JP4667649B2 - Scroll compressor - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a scroll compressor used in a refrigeration air conditioner.
[0002]
[Prior art]
FIG. 3 is a longitudinal sectional view of a conventional scroll compressor disclosed in, for example, Japanese Patent Laid-Open No. 11-107938, and FIG. 4 is a detailed view of the vicinity of the oil supply hole in FIG. 3 and 4, reference numeral 1 denotes a fixed scroll, and the outer peripheral portion is fastened to a guide frame 4 (described later) by bolts (not shown), and is also on one surface (right side in FIG. 3) of the base plate portion 1a. Is formed with a plate-like spiral tooth 1b. Further, a cylindrical fitting surface 1c that engages with an upper fitting cylindrical surface 3a of a compliant frame 3 to be described later is formed on the outer peripheral portion, and suction is performed from the upper surface direction (left side in FIG. 3) of the fixed scroll 1. A tube 14 a is press-fitted through the sealed container 14.
Reference numeral 2 denotes a swing scroll, and a plate-like spiral tooth 2b having substantially the same shape as the plate-like spiral tooth 1b of the fixed scroll 1 is formed on one surface (left side in FIG. 3) of the base plate portion 2a. Further, a hollow cylindrical boss 2f is formed at the center of the surface opposite to the plate-like spiral tooth 2b (right side in FIG. 3) of the base plate 2a, and on the inner surface of the boss 2f. A rocking bearing 2d is formed and is rotatably engaged with a slider (not shown). In addition, a thrust surface that can slide in pressure contact with the thrust bearing 3g of the compliant frame 3 is formed on the outer peripheral portion of the surface on the same side as the boss portion 2f. In addition, a spiral groove is formed in the tooth tip portion of the plate-like spiral tooth 1b of the fixed scroll 1 and the plate-like spiral tooth 2b of the orbiting scroll 2, and chip seals (not shown) are respectively formed in the grooves. ) Is inserted.
[0003]
Reference numeral 3 denotes a compliant frame, and a main bearing 3c and an auxiliary main bearing 3d that support the main shaft 5 that is rotationally driven by an electric motor in the radial direction are formed at the center of the compliant frame 3. A dimension stop plate 17 is inserted between the dimension stop surface (not shown) of the compliant frame 3 and the dimension stop surface 1 d of the fixed scroll 1.
[0004]
Reference numeral 4 denotes a guide frame. Although the outer peripheral surface of the guide frame 4 is fixed to the hermetic container 14 by shrink fitting or welding, a high pressure refrigerant gas discharged from the discharge port 1e of the fixed scroll 1 is guided into the guide frame. 4, the flow path leading to the discharge pipe 14 b provided on the motor side (on the right side in FIG. 3, the motor stator 8 and the motor rotor 8 a side) is secured in the upper half of the sealed container 14, and at the same time A flow path that allows the refrigerating machine oil 13 to come and go is secured in the lower half of 14. Further, a lower fitting cylindrical surface 4b is formed on the motor side (right side in FIG. 3) of the inner side surface of the guide frame 4, and the lower fitting cylindrical surface 3b formed on the outer peripheral surface of the compliant frame 3; Is engaged.
In addition, the inner side surface 4c of the guide frame 4 is formed with two sealing grooves for storing the sealing material, and the upper sealing material 9 and the lower sealing material 10 are fitted into these sealing grooves. A space formed by these two sealing materials 9, 10 and the inner side surface 4c of the guide frame 4 and the outer side surface 3h of the compliant frame 3, that is, the frame space 4d is a pressure equalizing hole 3q formed in the compliant frame 3. It communicates with the boss portion outer space 2h via.
[0005]
The space on the outer peripheral side of the thrust bearing 3g surrounded by the base plate 2a of the orbiting scroll 2 and the compliant frame 3, that is, the base plate outer peripheral space 2g, is a space near the end of winding of the plate-like spiral teeth. Since it is in communication with the low pressure space 11 into which the suction gas is sucked, the suction gas atmosphere is formed. A pin portion (not shown) having a flat portion substantially parallel to the axial direction of the main shaft is formed at an end of the main shaft 5 on the swing scroll side (left side in FIG. 3). And a flat portion formed on the inner surface of the slider are engaged so as to be slidable back and forth. A main shaft balancer 5d is shrink fitted on the lower side, and a main shaft portion that is rotatably engaged with the main bearing 3c and the auxiliary main bearing 3d of the compliant frame 3 is formed on the lower side. .
[0006]
Further, the other end portion of the main shaft is formed with a sub-shaft portion that is rotatably engaged with the sub-bearing 18a and the auxiliary sub-bearing 18b of the sub-frame 18, and between the sub-shaft portion and the main shaft portion described above. An electric motor rotor 8a is shrink-fitted into. An upper balancer 8b is fastened to the left end of the motor rotor 8a, and a lower balancer 8c is fastened to the right end surface. The three balancers with the main spindle balancer 5d described above achieve a static balance and a dynamic balance. ing. A subframe cover 18 c is attached to the subframe 18, and a subbearing space 18 d is formed between the lower end surface of the main shaft 5. A glass terminal 14 c is attached to the side surface of the sealed container 14, and a lead wire from the motor stator 8 is joined.
[0007]
Next, the basic operation of this scroll compressor will be described. During steady operation, although the sum of the force resulting from the intermediate pressure in the boss outer space 2h and the pressing force from the orbiting scroll 2 via the thrust bearing 3g acts on the compliant frame 3 as a downward force, The sum of the force caused by the intermediate pressure in the frame space 4d and the force caused by the high pressure acting on the portion exposed to the high-pressure atmosphere at the lower end surface acts as an upward force, and this upward force is the downward force described above. It is set to be greater than the force. Therefore, the compliant frame 3 is guided by the upper fitting cylindrical surface 3 c of the fixed scroll 1 and the lower fitting cylindrical surface 3 b of the guide frame 4 by the lower fitting cylindrical surface 4 b of the fixed scroll 1. As a result, the dimension stop surface of the compliant frame 3 is in pressure contact with the dimension stop surface 1d of the fixed scroll 1 via the dimension stop plate 17. On the other hand, the swing scroll 2 pressed against the compliant frame 3 via the thrust bearing 3g moves to the left by being pressed by the compliant frame 3, but the tooth tip and the tooth bottom of the swing scroll 2 are fixed. The scroll 1 is operated with a predetermined gap between the tooth bottom and the tooth tip.
Thus, the low-pressure suction gas sucked from the suction pipe 14a is compressed in the compression chamber formed by the respective plate-like spiral teeth 1b and 2b of the fixed scroll 1 and the swing scroll 2, and the high-pressure gas. Then, the liquid is discharged from the discharge port 1e into the sealed container 14, and discharged from the discharge pipe 14b to the outside of the sealed container 14.
[0008]
Depending on the operating conditions, specifically, when the discharge gas temperature is high, such as in a high compression ratio operation, the thermal expansion of both plate-like spiral teeth increases particularly near its center, and the teeth of both plate-like spiral teeth It may happen that the tip and the root of the tooth come into pressure contact. However, in that case, the rocking scroll 2 is slightly relieved together with the compliant frame 3, so that there is no problem of reliability such as seizure.
[0009]
Further, at the time of start-up or liquid compression, the thrust direction gas load Fgth acting on the orbiting scroll 2 increases, and the orbiting scroll 2 moves the compliant frame 3 to the opposite side of the fixed scroll via the thrust bearing 3g ( 3 (rightward in FIG. 3), the gap 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 becomes relatively large, and an abnormal pressure rise in the compression chamber is avoided. The
[0010]
The compliant frame 3 receives part or all of the overturning moment of the orbiting scroll 2 via the thrust bearing 3g, but the bearing load received from the main bearing 3c and the resultant force of the two forces, that is, the upper force The couple generated by the resultant force of the reaction force received from the fixed scroll 1 via the fitting cylindrical surface 3a and the reaction force received from the guide frame 4 via the lower fitting cylindrical surface 3b acts so as to cancel the rollover moment. Therefore, it has very good following operation stability and relief operation stability during steady operation.
[0011]
Next, the oil supply path of the conventional scroll compressor will be described with reference to FIGS. The refrigerating machine oil 13 collected at the bottom of the sealed container 14 is sucked with a slight differential pressure into an oil supply hole 4 e provided at the guide frame 4 and opened at the bottom of the sealed container 14, and the compliant frame 3 and the guide frame 4 To the second frame space 4f. In the second frame space 4f, the left side in FIG. 4 is partitioned from the frame space 4d, which is an intermediate pressure, by the lower sealing material 10, and the right side is below the lower fitting cylindrical surface 3b of the compliant frame 3 and the guide frame 4. It is partitioned at a fitting portion with the fitting cylindrical surface 4b. Next, the refrigerating machine oil 13 in the second frame space 4 f enters the spindle lubrication inlet space 3 s through the oil supply hole 3 r provided in the compliant frame 3. Most of the refrigerating machine oil 13 is squeezed by the bearing clearance of the main bearing 3c and proceeds to the left in FIG. 3 or FIG. 4 while reducing the pressure. Become. On the other hand, the remaining refrigerating machine oil 13 guided to the main shaft lubrication inlet space 3s is guided to the main shaft lower half oblique vertical groove 5e of the main shaft 5 as shown in FIG. 4, and lubricates the auxiliary main bearing 3d.
[0012]
Since the lower half oblique vertical groove 5e of the main shaft communicates with the main shaft lubrication inlet space 3s and the lower end stops in the middle of the auxiliary main bearing 3d, a large amount of refrigerating machine oil 13 is supplied to the auxiliary main bearing. There is no leakage from the right edge of 3d. Further, the main shaft lower half oblique vertical groove 5e is twisted in the direction opposite to the rotation direction of the main shaft 5 from the inlet toward the bag path (from left to right in FIGS. 3 and 4). The refrigerating machine oil 13 in the spindle lubrication inlet space 3s is pumped toward the bag path (to the right in FIGS. 3 and 4).
[0013]
[Problems to be solved by the invention]
3 and FIG. 4, for example, according to the configuration of the scroll compressor disclosed in Japanese Patent Application Laid-Open No. 11-107938, the compliant frame 3 has an upper fitting cylindrical surface 3a formed on the upper fitting cylindrical surface 3c. Further, the lower fitting cylindrical surface 3b is guided by the lower fitting cylindrical surface 4b of the guide frame 4 and is movable in the axial direction. Therefore, although the compliant frame 3 receives a part or all of the overturning moment of the orbiting scroll 2 through the thrust bearing 3g, the compliant frame 3 receives the bearing load received from the main bearing 3c and the resultant force of the two forces, that is, the upper force. The couple generated by the resultant force of the reaction force received from the fixed scroll 1 via the fitting cylindrical surface 3a and the reaction force received from the guide frame 4 via the lower fitting cylindrical surface 3b acts so as to cancel the rollover moment. Therefore, it has very good following operation stability and relief operation stability during steady operation.
[0014]
However, although the oil supply path for ensuring the bearing reliability is formed as described above, with respect to the fitting cylindrical surface 1c of the fixed scroll 1 and the lower fitting cylindrical surface 4b of the guide frame 4. The upper fitting cylindrical surface 3a or the lower surface of the compliant frame 3 performs a minute sliding movement of about several tens of μ during steady operation and about a few hundred μ during a non-steady operation during startup or liquid compression. Since the oil supply path to the fitting cylindrical surface 3b is not formed, abnormal wear occurs in these engaging portions due to the minute sliding movement of the compliant frame 3, and the cooling effect by the refrigerator oil 13 cannot be expected. In addition, the contact temperature at the engaging portion becomes very high, which in turn induces a harmful effect of promoting the deterioration of the refrigerating machine oil. This phenomenon significantly impairs the reliability of the scroll compressor.
[0015]
The present invention has been made to solve these problems, and relates to the relationship between a movable frame such as a compliant frame 3 and a guide member such as a fixed scroll 1 or a guide frame 4. An object of the present invention is to improve the reliability of the scroll compressor by preventing the abnormal wear of the engaging portion due to the sliding motion of the movable frame and the deterioration of the refrigerating machine oil, etc. by supplying oil to the joint portion.
It is another object of the present invention to allow refrigeration oil to spread over the entire surface of the engaging portion.
It is another object of the present invention to prevent the refrigerating machine oil from being excessively supplied to the engaging portion so that the oil supply to other oil supply locations is not insufficient.
It is another object of the present invention to supply oil to the engaging portion so as not to adversely affect the oil supply to the bearing of the main shaft.
It is another object of the present invention to allow the movable frame and the guide member to smoothly slide at the engaging portion.
[0016]
[Means for Solving the Problems]
  Main departureClearlyThe scroll compressor according to the present invention is provided in a hermetic container, and a fixed scroll and an oscillating scroll in which respective plate-like spiral teeth are meshed with each other so as to form a compression chamber therebetween, and an oscillating scroll. -A movable frame that supports the shaft in the axial direction, the movable frame that supports the main shaft that drives the oscillating scroll in the radial direction via a bearing, and the movable frame that moves in the axial direction In a scroll compressor including a guide member that engages with each other, an engagement portion oil supply means that supplies refrigerating machine oil to an engagement portion between the movable frame and the guide member is provided.The engaging part oil supply means is provided in the movable frame, and one end opens to the inner surface side of the movable frame and the other end opens to the engaging part side of the movable frame and the guide member. A frame oil supply passage that forms an oil passage through which the refrigeration oil is supplied from the inner surface side of the movable frame, and the opening on the inner surface side of the movable frame in the frame oil supply passage and the main shaft The opening on the outlet side of the shaft oil supply passage that is the formed oil passage communicates with the rotation of the main shaft.Is.
[0018]
  In addition, this departureClearlyThe scroll compressor involved is, mainAn axial oil supply passage which is an oil flow path formed on the shaft is divided into an axial oil supply passage formed in the axial direction of the main shaft, a branch branched from the axial oil supply passage to the movable frame side, and opened to the outer peripheral surface of the main shaft A shaft oil supply passage is provided, and the opening on the outer peripheral surface of the main shaft of the branch shaft oil supply passage communicates with the opening on the inner surface of the movable frame of the frame oil supply passage by the rotation of the main shaft.
[0019]
  In addition, this departureClearlyThe scroll compressor involved is, mainThe shaft bearings are a first bearing and a second bearing that are spaced apart in the axial direction of the main shaft, and the two openings communicate with each other through a space between the bearings.
[0020]
  In addition, this departureClearlyThe scroll compressor involved isYesAn oil groove is provided on at least one side of the engaging portion between the moving frame and the guide member in a direction that is angled with respect to the axial direction of the main shaft and along the engaging surface of the engaging portion.
In the scroll compressor according to the present invention, the oil groove is formed in an annular shape on the engaging surface of the engaging portion.
[0021]
  In addition, this departureClearlyThe scroll compressor involved isYesAn oil groove is provided so that the opening of the frame oil supply passage that opens to the engaging portion between the moving frame and the guide member opens to the oil groove.
[0022]
  In addition, this departureClearlyThe scroll compressor involved is, ClerkThe joint oil supply means has a high pressure through the engagement portion between the higher pressure chamber to which the refrigerating machine oil is supplied, the lower pressure chamber, and the movable frame and the guide member. This is an oil flow path that connects the pressure chamber of one side and the pressure chamber of the lower pressure side.
[0023]
  In addition, this departureClearlyThe scroll compressor involved is, PressureThe pressure chamber with the higher force is the pressure chamber whose pressure contributes to the axial movement of the movable frame, and the pressure chamber with the lower pressure is the pressure chamber of the suction gas pressure, An opening / closing valve is provided between the pressure chamber having the higher pressure and the engaging portion, which opens when the pressure difference between the two pressure chambers exceeds a predetermined pressure.
[0024]
  In addition, this departureClearlyThe scroll compressor involved isYesThe engaging portions between the moving frame and the guide portion are engaged with each other by the formed cylindrical surfaces so as to be movable in the axial direction of the main shaft.
[0025]
DETAILED DESCRIPTION OF THE INVENTION
Embodiment 1 FIG.
The present invention will be described below with reference to the first embodiment. FIG. 1 is a longitudinal sectional view showing a scroll compressor according to Embodiment 1 of the present invention, and FIG. 2 is a detailed view of part A of FIG. Moreover, the arrow shown to a figure shows the flow of refrigerator oil.
1 and 2, reference numeral 1 denotes a fixed scroll, and an outer peripheral portion thereof is fastened to a guide frame 4 described later by bolts (not shown). Further, a plate-like spiral tooth 1b is formed on one surface (lower side in FIG. 1) of the base plate portion 1a.
Reference numeral 2 denotes an orbiting scroll, and a plate-like spiral tooth 2b having substantially the same shape as the plate-like spiral tooth 1b of the fixed scroll 1 is formed on one surface (upper side in FIG. 1) of the base plate portion 2a. In addition, a hollow cylindrical boss 2f is formed at the center of the surface opposite to the plate-like spiral tooth 2b (lower side in FIG. 1) of the base plate 2a, and the inner surface of the boss 2f Is formed with a rocking bearing 2d, which is rotatably engaged with a slider (not shown). In addition, a thrust surface is formed on the outer peripheral portion of the surface on the same side as the boss portion 2f so as to be slidable against a thrust bearing 3g of a compliant frame 3 described later. In addition, spiral grooves are respectively formed in the tooth tip portions of the plate-like spiral teeth 1b of the fixed scroll 1 and the plate-like spiral teeth 2b of the orbiting scroll 2, and chip seals (not shown) are respectively formed in the grooves. (Omitted) is inserted.
Further, the base plate portion 2a is formed with a bleed hole 2c, which is a thin hole communicating the upper surface with the surface on the compliant frame 3 side. Reference numeral 7 denotes an Oldham ring, which restrains the rotation of the orbiting scroll 2 and realizes a revolving motion with respect to the fixed scroll 1.
[0026]
Reference numeral 3 denotes a compliant frame, and reference numeral 4 denotes a guide frame. The outer peripheral surface of the guide frame 4 is fixed to the sealed container 14 by shrink fitting or welding.
The compliant frame 3 has an upper fitting cylindrical surface 3a and a lower fitting cylindrical surface 3b fitted and engaged with the upper fitting cylindrical surface 4a and the lower fitting cylindrical surface 4b of the guide frame 4, respectively. Restrained by a normal method, movement is allowed only in the axial direction of the main shaft 5.
That is, the compliant frame 3 that is a movable frame engages with the guide frame 4 that is a guide member, forms two engaging portions, and is guided by the guide frame 4 to the shaft of the main shaft 5. It is engaged so as to be movable in the direction.
The compliant frame 3 includes a main bearing 3c, which is a first bearing that radially supports the main shaft portion of the main shaft 5 that is rotationally driven by the motor stator 8 and the motor rotor 8a, and a second bearing. A bearing composed of the auxiliary main bearing 3d is formed with an inter-bearing space 3t between the two bearings.
However, in the above description, the bearings are the first bearing and the second bearing, but they may be integral bearings or may be separate members from the compliant frame 3.
In addition, an upper seal groove 3e and a lower seal groove 3f for accommodating a seal material such as an O-ring are formed on the outer surface 3h of the compliant frame 3, and the upper seal material 9 and the lower seal groove 3f are formed in these seal grooves. A sealing material 10 is fitted. A frame space 4 d is formed by the two sealing materials 9 and 10, the inner side surface 4 c of the guide frame 4, and the outer side surface 3 h of the compliant frame 3. Further, a communication hole 3 i that communicates with the frame space 4 d is formed in the compliant frame 3 from the surface of the thrust bearing 3 g of the compliant frame 3.
[0027]
Further, 3j is an on-off valve provided in the oil flow path that opens when a predetermined pressure difference is given, and a low pressure space that is a lower pressure chamber from the intermediate pressure chamber 3k that is a higher pressure chamber. This is a check valve that allows the flow of refrigerating machine oil only in the 11 direction. Here, the intermediate pressure chamber 3k is surrounded by the oscillating scroll 2, the compliant frame 3, and the main shaft 5, and the thrust bearing 3g of the compliant frame 3, the oscillating bearing 2d of the oscillating scroll 2, and the main body of the compliant frame 3. It is sealed and formed by the bearing 3c. The low-pressure space 11 is a space near the end of winding of the plate-like spiral teeth 1b and 2b, and is a space into which low-pressure intake gas is sucked.
The check valve 3j, which is the on-off valve, is provided in an oil passage that extends from the lower portion of the intermediate pressure chamber 3k to the engaging portion of the compliant frame 3 and the guide frame 4.
[0028]
Further, as shown in FIG. 2, the lower fitting cylindrical surface 3b of the compliant frame 3 has a flange penetrating from the bearing space 3t between the main bearing 3c and the auxiliary main bearing 3d to the lower fitting cylindrical surface 3b. A frame oil supply passage 3U is formed, and the frame oil supply passage 3U opens into an oil groove 3m formed in an annular shape in the lower fitting cylindrical surface 3b.
That is, one end of the inter-bearing space 3t between the main bearing 3c as the first bearing and the auxiliary main bearing 3d as the second bearing is on the inner surface side of the compliant frame 3 that is the movable frame. The compliant frame 3 is provided with a frame oil supply passage 3U having an opening at the other end and an opening at the other end.
[0029]
A pin portion (not shown) having a flat portion substantially parallel to the axial direction of the main shaft is formed at the end of the main shaft 5 on the orbiting scroll side. The flat portion of this pin portion and a slider (not shown) are formed. ) Is engaged with a flat surface portion formed on the inner side surface so as to be able to reciprocate. A main shaft balancer 5d is shrink fitted on the lower side, and a main shaft portion that is rotatably engaged with the main bearing 3c and the auxiliary main bearing 3d of the compliant frame 3 is formed on the lower side. .
Further, the other end portion of the main shaft 5 is formed with a sub shaft portion that is rotatably engaged with the sub bearing 18a of the sub frame 18, and the electric motor is interposed between the sub shaft portion and the main shaft portion described above. The rotor 8a is shrink-fitted. Further, an upper balancer 8b is fastened to one end of the motor rotor 8a, and a lower balancer 8c is fastened to the other end, and the static balance and dynamic balance are achieved by the three balancers with the main spindle balancer 5d. It has been.
Reference numeral 5a denotes an axial oil supply passage 5a provided through the main shaft 5 in the axial direction, and an oil pipe 6 is press-fitted and fixed to the lower end thereof and extends into the refrigerating machine oil 13 at the bottom of the sealed container 14. Further, the other end of the axial oil supply passage 5 a opens into a boss portion space 2 e formed by the upper end portion of the main shaft 5 and the base plate portion 2 a of the swing scroll 2. Further, the main shaft 5 is formed with a branch shaft oil supply passage 5b in the middle of the axial oil supply passage 5a, and opens to the inter-bearing space 3t between the main bearing 3c and the auxiliary main bearing 3d. Refrigerating machine oil 13 is supplied to the main bearing 3c and the auxiliary main bearing 3d of the frame 3.
Moreover, let the oil flow path formed in the main shafts 5, such as the said axial direction oil supply path 5a and the branch shaft oil supply path 5b, be an axial oil supply path.
[0030]
Reference numeral 14 a denotes a suction pipe that is press-fitted through the sealed container 14, whereby low-pressure suction gas (low-pressure refrigerant gas) is introduced into the low-pressure space 11. Reference numeral 14b denotes a discharge pipe, and the low pressure gas sucked from the suction pipe 14a is compressed by a compression chamber formed by the plate-like spiral teeth 1b and 2b of the fixed scroll 1 and the swing scroll 2 respectively. As a result, the gas becomes high-pressure gas (high-pressure refrigerant gas), is discharged into the sealed container 14 from the discharge port 1e of the fixed scroll 1, and is discharged out of the sealed container 14 from the discharge pipe 14b.
[0031]
Next, the operation of this scroll compressor will be described. However, since the compression operation of this compressor is the same as that of a normal scroll compressor, it is omitted.
During steady operation, the refrigerating machine oil 13 at the bottom of the sealed container 14 is provided penetrating in the axial direction in the main shaft 5 due to the high pressure in the sealed container 14 and the centrifugal force when the axial oil supply passage 5a is eccentric. Then, it is guided to the boss space 2e of the orbiting scroll 2 through the axial oil supply passage 5a. The high-pressure refrigerating machine oil 13 is depressurized by the rocking bearing 2d to become an intermediate pressure and flows into the intermediate pressure chamber 3k. On the other hand, as another oil flow path, the high-pressure refrigerating machine oil 13 in the axial oil supply passage 5a reaches the inter-bearing space 3t from the branch shaft oil supply passage 5b provided in the main shaft 5, and a part flows to the auxiliary main bearing 3d. The other is guided to the lower part of the compliant frame 3 on the high-pressure side of the main bearing 3c, and while supplying oil to the main bearing 3c, the pressure is reduced by the main bearing 3c to become an intermediate pressure, which also flows into the intermediate pressure chamber 3k. At this time, the intermediate pressure Pm1 in the intermediate pressure chamber 3k is communicated with the intermediate pressure chamber 3k, and is determined by a predetermined magnification α that is substantially determined by a check valve 3j provided in an oil passage formed in the compliant frame 3. ,
Pm1 = Ps × α (Ps is the pressure in the low pressure space 11)
It is controlled by.
[0032]
On the other hand, the bleed hole 2c provided in the base plate portion 2a of the orbiting scroll 2 communicates with the communication hole 3i provided in the compliant frame 3 constantly or intermittently. For this reason, the refrigerant gas that is being compressed from the compression chamber formed by the fixed scroll 1 and the orbiting scroll 2 passes through the bleed hole 2c of the orbiting scroll 2 and the communication hole 3i of the compliant frame 3 in the frame space 4d. Led to. Therefore, the intermediate pressure Pm2 in the frame space 4d is determined by a predetermined magnification β substantially determined at the position of the compression chamber where the bleed hole 2c substantially communicates.
Pm2 = Ps × β (Ps is the pressure in the low pressure space 11)
It is controlled by.
[0033]
In the compliant frame 3, although the resultant force of the force resulting from the intermediate pressure Pm1 of the intermediate pressure chamber 3k and the pressing force from the swinging scroll 2 via the thrust bearing 3g acts as a downward force, The resultant force of the force caused by the intermediate pressure Pm2 in the space 4d and the force caused by the pressure in the high pressure space 12 acting on the lower end surface 3n of the compliant frame 3 acts upward, and this upward force is the downward force. Since it is set to be larger, the compliant frame 3 that is a movable frame has an upper fitting cylindrical surface 3a and a lower fitting cylindrical surface 3b that is an upper fitting cylindrical surface of the guide frame 4 that is a guide member. 4a is guided by the lower fitting cylindrical surface 4b and floats to the fixed scroll side (upward in FIG. 1). Therefore, the orbiting scroll 2 pressed against the compliant frame 3 via the thrust bearing 3g is also lifted upward. As a result, the tooth tip of the plate-like spiral tooth 2b of the orbiting scroll 2 and the tooth bottom of the base plate portion 2a. Are respectively in contact with the tooth bottom of the base plate portion 1a of the fixed scroll 1 and the tooth tip of the plate-like spiral tooth 1b, and compress the refrigerant gas while sliding, so that the refrigerant gas leaks with high efficiency. A compressor is obtained. The compliant frame 3 receives part or all of the overturning moment of the orbiting scroll 2 through the thrust bearing 3a, but the bearing load received from the main bearing 3c and the resultant force of the two forces, ie, the top fitting Coupled force generated by the resultant force of the reaction force received from the guide frame 4 via the combined cylindrical surface 3a and the reaction force received from the guide frame 4 via the lower fitting cylindrical surface 3b acts so as to cancel the overturning moment. Therefore, it has very good tracking operation stability during steady operation.
[0034]
Further, at the time of start-up or liquid compression, the thrust direction gas load Fgth acting on the orbiting scroll 2 increases, and the orbiting scroll 2 moves the compliant frame 3 to the opposite side of the fixed scroll via the thrust bearing 3g ( 1 is pushed down (lower in FIG. 1), and is relatively large between the tooth tips of the plate-like spiral teeth 2b and 1b of the rocking scroll 2 and the fixed scroll 1 and the tooth bottoms of the base plate portions 1a and 2a facing each other. Since a gap is generated and an abnormal pressure rise in the compression chamber is avoided, a highly reliable rotary compressor with less vortex and bearing damage can be obtained.
[0035]
Further, the compliant frame 3 that is a movable frame has one end opened in the inter-bearing space 3t between the main bearing 3c and the auxiliary main bearing 3d, and the other end annularly formed in the lower fitting cylindrical surface 3b. Since the frame oil supply path 3U that opens in the formed oil groove 3m is formed, the refrigerating machine oil 13 at the bottom of the hermetic container 14 is provided in the axial direction through the main shaft 5 in the axial direction. The bearing space 3t is reached via the branch shaft oil supply passage 5b that branches from now on, and is supplied to the main bearing 3c and the auxiliary main bearing 3d from the space 3t between the bearings and through the frame oil supply passage 3U. It is supplied to the groove 3m.
Accordingly, the compliant movement of the lower fitting cylindrical surface 4b of the guide frame 4 is about a dozen micro movements during steady operation and about a few hundred micro movements during start-up and non-steady operation during liquid compression. The refrigerating machine oil 13 can be supplied to the lower fitting cylindrical surface 3b of the frame 3.
That is, oil is supplied to the engaging portion between the lower fitting cylindrical surface 3b of the compliant frame 3 and the lower fitting cylindrical surface 4b of the guide frame 4, and abnormal wear does not occur even if these engaging portions slide. Furthermore, since the cooling effect by the refrigerating machine oil 13 can be expected, an increase in the contact temperature can be suppressed, and the refrigerating machine oil is hardly deteriorated.
[0036]
Further, due to the rotational movement of the main shaft 5, the branch shaft oil supply passage 5b of the main shaft 5 and the frame oil supply passage 3U formed in the compliant frame 3 constrained to rotate are communicated via the inter-bearing space 3t. However, since it is intermittent communication, it is possible to prevent excessive refrigeration oil from being supplied to the engaging portion, and it is downstream of the axial oil supply passage 5a provided through the main shaft 5 in the axial direction. There is no shortage of the amount of refrigerating machine oil supplied to lubricate the rocking bearing 2d and the like. That is, the amount of the refrigerating machine oil 13 guided to the boss space 2e of the orbiting scroll 2 via the axial oil supply passage 5a provided through the main shaft 5 in the axial direction is not significantly reduced. A required amount of oil is supplied to the bearing 2d, and the reliability of the rocking bearing 2d can be maintained.
[0037]
Further, the frame oil supply path 3U of the compliant frame 3 penetrates the compliant frame 3 from the inter-bearing space 3t between the main bearing 3c and the auxiliary main bearing 3d, and the oil on the lower fitting cylindrical surface 3b. Since the groove 3m is open, it is possible to supply oil to the engaging portion and also to supply oil from the inter-bearing space 3t to the main bearing 3c and the auxiliary main bearing 3d, and the main shaft 5 required for the main bearing 3c and the auxiliary main bearing 3d. Thus, a more reliable scroll compressor can be obtained without affecting the oil film forming ability for supporting the bearing load acting on the bearing.
In this case, the frame oil supply passage 3U opens into the oil groove 3m of the lower fitting cylindrical surface 3b of the compliant frame 3, but without providing the oil groove 3m, the compliant frame 3 directly You may open in the engaging part of the lower fitting cylindrical surface 3b and the lower fitting cylindrical surface 4b of the guide frame 4. FIG.
[0038]
When the frame oil supply path 3U is open in the oil groove 3m, the refrigerating machine oil 13 is not subjected to flow path resistance, and the lower fitting cylindrical surface 3b of the compliant frame 3 and the guide frame 4 are promptly used. It is possible to obtain an effect of being supplied to the engaging portion of the lower fitting cylindrical surface 4b and being easily supplied to the entire surface of the engaging portion. In this case, the bearings may be lubricated separately, and the branch shaft lubrication path 5b and the frame lubrication path 3U may communicate directly without the inter-bearing space 3t.
[0039]
Therefore, it is not necessary for both ends of the frame oil supply passage 3u to open to the inter-bearing space 3t and the oil groove 3m, and one end opens to the inner surface of the compliant frame 3, for example, to the main shaft 5. Refrigerating machine oil is supplied in communication with the opening on the outer peripheral surface side of the main shaft 5 of the formed branch shaft oil supply passage 5b, and the other end opens on the outer surface of the compliant frame 3, and engages with the guide frame. You may make it open to. The branch shaft oil supply path 5b and the frame oil supply path 3u are also intermittently communicated in this case.
That is, as an engaging portion oil supply means, an oil flow path provided in the compliant frame 3 has one end opened to the inner surface side of the compliant frame 3 and the other end engaged with the guide frame. If the frame oil supply passage 3u is opened to the side, and the refrigerating machine oil is supplied from the opening on the inner surface side, the lower fitting cylindrical surface 3b of the compliant frame 3 and the guide frame are provided by the engagement portion oil supply means. The oil can be supplied to the engaging portion with the lower fitting cylindrical surface 4b.
[0040]
Further, the main shaft oil passage communicating with the opening on the inner surface side of the frame oil supply passage 3U may be an opening on the outlet side of the shaft oil supply passage instead of the branch shaft oil supply passage 5b.
[0041]
The oil groove 3m is formed in an annular shape on the lower fitting cylindrical surface 3b of the compliant frame 3, and the opening on the outlet side of the frame oil supply passage 3u is open. Instead of this, the following may be used.
The oil groove 3m extends along the engagement surface in an angled direction on at least one side of the engaging portion of the compliant frame 3 and the guide frame 4 instead of being parallel to the axial direction of the main shaft 5. The opening on the outlet side of the frame oil supply passage 3u may be formed in the oil groove 3m. Even if it does in this way, the same effect as the above is acquired.
Further, even if the opening on the outlet side of the frame oil supply passage 3u does not open to the oil groove 3m, the refrigerating machine oil supplied to the engaging portion from the opening on the outlet side of the frame oil supply passage 3u is: This oil groove 3m facilitates spreading over the entire engagement surface.
In this case, if a plurality of oil grooves 3m are formed in the axial direction of the engagement surface, the refrigerating machine oil is more easily spread.
Furthermore, the oil groove 3m has both the effect of reducing the flow resistance and the refrigerating machine oil by forming both the oil groove 3m having an opening on the outlet side of the frame oil supply passage 3u and the oil groove 3m not opening. The effect of facilitating expansion on the engagement surface can be obtained together.
[0042]
Further, a plurality of frame oil supply passages 3 u having one end opened on the inner surface side of the compliant frame 3 and the other end opened on the engaging portion side with the guide frame are formed along the outer periphery of the main shaft 5. As a result, the chance of intermittent communication with the opening of the branch shaft oil supply passage 5b formed in the main shaft 5 is increased, oil supply to the engagement surface is facilitated, and refrigerating machine oil is easily spread uniformly on the engagement surface. There is an effect.
If the oil groove 3m is formed on each of the plurality of formed frame oil supply passages 3u as described above or selectively, the oil supply effect is further increased.
Further, in the oil flow path from the branch shaft oil supply path 5b to the engaging portion between the movable frame and the guide member, selecting the presence or absence of the inter-bearing space 3t and the formation of various oil grooves 3m is distributed. Therefore, the present invention can also be used for adjusting the amount of oil supplied to the bearing and the engaging portion, which are oil supply portions.
[0043]
The axial movement of the compliant frame 3 is such that the upper fitting cylindrical surface 3a and the lower fitting cylindrical surface 3b of the compliant frame 3 are moved by the upper fitting cylindrical surface 4a and the lower fitting cylindrical surface 4b of the guide frame 4. Since it is guided, that is, it is the engagement of the cylindrical surface, there can be no place (contact Hertz stress becomes very large) that impairs the guide function in the surface of these engaging portions, A smooth sliding form can be secured.
[0044]
The high-pressure refrigeration oil 13 guided to the boss space 2e of the orbiting scroll 2 through the axial oil supply passage 5a provided through the main shaft 5 in the axial direction is connected to the orbiting bearing 2d as described above. The pressure is reduced via the pressure to an intermediate pressure and flows into the intermediate pressure chamber 3k. Thereafter, when the pressure on the intermediate pressure chamber 3k side becomes a predetermined pressure higher than the pressure on the low pressure space 11 side, the check valve 3j in the oil flow path opens, and the intermediate pressure chamber 3k enters the low pressure space 11 through the check valve 3j. However, the engaging portion between the upper fitting cylindrical surface 3a of the compliant frame 3 and the upper fitting cylindrical surface 4a of the guide frame 4 is arranged on a flow path of a series of flows of the refrigerating machine oil 13 caused by this pressure difference. Therefore, this engaging part also becomes a kind of oil flow path, and the refrigerating machine oil 13 can be supplied to this engaging part by flowing the refrigerating machine oil from the intermediate pressure chamber 3k to the low pressure space 11.
[0045]
Therefore, even if the upper fitting cylindrical surface 3a of the compliant frame 3 and the upper fitting cylindrical surface 4a of the guide frame 4 slide in these engaging portions, abnormal wear does not occur, and further Since the cooling effect by the machine oil 13 can be expected, an increase in the contact temperature at the engaging portion can be suppressed, and as a result, the refrigeration oil is hardly deteriorated, so that a highly reliable scroll compressor can be obtained.
That is, the engagement portion is configured by a pressure chamber having a higher pressure to which the refrigerating machine oil is supplied, a pressure chamber having a lower pressure, and an oil flow path connecting the pressure chambers via the engagement portions. The refrigerating machine oil 13 can be supplied to the engaging part of the compliant frame 3 and the guide frame 4 by the engaging part oil supply means for supplying the refrigerating machine oil to the compliant frame 3.
[0046]
Further, the pressure difference between the two pressure chambers is equal to or higher than a predetermined pressure on the upstream side of the engaging portion of the oil flow path connecting the higher pressure chamber and the lower pressure chamber. Since the on-off valve that opens in this case is provided, the on-off valve can be opened to supply oil to the engaging portion, and the pressure in the higher pressure chamber can be increased by a predetermined pressure from the pressure of the suction gas. The fluctuation of the force that moves the movable scroll in the axial direction can be reduced, the fluctuation of the meshing force of the plate-like spiral teeth of both fixed and swinging scrolls can be reduced, and a highly reliable scroll compressor can be achieved. Obtainable.
In addition, since the control for increasing the intermediate pressure chamber 3k by a predetermined pressure from the low suction pressure is realized only by providing the check valve in the oil flow path of the engagement portion oil supply means, the intermediate pressure chamber It is not necessary to form a dedicated pressure adjusting passage for the 3k pressure control.
[0047]
In the present embodiment, the higher pressure chamber is the intermediate pressure chamber 3k surrounded by the oscillating scroll, the movable frame and the main shaft at the intermediate pressure. However, the present invention is not limited to this. Instead, the engaging portion oil supply means may be a pressure chamber having a pressure higher than that of the lower pressure chamber, which generates a pressure difference that causes an oil flow in the oil passage.
Further, as in the case of the engaging portion of the lower fitting cylindrical surface, the engaging portion of the upper fitting cylindrical surface is provided with an angle with respect to the axial direction of the main shaft at least on one of the upper fitting cylindrical surfaces. An oil groove may be provided. By doing in this way, the effect similar to the case of the engaging part of the said lower fitting cylindrical surface is acquired.
The oil groove may be formed up to the end of the oil flow path connected to the inlet and outlet of the engaging portion, or may be formed in the engaging portion. The same applies to the case where the engaging portion communicates directly with the lower pressure chamber.
[0048]
In the present embodiment, of the two fitting cylindrical surfaces 3a and 3b of the compliant frame 3 that is a movable frame, the guide member that engages with the upper fitting cylindrical surface 3a is provided above the guide frame 4. Although the case of the fitting cylindrical surface 4a has been described, there is a case in which the fitting cylindrical surface of the fixed scroll is used as in the scroll compressor described in JP-A-11-107938 described in the prior art. The engaging portion oil supply technique described in the present embodiment can be applied.
In this embodiment, the engaging portion between the compliant frame 3 and the guide frame 4 is formed by fitting the cylindrical surface. However, the present invention is not limited to this, and in short, the compliant frame. 3 may be used as long as it is guided by the guide frame 4 and can slide in the axial direction of the main shaft 5. At that time, it is more desirable to have a structure that can prevent the compliant frame from rotating at the same time as sliding in the axial direction by fitting in the engaging portion.
[0049]
【The invention's effect】
  Main departureClearlyAccording to the scroll compressor, the fixed scroll and the swinging scroll, which are provided in the hermetic container and in which the respective plate-like spiral teeth are meshed with each other so as to form a compression chamber between them, A movable frame that supports the moving scroll in the axial direction, and that supports the main shaft for driving the oscillating scroll in the radial direction via a bearing, and the movable frame in the axial direction. In the scroll compressor having a guide member that is movably engaged with the movable portion, the engagement portion oil supply means for supplying the refrigerating machine oil to the engagement portion between the movable frame and the guide member is provided. Even if the frame slides, refrigeration oil is supplied to the engagement portions from the engagement portion oil supply means, and abnormal wear does not occur in these engagement portions, and further, the cooling effect by the refrigeration oil. Therefore, it is possible to suppress the increase in contact temperature due to sliding. And thus it can prevent the deterioration of the refrigerating machine oil, highly reliable scroll - Le compressor is obtained.
The engaging portion oil supply means is provided in the movable frame, and one end opens on the inner surface side of the movable frame, and the other end opens on the engaging portion side between the movable frame and the guide member. The main shaft is disposed on at least one side of a frame oil supply path that forms an oil flow path to which refrigeration oil is supplied from the inner surface side of the movable frame, and an engaging portion between the movable frame and the guide member. The direction is an angled direction and has an oil groove along the engaging surface of the engaging portion, and is formed on the main shaft and the opening on the inner surface side of the movable frame of the frame oil supply passage The opening on the outlet side of the shaft oil supply passage, which is an oil passage, communicates with the rotation of the main shaft. For this reason, it is possible to supply oil by communication between the engaging portions of the movable frame and the guide member, and it is possible to prevent excessive supply of refrigeration oil because of the intermittent communication.
[0051]
  Main departureClearlyAccording to the scroll compressor involved, mainAn axial oil supply passage which is an oil flow path formed on the shaft is divided into an axial oil supply passage formed in the axial direction of the main shaft, a branch branched from the axial oil supply passage to the movable frame side, and opened to the outer peripheral surface of the main shaft A shaft oil passage, and the opening on the outer peripheral surface of the main shaft of the branch shaft oil passage communicates with the opening on the inner surface of the movable frame of the frame oil passage by rotation of the main shaft. The branch shaft oil supply passage does not flow excessively, and the remaining refrigerating machine oil can be supplied to another oil supply portion to which the refrigerating machine oil is supplied from the axial oil supply passage. In particular, the shortage of oil supply to the downstream oil supply part can be solved.
[0052]
  Main departureClearlyAccording to the scroll compressor involved, mainThe shaft bearings are a first bearing and a second bearing that are spaced apart in the axial direction of the main shaft, and the two openings communicate with each other through the space between the bearings. Oil can be supplied to the first bearing and the second bearing from the space between the bearings of the main shaft without affecting the oil film forming ability of the main shaft bearing, that is, the oil film for supporting the bearing load acting on the main shaft. In addition to satisfying the forming ability, oil can be supplied to the engaging portion between the movable frame and the guide member.
[0053]
  Main departureClearlyAccording to the scroll compressor involvedYesSince an oil groove is provided on at least one side of the engaging portion between the moving frame and the guide member in a direction having an angle with the axial direction of the main shaft and along the engaging surface of the engaging portion. The oil groove makes it easier for the refrigerating machine oil to spread over the entire engaging portion, and a higher lubrication effect, cooling effect, and refrigerating machine oil deterioration preventing effect can be obtained.
[0054]
  Main departureClearlyAccording to the scroll compressor involvedYesSince the oil groove is provided so that the opening of the frame oil supply passage that opens to the engaging portion between the dynamic frame and the guide member opens to the oil groove, the refrigeration oil is transferred from the frame oil supply passage to the oil groove. It is possible to flow quickly without receiving the flow path resistance, and more easily reach the entire engaging portion, and obtain a higher lubrication effect, cooling effect, and refrigerating machine oil deterioration preventing effect.
[0055]
  Main departureClearlyAccording to the scroll compressor involved, ClerkThe joint oil supply means has a high pressure through the engagement portion between the higher pressure chamber to which the refrigerating machine oil is supplied, the lower pressure chamber, and the movable frame and the guide member. Since the oil flow path connecting the one pressure chamber and the pressure chamber having the lower pressure is used, the refrigerating machine oil supplied to the pressure chamber having the higher pressure has a lower pressure due to the pressure difference due to the oil flow path. However, since the engaging part forms part of the oil flow path, the refrigeration oil is supplied to the engaging part, and no abnormal wear occurs in the engaging part. Since a cooling effect can be expected, an increase in contact temperature can be suppressed, and further, deterioration of the refrigeration oil can be prevented, and a highly reliable scroll compressor can be obtained.
[0056]
  Main departureClearlyAccording to the scroll compressor involved, PressureThe pressure chamber with the higher force is the pressure chamber whose pressure contributes to the axial movement of the movable frame, and the pressure chamber with the lower pressure is the pressure chamber of the suction gas pressure, Since there is an on-off valve that opens when the pressure difference between the two pressure chambers exceeds a predetermined pressure between the pressure chamber with the higher pressure and the engaging part, the on-off valve opens to the engaging part. In addition to being able to lubricate, the pressure in the higher pressure chamber can be higher than the pressure of the suction gas by a predetermined pressure, thus reducing fluctuations in the force that moves the movable frame in the axial direction, and moving the movable frame. A highly reliable scroll compressor can be obtained that can stabilize, reduce and stabilize fluctuations in the meshing force of the plate-like spiral teeth of both fixed and swinging scrolls.
  In addition, both the functions of supplying oil to these engaging portions and stabilizing the movement of the movable frame can be achieved by the oil flow path provided with the on-off valve.
[0057]
  Main departureClearlyAccording to the scroll compressor involvedYesSince the engaging portion between the moving frame and the guide portion is engaged so as to be movable in the axial direction of the main shaft by the formed fitting cylindrical surface, a guide function is provided in these fitting cylindrical surfaces. There can be no point that would damage the contact (the contact Hertz stress becomes very large)the aboveIn addition to the effect of any of the inventions, a smoother sliding form can be secured.
[Brief description of the drawings]
FIG. 1 is a longitudinal sectional view showing a first embodiment of the present invention.
FIG. 2 is a detailed view of part A in FIG.
FIG. 3 is a longitudinal sectional view of a conventional scroll compressor
4 is a detailed view of the vicinity of the oil supply hole in FIG.
[Explanation of symbols]
1 fixed scroll, 1b plate-like spiral tooth, 2 orbiting scroll, 2b plate-like spiral tooth, 3 movable frame, 3a fitting cylindrical surface, 3b fitting cylindrical surface, 3c first bearing (bearing), 3d first 2 bearings (bearings), 3j open / close valve, 3k pressure chamber with higher pressure, 3m oil groove, 3t space between bearings, 3u frame oil supply path, 4 guide member, 4a fitting cylinder surface, 4b fitting cylinder Surface, 5 main shaft, 5a axial oil supply passage (shaft oil supply passage), 5b branch shaft oil supply passage (shaft oil supply passage), 11 lower pressure chamber, 13 refrigerating machine oil, 14 airtight container.

Claims (9)

A fixed scroll and an oscillating scroll, which are provided in a sealed container and in which the respective plate-like spiral teeth mesh with each other so as to form a compression chamber therebetween, and support the oscillating scroll in the axial direction. A movable frame that supports a main shaft for driving the swing scroll in a radial direction via a bearing, and engages the movable frame so as to be movable in the axial direction. In a scroll compressor provided with a guide member,
An engagement portion oil supply means for supplying refrigerating machine oil to the engagement portion between the movable frame and the guide member ;
The engaging part oil supply means includes
The movable frame is provided with one end opened to the inner surface side of the movable frame, the other end opened to the engaging portion side of the movable frame and the guide member, and the movable frame A frame oil supply passage that forms an oil passage through which refrigerating machine oil is supplied from the inner surface side of
The opening on the inner surface side of the movable frame of the frame oil supply passage communicates with the opening on the outlet side of the shaft oil supply passage which is an oil passage formed in the main shaft by the rotation of the main shaft. A featured scroll compressor. The movable frame - on at least one side of the engaging portion of the arm and the guide member, in a direction remembering angle to the axial direction of the main shaft, and provided with oil grooves along the engaging surface of the engaging portion 2. A scroll compressor according to claim 1, wherein 3. The scroll compressor according to claim 2, wherein the oil groove is formed in an annular shape on an engaging surface of the engaging portion. The movable frame - arm and said frame opening to the engagement portion between the guide member - claim opening of arm supply passage, characterized in that a said oil groove so as to open into the oil groove 2 Or a scroll compressor according to claim 3 ; An axial oil supply passage, which is an oil passage formed in the main shaft, is divided into an axial oil supply passage formed in the axial direction of the main shaft and the axial oil supply passage toward the movable frame, and an outer peripheral surface of the main shaft A branch shaft oil supply passage that opens to the side, and an opening on the outer peripheral surface side of the main shaft of the branch shaft oil supply passage is formed between an opening on the inner surface side of the movable frame of the frame oil supply passage and the main shaft. The scroll compressor according to any one of claims 1 to 4, wherein the scroll compressor is communicated by rotation. The bearing of the main shaft is a first bearing and a second bearing that are spaced apart in the axial direction of the main shaft, and the two openings communicate with each other through a space between the bearings. The scroll compressor according to any one of claims 1 to 5, wherein:   The engagement part oil supply means is configured to pass through the engagement part of the higher pressure chamber to which the refrigerating machine oil is supplied, the lower pressure chamber, the movable frame, and the guide member. 2. The scroll compressor according to claim 1, wherein the scroll compressor is an oil passage connecting the pressure chamber having the higher pressure and the pressure chamber having the lower pressure.   The pressure chamber having the higher pressure is a pressure chamber in which the pressure contributes to the axial movement of the movable frame, and the pressure chamber having the lower pressure is a pressure chamber in an intake gas atmosphere; The oil flow path between the pressure chamber having the higher pressure and the engaging portion is provided with an on-off valve that opens when a pressure difference between the two pressure chambers exceeds a predetermined pressure. The scroll compressor according to claim 7.   9. The engagement portion between the movable frame and the guide portion is formed by engagement of a fitting cylindrical surface formed respectively. Scroll compressor.

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