comprised with the scroll compressor was demonstrated, it can utilize also when the compressor 1 is comprised with the compressor of another system, for example, a rotary compressor, a screw compressor, a reciprocating compressor. Needless to say. Moreover, the 1st flow regulating device 7 and the 2nd flow regulating device 8 should just adjust the refrigerant | coolant flow volume which flows through the injection circuit 6, and do not specifically limit a kind. For example, the first flow rate adjusting device and the second flow rate adjusting device 8 may be configured by a valve device that can control the refrigerant flow rate by a stepping motor drive type. Note that the same type of device may be used for the first flow rate adjusting device 7 and the second flow rate adjusting device 8, or different devices may be used.

  The opening / closing device 10 is not particularly limited as long as the bypass circuit 9 can be opened and closed. For example, the opening / closing device 10 may be composed of a two-way valve, a pressure reducing mechanism, or the like. Furthermore, if a temperature sensor and a pressure sensor that can detect the temperature and pressure of the refrigerant, the outside air temperature, the temperature of the sealed container 22 and the like are installed, and the control device can select the operation mode based on the information. Good.

  In addition, in the case of chlorofluorocarbon-based low GWP refrigerants such as R32, the discharge temperature is higher than that of conventional refrigerants, thus preventing temperature deterioration of sealing materials, sliding members and refrigerator oil used in the refrigeration cycle. In order to secure sliding clearance, it is necessary to prevent the discharge temperature from rising excessively. However, according to the refrigeration cycle apparatus 100, since the injection operation mode is provided, a cold refrigerant is supercharged into the compression chamber 23. It is possible to suppress an excessive increase in the discharge temperature.

  In addition, when using chlorofluorocarbon-based low GWP refrigerants such as HFO1234yf and hydrocarbon-based natural refrigerants such as propane, in order to obtain refrigeration capacity, heating capacity, or efficiency equivalent to or higher than conventional ones, the compression rate of the refrigerant must be increased. Although it is necessary to take a wide range and a large refrigerant circulation amount is required, the refrigeration cycle apparatus 100 has a capacity control operation mode, so that it is possible to reduce pressure loss.

  1 compressor, 1a discharge pipe, 1b suction pipe, 1c injection pipe, 2 condenser, 3 pressure reducing mechanism, 4 evaporator, 5 pipe, 5a pipe, 5b pipe, 5c pipe, 5d pipe, 6 injection circuit, 6a 1st Injection circuit, 6b Second injection circuit, 7 First flow rate adjustment device, 8 Second flow rate adjustment device, 9 Bypass circuit, 10 Opening / closing device, 11 Fixed scroll, 11a End plate, 11b Lapping part, 11c Discharge port, 12 Swing scroll , 12a End plate, 12b Lapping part, 12c Orbiting scroll boss part, 13 frame, 14 Rotating spindle, 14a Eccentric pin part, 14b Oil supply flow path, 15 Oldham ring, 16 Subframe, 17 Ball bearing, 18 Oil pump, 19 Oil Reservoir, 20 motor rotor, 21 motor Stator, 22 sealed container, 23 compression chamber, 24 injection port, 25 discharge valve, 26 seal, 33 discharge space, 36 main bearing, 50 compression mechanism, 60 electric motor, 100 refrigeration cycle apparatus.

Claims (7)

A compressor that compresses and discharges the refrigerant, a radiator that exchanges heat between the refrigerant discharged from the compressor and a heat medium, a decompression mechanism that decompresses the refrigerant that has flowed out of the radiator, and a pressure that is decompressed by the decompression mechanism A refrigeration cycle in which an evaporator that exchanges heat between the refrigerant and the heat medium is connected by piping;
An injection circuit for connecting a pipe between the radiator and the pressure reducing mechanism and a compression chamber in the course of compression in the compressor;
A bypass circuit connecting the suction pipe of the compressor and the injection circuit;
A first flow rate adjusting device installed on the radiator side from a connection point where the bypass circuit of the injection circuit is connected;
A second flow rate adjusting device installed on the compressor side from a connection point where the bypass circuit of the injection circuit is connected;
A switchgear installed in the bypass circuit,
An injection operation mode, a capacity control operation mode, a normal operation mode, and a suction pipe injection operation mode that are executed by controlling the first flow rate adjustment device, the second flow rate adjustment device, and the opening / closing device; ,
The injection operation mode is:
The refrigerant is circulated in the refrigeration cycle, and is executed by injecting the refrigerant into the compression chamber in the course of compression in the compressor via the injection circuit,
The capacity control operation mode is:
The refrigerant is circulated in the refrigeration cycle, and the second flow rate adjusting device is installed in the injection circuit, and the compression is performed via an injection circuit and a bypass circuit connected to a compression chamber in the middle of compression in the compressor. It is executed by passing a refrigerant from the compression chamber in the middle of compression in the machine to the suction pipe of the compressor,
The normal operation mode is:
It is executed by circulating a refrigerant in the refrigeration cycle without using the injection circuit and the bypass circuit,
The suction pipe injection operation mode is:
The refrigerant is circulated through the refrigeration cycle, and the first flow rate adjusting device is installed in the injection circuit, and is connected to a pipe between the radiator and the pressure reducing mechanism via the injection circuit and the bypass circuit. The refrigeration cycle apparatus is executed by injecting refrigerant into the suction side of the compressor. When the high pressure differential operation is required, the injection operation mode is executed,
When the required load is smaller than a predetermined value set in advance, the capacity control operation mode is executed,
When the high pressure difference operation is required and the refrigerant circulation amount is smaller than a predetermined value set in advance, the suction pipe injection operation mode is executed,
The refrigeration cycle apparatus according to claim 1, wherein the normal operation mode is executed at other times. The second flow rate adjusting device is installed in the injection circuit, and the pressure loss of the injection circuit connected to the compression chamber in the middle of compression in the compressor is set, and the first flow rate adjusting device is installed in the injection circuit. The refrigeration cycle apparatus according to claim 1, wherein the pressure loss is smaller than a pressure loss of an injection circuit connected to a pipe between the radiator and the pressure reducing mechanism. By bringing the connection point of the injection circuit and the bypass circuit close to the second flow rate adjustment valve, and making the connection point of the bypass circuit and the suction side of the compressor close to the suction pipe of the compressor,
The second flow rate adjusting device is installed in the injection circuit, and the pressure loss of the injection circuit connected to the compression chamber in the middle of compression in the compressor is set, and the first flow rate adjusting device is installed in the injection circuit. The refrigeration cycle apparatus according to claim 3, wherein the pressure loss is smaller than a pressure loss of an injection circuit connected to a pipe between the radiator and the pressure reducing mechanism. The refrigeration cycle apparatus according to any one of claims 1 to 4, wherein the compressor is a low-pressure vessel type scroll compressor. The refrigeration cycle apparatus according to any one of claims 1 to 5, wherein the compressor is configured by an inverter compressor capable of inverter control. The refrigeration cycle apparatus according to any one of claims 1 to 6, wherein a chlorofluorocarbon low GWP refrigerant or a hydrocarbon natural refrigerant is used as the refrigerant.

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