JP5538324B2 - Scroll compressor - Google Patents

Description

  The present invention relates to a scroll compressor.

  2. Description of the Related Art Conventionally, a high-pressure shell type refrigerant compressor that compresses a refrigerant introduced into an airtight container using a compression mechanism driven by an electric motor is known. For example, in a high-pressure shell type scroll compressor disclosed in Patent Document 1 below, a swing scroll having a spiral wrap and a fixed scroll are combined to face each other, and a base plate of the swing scroll is swung by a fixed scroll and a frame. It is clamped with a possible gap. The orbiting scroll is provided with a conduction hole that communicates the back pressure chamber formed between the compression chamber, the frame, and the orbiting scroll. The pressure in the back pressure chamber is maintained at an intermediate pressure between the suction pressure and the discharge pressure through the conduction hole, thereby pressing the swing scroll against the fixed scroll. An oil hole is provided in the main shaft (crankshaft), and the back pressure chamber and the oil sump are communicated with each other by a groove formed in the longitudinal direction of the shaft surface of each bearing portion of the main shaft. In addition, since the oil sump is at the discharge pressure, the refrigeration oil is supplied to the rocking bearing and the upper main bearing due to the pressure difference with the back pressure chamber, and then accumulated in the back pressure chamber and through the conduction hole. Guided to the compression chamber. A suction pipe that is welded and fixed to the upper shell via an O-ring is connected to the end portion of the fixed scroll in the axial direction of the main shaft.

  The valve disposed in the valve passage is urged in the closing direction by a spring, and is pushed downward against the urging force of the spring by a pressure difference in the refrigerant suction state. On the other hand, in a non-suction state when the operation is stopped, the valve is pushed upward by a spring, and the lower end surface of the suction pipe serves as a seat surface of the valve to prevent the backflow of the refrigerant gas.

  During operation of the scroll compressor, when refrigerant gas is drawn through the suction pipe, the pressure of the refrigerant gas causes the valve to be pushed down to a position sufficient to suck the gas against the spring bias. , Fully open. Then, the sucked refrigerant gas flows into a compression chamber formed by the fixed scroll and the swing scroll. The swinging scroll is prevented from rotating by the swinging scroll side claw and Oldham ring, and swings through the swinging bearing by the eccentric main shaft, sequentially transports the compression chamber toward the center, and sucks the refrigerant. The gas is compressed and discharged from the discharge port to the discharge chamber. The discharged high-pressure gas flows from the outer periphery of the frame to the motor side, cools the motor, and then is discharged outside the machine through the piping.

  On the other hand, when the operation of the scroll compressor is stopped, the valve is pushed up by the urging force of the spring and is closed in contact with the lower end surface of the suction pipe. As a result, the refrigeration oil does not flow back to the suction side due to the differential pressure, and there is no reverse rotation of the orbiting scroll.

  Further, in the low-pressure shell type compressor shown in the following Patent Document 2, a high-pressure space in an upper discharge muffler provided with a discharge pipe, a suction pipe, and an electric motor are arranged in a hermetic container by a compression mechanism and a frame. It is divided into a low pressure space in the lower part. The compressor includes an electric motor in a lower part inside the sealed container, and the electric motor drives a compression mechanism installed in an upper part in the sealed container via a drive shaft. The fixed scroll has a discharge path at its center, and high-pressure gas is discharged into the discharge muffler through this discharge path.

  A disc-type discharge check valve device is fitted and provided at the discharge port in the sealed container so as to supply high-pressure gas to the downstream refrigerant circuit. In addition, the closed container is provided with a suction pipe for sucking the refrigerant from the upstream refrigerant circuit.

  During the operation of the compressor, the pressure in the discharge muffler is higher than the pressure on the downstream side of the discharge check valve device, so that the high pressure gas passes through the opening, so that the flow valve moves to the open position. Therefore, the high pressure gas flows through the opening to the downstream refrigerant circuit.

  On the other hand, when the compressor is stopped, the pressure in the discharge muffler decreases to a value lower than the pressure downstream of the discharge check valve device, so that the valve overlaps the opening due to the pressure difference before and after the valve opening. Moved to the closed position prevents back flow of high pressure gas into the discharge muffler.

Japanese Patent Publication No. 1-334312 Japanese Patent Laid-Open No. 4-231691

  However, in the conventional technique disclosed in Patent Document 1, the suction check is weak because the force for moving the suction check valve in the opening direction against the biasing force of the refrigerant gas spring is weak in an operation state where the refrigerant flow rate is small. There was a problem that the valve opening could not be sufficiently obtained and pressure loss occurred due to the suction check valve narrowing the flow passage area of the suction port of the compression mechanism.

  In addition, as described above, the prior art disclosed in Patent Document 2 includes a high-pressure space in an upper discharge muffler provided with a discharge pipe, a suction pipe, and an electric motor in a sealed container by a compression mechanism and a frame. It is divided into a low pressure space in the lower part. When the compressor is stopped, the pressure in the discharge muffler decreases to a value lower than the pressure downstream of the discharge check valve device, so that a pressure difference occurs and the discharge check valve moves to the closed position. It becomes. Here, in the high-pressure shell type compressor, the compressed gas compressed to a high pressure by the compression mechanism fills the sealed container in a high-pressure atmosphere, and the compressed gas is eventually discharged from the discharge pipe to the outside of the compressor. When the compressor is stopped, the pressure in the sealed container and the pressure in the compression mechanism are gradually equalized, but the volume in the sealed container is larger than the volume in the compression mechanism. Since only a slight pressure difference is generated with respect to the pressure on the downstream side of the pipe, there has been a problem that reverse rotation occurs when the discharge check valve is delayed. That is, when the discharge check valve according to the prior art disclosed in Patent Document 2 is applied to a high-pressure shell type compressor, the discharge check valve is delayed in closing, causing a problem that reverse rotation of the orbiting scroll occurs.

  The present invention has been made in view of the above, and suppresses suction pressure loss during operation of the compressor, and reverse rotation of the orbiting scroll accompanying delay in closing the discharge check valve when the compressor is stopped. It is an object of the present invention to obtain a scroll compressor that can prevent the above.

  In order to solve the above-described problems and achieve the object, the present invention comprises a fixed scroll and an orbiting scroll, and compresses refrigerant gas introduced from the outside of the hermetic container through a suction pipe penetrating the hermetic container. And a compression mechanism that discharges into the sealed container, a frame that is fixed to the fixed scroll and that supports a rotating shaft that drives the orbiting scroll, and is provided through the sealed container and the frame. A discharge pipe for discharging the compressed refrigerant gas to the outside of the sealed container; and a flow of the refrigerant gas from the inside of the sealed container to the outside of the sealed container through the discharge pipe is opened, and the flow in the opposite direction is closed. And a first spring that urges the check valve in a closing direction, the frame includes a valve passage that slidably houses the check valve, and the discharge pipe. Previous A refrigerant passage that is provided between the valve passage and communicates the inside of the sealed container and the discharge pipe; the first spring; and the refrigerant gas compressed by the compression mechanism A valve stop surface that stops the check valve that is pressed against the urging force of the first spring by discharge pressure when discharging to the outside, and a space on the valve stop surface side of the communication path and the check valve. And a refrigerant introduction path that introduces refrigerant gas that flows back from the outside of the hermetic container to the communication path when the check valve is rubbed against the valve stop surface. It is characterized by being.

  According to this invention, since the check valve is not provided at the suction pipe outlet and the refrigerant introduction path is provided at the valve stop surface, the suction pressure loss during the operation of the compressor is suppressed, and the compressor There is an effect that it is possible to prevent the reverse rotation of the orbiting scroll accompanying the delay in closing the discharge check valve at the time of stopping.

1 is a longitudinal sectional view of a scroll compressor according to Embodiment 1 of the present invention. FIG. 2 is a longitudinal sectional view of the gas leakage prevention mechanism shown in FIG. FIG. 3 is a longitudinal sectional view of a conventional high-pressure shell type scroll compressor. FIG. 4 is a longitudinal sectional view of a conventional low-pressure shell type scroll compressor. FIG. 5 is a longitudinal sectional view of a scroll compressor according to Embodiment 2 of the present invention. FIG. 6 is a diagram for explaining the configuration of the discharge valve and the discharge port according to Embodiment 3 of the present invention. FIG. 7 is a longitudinal sectional view of a scroll compressor according to Embodiment 4 of the present invention. FIG. 8 is a longitudinal sectional view of a scroll compressor according to Embodiment 5 of the present invention. FIG. 9 is a longitudinal sectional view of a scroll compressor according to Embodiment 6 of the present invention. FIG. 10 is a longitudinal sectional view of a scroll compressor according to Embodiment 7 of the present invention. FIG. 11 is a longitudinal sectional view of a scroll compressor according to Embodiment 8 of the present invention.

  Embodiments of a scroll compressor according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a longitudinal sectional view of a scroll compressor (hereinafter simply referred to as “compressor”) 100 according to Embodiment 1 of the present invention. 2 is a longitudinal sectional view of the gas leakage prevention mechanism 80 shown in FIG. 1, and is an enlarged view of the gas leakage prevention mechanism 80 shown in FIG.

  The compressor 100 mainly includes a sealed container 10 whose inside is a high-pressure space 10a, a suction pipe 13 that penetrates the sealed container 10 and sucks refrigerant gas from an upstream refrigerant circuit (not shown), and a fixed scroll. 1 and an orbiting scroll 2 and compressing the refrigerant gas introduced through the suction pipe 13 and discharging it into the sealed container 10; and the refrigerant gas in the sealed container 10 downstream of the refrigerant circuit (not shown). A discharge pipe 12 for discharging to the downstream side, a discharge check valve 20 for blocking refrigerant gas flowing back from the downstream refrigerant circuit, a spring 22 for urging the discharge check valve 20 in the sealed container 10 inward, And a valve stop surface 4g provided with a refrigerant introduction passage 4e for guiding the refrigerant gas flowing backward from the refrigerant circuit to the back surface of the discharge check valve 20.

  The outer peripheral portion of the fixed scroll 1 shown in the upper side of FIG. 1 is fastened to the guide frame 4 with bolts (not shown), and is attached to one surface (the lower surface in FIG. 1) of the base plate portion 1 a of the fixed scroll 1. A plate-like spiral tooth 1b is formed, and a pair of Oldham guide grooves 1c are formed in a substantially straight line on the outer peripheral portion of the fixed scroll 1. A pair of fixed-side keys 9a of the Oldham mechanism 9 is engaged with the Oldham guide groove 1c so as to be freely slidable.

  A plate-like spiral tooth 2 b having the same shape as the plate-like spiral tooth 1 b of the fixed scroll 1 is formed on one surface (the upper surface in FIG. 1) of the base plate portion 2 a of the swing scroll 2. The plate-like spiral teeth 1b of the fixed scroll 1 and the plate-like spiral teeth 2b of the orbiting scroll 2 are combined so as to mesh with each other, thereby being separated by the combined plate-like spiral teeth 1b and plate-like spiral teeth 2b. A plurality of compression chambers 1f for compressing the refrigerant gas is formed in the space.

  Further, in the base plate portion 2a, a hollow cylindrical boss portion 2d is formed at the center of the surface opposite to the surface on which the plate-like spiral teeth 2b are formed (the lower surface in FIG. 1). A rocking bearing 2e is formed on the inner surface of 2d. A thrust surface 2f is formed on the outer peripheral portion of the surface on the same side as the boss portion 2d. The thrust surface 2f is slidable against the thrust bearing 3a of the compliant frame 3. A pair of Oldham guide grooves 2c having a phase difference of about 90 degrees with the Oldham guide groove 1c of the fixed scroll 1 are formed on the outer peripheral portion of the base plate portion 2a of the orbiting scroll 2 in a substantially straight line. The Oldham guide groove 2c is engaged with a pair of two swing-side keys 9b of the Oldham mechanism 9 so as to be reciprocally slidable. Further, the base plate portion 2a of the orbiting scroll 2 has a thin bleed hole through which the surface on the orbiting scroll 2 side (upper surface in FIG. 1) and the surface on the compliant frame 3 side (lower surface in FIG. 1) communicate. 2g is formed. The opening of the bleed hole 2g on the side of the compliant frame 3, that is, the lower opening 2h is arranged so that the circular locus always fits inside the thrust bearing 3a of the compliant frame 3 during normal operation. Yes.

  On the outer side of the thrust bearing 3a of the compliant frame 3, a reciprocating sliding surface 3b, which is a surface on which the Oldham mechanism annular portion 9c reciprocates, is formed. At the center of the compliant frame 3, a main bearing 3c and an auxiliary main bearing 3d that support the main shaft 6 that is rotationally driven by the electric motor 5 in the radial direction are formed. The compliant frame 3 is formed with a communication hole 3e that communicates from the thrust bearing 3a to the frame lower space 4b at a position facing the lower opening 2h of the orbiting scroll 2. Further, the reciprocating sliding surface 3b of the Oldham mechanism annular portion 9c of the compliant frame 3 has a communication hole 3f communicating with the base plate outer peripheral space 2k and the frame upper space 4a, which communicates with the inner side of the Oldham mechanism annular portion 9c. It is formed as follows. Also, the compliant frame 3 has an intermediate pressure adjusting valve space for accommodating an intermediate pressure adjusting valve 3g for adjusting the pressure of the boss outer diameter space 2n, an intermediate pressure adjusting valve presser 3h, and an intermediate pressure adjusting spring 3k. 3n is provided. Then, the intermediate pressure adjusting spring 3k is retracted from the natural length and stored.

  As shown in FIG. 1, an upper fitting cylindrical surface 4c is formed on the inner side surface of the guide frame 4 on the fixed scroll 1 side (upper side in FIG. 1), and this upper fitting cylindrical surface 4c is compliant. The upper fitting surface 3p formed on the outer peripheral surface of the frame 3 is engaged. On the other hand, a lower fitting cylindrical surface 4d is formed on the inner surface of the guide frame 4 on the electric motor 5 side (lower side in FIG. 1), and this lower fitting cylindrical surface 4d is the outer peripheral surface of the compliant frame 3. Is engaged with the lower fitting cylindrical surface 3s.

  A frame lower space 4b formed between the inner side surface of the guide frame 4 and the outer side surface of the compliant frame 3 is partitioned by an upper ring-shaped sealing material 7a and a lower ring-shaped sealing material 7b. In the example of FIG. 1, two ring-shaped seal grooves for accommodating the upper ring-shaped seal material 7 a and the lower ring-shaped seal material 7 b are formed on the outer peripheral surface of the compliant frame 3. For example, the guide frame 4 may be formed at two locations on the inner peripheral surface. Further, the space on the outer peripheral side of the thrust bearing 3a (that is, the base plate outer peripheral space 2k) surrounded by the base plate portion 2a of the orbiting scroll 2 and the compliant frame 3 in the upper and lower directions is an intake gas atmosphere (intake pressure). It is a low-pressure space.

  Further, the guide frame 4 is provided with a discharge communication passage 4h as shown in FIG. 2, and the discharge communication passage 4h is provided with a discharge pipe 12 which is press-fitted through the sealed container 10. A refrigerant introduction path 4e and a valve path 4f are provided so as to communicate with the discharge communication path 4h. The valve passage 4f is provided with a discharge check valve 20 so as to slide inside the valve passage 4f. A discharge check valve is provided at the inlet of the valve passage 4f (that is, the lower surface side of the discharge check valve 20). A valve presser 21 is provided.

  The discharge check valve 20 is biased in the closing direction (lower side in FIG. 2) by a spring 22 and stops at the end surface of the discharge check valve retainer 21. The space between the discharge check valve 20 and the discharge check valve retainer 21 is sealed, thereby preventing the reverse flow of the refrigerant gas (the refrigerant gas flowing from the valve passage 4f to the high-pressure space 10a side).

  Further, immediately after the operation of the compressor 100 is stopped, the valve stop surface 4g is sealed through the discharge pipe 12 from a refrigerant circuit on the downstream side of the discharge pipe 12 (a refrigerant circuit (not shown) connected to the left end side of the discharge pipe 12). A refrigerant introduction path 4e is provided for guiding the refrigerant gas that flows back into the container 10 to the rear end face of the discharge check valve 20 (the upper surface of the discharge check valve 20 in FIG. 2). More specifically, in the refrigerant introduction path 4e, the fixed scroll 1 and the guide frame 4 come into contact with each other from a space (discharge communication path 4h) provided between the one end 12a of the discharge pipe 12 and the valve path 4f. It is a space penetrating to the place.

  The operation of the refrigerant introduction path 4e will be specifically described. For example, when the compressed gas in the high-pressure space 10 a acts on the discharge check valve 20 provided on the outer surface of the guide frame 4, the discharge check valve 20 overcomes the urging force of the spring 22 and the valve stop surface. It hits 4g. As a result, the compressed gas in the high pressure space 10a flows into the downstream refrigerant circuit through the discharge pipe 12.

  Here, the case where the refrigerant introduction path 4e is not provided will be described. As described above, when the compressed gas in the high-pressure space 10a is acting on the discharge check valve 20, the discharge check valve 20 is in a state of hitting the valve stop surface 4g. Therefore, the refrigerant gas flowing backward from the refrigerant circuit on the downstream side of the discharge pipe 12 is guided to the front side end face of the valve discharge check valve 20 (the lower side face of the discharge check valve 20 in FIG. 2). At this time, although the biasing force of the spring 22 acts on the discharge check valve 20, the refrigerant gas flowing backward from the refrigerant circuit on the downstream side of the discharge pipe 12 flows to the front end surface of the valve discharge check valve 20. Therefore, this refrigerant gas acts as a resistance against the movement of the discharge check valve 20, and a delay in closing the discharge check valve 20 occurs. Therefore, due to the delay in closing the discharge check valve 20, a reverse sound accompanying the backflow of the refrigerant gas is generated.

  In order to suppress such a closing delay of the discharge check valve 20, the compressor 100 according to the first embodiment introduces a refrigerant introduction path that guides the refrigerant gas flowing backward from the downstream refrigerant circuit to the back surface of the discharge check valve 20. 4e is provided, the refrigerant gas flowing back to the front end face of the valve discharge check valve 20 is reduced when the refrigerant gas that has flowed back is guided to the refrigerant introduction path 4e, and therefore the discharge check valve 20 The discharge check valve 20 smoothly moves downward without delaying closing and stops at the end face of the discharge check valve retainer 21, and the discharge check valve 20 and the discharge check valve retainer 21 The gap is sealed. Therefore, the occurrence of reverse sound due to the backflow of the refrigerant gas is suppressed.

  Next, the gas leakage prevention mechanism 80 (mechanism for preventing refrigerant gas from the refrigerant circuit on the downstream side from flowing into the sealed container 10 (gas leakage) through a path other than the discharge check valve 20) will be described. The sealed container 10 is provided with a joint pipe 60 having one end 60 a inserted into the sealed container 10 and the other end 60 b protruding outside the sealed container 10. The discharge pipe 12 described above is inserted into the inner peripheral portion of the joint pipe 60, and one end 12 a thereof is closely fitted in the discharge communication path 4 h provided in the guide frame 4. Moreover, the other end 60b of the joint pipe 60 and the outer peripheral surface of the discharge pipe 12 are joined by welding, for example. By joining in this way, the downstream side of the discharge pipe 12 and the space (the high-pressure space 10a) in the sealed container 10 are partitioned. Therefore, the refrigerant gas flowing backward from the refrigerant circuit downstream of the discharge pipe 12 into the sealed container 10 flows into the sealed container 10 through, for example, the sealed container 10 and the guide frame 4 without passing through the discharge check valve 20. Can be prevented. In the above description, the other end 60b of the joint pipe 60 and the outer peripheral surface of the discharge pipe 12 are joined by welding. However, the present invention is not limited to welding, and the other end 60b of the joint pipe 60 and the discharge pipe 12 are connected. The same effect can be obtained even if the outer peripheral surface is joined by a technique other than welding.

  At the end of the main shaft 6 on the side of the orbiting scroll 2 (upper side in FIG. 1), an orbiting shaft portion 6a that is rotatably engaged with the orbiting bearing 2e of the orbiting scroll 2 is formed. A main shaft portion 6b that is rotatably engaged with the main bearing 3c and the auxiliary main bearing 3d of the compliant frame 3 is formed below 6a. Further, the other end portion of the main shaft 6 is formed with a sub-shaft portion 6c that is rotatably engaged with the sub-bearing 8a of the sub-frame 8, and the refrigerating machine oil 11 is stored in the bottom portion of the sealed container 10, The refrigerating machine oil 11 is sucked up from the lower end surface of the main shaft 6 (that is, the oil supply port 6d) by the oil supply mechanism provided on the main shaft 6.

  Next, the operation at the time of steady operation of the compressor 100 according to Embodiment 1 will be described. By the operation of the compressor 100, the refrigerant gas is sucked from the suction pipe 13 and enters the compression chamber 1 f formed by the plate-like spiral teeth 2 b of the fixed scroll 1 and the swing scroll 2. The orbiting scroll 2 driven by the electric motor 5 reduces the volume of the compression chamber 1f with an eccentric orbiting motion. In this compression stroke, the suction refrigerant gas becomes high pressure, and the high pressure compressed gas is discharged from the discharge port 1 d of the fixed scroll 1 into the sealed container 10. Therefore, the inside of the sealed container 10 is filled with a high pressure atmosphere. FIG. 1 shows a high-pressure space 10a filled with this compressed gas in a high-pressure atmosphere. The compressed gas in the high-pressure space 10a acts on the discharge check valve 20 provided on the outer surface of the guide frame 4, so that the discharge check valve 20 biases the discharge check valve 20 in the closing direction. The urging force of the spring 22 is overcome and the valve stops face 4g. As a result, the compressed gas in the high-pressure space 10a is released from the discharge pipe 12 to the outside of the compressor 100.

  When the compressed gas in the high-pressure space 10a acts on the refrigerating machine oil 11 stored at the bottom of the hermetic container 10, the refrigerating machine oil 11 flows into the oil supply port 6d. The refrigerating machine oil 11 that has flowed into the oil supply port 6d flows upward through a high-pressure oil supply hole 6e provided through the main shaft 6 in the axial direction. The refrigerating machine oil 11, which is high-pressure oil guided to the oscillating shaft upper surface boss space 2p between the upper surface of the oscillating shaft 6a and the boss portion 2d, is the narrowest oscillating shaft 6a in the oil supply path. Is reduced in the oscillating shaft side boss space 2r, which is a clearance between the oscillating bearing 2e, and becomes an intermediate pressure higher than the suction pressure and lower than the discharge pressure, and flows into the boss outer diameter space 2n. Separately from this, the refrigerating machine oil 11 in the high-pressure oil supply hole 6e is guided to the high-pressure side end face (lower end face in FIG. 1) of the main bearing 3c from the lateral hole provided in the main shaft 6, and in this oil supply path The pressure is reduced in the space 3u between the narrowest main bearing 3c and the main shaft portion 6b to become an intermediate pressure, which also flows into the outer boss space 2n. Refrigerating machine oil 11 having an intermediate pressure in boss outer diameter space 2n (generally a two-phase flow of gas refrigerant and refrigerating machine oil 11 due to firing of refrigerant dissolved in refrigerating machine oil 11) When passing through the regulating valve storage space 3n, the urging force of the intermediate pressure regulating spring 3k is overcome and the intermediate pressure regulating valve 3g is pushed up to flow into the frame upper space 4a, and then through the communication hole 3f, the Oldham mechanism annular portion 9c. It is discharged inside.

  The refrigerating machine oil 11 is supplied to the thrust surface 2f of the orbiting scroll 2 and the sliding portion of the thrust bearing 3a of the compliant frame 3, and then discharged to the inside of the Oldham mechanism annular portion 9c. The refrigerating machine oil 11 discharged from these is supplied to the sliding surface and the key sliding surface of the Oldham mechanism annular portion 9c, and then released to the base plate outer peripheral space 2k.

  As described above, the intermediate pressure Pm1 in the boss portion outer diameter space 2n is a predetermined pressure α substantially determined by the spring force of the intermediate pressure adjustment spring 3k and the intermediate pressure exposure area of the intermediate pressure adjustment valve 3g, and It is controlled by the suction atmosphere pressure (ie low pressure) Ps, and is derived by Pm1 = Ps + α.

  Further, in FIG. 1, a lower opening 2h of the bleed hole 2g provided in the base plate 2a of the orbiting scroll 2 is a thrust bearing opening 3t of the communication hole 3e provided in the compliant frame 3 (that is, FIG. 1). , The upper opening of the communication hole 3e) is always or intermittently communicated. Therefore, refrigerant gas (an intermediate pressure refrigerant gas higher than the suction pressure and lower than the discharge pressure) in the compression chamber 1 f formed by the fixed scroll 1 and the swing scroll 2 is compressed in the swing scroll 2. The air is guided to the frame lower space 4 b through the extraction hole 2 g and the communication hole 3 e of the compliant frame 3. However, although it is guided to the frame lower space 4b, the frame lower space 4b is a closed space sealed by the upper ring-shaped sealing material 7a and the lower ring-shaped sealing material 7b, and therefore the pressure fluctuation in the compression chamber during steady operation. In response to this, the compression chamber 1f and the frame lower space 4b have a minute flow in both directions, that is, in a state of breathing.

  As described above, the intermediate pressure Pm2 in the frame lower space 4b is controlled by the predetermined magnification β that is substantially determined at the position of the compression chamber 1f that communicates with the suction atmosphere pressure (ie, low pressure) Ps, and Pm2 = Ps + β Led by.

  The compliant frame 3 is guided by the guide frame 4 by the structure (that is, the two intermediate pressures Pm1 and Pm2) and the pressure of the high pressure space 10a acting on the lower end surface 3v of the compliant frame 3 (the fixed scroll 1 side ( It floats up in FIG. Therefore, the orbiting scroll 2 pressed against the compliant frame 3 via the thrust bearing 3a is also lifted upward. As a result, the tooth tip and the tooth bottom of the orbiting scroll 2 are in contact with the tooth bottom of the fixed scroll 1 respectively. Since refrigerant gas is compressed while contacting and sliding on the tooth tip, a highly efficient rotary compressor with less refrigerant gas leakage is obtained.

  On the other hand, since the gas load (Fgth) in the thrust direction acting on the orbiting scroll 2 becomes large at the time of starting or liquid compression, the orbiting scroll 2 anti-fixes the compliant frame 3 via the thrust bearing 3a. It is pushed down to the scroll 1 side (lower side in FIG. 1). Accordingly, a relatively large gap is generated between the tooth tip and the tooth bottom of the orbiting scroll 2 and the tooth bottom and the tooth tip of the fixed scroll 1, and an abnormal pressure increase in the compression chamber 1f is avoided. A highly reliable rotary compressor with less vortex and bearing damage is obtained, and the compressor 100 can be used for a long time. Furthermore, since the compressor 100 according to the first embodiment does not include a check valve in the vicinity of the suction port 1e of the fixed scroll 1, it is possible to prevent the flow path area from being narrowed and the suction pressure loss from occurring.

  Next, the operation when the compressor 100 is stopped will be described. When the operation of the compressor 100 is stopped, the fixed scroll 1 and the orbiting scroll 2 are configured, and the refrigerant mechanism does not flow from the compression chamber 1f to the frame lower space 4b when the compression mechanism 14 is stopped, and the intermediate pressure Pm2 cannot be maintained. The compliant frame 3 is lowered in the axial direction. That is, the compliant frame 3 is lowered to the guide frame 4 side. At the same time, the orbiting scroll 2 pushed up together with the compliant frame 3 is also lowered downward, and the plate-like spiral teeth 1b and the plate-like spiral teeth 2b which are combined so as to mesh with each other are separated, and a gap is generated at the tooth tip. That is, a plurality of compression chambers 1f formed by being separated by the plate-like spiral teeth 1b and the plate-like spiral teeth 2b become one space. Further, since the compression chamber 1f communicates with the suction pipe 13 through the suction port 1e, the compression chamber 1f becomes a low pressure space similar to the low pressure space of the upstream refrigerant circuit (not shown). Note that the space filled with the intermediate pressure, such as the frame lower space 4b, also communicates with the compression chamber 1f, and thus becomes a low pressure space.

  In this state, when the high pressure space of the refrigerant circuit disposed on the downstream side of the discharge pipe 12 and the low pressure space of the refrigerant circuit disposed on the upstream side of the suction pipe 13 try to equalize the refrigerant, The gas and the refrigerating machine oil 11 are discharged to the low-pressure space of the refrigerant circuit disposed on the upstream side of the suction pipe 13 through the discharge port 1d or the high-pressure oil supply hole 6e, resulting in insufficient oil supply or reverse rotation of the rocking scroll 2. .

  As shown in FIG. 2, the compressor 100 according to Embodiment 1 is provided with a refrigerant introduction path 4e on the valve stop surface 4g, whereby the refrigerant has flown back from the refrigerant circuit on the downstream side of the discharge pipe 12 to the sealed container 10. Gas is guided to the rear end face of the discharge check valve 20, and the discharge check valve 20 smoothly moves in the closing direction (lower side in FIG. 2) without being delayed due to the biasing force of the spring 22, and the discharge check valve 20 and the discharge check valve retainer 21 are sealed. Therefore, the backflow of the high pressure gas due to the delay in closing the discharge check valve 20 is prevented, and the occurrence of reverse sound is suppressed. Furthermore, the refrigerating machine oil 11 can be prevented from being taken out of the sealed container 10. As a result, it is possible to prevent a decrease in bearing reliability due to insufficient lubrication.

  One end 12 a of the discharge pipe 12 is provided on the guide frame 4 with one end 60 a inserted into the sealed container 10 and the other end 60 b inserted into the inner peripheral portion of the joint pipe 60 protruding outside the sealed container 10. The discharge communication passage 4h is closely fitted. Further, since the outer peripheral surface of the discharge pipe 12 and the other end 60b of the joint pipe 60 are joined together by welding, for example, the downstream side of the discharge pipe 12 and the space (the high pressure space 10a) in the sealed container 10 are partitioned. It is done. Therefore, according to the compressor 100 according to the first embodiment, the refrigerant gas flowing backward from the refrigerant circuit on the downstream side of the discharge pipe 12 to the sealed container 10 does not pass through the discharge check valve 20, for example, with the sealed container 10. It is possible to prevent the air from flowing into the sealed container 10 through the guide frame 4.

  Further, the compressor 100 according to Embodiment 1 is provided with a conventional suction check valve 23 and this check valve at the outlet of the suction pipe 13 in contrast to the conventional high-pressure shell type compressor with a suction check valve. Since the spring 24 is not provided, the check valve cannot be sufficiently opened in the operating state, and the check valve does not narrow the flow passage area of the suction port of the suction pipe 13. This has the effect of preventing the occurrence of pressure loss.

  Next, the effect of the compressor 100 according to Embodiment 1 of the present invention will be described in comparison with a conventional scroll compressor. In the following, the same parts as those of the compressor 100 shown in FIG. 1 are denoted by the same reference numerals and the description thereof is omitted, and only different parts will be described here.

  FIG. 3 is a longitudinal sectional view of a conventional high-pressure shell type scroll compressor 110. In the scroll compressor 100 shown in FIG. 3, the suction check valve 23 disposed in the valve passage is biased in the closing direction by the spring 24, and in the refrigerant suction state, the biasing force of the spring 24 is caused by the pressure difference. It is pushed down against. On the other hand, in the non-suction state when the operation is stopped, the suction check valve 23 is pushed upward by the spring 24, and the lower end surface of the suction pipe 13 becomes the seat surface of the suction check valve 23 and the refrigerant gas It has a structure that prevents backflow.

  When the scroll compressor 110 shown in FIG. 3 is operated, when the refrigerant gas in the low-pressure space of the upstream refrigerant circuit (not shown) is drawn through the suction pipe 13, the suction check valve 23 is spring-loaded by the suction pressure of the refrigerant gas. It is pushed down to a position sufficient to sufficiently suck the refrigerant gas against the force and is fully opened. Then, the sucked refrigerant gas flows into a compression chamber 1 f formed by the fixed scroll 1 and the swing scroll 2. The oscillating scroll 2 is oscillated by the eccentric main shaft 6 via the oscillating bearing 2e, sequentially transfers the compression chamber 1f toward the center, compresses the sucked refrigerant gas, and discharges from the discharge port 1d to the discharge chamber. To discharge. The high-pressure gas discharged into the discharge chamber flows from the outer periphery of the frame 36 toward the electric motor 5, cools the electric motor 5, and then is discharged outside the apparatus through a pipe (not shown). On the other hand, when the operation of the scroll compressor 110 shown in FIG. 3 is stopped, the suction check valve 23 is pushed up by the spring force and is brought into contact with the lower end surface of the suction pipe 13 to be closed. Thereby, the refrigerating machine oil does not flow back to the suction side due to the differential pressure, and the rocking scroll 2 is not reversed, so that no noise is generated due to the reverse rotation sound.

  However, the scroll compressor 110 shown in FIG. 3 has a weak force to move the suction check valve 23 in the opening direction against the urging force of the refrigerant gas spring 24 in an operation state where the refrigerant flow rate is small. The opening degree of the suction check valve 23 is not sufficiently obtained, and the suction check valve 23 narrows the flow passage area of the suction port of the compression mechanism 14, thereby causing a pressure loss.

  Compared to such a conventional scroll compressor 110, the compressor 100 according to the first embodiment of the present invention does not include a check valve in the vicinity of the suction port 1e of the fixed scroll 1, so that the flow path area is narrowed. Therefore, it is possible to prevent the occurrence of suction pressure loss.

  FIG. 4 is a longitudinal sectional view of a conventional low-pressure shell type scroll compressor 120. FIG. 4A is a longitudinal sectional view centering on a main part of the low-pressure shell type scroll compressor 120, and FIG. 4B is a diagram of the discharge check valve device 42 shown in FIG. It is a longitudinal cross-sectional view.

  In the sealed container 10 of the scroll compressor 120 shown in FIG. 4A, the high pressure space in the upper discharge muffler 43 provided with the discharge check valve device 42 and the suction pipe 13 are provided by the compression mechanism 14 and the frame 36. And the lower pressure space where the electric motor 5 is disposed. The fixed scroll 1 has a discharge path 45 at the center thereof, and high-pressure gas is discharged into the discharge muffler 43 through the discharge path 45. A disc-type discharge check valve device 42 is fitted to the discharge port in the sealed container 10 so as to supply high-pressure gas to the downstream refrigerant circuit. The sealed container 10 is provided with a suction pipe 13 for sucking the refrigerant from the upstream refrigerant circuit.

  When the scroll compressor 120 is in operation, the pressure in the discharge muffler 43 is higher than the pressure on the downstream side of the discharge check valve device 42, so that the high pressure gas passes through the openings 72, 74, 76, thereby Move to the open position. Therefore, the high-pressure gas flows to the downstream refrigerant circuit through the openings 72, 74, and 76. On the other hand, when the scroll compressor 120 is stopped, the pressure in the discharge muffler 43 decreases to a value lower than the pressure on the downstream side of the discharge check valve device 42. Therefore, the openings 72 and 74 of the discharge check valve device 42 are used. The flow valve 70 is moved to the closed position where it overlaps the openings 72 and 74 due to the pressure difference between before and after the high pressure gas, and the backflow of the high pressure gas into the discharge muffler 43 is prevented.

  However, when the scroll compressor 120 is stopped, the pressure in the discharge muffler 43 decreases to a value lower than the pressure on the downstream side of the discharge check valve device 42, so that a pressure difference occurs and the flow valve 70 is brought into the closed position. Will move. In general, in a high-pressure shell type compressor, the compressed gas compressed to a high pressure by the compression mechanism 14 fills the sealed container in a high-pressure atmosphere, and the compressed gas is eventually discharged from the discharge pipe to the outside of the compressor. When the compressor is stopped, the pressure in the sealed container and the pressure in the compression mechanism 14 are gradually equalized, but the volume in the sealed container is larger than the volume in the compression mechanism 14, and the pressure in the sealed container is larger. There is only a slight pressure difference between the pressure on the downstream side of the discharge pipe. Therefore, when the discharge check valve device 42 shown in FIG. 4B is applied to a high-pressure shell type compressor, a reverse rotation occurs in the compressor as the flow valve 70 is delayed.

  Compared to such a conventional scroll compressor 120, the compressor 100 according to Embodiment 1 of the present invention is provided with the refrigerant introduction passage 4e on the valve stop surface 4g, and therefore, on the downstream side of the discharge pipe 12. Refrigerant gas that has flowed back from the refrigerant circuit to the sealed container 10 is guided to the rear end face of the discharge check valve 20, and the discharge check valve 20 is closed in the closing direction (lower side in FIG. 2 without being delayed by the biasing force of the spring 22). ), The backflow of the high pressure gas due to the delay in closing the discharge check valve 20 is prevented, and the occurrence of reverse sound is suppressed.

  As described above, the compressor 100 according to the first embodiment of the present invention includes the fixed scroll 1 and the orbiting scroll 2, and from the outside of the sealed container 10 through the suction pipe 13 penetrating the sealed container 10. A compression mechanism 14 that compresses the introduced refrigerant gas and discharges it into the hermetic container 10, and a frame (guide frame) 4 that supports a rotating shaft (main shaft) 6 that is fixed to the fixed scroll 1 and drives the orbiting scroll 2. A discharge pipe 12 that discharges refrigerant gas that is provided in the closed container 10 and the guide frame 4 and is compressed by the compression mechanism 14 to the outside of the closed container 10, and from the inside of the closed container 10 through the discharge pipe 12. A check valve (discharge check valve) 20 that opens the flow of refrigerant gas toward the outside and closes the flow in the reverse direction, and a first valve that urges the discharge check valve 20 in the closing direction. (Spring) 22, and the guide frame 4 includes a valve passage 4 f that slidably accommodates the discharge check valve 20, and is disposed between the discharge pipe 12 and the valve passage 4 f. 4h for connecting the discharge pipe 12 and the discharge pipe 12 and the spring 22 by holding the spring 22 and the discharge pressure when the refrigerant gas compressed by the compression mechanism 14 is discharged to the outside of the sealed container 10 The valve stop surface 4g that stops the discharge check valve 20 that is pressed against the urging force of 22 and the space on the side of the valve stop surface 4g of the discharge check valve 20 are provided to communicate with each other. A refrigerant introduction path 4e for introducing refrigerant gas that has flowed back from the outside of the hermetic container 10 to the discharge communication path 4h when the discharge check valve 20 is slid on the surface 4g. Sealed from refrigerant circuit downstream of tube 12 The refrigerant gas that has flowed back to the vessel 10 is guided to the rear end face (refrigerant introduction path 4e) of the discharge check valve 20, and the discharge check valve 20 moves smoothly in the closing direction without being delayed by the biasing force of the spring 22. Then, the gap between the discharge check valve 20 and the discharge check valve retainer 21 is sealed. Therefore, the backflow of the high-pressure gas due to the delay in closing the discharge check valve 20 can be prevented, and the refrigerating machine oil 11 can be prevented from being taken out of the sealed container 10. As a result, it is possible to suppress the occurrence of reverse rotation noise and to prevent a decrease in bearing reliability due to insufficient lubrication. Further, since the downstream side of the discharge pipe 12 and the space in the sealed container 10 are partitioned, the refrigerant gas flowing backward from the refrigerant circuit on the downstream side of the discharge pipe 12 to the sealed container 10 does not pass through the discharge check valve 20. For example, it can prevent flowing into the sealed container 10 through between the sealed container 10 and the guide frame 4.

Embodiment 2. FIG.
FIG. 5 is a longitudinal sectional view of scroll compressor 100 according to Embodiment 2 of the present invention. The difference from the first embodiment is that a discharge valve presser 31 and a discharge valve 30 constituting a discharge valve mechanism are provided. Hereinafter, the same reference numerals are given to the same parts as those in the first embodiment, and the description thereof is omitted, and only different parts will be described here.

  The discharge valve mechanism includes a discharge valve 30 and a discharge valve retainer 31. The discharge valve 30 is provided in the fixed scroll 1 so as to be provided in the center of the back side of the fixed scroll 1 and to close (cover) the discharge port 1d that allows the inside of the compression chamber 1f and the sealed container 10 to communicate with each other. A discharge valve retainer 31 provided above the discharge valve 30 is for regulating the amount of movement of the discharge valve 30. The discharge valve 30 and the discharge valve retainer 31 are fixed to the back surface of the fixed scroll 1 with bolts 32.

  Next, the operation will be described. During the steady operation of the scroll compressor 100, the compression chamber 1f moves from the outer peripheral portion in the vicinity of the suction port 1e to the inner peripheral portion with the swinging motion of the swing scroll 2, so that the refrigerant gas inside the compression chamber 1f is changed. Compressed. When the pressure in the compression chamber 1f is higher than the pressure in the sealed container 10 when the compression chamber 1f is connected to the discharge port 1d in the final stage, the refrigerant enters the sealed container 10 from the compression chamber 1f through the discharge port 1d. Gas is discharged.

  On the other hand, when the compression chamber 1f is connected to the discharge port 1d in an operation state in which the ratio of the pressure on the downstream side of the discharge pipe 12 and the pressure on the upstream side of the suction pipe 13 is high, the pressure in the compression chamber 1f is hermetically sealed. When the pressure is lower than 10, the refrigerant gas flows backward from the space inside the sealed container 10 into the compression chamber 1f (that is, re-inhaled into the compression chamber 1f), and the compression chamber 1f recompresses the refrigerant gas again. Loss.

  Since the scroll compressor 100 is provided with the discharge valve 30 in the fixed scroll 1, the discharge valve 30 is closed when the pressure in the compression chamber 1f is lower than the pressure in the sealed container 10 (the discharge valve 30 is connected to the discharge port 1d). However, when the pressure in the compression chamber 1d becomes higher than the pressure in the sealed container 10, the discharge valve 30 is opened (the discharge valve 30 separates from the discharge port 1d). Therefore, the refrigerant gas is discharged from the compression chamber 1f into the sealed container 10 through the discharge port 1d. Thus, by providing the discharge valve 30, the high-pressure refrigerant gas once discharged from the discharge port 1d is re-inhaled into the compression chamber 1f again through the discharge port 1d during the operation of the compressor 100. Can be prevented. As a result, loss due to recompression can be prevented.

  As described above, according to the compressor 100 according to Embodiment 2 of the present invention, the fixed scroll 1 is communicated with the inside of the compression mechanism 14 and the sealed container 10 and compressed by the compression mechanism 14. A discharge port 1d that discharges the refrigerant gas to the inside of the sealed container 10 and a plate-like one end 31a are fixed to the outside of the fixed scroll 1, and the other end 31b covers the discharge port 1d from the outside of the fixed scroll 1, and is compressed. The discharge valve 30 that opens the flow of the refrigerant gas from the inside of the mechanism 14 toward the sealed container 10 and closes the flow in the opposite direction, and the surface opposite to the surface where the discharge valve 30 and the fixed scroll 1 face each other And a discharge valve presser 31 that restricts the maximum opening of the discharge valve 30 is provided, so that the high-pressure refrigerant gas once discharged from the discharge port 1d passes through the discharge port 1d. Again into the compression chamber 1f. It can be prevented from being input, so that it is possible to prevent the loss due to recompression.

Embodiment 3 FIG.
FIG. 6 is a diagram for explaining the configuration of the discharge valve 30 and the discharge port 1d according to Embodiment 3 of the present invention. The difference from the second embodiment is that an opening 30a is formed in the discharge valve 30 or an opening 1j is formed in the discharge port 1d. Hereinafter, the same parts as those of the second embodiment are denoted by the same reference numerals and the description thereof is omitted, and only different parts will be described here.

  The discharge valve 30 shown in FIG. 6A is provided with an opening 30 a that is formed smaller than the opening area of the discharge port 1 d and that allows the discharge port 1 d to communicate with the inside of the sealed container 10. The position of the opening 30a is not particularly limited, and is provided at a position where the discharge port 1d can communicate with the inside of the sealed container 10 when the discharge valve 30 covers the discharge port 1d. It only has to be.

  Further, as shown in FIG. 6B, the fixed scroll 1 is provided with a cutout shape at the inner peripheral edge 1k of the discharge port 1d, and the discharge port 1d at a position outside the outer peripheral edge 30b of the discharge valve 30. And an opening 1j that communicates the inside of the sealed container 10 with each other.

  The opening area of the opening 30a and the opening 1j is such that the high-pressure refrigerant gas discharged from the discharge port 1d is re-inhaled into the compression chamber 1f again through the discharge port 1d when the compressor 100 is in operation. Any size that can minimize the loss associated with is necessary.

  Next, the operation will be described. When the compressor 100 is stopped, the high pressure space and the low pressure space of the refrigerant circuit try to equalize the pressure, but the discharge valve 30 causes the high pressure gas in the hermetic container 10 to flow back to the compression chamber 1f through the discharge port 1d. Hindering. Therefore, the high-pressure refrigerant gas is equalized through the high-pressure oil supply hole 6e of the oil supply mechanism of the main shaft 6, and the refrigerating machine oil 11 as well as the high-pressure gas rises through the high-pressure oil supply hole 6e of the main shaft 6 and is discharged to the suction port 1e. Then, it further tries to flow out to the refrigerant circuit outside the compressor 100 through the suction pipe 13. If the oil level of the refrigerating machine oil 11 stored in the bottom of the hermetic container 10 falls below the oil supply port 6d of the main shaft 6 and cannot be sucked up, the oil cannot be supplied to the sliding part when the compressor 100 is started next time. The moving part may be damaged.

  Since the discharge valve 30 according to Embodiment 3 is provided with an opening 30a that connects the discharge port 1d and the inside of the sealed container 10, high-pressure refrigerant gas is introduced from the opening 30a of the discharge valve 30 to equalize the flow. By providing the path, the amount of the refrigerating machine oil 11 discharged through the high-pressure oil supply hole 6e to the external refrigerant circuit can be reduced. In addition, since the fixed scroll 1 according to the third embodiment is provided with the opening 1j that connects the discharge port 1d and the inside of the sealed container 10, the pressure equalizing flow path is provided in the same manner as described above. The amount discharged to the external refrigerant circuit through the high-pressure oil supply hole 6e can be reduced. Note that only one or both of the opening 30a and the opening 1j may be provided.

  In addition, since the volume of the high-pressure space and the low-pressure space of the refrigerant circuit to be equalized is large, when the compressor 100 is stopped in the operation state in which the refrigerant flow rate is large or the high-low pressure difference is large, Since the flow rate of the refrigerant flowing back from the low pressure space to the low pressure space is large, even if the opening 30a or the opening 1j is provided, the refrigerating machine oil 11 may be discharged in large quantities to the external refrigerant circuit through the high-pressure oil supply hole 6e. Seem. However, by closing the discharge check valve 20 shown in FIG. 1, the reverse flow of the refrigerant from the discharge pipe 12 into the sealed container 10 is prevented, and the refrigerator oil 11 is prevented from being taken out of the compressor 100. Can do. Therefore, it is possible to prevent a decrease in bearing reliability due to insufficient lubrication.

  As described above, according to the compressor 100 according to Embodiment 3 of the present invention, the discharge valve 30 is formed smaller than the opening area of the discharge port 1d, and the discharge port 1d and the inside of the sealed container 10 are provided. An opening 30a for communication is formed, or the fixed scroll 1 is provided in a cutout shape on the inner peripheral edge 1k of the discharge port 1d and sealed with the discharge port 1d at a position outside the outer peripheral edge 30b of the discharge valve 30. Since the opening part 1j which connects the inside of the container 10 is formed, the quantity by which the refrigerating machine oil 11 is discharged | emitted to the external refrigerant circuit through the oil supply path | route 6e can be reduced.

Embodiment 4 FIG.
FIG. 7 is a longitudinal sectional view of a scroll compressor according to Embodiment 4 of the present invention. The difference from the first embodiment is that the suction pipe 13 is provided with a suction check valve 40, a spring 41, a valve passage 1g, and a valve stop surface 1h. Hereinafter, the same reference numerals are given to the same parts as those in the first embodiment, and the description thereof is omitted, and only different parts will be described here.

  In FIG. 7, the valve passage 1 g is provided so as to communicate with the suction chamber from a direction orthogonal to or orthogonal to the plate-like spiral tooth 1 b of the fixed scroll 1. Inside, a suction check valve 40 is slidably provided, and the suction pipe 13 is press-fitted through the sealed container 10. The suction check valve 40 is biased by the spring 41 in the closing direction of the suction pipe 13, hits the end surface of the suction pipe 13, is sealed, and prevents the refrigerant from flowing backward.

  Next, the operation at the time of steady operation of the compressor 100 according to Embodiment 4 will be described. Due to the operation, the refrigerant is sucked from the suction pipe 13, and the suction check valve 40 overcomes the spring force by the suction pressure and hits the valve stop surface 1h. At this time, the suction refrigerant flows into the compression chamber 1 f formed by the plate-like spiral teeth 2 b of the fixed scroll 1 and the swing scroll 2. The compression chamber 1f moves from the outer peripheral portion near the suction port 1e to the inner peripheral portion in accordance with the swinging motion of the swing scroll 2, whereby the refrigerant gas inside the compression chamber 1f is compressed. As a result, the suction refrigerant becomes a high pressure and is discharged from the discharge port 1d of the fixed scroll 1 into the sealed container 10.

  When operating in an operating state with a large refrigerant flow rate or an operating state with a large high / low pressure difference, when the compressor 100 stops operating, the suction check valve 20 is closed to prevent the backflow of the refrigerant gas downstream of the discharge pipe 12. However, since a large amount of high-pressure gas exists in the hermetic container 10, the high-pressure gas tends to flow back to the low-pressure space upstream of the suction pipe 13 through the discharge port 1d. However, the backflow of the refrigerant gas is prevented by closing the suction check valve 40. Therefore, it is possible to prevent the occurrence of reverse rotation sound and to prevent the refrigerating machine oil 11 from being taken out of the compressor 100, thereby preventing a decrease in bearing reliability due to insufficient lubrication.

  As described above, according to the compressor 100 according to the fourth embodiment of the present invention, the flow of the refrigerant gas from the outside of the sealed container 10 toward the compression mechanism 14 is opened through the suction pipe 13, and the reverse direction A valve (suction check valve) 40 that closes the flow and a second spring (spring) 41 that biases the suction check valve 40 in a closing direction are provided. The valve passage 1g for slidably storing the valve 40 and the spring 41 are held, and the biasing force of the spring 41 is overcome by the pressure when the refrigerant gas introduced from the suction pipe 13 is introduced into the compression mechanism 14. Since the valve stop surface 1h that stops the suction check valve 40 to be pressed is provided, it is possible to prevent the occurrence of reverse rotation sound and to prevent the refrigerating machine oil 11 from being taken out of the compressor 100. Can be refueled The reduction of the bearing reliability can be prevented that.

Embodiment 5 FIG.
FIG. 8 is a longitudinal sectional view of a scroll compressor according to Embodiment 5 of the present invention. The difference from the first to fourth embodiments is that a high-pressure relief valve 50 is provided between the compression mechanism 14 and the electric motor 5. Hereinafter, the same reference numerals are given to the same parts as those in the first to fourth embodiments, and the description thereof will be omitted, and only different parts will be described here.

  FIG. 8A shows the relationship among the guide frame 4 provided with the high pressure relief valve 50, the low pressure space 10b, and the high pressure space 10a. FIG. 8B shows the detailed configuration of the high pressure relief valve 50. A high-pressure relief valve 50 shown in FIG. 8 communicates with a communication hole 51 that connects the high-pressure space 10 a and the low-pressure space 10 b, a steel ball 53 that sits on a seating surface 52 formed in the communication hole 51, and a steel ball 53. A spring 54 that presses and urges the seating surface 52 of the hole 51 with a predetermined load Fs and a spring retainer 55 that deforms the spring 54 to obtain the predetermined load Fs are configured.

  When the compressor 100 according to the fifth embodiment is operated by being applied to a refrigeration air conditioner (such as a refrigerator or an air conditioner), the high pressure or airtightness in the refrigerant circuit may be caused by stopping a condenser fan (not shown) or closing the refrigeration circuit When the pressure in the container 10 rises abnormally, the load Fp due to the pressure difference between the high pressure space 10a and the low pressure space 10b becomes larger than the predetermined load Fs due to the spring 54 of the high pressure relief valve 50. At this time, the steel ball 53 of the high pressure relief valve 50 is separated from the seating surface 52 formed in the communication hole 51, and the pressure of the high pressure space 10a is released to the low pressure space 10b side.

  By this operation, the pressing force of the compliant frame 3 that is dependent on the pressure of the high-pressure space 10a against the orbiting scroll 2 is prevented from becoming excessively large, so that the thrust bearing formed on the compliant frame 3 Even in 3a, a sufficient oil film is formed, and a more reliable rotary compressor can be obtained.

  In addition, the high pressure relief valve 50 allows the high pressure space 10a to be inserted into the tooth tip of the orbiting scroll 2 and the tooth tip of the fixed scroll 1 that support the pressing force of the compliant frame 3 against the orbiting scroll 2 via the thrust bearing 3a. Since an abnormal pressure increase is avoided, the possibility of abnormal wear or seizure of the tooth tip due to increased pressing force is extremely low.

  As described above, according to the compressor 100 according to the fifth embodiment of the present invention, the frame 4 is provided between the suction pipe 13 and the compression mechanism 14 with a predetermined pressure (the above-described suction atmospheric pressure). A communication hole 51 for communicating the first space (low pressure space) 10b filled with the second space (high pressure space) 10a filled with the refrigerant gas compressed by the compression mechanism 14 in a high pressure atmosphere higher than the predetermined pressure. A spherical valve (steel) that is provided on the high-pressure space 10a side in the communication hole 51, opens the refrigerant gas flow from the high-pressure space 10a to the low-pressure space 10b through the communication hole 51, and closes the flow in the opposite direction. Sphere) 53, a third spring 54 for urging the valve 53 in the closing direction, and the low pressure space 10b in the communication hole 51, and the refrigerant gas flowing from the high pressure space 10a toward the low pressure space 10b. The flow A spring retainer 55 that is formed in a size that does not stop and that presses the spring 54 is provided, so that an excessively large pressing force of the compliant frame 3 against the orbiting scroll 2 is avoided, and the thrust bearing 3a. Thus, abnormal wear or seizure of the tooth tip of the orbiting scroll 2 and the tooth tip of the fixed scroll 1 is suppressed, and a highly reliable rotary compressor can be obtained.

Embodiment 6 FIG.
FIG. 9 is a longitudinal sectional view of a scroll compressor according to Embodiment 6 of the present invention. The difference from the first to fourth embodiments is that the fixed scroll 1 is provided with a high-pressure relief valve 50. Hereinafter, the same reference numerals are given to the same parts as those in the first to fourth embodiments, and the description thereof will be omitted, and only different parts will be described here.

  FIG. 9A shows the relationship among the fixed scroll 1 provided with the high pressure relief valve 50, the low pressure space 10b, and the high pressure space 10a. FIG. 9B shows a detailed configuration of the high pressure relief valve 50. A high-pressure relief valve 50 shown in FIG. 9 communicates with a communication hole 51 that connects the high-pressure space 10 a and the low-pressure space 10 b, a steel ball 53 that sits on a seating surface 52 formed in the communication hole 51, and the steel ball 53. A spring 54 that presses and urges the seating surface 52 of the hole 51 with a predetermined load Fs and a spring retainer 55 that deforms the spring 54 to obtain the predetermined load Fs are configured.

  When the compressor 100 according to the sixth embodiment is operated by applying it to a refrigeration air conditioner, the high pressure in the refrigerant circuit or the pressure in the sealed container 10 is caused by stopping the condenser fan (not shown) or closing the refrigeration circuit. When the pressure rises abnormally, the load Fp due to the pressure difference between the high-pressure space 10a and the low-pressure space 10b becomes larger than the predetermined load Fs due to the spring 54 of the high-pressure relief valve 50. At this time, the steel ball 53 of the high pressure relief valve 50 is separated from the seating surface 52 formed in the communication hole 51, and the pressure of the high pressure space 10a is released to the low pressure space 10b side.

  By this operation, the pressing force of the compliant frame 3 that is dependent on the pressure of the high-pressure space 10a against the orbiting scroll 2 is prevented from becoming excessively large, so that the thrust bearing formed on the compliant frame 3 Even in 3a, a sufficient oil film is formed, and a more reliable rotary compressor can be obtained.

  In addition, the high pressure relief valve 50 allows the high pressure space 10a to be inserted into the tooth tip of the orbiting scroll 2 and the tooth tip of the fixed scroll 1 that support the pressing force of the compliant frame 3 against the orbiting scroll 2 via the thrust bearing 3a. Since an abnormal pressure increase is avoided, the possibility of abnormal wear or seizure of the tooth tip due to increased pressing force is extremely low.

  As described above, according to the compressor 100 according to Embodiment 6 of the present invention, the fixed scroll 1 is provided between the suction pipe 13 and the compression mechanism 14 with a predetermined pressure (the above-described suction atmospheric pressure). ) Communicating with the first space (low pressure space) 10b filled with the second space (high pressure space) 10a filled with the refrigerant gas compressed by the compression mechanism 14 in a high pressure atmosphere higher than the predetermined pressure. 51, a spherical valve (provided on the high-pressure space 10a side in the communication hole 51, which opens the refrigerant gas flow from the high-pressure space 10a to the low-pressure space 10b through the communication hole 51 and closes the flow in the opposite direction) (Steel ball) 53, a third spring (spring) 54 that biases the valve 53 in the closing direction, and a refrigerant gas that is disposed on the low-pressure space 10b side in the communication hole 51 and travels from the high-pressure space 10a toward the low-pressure space 10b. of Since the spring presser 55 is formed in such a size that does not prevent this, and the spring 54 is pressed down, it is possible to avoid an excessive increase in the pressing force of the compliant frame 3 against the orbiting scroll 2. Abnormal wear or seizure of the bearing 3a, the tooth tip of the orbiting scroll 2 and the tooth tip of the fixed scroll 1 is suppressed, and a highly reliable rotary compressor can be obtained.

Embodiment 7 FIG.
FIG. 10 is a longitudinal sectional view of a scroll compressor according to Embodiment 7 of the present invention. The difference from the first to sixth embodiments is that a motor protection device 56 is provided at the coil end 5 c of the motor 5. Hereinafter, the same parts as those in the first to sixth embodiments are denoted by the same reference numerals, and the description thereof will be omitted. Only different parts will be described here.

  As shown in FIG. 10, a temperature detection type motor protection device 56 is mounted between the compression mechanism 14 and the coil end 5 c wound around the stator 5 b of the motor 5.

  When the high pressure in the refrigerant circuit or the pressure in the sealed container 10 rises abnormally due to the stoppage of the condenser fan (not shown), the refrigeration circuit being blocked, etc., and the high pressure relief valve 50 is actuated, The high-pressure and high-temperature refrigerant gas that flows in is compressed again by the compression mechanism 14, and the refrigerant discharge gas temperature rapidly rises. At this time, the temperature of the electric motor 5 disposed in the high-pressure space 10a from which the refrigerant gas has been once released also rises almost in synchronization with the sudden rise in the temperature of the discharge gas. However, since the motor protection device 56 attached to the coil end 5c of the motor 5 directly detects the temperature of the coil end 5c, the rapid temperature rise of the motor 5 is immediately detected and the compressor 100 is stopped. Deterioration and burnout of the insulating material of the electric motor 5, deterioration of the refrigerating machine oil 11, and the like are prevented, and high reliability can be obtained.

  As described above, according to the compressor 100 according to the seventh embodiment of the present invention, the coil end 5c wound around the stator 5b of the electric motor 5 that rotationally drives the main shaft 6 includes the sealed container 10. An increase in the internal temperature is detected, and the detected temperature value becomes a predetermined value before the electric motor 5 reaches a failure state (for example, a value that is lower by several degrees to several tens of degrees C. than a temperature limit value at which the electric motor 5 will fail). Since the motor protection device 56 for stopping the electric motor 5 when it reaches is provided, it is possible to immediately detect a rapid temperature rise of the electric motor 5 and stop the compressor 100. As a result, it is possible to prevent deterioration of the insulating material of the electric motor 5, burnout, deterioration of the refrigerating machine oil 11, and the like, and to obtain high reliability.

Embodiment 8 FIG.
FIG. 11 is a longitudinal sectional view of a scroll compressor according to Embodiment 8 of the present invention. The difference from the first to sixth embodiments is that an electric motor protection device 57 is provided in the upper part of the sealed container 10. Hereinafter, the same parts as those in the first to sixth embodiments are denoted by the same reference numerals, and the description thereof will be omitted. Only different parts will be described here.

  As shown in FIG. 11, an electric motor protection device 57, which is a temperature detection type switch or sensor, is attached to the upper part of the sealed container 10.

  When the high pressure in the refrigerant circuit or the pressure in the sealed container 10 rises abnormally due to the stoppage of the condenser fan (not shown), the refrigeration circuit being blocked, etc., and the high pressure relief valve 50 is activated, the high pressure space 10a is changed to the low pressure space 10b. The high-pressure and high-temperature refrigerant gas that flows in is compressed again by the compression mechanism 14, and the refrigerant discharge gas temperature rapidly rises. At this time, the temperature of the electric motor 5 disposed in the high-pressure space 10a from which the refrigerant gas has been once released also rises almost in synchronization with the sudden rise in the temperature of the discharge gas. However, since the temperature of the refrigerant gas discharged from the discharge port 1d can be quickly detected by the motor protection device 57 mounted in the vicinity of the discharge port 1d and on the upper portion of the sealed container 10, the inside of the sealed container 10 The compressor 100 can be stopped by predicting the temperature increase of the electric motor 5 due to the temperature increase. As a result, it is possible to prevent deterioration of the insulating material of the electric motor 5, burnout, deterioration of the refrigerating machine oil 11, and the like, and to obtain high reliability. Since the electric motor protection device 57 can be retrofitted to the existing compressor 100, the reliability of the existing compressor 100 can be improved.

  As described above, according to the compressor 100 according to the eighth embodiment of the present invention, an increase in the internal temperature of the sealed container 10 is caused on the outer peripheral surface of the sealed container 10 covered on the upper side of the fixed scroll 1. When the detected temperature value reaches a predetermined value before the electric motor 5 reaches the failure state (for example, a value that is lower by about several degrees Celsius to several tens of degrees Celsius than the temperature limit value at which the electric motor 5 will fail). Since the motor protection device 57 for stopping the engine is disposed, the insulating material of the motor 5 is prevented from being deteriorated and burned out, the refrigerator oil 11 is prevented from being deteriorated, and high reliability can be obtained.

  The scroll compressor shown in the embodiment of the present invention shows an example of the contents of the present invention, and can be combined with another known technique, and deviates from the gist of the present invention. Of course, it is possible to change and configure such as omitting a part within the range.

  As described above, the present invention is applicable to a scroll compressor, and is particularly useful as an invention that can improve the reliability of the scroll compressor.

DESCRIPTION OF SYMBOLS 1 Fixed scroll 1a, 2a Base plate part 1b, 2b Plate-shaped spiral tooth 1c, 2c Oldham guide groove 1d Discharge port 1e Suction port 1f Compression chamber 1g, 4f Valve channel | path 1h, 4g Valve stop surface 1j Opening part 1k Inner periphery 2 Shaking Dynamic scroll 2d Boss part 2e Oscillating bearing 2f Thrust surface 2g Extraction hole 2h Lower opening 2k Base plate outer peripheral space 2n Boss outer diameter space 2p Oscillating shaft upper surface boss part space 2r Oscillating axis side boss part space 3 Compliant Frame 3a Thrust bearing 3b Reciprocating sliding surface 3c Main bearing 3d Auxiliary main bearing 3e, 3f, 51 Communication hole 3g Intermediate pressure adjusting valve 3h Intermediate pressure adjusting valve holder 3k Intermediate pressure adjusting spring 3n Intermediate pressure adjusting valve space 3p Upper fitting surface 3s Lower fitting cylindrical surface 3t Thrust bearing opening 3u Space 3v Lower end surface 4 Guide frame (frame)
4a Frame upper space 4b Frame lower space 4c Upper fitting cylindrical surface 4d Lower fitting cylindrical surface 4e Refrigerant introduction passage 4h Discharge communication passage (communication passage)
5 Motor 5b Stator 5c Coil end 6 Spindle (Rotating shaft)
6a Oscillating shaft portion 6b Main shaft portion 6c Sub shaft portion 6d Oil supply port 6e High pressure oil supply hole 7a Upper ring-shaped seal material 7b Lower ring-shaped seal material 8 Subframe 8a Sub bearing 9 Oldham mechanism 9a Fixed side key 9b Oscillating side key 9c Oldham mechanism annulus 10 Sealed container 10a High-pressure space (second space)
10b Low pressure space (first space)
11 Refrigerating machine oil 12 Discharge pipe 12a, 31a, 60a One end 13 Suction pipe 14 Compression mechanism 20 Discharge check valve (check valve)
21 Discharge check valve retainer 22 Spring (first spring)
24 Spring 23, 40 Suction check valve 30 Discharge valve 30a Opening 30b Outer peripheral edge 31 Discharge valve retainer 31b, 60b The other end 32 Bolt 36 Frame 41 Spring (second spring)
42 Discharge check valve device 43 Discharge muffler 45 Discharge path 50 High pressure relief valve 52 Seating surface 53 Steel ball (valve)
54 Spring (third spring)
55 Spring retainer 56, 57 Motor protection device 60 Joint pipe (pipe)
70 Flow valve 80 Gas leak prevention mechanism 100, 110 Compressor

Claims (8)

A compression mechanism comprising a fixed scroll and an orbiting scroll, and compressing a refrigerant gas introduced from the outside of the sealed container through a suction pipe penetrating the sealed container and discharging the refrigerant gas to the inside of the sealed container;
A frame that is fixed to the fixed scroll and supports a rotating shaft that drives the orbiting scroll;
A discharge pipe penetrating the sealed container and the frame and discharging the refrigerant gas compressed by the compression mechanism to the outside of the sealed container;
A check valve that opens the flow of the refrigerant gas from the inside of the sealed container to the outside of the sealed container through the discharge pipe, and closes the flow in the reverse direction;
A first spring that biases the check valve in a closing direction;
With
The frame includes
A valve passage for slidably storing the check valve;
A communication path that is provided between the discharge pipe and the valve path and communicates the inside of the sealed container and the discharge pipe;
The check valve that holds the first spring and is pressed against the urging force of the first spring by a discharge pressure when the refrigerant gas compressed by the compression mechanism is discharged to the outside of the sealed container. A valve stop surface to stop
The communication path and the valve stop surface side space of the check valve are provided so as to communicate with each other, and the check valve is slid on the valve stop surface from the outside of the sealed container. A refrigerant introduction path for introducing refrigerant gas that has flowed back into the communication path;
The scroll compressor characterized by being provided. For the fixed scroll,
A discharge port for communicating the inside of the compression mechanism and the sealed container, and discharging the refrigerant gas compressed by the compression mechanism to the inside of the sealed container;
It has a plate shape, one end is fixed to the outside of the fixed scroll and the other end covers the discharge port from the outside of the fixed scroll, and the flow of the refrigerant gas from the inside of the compression mechanism toward the sealed container is opened, A discharge valve that closes the flow in the opposite direction;
A discharge valve presser that is superposed on the discharge valve on a surface opposite to a surface on which the discharge valve and the fixed scroll face, and restricts a maximum opening of the discharge valve;
The scroll compressor according to claim 1, wherein the scroll compressor is provided.   The discharge valve is formed with an opening that is smaller than the opening area of the discharge port and allows the discharge port to communicate with the inside of the sealed container, or the discharge port has an inner peripheral edge of the discharge port. The opening part which connects the said discharge outlet and the inside of the said airtight container in the position outside the outer periphery of the said discharge valve provided in the notch shape is formed. Scroll compressor. A valve for opening the flow of the refrigerant gas from the outside of the sealed container to the compression mechanism through the suction pipe and closing the flow in the opposite direction;
A second spring that biases the valve in a closing direction;
With
For the fixed scroll,
A valve passage for slidably storing the valve;
A valve stop for holding the second spring and stopping the valve pressed against the urging force of the second spring by the pressure when the refrigerant gas introduced from the suction pipe is introduced into the compression mechanism. Surface,
Is provided, The scroll compressor as described in any one of Claims 1-3 characterized by the above-mentioned. The frame includes
A first space provided between the suction pipe and the compression mechanism and filled with a predetermined pressure, and a second space filled with a high-pressure atmosphere higher than the predetermined pressure by the refrigerant gas compressed by the compression mechanism. A communication hole for communication,
A spherical shape that is provided on the second space side in the communication hole, opens the refrigerant gas flow from the second space to the first space through the communication hole, and closes the flow in the opposite direction. A valve,
A third spring that biases the valve in a closing direction;
A spring retainer that is disposed on the first space side in the communication hole, is formed in a size that does not block the flow of the refrigerant gas from the second space toward the first space, and that presses the third spring. When,
Is provided, The scroll compressor as described in any one of Claims 1-4 characterized by the above-mentioned. For the fixed scroll,
A first space provided between the suction pipe and the compression mechanism and filled with a predetermined pressure, and a second space filled with a high-pressure atmosphere higher than the predetermined pressure by the refrigerant gas compressed by the compression mechanism. A communication hole for communication,
A spherical shape that is provided on the second space side in the communication hole, opens the refrigerant gas flow from the second space to the first space through the communication hole, and closes the flow in the opposite direction. A valve,
A third spring that biases the valve in a closing direction;
A spring retainer that is disposed on the first space side in the communication hole, is formed in a size that does not block the flow of the refrigerant gas from the second space toward the first space, and that presses the third spring. When,
Is provided, The scroll compressor as described in any one of Claims 1-4 characterized by the above-mentioned. In the coil end wound around the stator of the electric motor that rotationally drives the rotating shaft,
An electric motor protection device is provided that detects an increase in the internal temperature of the hermetic container and stops the electric motor when the detected temperature value reaches a predetermined value before the electric motor reaches a failure state. A scroll compressor according to any one of claims 1 to 6. On the outer peripheral surface of the sealed container covered on the upper side of the fixed scroll,
An electric motor protection device that detects an increase in the internal temperature of the sealed container and stops the electric motor when the value of the detected temperature reaches a predetermined value before the electric motor reaches a failure state is provided. The scroll compressor according to any one of claims 1 to 6.

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