JP4169620B2 - Refrigerant cycle equipment - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a refrigerant cycle apparatus including an oil separator for separating oil in refrigerant discharged from a rotary compressor and returning the oil into a sealed container.
[0002]
[Prior art]
In recent years, carbon dioxide (CO ₂ ) has been used as a refrigerant in a refrigerant cycle device of an air conditioner such as a car air conditioner in order to cope with global environmental problems (see Patent Document 1). In such a refrigerant cycle device, for example, an internal intermediate pressure type multi-stage (two-stage) compression rotary compressor is used. The rotary compressor includes a driving element and a rotary compression mechanism in a sealed container, and a gas refrigerant is sucked into the low pressure chamber side of the cylinder from the suction port of the first rotary compression element constituting the rotary compression mechanism. Compressed by the operation of the vane and becomes an intermediate pressure, and is discharged from the high pressure chamber side of the cylinder into the sealed container through the discharge port and the discharge silencer chamber.
[0003]
The intermediate-pressure gas refrigerant in the sealed container is sucked into the low-pressure chamber side of the cylinder from the suction port of the second rotary compression element, and the second-stage compression is performed by the operation of the roller and the vane, so It became a gas refrigerant, and was discharged from the refrigerant discharge pipe to the outside through the discharge port and the discharge silencer chamber from the high pressure chamber side.
[0004]
The gas refrigerant discharged from the rotary compressor flows into the gas cooler of the refrigerant circuit, dissipates heat, is throttled by an expansion valve, evaporated by an evaporator, and sucked into the first rotary compression element of the rotary compressor. Repeat the refrigerant cycle.
[0005]
[Patent Document 1]
Japanese Patent Laid-Open No. 2-294857
[Problems to be solved by the invention]
Here, in the refrigerant cycle device provided with such a rotary compressor, the gas refrigerant discharged from the second rotary compression element is discharged as it is to the external heat exchanger, so that oil flows out to the refrigerant circuit increases. . When the oil discharge amount increases, there is a problem in that the refrigerant circulation in the refrigerant circuit is hindered, the oil level in the rotary compressor is lowered, and the sliding performance and the sealing performance are lowered. This problem occurs not only in the internal intermediate pressure type rotary compressor but also in an internal low pressure type rotary compressor in which the refrigerant sucked into the hermetic container is compressed by the rotary compression element and discharged to the outside.
[0007]
Therefore, conventionally, an oil separator is connected to the refrigerant discharge pipe coming out of the rotary compressor to separate the oil from the discharged gas refrigerant and return to the sealed container through the oil return pipe. Since the inside of the vessel is at a high pressure, pressure adjustment is required to return the oil to a lower intermediate pressure or low pressure sealed container. For this reason, a conventional capillary tube is usually provided in the oil return pipe. However, if the rotational speed of the drive element is lowered and the oil discharge amount is reduced, the oil is not contained in the oil return pipe, and the refrigerant cycle is passed through the oil return pipe. The high pressure side and the intermediate pressure side (low pressure side) of the apparatus are communicated and bypassed. This causes a significant reduction in efficiency.
[0008]
On the other hand, when the rotational speed of the drive element increases and the oil discharge rate increases, the oil return amount is insufficient and the oil level decreases, resulting in the problem of oil exhaustion and sliding performance and sealing performance. there were.
[0009]
The present invention has been made in order to solve the conventional technical problems, and provides a refrigerant cycle device capable of accurately returning oil to a rotary compressor.
[0010]
[Means for Solving the Problems]
According to the first aspect of the present invention, a rotary compressor having a driving element and a rotary compression mechanism driven by the driving element in a sealed container, and oil in the refrigerant discharged from the rotary compressor are separated, In a refrigerant cycle device including an oil separator for returning to an airtight container through a return pipe, an electric expansion valve provided in the oil return pipe and a control device for controlling the opening degree of the electric expansion valve are provided. The control device controls the opening degree of the electric expansion valve in proportion to the square of the rotational speed of the drive element, and when the rotational speed becomes low, the amount of oil returning from the oil return pipe into the sealed container is reduced, and the rotational speed When the number is increased, the amount of oil returning from the oil return pipe into the sealed container is increased, so that it is possible to prevent oil depletion in the sealed container when the rotational speed of the drive element is high.
[0011]
According to a second aspect of the present invention, a rotary compressor having a driving element and a rotary compression mechanism driven by the driving element in an airtight container is separated from the oil in the refrigerant discharged from the rotary compressor, In a refrigerant cycle device including an oil separator for returning to an airtight container through a return pipe, an electromagnetic valve provided in the oil return pipe and a control device for controlling the opening time or the number of times of opening of the electromagnetic valve The control device controls the opening time or the number of times of opening of the solenoid valve in proportion to the square of the rotational speed of the drive element, and reduces the amount of oil returned from the oil return pipe to the sealed container when the rotational speed becomes low. However, when the rotational speed increases, the amount of oil returning from the oil return pipe to the sealed container increases, so that the oil in the sealed container is prevented from being exhausted when the rotational speed of the drive element is high. It becomes possible way.
[0012]
As a result, the optimum oil return can be realized at all times, and the reliability of the rotary compressor can be improved and the performance and efficiency can be significantly improved.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described in detail with reference to the drawings. FIG. 1 is a longitudinal sectional view of an internal intermediate pressure multi-stage (two-stage) compression rotary compressor 10 as an embodiment of a rotary compressor used in a refrigerant cycle apparatus 1 to which the present invention is applied, and FIG. 2 is a refrigerant cycle of the present invention. The refrigerant circuit figure of the apparatus 1 is shown, respectively. The refrigerant cycle device 1 of the embodiment is a transcritical refrigerant cycle in which the high pressure side is supercritical.
[0014]
Internal intermediate pressure type multistage (two-stage) compression type rotary compressor in the drawing 10 is to use carbon dioxide (CO ₂₎ as refrigerant, the rotary compressor 10 is a cylindrical sealed container 12 made of steel sheet, the sealed container 12 The drive element 14 arranged and housed above the internal space of the first and second rotary compression elements 32 (first stage) and the first rotary compression element 32 arranged below the drive element 14 and driven by the rotary shaft 16 of the drive element 14. The rotary compression mechanism section 18 is composed of two rotary compression elements 34 (second stage).
[0015]
The sealed container 12 has an oil sump T at the bottom, a container main body 12A that houses the drive element 14 and the rotary compression mechanism 18, and a generally bowl-shaped end cap (lid) 12B that closes the upper opening of the container main body 12A. It consists of and. A circular attachment hole 12D is formed at the center of the upper surface of the end cap 12B, and a terminal (wiring is omitted) 20 for supplying power to the drive element 14 is attached to the attachment hole 12D.
[0016]
Around the terminal 20 of the end cap 12B, a stepped portion 12C having a predetermined curvature is formed in an annular shape by press-fitting. Further, the terminal 20 includes a circular glass portion 20A to which the terminals 139 and 139 are attached and a metal attachment portion 20B formed around the glass portion 20A and projecting obliquely outward and downward in a bowl shape. It is configured. And the terminal 20 inserts the glass part 20A into the mounting hole 12D from the lower side and faces the upper side, and attaches the mounting part 20B to the peripheral edge of the mounting hole 12D, and the peripheral edge of the mounting hole 12D of the end cap 12B. The attachment portion 20B is welded to the end cap 12B.
[0017]
The drive element 14 includes a stator 22 that is annularly attached along the inner peripheral surface of the upper space of the sealed container 12, and a rotor 24 that is inserted and arranged with a slight gap inside the stator 22. Yes. The rotor 24 is fixed to a rotating shaft 16 that passes through the center and extends in the vertical direction.
[0018]
The stator 22 includes a laminated body 26 in which donut-shaped electromagnetic steel plates are laminated, and a stator coil 28 wound around a tooth portion (not shown) formed in the laminated body 26 by a direct winding (concentrated winding) method. . Similarly to the stator 22, the rotor 24 is also formed by a laminated body 30 of electromagnetic steel plates, and a permanent magnet MG is inserted into the laminated body 30.
[0019]
An intermediate partition plate 36 is sandwiched between the first rotary compression element 32 and the second rotary compression element 34. That is, the second rotary compression element 34 and the first rotary compression element 34 include an intermediate partition plate 36, cylinders 38 and cylinders 40 disposed above and below the intermediate partition plate 36, and the upper and lower cylinders 38 and 40. The upper and lower rollers 46 and 48 that are fitted to the upper and lower eccentric portions 42 and 44 provided on the rotary shaft 16 with a phase difference of 180 degrees and rotate eccentrically, and the upper and lower cylinders in contact with the upper and lower rollers 46 and 48. 38 and 40 are divided into a low pressure chamber side and a high pressure chamber side, which will be described later, upper and lower vanes (not shown), an upper surface of the upper cylinder 38 (drive element 14 side), and a lower side of the lower cylinder 40 (drive). The upper support member 54 and the lower support member 56 are configured as support members that close the opening surface on the side opposite to the element 14 and also serve as a bearing for the rotary shaft 16.
[0020]
The upper support member 54 and the lower support member 56 are formed with suction passages 58 and 60 that communicate with the inside of the upper and lower cylinders 38 and 40 through suction ports 161 and 162, and recessed discharge silencer chambers 62 and 64, respectively. The openings of both the discharge silencing chambers 62 and 64 are respectively closed by covers. That is, the discharge silence chamber 62 is closed by an upper cover 66 as a cover, and the discharge silence chamber 64 is closed by a lower cover 68 as a cover.
[0021]
In this case, a bearing 54A that is a long bearing protruding in the direction of the drive element 14 is formed upright at the center of the upper support member 54, and a cylindrical bush 122 is mounted on the inner surface of the bearing 54A. The bush 122 is interposed between the rotating shaft 16 and the bearing 54A, and the inner surface of the bush 122 is in slidable contact with the rotating shaft 16. The bush 122 is made of a highly wear-resistant carbon material that can maintain good slidability even in a situation where lubrication is insufficient.
[0022]
A bearing 56A, which is a short bearing compared to the bearing 54A, is formed through the center of the lower support member 56, and a bush 124 similar to the bush 122 is mounted on the inner surface of the bearing 56A. The bush 124 is also interposed between the rotary shaft 16 and the bearing 56A, and the inner surface of the bush 124 is slidably in contact with the rotary shaft 16. Thus, the rotary shaft 16 is held on the bearing 54A of the upper support member 54 via the bush 122 on the drive element 14 side (upper side) of the rotary compression mechanism portion 18, and the opposite side (lower side) of the drive element 14 on the bush side. It is held by a bearing 56 </ b> A of the lower support member 56 via 124.
[0023]
The lower cover 68 is formed of a donut-shaped circular steel plate, and is fixed to the lower support member 56 from below by main bolts 129... At the four peripheral portions, and the lower cylinder 40 of the first rotary compression element 32. The lower surface opening of the discharge silencing chamber 64 communicating with the inside is closed. The front ends of the main bolts 129 are screwed into the upper support member 54.
[0024]
The discharge silencer chamber 64 and the drive element 14 side of the upper cover 66 in the sealed container 12 are communicated with each other through a communication path (not shown) that is a hole penetrating the upper and lower cylinders 38 and 40 and the intermediate partition plate 36. An intermediate discharge pipe 121 is erected at the upper end of the communication path, and the intermediate discharge pipe 121 is directed to a gap between adjacent stator coils 28 and 28 wound around the stator 22 of the upper drive element 14. is doing.
[0025]
The upper cover 66 closes the upper opening of the discharge silencer chamber 62 communicating with the inside of the upper cylinder 38 of the second rotary compression element 34, and partitions the inside of the sealed container 12 into the discharge silencer chamber 62 and the drive element 14 side. . The upper cover 66 is fixed to the upper support member 54 from above by four main bolts 78. The front ends of the main bolts 78 are screwed into the lower support member 56.
[0026]
Next, in the intermediate partition plate 36 that closes the lower opening surface of the upper cylinder 38 and the upper opening surface of the lower cylinder 40, the inner periphery from the outer peripheral surface is located at a position corresponding to the suction side in the upper cylinder 38. A through-hole 131 is formed in which the outer peripheral surface and the inner peripheral surface communicate with each other to form an oil supply passage. The sealing material 132 is press-fitted into the outer peripheral surface side of the through-hole 131 and the outer peripheral surface side The opening is sealed. A communication hole 133 extending upward is formed in the middle of the through hole 131.
[0027]
On the other hand, a communication hole 134 communicating with the communication hole 133 of the intermediate partition plate 36 is formed in the suction port 161 (suction side) of the upper cylinder 38. In addition, an oil hole (not shown) provided in the vertical direction around the shaft center and lateral oil supply holes 82 and 84 communicating with the oil hole are formed in the rotary shaft 16 (not shown). The oil supply holes are also formed in the upper and lower eccentric portions 42 and 44 of the shaft 16), and the opening on the inner peripheral surface side of the through hole 131 of the intermediate partition plate 36 is connected to the oil hole via these oil supply holes 82 and 84. Communicating with
[0028]
And since the inside of the sealed container 12 has an intermediate pressure as will be described later, it is difficult to supply oil into the upper cylinder 38, which has a high pressure in the second stage. The oil pumped up from the oil reservoir T at the bottom of the inside of the sealed container 12 rises from the oil hole, exits from the oil supply holes 82 and 84, enters the through hole 131 of the intermediate partition plate 36, and passes from the communication holes 133 and 134 to the upper cylinder. 38 is supplied to the suction side (suction port 161).
[0029]
By the way, the connecting portion 90 that connects the upper and lower eccentric portions 42 and 44 formed integrally with the rotating shaft 16 with a phase difference of 180 degrees has a cross-sectional shape that is larger than the circular cross section of the rotating shaft 16. In order to enlarge and give rigidity, it is made into a non-circular shape such as a rugby ball. That is, the cross-sectional shape of the connecting portion 90 that connects the upper and lower eccentric portions 42 and 44 provided on the rotating shaft 16 is increased in thickness in a direction perpendicular to the eccentric direction of the upper and lower eccentric portions 42 and 44.
[0030]
As a result, the cross-sectional area of the connecting portion 90 that connects the upper and lower eccentric portions 42 and 44 provided integrally with the rotating shaft 16 is increased, the secondary moment is increased, the strength (rigidity) is increased, and durability and reliability are increased. Improves sex. In particular, when a refrigerant having a high operating pressure is compressed in two stages, the load applied to the rotary shaft 16 increases because the pressure difference between high and low pressures increases. However, the strength (rigidity) of the connecting portion 90 is increased by increasing the cross-sectional area. Therefore, it is possible to prevent the rotary shaft 16 from being elastically deformed.
[0031]
The rotary compressor 10 uses the carbon dioxide (CO ₂ ), which is a natural refrigerant in consideration of flammability and toxicity, as a refrigerant. The oil as the lubricating oil is, for example, mineral oil. Existing oils such as (mineral oil), alkylbenzene oil, ether oil and ester oil are used.
[0032]
The side surface of the sealed container 12 (the side surface of the container main body 12A) substantially corresponds to the suction passages 58 and 60 of the upper support member 54 and the lower support member 56, the discharge silencer chamber 62, and the upper cover 66 (the lower end of the drive element 14). The sleeves 141, 142, 143, and 144 are fixed by welding at positions corresponding to the positions of The sleeves 141 and 142 are adjacent to each other vertically, and the sleeve 143 is substantially diagonal to the sleeve 141. Further, the sleeve 144 is located at a position shifted by approximately 90 degrees from the sleeve 141.
[0033]
One end of a refrigerant introduction pipe 92 for introducing a gas refrigerant into the upper cylinder 38 is inserted into and connected to the sleeve 141, and one end of the refrigerant introduction pipe 92 communicates with a suction passage 58 of the upper cylinder 38. The refrigerant introduction pipe 92 passes through the outside of the sealed container 12 to reach the sleeve 144, and the other end is inserted and connected into the sleeve 144 to communicate with the sealed container 12.
[0034]
Further, one end of a refrigerant introduction pipe 94 for introducing a gas refrigerant into the lower cylinder 40 is inserted and connected into the sleeve 142, and one end of the refrigerant introduction pipe 94 is communicated with the suction passage 60 of the lower cylinder 40. A refrigerant discharge pipe 96 is inserted and connected into the sleeve 143, and one end of the refrigerant discharge pipe 96 is communicated with the discharge silencer chamber 62. One end of an oil return pipe 190, which will be described later, is welded and fixed between the refrigerant discharge pipe 96 on the side surface of the container body 12A and the driving element 14, and the other end opens into the sealed container 12, and the other end is an oil cooling passage 184, which will be described later. It is welded and fixed to the outlet.
[0035]
Further, a flange portion 151 (the flange portion of the sleeve 144 is not shown) is formed around the outer surface of the sleeves 141, 143, and 144 so that a coupler for pipe connection can be engaged. A connecting screw groove 152 is formed. As a result, the sleeves 141, 143, and 144 can easily connect a coupler (not shown) of the test pipe to the flange 151 when performing a hermetic test in the completion inspection in the manufacturing process of the rotary compressor 10, and the sleeve 142. In this case, the test pipe can be easily screwed by using the screw groove 152. In particular, the sleeves 141 and 142 that are adjacent in the vertical direction are formed with a flange 151 on one sleeve 141 and a thread groove 152 on the other sleeve 142, so that the test pipes can be connected to the sleeves 141 and 142 in a narrow space. Can be connected.
[0036]
The rotary compressor 10 constitutes a part of the refrigerant circuit of the refrigerant cycle device 1 such as a refrigerator, a room air conditioner, a car air conditioner, and a packaged air conditioner as shown in FIG. That is, the refrigerant discharge pipe 96 of the rotary compressor 10 is connected to the oil separator 170, and the refrigerant outlet of the oil separator 170 is connected to the inlet of the gas cooler 154. A pipe 153 on the outlet side of the gas cooler 154 reaches an inlet of an evaporator (evaporator) 157 via an expansion valve 156 as a pressure reducing device, and the outlet of the evaporator 157 is connected to a refrigerant introduction pipe 94.
[0037]
One end of an oil return pipe 190 is connected to the oil outlet of the oil separator 170. An electric expansion valve 172 as a flow path control device is connected to the oil return pipe 190, and the other end of the oil return pipe 190 is connected in communication with the sealed container 12. Reference numeral 171 denotes a controller having an inverter as a control device, and the controller 171 controls the rotational speed (operating frequency) of the drive element 14 of the rotary compressor 10 using the inverter. Further, the controller 171 controls the valve opening degree of the electric expansion valve 172 as will be described later using the rotation speed (operation frequency) of the drive element 14.
[0038]
Next, the operation of the refrigerant cycle device 1 with the above configuration will be described. When the drive element 14 of the rotary compressor 2 is energized by the controller 171 and thereby the first and second rotary compression elements 52 and 53 are driven, the rotary compressor 10 performs two-stage compression as described above, and the supercritical pressure The resulting gas refrigerant (CO ₂ ) is discharged into the refrigerant discharge pipe 96. The discharged gas refrigerant enters the oil separator 170 from the refrigerant discharge pipe 96, where oil mixed in the refrigerant is separated and collected at the bottom of the oil separator 170.
[0039]
The high-temperature and high-pressure gas refrigerant from which the oil has been separated by the oil separator 170 flows into the gas cooler 154 and is air-cooled (where the heating action is exhibited), but at this point, the refrigerant is still in the supercritical region and does not condense. . The refrigerant cooled to a predetermined temperature in the gas cooler 154 enters the expansion valve 156 from the pipe 153 and condenses in the process of being depressurized there. The liquefied refrigerant then enters the evaporator 157 where it evaporates and exhibits a cooling action. Thereafter, the refrigerant exiting the evaporator 157 repeats the cycle of being sucked into the first rotary compression element 32 of the rotary compressor 10.
[0040]
On the other hand, the oil separated by the oil separator 170 enters the oil return pipe 190 and returns to the sealed container 12 through the electric expansion valve 172. Here, the valve opening degree control of the electric expansion valve 172 by the controller 171 will be described with reference to FIG.
[0041]
The controller 171 controls the rotational speed (operating frequency) of the drive element 14 of the rotary compressor 10 based on the cooling capacity required by the evaporator 157 or the heating capacity required by the gas cooler 154. The controller 171 controls the valve opening degree of the electric expansion valve 172 in proportion to the square of the rotational speed (operating frequency) of the drive element 14. In FIG. 3, the horizontal axis X represents the operating frequency (rotation speed) of the drive element 14, the vertical axis Y represents the valve opening of the electric expansion valve 172, and the function used for control is represented by Y = F (X ² ). The
[0042]
As a result, the amount of oil returning from the oil separator 170 through the oil return pipe 190 into the sealed container 12 changes in proportion to the square of the rotational speed (operating frequency) of the drive element 14. That is, when the rotational speed of the drive element 14 is doubled, the valve opening degree of the electric expansion valve 172 is increased in proportion to the square of 2, thereby increasing the amount of oil returned from the oil return pipe 190. When the rotational speed of the drive element 14 is halved, the valve opening of the electric expansion valve 172 is narrowed in proportion to the square of ½, thereby reducing the amount of feedback oil.
[0043]
Here, it is known that the amount of oil discharged from the second rotary compression element 34 to the refrigerant discharge pipe 96 increases in proportion to the square of the rotational speed of the drive element 14. Since a large amount of oil can be returned to the sealed container 12 when the rotational speed of the element 14 is high, oil depletion does not occur. Thereby, the problem that the sealing performance and slidability in the rotary compression mechanism 18 at the time of high rotation are reduced is also avoided.
[0044]
Further, when the rotational speed of the drive element 14 is lowered, the oil discharge amount from the second rotary compression element 34 is also reduced in proportion to the square thereof, so that the amount of oil accumulated in the oil separator 170 is also reduced. Accordingly, the amount of oil entering the oil return pipe 190 from the oil separator 170 is also reduced. When oil is no longer present in the oil return pipe 190, the oil separator 170 and the sealed container 12 are communicated with each other, and the high pressure side and the intermediate pressure side of the refrigerant circuit are bypassed. 171 narrows the valve opening degree of the electric expansion valve 172 to avoid the occurrence of the bypass phenomenon. Thereby, the efficiency deterioration of the refrigerant cycle apparatus 1 is prevented.
[0045]
In the embodiment, the electric expansion valve 172 is used as the flow path control device for the oil return pipe 190. However, the present invention is not limited to this, and a normal electromagnetic valve may be used. In that case, the controller 171 controls the time that the solenoid valve is open per unit time and the number of times that the solenoid valve is opened per unit time (one open time is fixed) in proportion to the square of the rotational speed of the drive element 14. Will do.
[0046]
In the embodiment, the internal intermediate pressure type two-stage compression rotary compressor has been described as an example. However, the present invention is not limited to this, and the refrigerant from the evaporator 157 is sucked into the sealed container, and the low-pressure refrigerant in the sealed container is used as the rotary compression element. The present invention is also effective for a so-called internal low-pressure type rotary compressor that compresses and discharges outside. Such an internal low pressure type rotary compressor also increases oil discharge from the rotary compression element, so that it is possible to reliably prevent oil exhaustion of the rotary compressor and to bypass the high pressure oil separator 170 and the low pressure sealed container. To improve efficiency.
[0047]
【The invention's effect】
As described above in detail, according to the first aspect of the present invention, the rotary compressor including the driving element and the rotary compression mechanism portion driven by the driving element in the hermetic container, and the refrigerant discharged from the rotary compressor In the refrigerant cycle device having an oil separator for separating the oil of the oil and returning it to the sealed container via the oil return pipe, an electric expansion valve provided in the oil return pipe, and an opening degree of the electric expansion valve The control device controls the opening degree of the electric expansion valve in proportion to the square of the rotational speed of the drive element, and when the rotational speed becomes low, it returns to the sealed container from the oil return pipe. to reduce the amount of oil, the rotational speed increases, so increasing the amount of oil fed back into the sealed container from the oil return pipe, in preventing oil depletion in the closed container in the rotational speed is high drive element It becomes so that.
[0048]
According to the invention of claim 2, the rotary compressor provided with the driving element and the rotary compression mechanism portion driven by the driving element in the hermetic container, and the oil in the refrigerant discharged from the rotary compressor are separated. In the refrigerant cycle device having an oil separator for returning to the sealed container via the oil return pipe, a solenoid valve provided in the oil return pipe and control for controlling the opening time or the number of times of opening of the solenoid valve The control device controls the opening time or the number of times of opening of the solenoid valve in proportion to the square of the rotational speed of the drive element, and when the rotational speed becomes low, the amount of oil returning from the oil return pipe into the sealed container When the rotational speed is increased, the amount of oil returning from the oil return pipe to the sealed container is increased, so that the oil depletion in the sealed container is high when the rotational speed of the drive element is high. It will be able to prevent.
[0049]
As a result, the optimum oil return can be realized at all times, and the reliability of the rotary compressor can be improved and the performance and efficiency can be significantly improved.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view of an internal intermediate pressure type multi-stage (two-stage) rotary compressor used in a refrigerant circuit of an embodiment of a refrigerant cycle apparatus to which the present invention is applied.
FIG. 2 is a refrigerant circuit diagram of an embodiment of the refrigerant cycle device of the present invention.
3 is a diagram for explaining valve opening control of the electric expansion valve in FIG. 2; FIG.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Refrigerant-cycle apparatus 10 Rotary compressor 12 Sealed container 14 Drive element 18 Rotation compression mechanism part 32 1st rotation compression element 34 2nd rotation compression element 36 Intermediate | middle partition plate 96 Refrigerant discharge pipe 154 Gas cooler 156 Expansion valve 157 Evaporator 170 Oil Separator 171 Controller (control device)
172 Electric expansion valve 190 Oil return pipe

Claims (2)

A rotary compressor having a driving element and a rotary compression mechanism driven by the driving element in a hermetic container, and oil in the refrigerant discharged from the rotary compressor are separated, and the hermetic seal is provided via an oil return pipe. In the refrigerant cycle device provided with an oil separator for returning into the container,
An electric expansion valve provided in the oil return pipe , and a control device for controlling the opening degree of the electric expansion valve;
The control device controls the opening degree of the electric expansion valve in proportion to the square of the rotational speed of the drive element,
When the rotational speed is low, the amount of oil returning from the oil return pipe to the sealed container is reduced, and when the rotational speed is high, the amount of oil returning from the oil return pipe to the sealed container is increased. A refrigerant cycle device. A rotary compressor having a driving element and a rotary compression mechanism section driven by the driving element in a sealed container, and oil in the refrigerant discharged from the rotary compressor are separated, and the hermetic seal is provided via an oil return pipe. In the refrigerant cycle device provided with an oil separator for returning into the container,
A solenoid valve provided in the oil return pipe, and a control device for controlling the opening time or the number of times of opening of the solenoid valve;
The control device controls the opening time or number of opening of the solenoid valve in proportion to the square of the rotational speed of the driving element,
When the rotational speed is low, the amount of oil returning from the oil return pipe into the sealed container is reduced, and when the rotational speed is high, the amount of oil returning from the oil return pipe to the sealed container is increased. A refrigerant cycle device.

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