JP2007211255A5 - - Google Patents

Description

Composition for sliding member, sliding member and fluid machine

    The present invention relates to a sliding member composition, a sliding member, and a fluid machine.

    Most machines currently used use sliding members such as bearings and pistons. Such a sliding member is required to have a required mechanical strength, and at the same time, a sliding property or wear resistance is required on the surface.

    Therefore, conventionally, a method has been studied in which a coating layer mainly composed of a fluororesin or the like is formed on the surface of the sliding member to improve the wear resistance in addition to the sliding property.

As a means for improving wear resistance, a coating layer of a composition for a sliding member composed of a fluororesin, a binder, and one type of antiwear agent has been studied (for example, Patent Document 1). The coating layer of the composition for sliding member includes 0.5 to 12% by volume of an anti-wear agent having a Mohs hardness in the range of 2.0 to 5.0 with respect to the fluororesin. The wear resistance is improved. In particular, among the anti-wear agents having a Mohs hardness in the range of 2.0 to 5.0, fluorides such as calcium fluoride can utilize the solid lubricity and appropriate mechanical strength of the fluoride. Abrasion is reliably improved.
JP 2000-249063 A

    However, the coating layer described in Patent Document 1 can sufficiently exhibit the wear resistance effect of fluoride in a sliding member using an aluminum alloy as a base material or a counterpart material, and can improve the wear resistance. However, the wear resistance is not sufficient under severe sliding conditions in which the base material or the counterpart material is an iron-based material.

    The present invention has been made in view of the above points. The object of the present invention is to provide a sliding member composition having excellent slidability and wear resistance, and the sliding member composition. An object of the present invention is to provide a sliding member provided as a coating layer on the material surface and a fluid machine provided with the sliding member.

1st invention is the composition for sliding members comprised including a fluororesin, a binder, and two or more types of antiwear agents. Of the two or more types of antiwear agents, at least one type of antiwear agent is a fluoride of at least one of calcium fluoride, strontium fluoride, and magnesium fluoride, and at least one of the other antiwear agents. The type of antiwear agent is an antiwear particle of at least one of aluminum oxide, zirconium oxide, silicon oxide and silicon nitride. In addition, with respect to 100 parts by weight of the fluororesin, the binder is 100 parts by weight or more and 500 parts by weight or less, the fluoride is 50 parts by weight or more and 200 parts by weight or less, and the wear-resistant particles are 1 part by weight or more and 100 parts by weight or less.

    In the first invention, since the sliding member composition uses a fluororesin having a solid lubricating property, the sliding property is excellent. And since the said composition contains two or more types of antiwear agents, the solid lubricity and mechanical strength which each antiwear agent has can be utilized.

    That is, the inventors of the present application have found that adding two or more kinds of antiwear agents as a result of intensive studies over many years on the antiwear properties of the composition for sliding members. Specifically, as a method for improving the wear resistance of the composition for a sliding member, instead of fluoride, high-hardness wear-resistant particles having mechanical strength superior to fluoride are used as an antiwear agent. Thus, a method for improving the mechanical strength of the entire composition can be considered. However, in general, high-hardness wear-resistant particles having excellent mechanical strength do not have solid lubricity, so that there is a problem that the friction coefficient is increased on the sliding surface of the sliding member. In addition, it is difficult to select an antiwear agent that is extremely excellent in both properties of solid lubricity and mechanical strength. Therefore, by including one or more types of antiwear agents excellent in solid lubricity and antiwear agents excellent in mechanical strength in the above composition in an appropriate composition ratio that can exhibit both properties, , Improve the wear resistance of the composition.

Further, since the sliding member composition contains a fluororesin, the solid lubricity is improved. And, since 100 parts by weight of the fluororesin contains 50 parts by weight or more of fluoride and 1 part by weight or more of wear-resistant particles as an antiwear agent, the solid lubricity of fluoride and the wear resistance The excellent mechanical strength of the conductive particles can be effectively used more reliably. Moreover, since 100 weight part or more of binder is contained with respect to 100 weight part of fluororesins, the bond strength by the binder of the said composition improves. Furthermore, since the binder is 500 parts by weight or less, the fluoride is 200 parts by weight or less, and the wear-resistant particles are 100 parts by weight or less with respect to 100 parts by weight of the fluororesin, the solid lubricity of the fluororesin Is fully demonstrated.

    In a second aspect based on the first aspect, the fluororesin is polytetrafluoroethylene and the binder is a polyamideimide resin.

In the second invention, the friction coefficient of the composition for sliding member is lowered further, you mechanical strength is improved.

According to a third invention, in the first invention, the binder is 300 parts by weight, the fluoride is 75 parts by weight, and the wear-resistant particles are 25 parts by weight with respect to 100 parts by weight of the fluororesin. It is.

In the third aspect of the invention, since the fluoride is 75 parts by weight and the wear-resistant particles are 25 parts by weight with respect to 100 parts by weight of the fluororesin, the solid lubricity of the fluoride and the wear resistance The excellent mechanical strength of the particles can be reliably exhibited. In addition, since the binder is 300 parts by weight with respect to 100 parts by weight of the fluororesin, the bond strength by the binder is also reliably improved.

In a fourth aspect based on the first aspect , the wear-resistant particles are aluminum oxide.

In this 4th invention, since the said abrasion-resistant particle | grains are aluminum oxide, the abrasion resistance of the said composition improves reliably.

A fifth invention is a sliding member in which a coat layer is formed on the surface of a metal substrate, and the coat layer is composed of the composition for a sliding member according to any one of the first to fourth inventions. Has been.

In this 5th invention, since the coating layer of the said composition for sliding members is formed in the base-material surface, the abrasion resistance in a sliding contact surface improves.

6th invention is a fluid machine provided with the sliding member as described in 5th invention.

In the sixth aspect of the invention, the wear resistance of the coat layer on the substrate surface is improved in the machine.

In a seventh aspect based on the sixth aspect , the sliding member is a bearing member.

In the seventh invention, the wear resistance of the coat layer on the substrate surface is improved in the bearing member in the machine.

    According to the present invention, the composition for a sliding member is excellent in slidability because it uses a fluororesin having solid lubricity. And since the said composition contains the 2 or more types of antiwear agent, when the base material is an iron-type material, the solid lubricity and mechanical strength which each antiwear agent has can be utilized. Also, the wear resistance can be improved.

Moreover, since the solid lubricity which fluoride has and the mechanical strength which was excellent in the abrasion-resistant particle | grains can be utilized effectively, the abrasion resistance of the said composition can be improved.

Moreover, since the composition for sliding members contains a fluororesin, the solid lubricity is improved. Further, since 100 parts by weight of the fluororesin contains 50 parts by weight or more of fluoride and 1 part by weight or more of wear-resistant particles as an antiwear agent, the solid lubricity and wear resistance of fluoride. The excellent mechanical strength of the particles can be effectively used more reliably. Moreover, since 100 weight part or more of binder is contained with respect to 100 weight part of fluororesins, the bond strength by the binder of the said composition can be improved. Furthermore, since the binder is 500 parts by weight or less with respect to 100 parts by weight of the fluororesin, the fluoride is 200 parts by weight or less, and the wear-resistant particles are 100 parts by weight or less, the solid lubricity of the fluororesin is As a result, the wear resistance of the entire composition can be improved.

Further, according to the second aspect of the invention, the friction coefficient of the composition is lowered further, Ru can improve the mechanical strength.

Further , according to the third aspect of the invention, the fluoride is 75 parts by weight and the wear-resistant particles are 25 parts by weight with respect to 100 parts by weight of the fluororesin. The strong mechanical strength of the wear-resistant particles can be reliably exhibited. In addition, since the binder is 300 parts by weight with respect to 100 parts by weight of the fluororesin, the bond strength by the binder is also reliably improved. With these configurations, both solid lubricity and mechanical strength are improved, and as a result, the wear resistance of the entire composition can be improved.

According to the fourth aspect of the invention, since the wear-resistant particles are aluminum oxide, the wear resistance of the composition can be reliably improved.

According to the fifth aspect, since the coating layer of the sliding member composition is formed on the surface of the base material, the wear resistance on the sliding contact surface can be improved. As a result, since the durability of the member itself is also improved, it can be used for a long time.

Further, according to the sixth invention, the wear resistance of the coating layer on the surface of the substrate is improved in the machine, and the reliability of the machine itself can be improved.

Moreover, according to the said 7th invention, the abrasion resistance of a bearing member can improve and the reliability of a bearing function can be improved.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

    As shown in FIG. 1, the fluid machine of this embodiment is a scroll compressor (10). The scroll compressor (10) is provided in a refrigerant circuit of a refrigeration apparatus and is used to compress a gas refrigerant that is a fluid.

<Overall configuration of scroll compressor>
As shown in FIG. 1, the scroll compressor (10) is configured in a so-called fully sealed type. The scroll compressor (10) includes a casing (11) formed in a vertically long and cylindrical sealed container shape. In the casing (11), a lower bearing member (30), an electric motor (35), and a compression mechanism (40) are arranged in order from the bottom to the top. A drive shaft (20) that extends vertically is provided inside the casing (11).

    The interior of the casing (11) is partitioned vertically by a fixed scroll (60) of the compression mechanism (40). Inside the casing (11), the space above the fixed scroll (60) is the first chamber (12), and the space below it is the second chamber (13).

  A suction pipe (14) is attached to the body of the casing (11). The suction pipe (14) opens into the second chamber (13) in the casing (11). On the other hand, a discharge pipe (15) is attached to the upper end of the casing (11). The discharge pipe (15) opens into the first chamber (12) in the casing (11).

    The drive shaft (20) includes a main shaft portion (21), a flange portion (22), and an eccentric portion (23). The flange portion (22) is formed at the upper end of the main shaft portion (21) and has a disk shape with a larger diameter than the main shaft portion (21). On the other hand, the eccentric portion (23) protrudes from the upper surface of the flange portion (22). The eccentric portion (23) has a columnar shape with a smaller diameter than the main shaft portion (21), and the shaft center is eccentric with respect to the shaft center of the main shaft portion (21).

    The main shaft portion (21) of the drive shaft (20) passes through the frame member (41) of the compression mechanism (40). The main shaft portion (21) is supported by the frame member (41) via a roller bearing (42). Further, the flange portion (22) and the eccentric portion (23) of the drive shaft (20) are located in the first chamber (12) above the frame member (41).

    A slide bush (25) is attached to the drive shaft (20). The slide bush (25) includes a cylindrical part (26) and a balance weight part (27), and is placed on the flange part (22). The eccentric part (23) of the drive shaft (20) is rotatably inserted into the cylindrical part (26) of the slide bush (25).

    The lower bearing member (30) is located in the second chamber (13) in the casing (11). The lower bearing member (30) is fixed to the frame member (41) by bolts (32). The lower bearing member (30) supports the main shaft portion (21) of the drive shaft (20) via the ball bearing (31).

    An oil pump (33) is attached to the lower bearing member (30). The oil pump (33) is engaged with the lower end of the drive shaft (20). The oil supply pump (33) is driven by the drive shaft (20), and sucks the refrigeration oil accumulated at the bottom of the casing (11). The refrigerating machine oil sucked up by the oil supply pump (33) is supplied to the compression mechanism (40) and the like through a passage formed in the drive shaft (20).

  The electric motor (35) includes a stator (36) and a rotor (37). The stator (36) is fixed to the frame member (41) by bolts (32) together with the lower bearing member (30). On the other hand, the rotor (37) is fixed to the main shaft portion (21) of the drive shaft (20).

  A power feeding terminal (16) is attached to the body of the casing (11). The terminal (16) is covered with a terminal box (17). Electric power is supplied to the electric motor (35) through the terminal (16).

<Configuration of compression mechanism>
The compression mechanism (40) includes a movable scroll (50) and an Oldham ring (43) in addition to the fixed scroll (60) and the frame member (41). The compression mechanism (40) has a so-called asymmetric scroll structure.

  The movable scroll (50) includes a movable side flat plate portion (51), a movable side wrap (52), and a protruding portion (53). The movable side flat plate portion (51) is formed in a slightly thick disk shape. The protruding portion (53) is formed integrally with the movable side flat plate portion (51) so as to protrude from the lower surface of the movable side flat plate portion (51). Moreover, the protrusion part (53) is located in the approximate center of the movable side flat plate part (51). The cylindrical portion (26) of the slide bush (25) is inserted into the protruding portion (53). That is, the movable scroll (50) is engaged with the eccentric part (23) of the drive shaft (20) via the slide bush (25).

    The movable side wrap (52) is erected on the upper surface side of the movable side flat plate portion (51), and is formed integrally with the movable side flat plate portion (51). The movable side wrap (52) is formed in a spiral wall shape having a constant height.

    The movable scroll (50) is placed on the frame member (41) via the Oldham ring (43). The Oldham ring (43) has two pairs of keys. The Oldham ring (43) has a pair of keys engaged with the movable side flat plate portion (51) of the movable scroll (50) and the remaining pair of keys engaged with the frame member (41). The orbiting scroll (50) engaged with the eccentric part (23) of the drive shaft (20) is controlled to rotate by the Oldham ring (43) and revolves. That is, the Oldham ring (43) slides in contact with the movable scroll (50) and the frame member (41).

    As shown in FIG. 1, the fixed scroll (60) includes a fixed-side flat plate portion (61), a fixed-side wrap (63), and an edge portion (62). The fixed-side flat plate portion (61) is formed in a slightly thick disk shape. The diameter of the fixed flat plate portion (61) is substantially equal to the inner diameter of the casing (11). The edge portion (62) is formed in a wall shape extending downward from the peripheral portion of the fixed-side flat plate portion (61). The fixed scroll (60) is fixed to the frame member (41) by a bolt (44) in a state where the lower end of the edge (62) is in contact with the frame member (41). And the fixed scroll (60) partitions the inside of a casing (11) into the 1st chamber (12) and the 2nd chamber (13) because the edge (62) closely_contact | adheres with a casing (11).

    The fixed side wrap (63) is erected on the lower surface side of the fixed side flat plate portion (61) and is formed integrally with the fixed side flat plate portion (61). The fixed side wrap (63) is formed in a spiral wall shape having a constant height, and has a length of about 3 turns.

    The inner wrap surface (64) and the outer wrap surface (65) which are both sides of the fixed side wrap (63) are the outer wrap surface (54) and the inner wrap surface (55) which are both sides of the movable wrap (52). ). On the other hand, the lower surface of the fixed-side flat plate portion (61), that is, the tooth bottom surface (66) other than the fixed-side wrap (63) is slidably moved by the tip surface of the movable-side wrap (52). The tip surface of the fixed side wrap (63) is slidably moved on the upper surface of the tooth, that is, the bottom surface (56) other than the movable side wrap (52). Further, a discharge port (67) is formed in the vicinity of the winding start of the fixed side wrap (63) in the fixed side flat plate portion (61). The discharge port (67) passes through the fixed-side flat plate portion (61) and opens into the first chamber (12).

    As described above, the scroll compressor (10) of the present embodiment is provided in the refrigerant circuit of the refrigerator. In this refrigerant circuit, the refrigerant circulates to perform a vapor compression refrigeration cycle. At that time, the scroll compressor (10) sucks and compresses the low-pressure gas refrigerant from the evaporator, and sends the compressed high-pressure gas refrigerant to the condenser.

    When the scroll compressor (10) is operated, the cylindrical portion (26) of the slide bush (25) and the protruding portion (53) of the movable scroll (50) slide. In this embodiment, a lubrication part (70) which is a bearing metal is provided in this sliding part. The lubrication part (70) is a sliding member having a cylindrical shape and having a coating layer, which is a lubricant layer made of a composition for a sliding member, on an inner peripheral surface of iron as a base material. The inner surface of the lubricating part (70) provided with the lubricant layer slides with the outer peripheral surface of the cylindrical part (26) of the slide bush (25).

    The inner peripheral surface of the base material of the lubrication part (70) is roughened by chemical conversion treatment so that the surface roughness Ra becomes 3.7 μm. On top of that, polytetrafluoroethylene (hereinafter referred to as PTFE), polyamideimide resin (hereinafter referred to as PAI), calcium fluoride (hereinafter referred to as CaF2) and aluminum oxide (hereinafter referred to as Al2O3) as antiwear agents. A lubricant layer having a thickness of about 100 μm is formed by blending. Here, the surface roughness Ra is the arithmetic average height Ra of the contour curve defined in JIS B 0601-2001. If the surface roughness Ra is displayed after this, it is determined by JIS. It shall represent the prescribed arithmetic average height Ra.

  By arranging the lubrication part (70) having such a structure, even if the cylindrical part (26) of the slide bush (25) and the lubrication part (70) slide while exposed to the refrigerant, the friction coefficient is very low. Can keep sliding for a long time.

《Examination of sliding parts》
In the following, the study performed on the lubrication part (70) will be described.

The composition for a sliding member containing fluoride as an antiwear agent has a low coefficient of friction with a metal and excellent slidability. However, when the base material or the counterpart material is an iron-based material, the wear resistance is low. Not enough. Accordingly, the inventors of the present application include a fluoride and a wear-resistant particle having a 10-step Mohs hardness greater than 5 as an antiwear agent in the slide member composition, whereby the base material surface of the slide member is obtained. Whether the wear resistance and slidability of the coating layer of the composition for a sliding member in the case of improved is examined.

In this study, PTFE was used as the fluororesin and PAI was used as the binder. As the fluoride antiwear, using CaF2 or strontium fluoride (hereinafter SrF2 called.), 10 stages Mohs hardness as 5 greater wear-resistant particles, 10 steps Mohs hardness using Al2O3 of 9 . Then, the PTFE in the sliding member composition was 20% by mass, the PAI was 60% by mass, and the total content of the antiwear agent was 20% by mass. Specifically, as the antiwear agent, sample A having a composition ratio of PTFE / PAI / CaF2 = 20/60/20 containing only CaF2, and PTFE / PAI / CaF2 / Al2O3 = 20 / containing both CaF2 and Al2O3. Examination was made using 60/15/5 sample B, a composition for sliding members having three composition ratios of sample C containing PTFE / PAI / SrF2 / Al2O3 = 20/60/15/5 containing both SrF2 and Al2O3. did. In Samples B and C, the binder is 300 parts by weight, the fluoride is 75 parts by weight, and the wear-resistant particles are 25 parts by weight with respect to 100 parts by weight of the fluororesin.

    The examination method was performed by a journal test in a refrigerant as shown in FIG. 2, R410A was used as the refrigerant, and ether oil was used as the lubricating oil. First, a bearing (100) made of an iron base material is applied, and the inner peripheral surface of the base material of the bearing (100) is subjected to a surface roughness treatment of Ra 3.7 μm by chemical conversion treatment using manganese phosphate. On the top, a coating layer (101) of the sliding member composition comprising the above three types of samples was formed as a lubricant layer having a thickness of about 100 μm. The coating layer (101) was formed by applying the above sliding member composition and then baking, and then polishing the surface.

    Next, a shaft (102) made of SUJ2 (according to JIS G4805-1990) is inserted into the bearing (100) in the pressure vessel (105), and the shaft (102) is rotated at a constant speed. In addition, while forcibly supplying the bearing (100) to the bearing (100) from the container (103) through the oil supply section (104), a mixture of refrigerant and lubricating oil having a volume ratio of 65:35 is contained in the pressure container (105). Was collected and circulated. In the test, the sliding speed between the shaft (102) and the bearing (100) was 3 m / s, the bearing (100) was fixed by applying a load of 6 MPa, and the above three types of samples were coated after holding for 1 hour. The wear resistance was evaluated by comparing the amount of wear of the layer (101). Further, the friction coefficient μ between the coating layer (101) of the three types of sliding member compositions and the shaft (102) during the rotation of the shaft (102) at a constant speed was measured.

    FIG. 3 shows the result of the journal test in the refrigerant. The amount of wear of each sample was 22 μm for sample A containing only CaF2 as an antiwear agent, 2 μm for sample B using both CaF2 and Al2O3, and 2 μm for sample C using both SrF2 and Al2O3. It was. As a result, it can be seen that Samples B and C containing fluoride and Al2O3 have a small amount of wear and excellent wear resistance.

    The friction coefficient μ of each sample is 0.002 for sample A containing only CaF2 as an antiwear agent, 0.0007 for sample B using both CaF2 and Al2O3, and both SrF2 and Al2O3 are used. Sample C was 0.0008. As a result, it can be seen that also in samples B and C in which the content of fluoride in the antiwear agent is lower than that of sample A, the solid lubricity of fluoride is exhibited and the increase in the friction coefficient can be suppressed.

    As is apparent from the above results, by forming the coating layers of samples B and C containing both fluoride and Al2O3 as antiwear agents on the surface of the base material of the sliding member in the refrigerant using the lubricating oil, The amount of wear is reduced, and the wear resistance can be improved. Samples B and C using both fluoride and Al2O3 as antiwear agents also have a low coefficient of friction, so they exhibit excellent sliding performance and can maintain long-term sliding.

    Thus, the composition for the sliding member having a composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5 containing both fluoride and Al2O3 as an antiwear agent on the surface of the base material of the sliding member. By providing a coating layer made of a material, excellent wear resistance is exhibited even if the base material or the counterpart material is an iron-based material. Therefore, a coat layer having a composition ratio of PTFE / PAI / CaF2 / Al2O3 = 20/60/15/5 is formed on the inner peripheral surface of the lubrication part (70).

(Other embodiments)
The composition for sliding members of Sample B and Sample C in the above embodiment has a composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5. That is, PTFE is 100 parts by weight, PAI is 300 parts by weight, fluoride is 75 parts by weight, and Al2O3 is 25 parts by weight, but the composition ratio of the sliding member composition is limited to this value. The composition ratio is such that the solid lubricity of PTFE, the solid lubricity of fluoride as an antiwear agent, and the excellent mechanical strength of aluminum oxide are exhibited, and the binding force of PAI as a binder is exhibited. If it is. Specifically, with respect to 100 parts by weight of PTFE, PAI is 100 parts by weight or more and 500 parts by weight or less, fluoride is 50 parts by weight or more and 200 parts by weight or less, and Al 2 O 3 is 1 part by weight or more. What is necessary is just the composition for sliding members which is 100 weight part or less.

Moreover, in the said embodiment, although CaF2 and SrF2 are used as a fluoride, magnesium fluoride etc. can also be used for a fluoride, Moreover, it is not limited to these. In the above embodiment, Al2O3 is used as wear-resistant particles having a 10-step Mohs hardness greater than 5. However, various wear-resistant particles such as oxides such as zirconium oxide and silicon oxide, and silicon nitride are used. However, the present invention is not limited to these.

    Furthermore, in the said embodiment, although 1 type of fluoride and the said abrasion-resistant particle | grain are each mix | blended with the composition for sliding members, it should just contain at least 1 type or more respectively. And even if it is not fluoride and the above-mentioned wear-resistant particles, the wear resistance agent with solid lubricity and the wear resistance agent with excellent mechanical strength are each in a composition ratio so that each property can be effectively exhibited. One or more types may be included.

    Examples of the fluororesin include, but are not limited to, PTFE, tetrafluoroethylene-hexafluoropropylene copolymer resin, and the like. Further, by using PAI as a binder, it is possible to use the characteristics of PAI that are excellent in impact resistance and high in hardness, so that the impact resistance and wear resistance of the composition for sliding member can be improved. In addition to PAI, polyamide resins having similar characteristics can be used, and the present invention is not limited to these.

    In the above embodiment, the sliding portion of the cylindrical portion (26) of the slide bush (25) and the protruding portion (53) of the movable scroll (50) is provided with the lubrication portion (70) that is a bearing metal. The bearing metal (70) is not provided, and the projecting portion (53) of the movable scroll (50) is roughened by directly subjecting the inner surface of the cylinder to a rough surface, and then the PTFE / PAI / fluoride / Al2O3 = You may form directly the coating layer which consists of a composition for sliding members of the composition ratio of 20/60/15/5. Moreover, you may form the said coating layer directly in the outer peripheral surface of the cylindrical part (26) of a slide bush (25). As a result, it is not necessary to provide a separate lubrication part (70), so that the processing can be simplified and the cost can be reduced.

    Further, the composition for sliding member having a composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5 is obtained by the cylindrical portion (26) of the slide bush (25) and the protruding portion of the movable scroll (50). The same effect can be obtained by coating sliding members of various types and applications, not limited to the sliding portion with (53).

    Specifically, since the lower surface of the movable side flat plate portion (51) of the movable scroll (50) slides with the upper surface of the frame member (41) and the Oldham ring (43), the movable side flat plate of the movable scroll (50). A coat layer made of the sliding member composition having a composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5 may be formed on the lower surface of the part (51). Further, the coat layer may be formed on the entire movable scroll (50).

    Further, since the opposed surfaces of the movable scroll (50) and the fixed scroll (60) slide, the inner wrap surface (55), the outer wrap surface (54) of the movable side wrap (52) of the movable scroll (50), and A coating layer made of a composition for a sliding member having a composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5 may be formed on the front end surface, or the fixed side of the fixed scroll (60) The coating layer may be formed on the facing surface of the movable scroll (50) in the wrap (63), that is, the inner wrap surface (64), the outer wrap surface (65), and the tip surface of the fixed wrap (63). . Thereby, since the sealing performance in the opposing surface of the movable scroll (50) and the fixed scroll (60) is improved, the reliability as a compressor is also improved.

    The Oldham ring (43) slides on the lower surface of the movable side flat plate portion (51) of the movable scroll (50), and the main body and the other key of the Oldham ring (43) slide on the frame member (41). Therefore, a coat layer made of a composition for a sliding member having a composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5 may be formed on the surface of the Oldham ring (43). In the above embodiment, the movable scroll (50) is placed on the frame member (41) via the Oldham ring (43). However, the movable scroll (50) is mounted on the frame member via the Oldham ring (43) and the thrust bearing. When placed on the thrust bearing, the upper surface of the thrust bearing and the lower surface of the movable-side flat plate portion (51) of the movable scroll (50) slide, so the coating layer may be formed on the upper surface of the thrust bearing.

    Further, in the above embodiment, the main shaft portion (21) is supported by the roller bearing (42) and the ball bearing (31) as sliding portions, but the main shaft portion (21) is a journal bearing which is a slide bearing. In this case, the main shaft portion (21) and the sliding portion of the bearing are composed of a sliding member composition having a composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5. A coat layer may be formed. That is, the coat layer may be formed on the outer peripheral surface of the main shaft portion (21) or the inner peripheral surface of the bearing.

    Moreover, in the said embodiment, in the sliding member of scroll type compressor (10), the coating layer which consists of a composition for sliding members of the composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5 However, the compressor is not limited to the scroll type, and may be any type of compressor that compresses a fluid. Further, the fluid is not limited to the refrigerant. Furthermore, the sliding member of the present invention is not limited to the sliding member used in the compressor. Any part may be used as long as it is a sliding part such as a sliding member of a fluid machine other than the compressor, a driving part of a vehicle or a manufacturing apparatus, a rotating part, or the like.

    In the above sliding portion, only one member of the two members sliding with each other is coated with a sliding member composition having a composition ratio of PTFE / PAI / fluoride / Al2O3 = 20/60/15/5. A layer may be formed, or the coat layer may be formed on both members.

    Moreover, the roughening method of a base material is not limited to chemical conversion treatment, Various well-known methods, such as a sandblasting process, can be used. Moreover, the chemical | medical agent used for a chemical conversion treatment is not limited to manganese phosphate, Another phosphate and a well-known chemical | medical solution can be used.

    Further, the coating layer of the sliding member composition may contain a pigment such as carbon as a coloring agent and other additives in addition to the main component composed of a fluororesin, a binder and CaF2. . The addition amount of such an additive is set to such an extent that it does not adversely affect performance such as wear resistance of the layer containing the composition for sliding member and adhesion to the substrate. For example, carbon as an additive must be set to 3% by mass or less of the fluororesin, preferably 1% by mass or less, and more preferably 0.5% by mass or less.

    The thickness of the coating layer of the sliding member composition is preferably 35 μm or more and 120 μm or less. If it is thinner than 35 μm, the sliding performance may be inferior, and if it is thicker than 120 μm, the manufacturing cost increases. The thickness of this layer is more preferably 50 μm or more and 105 μm or less in terms of sliding performance and cost. In addition, the thickness of a layer here is an average thickness, Comprising: You may be the thickness outside this range locally.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the composition for a sliding member according to the present invention has excellent wear resistance and is useful as a coating layer for sliding members of air conditioners, vehicles, machine tools, and the like. The sliding member provided with the coating layer and the fluid machine provided with the sliding member are useful as sliding members and fluid machines for air conditioners, vehicles, machine tools, and the like.

1 is a cross-sectional view of a scroll compressor according to Embodiment 1. FIG. It is the schematic explaining the journal test in a refrigerant | coolant. It is a table | surface showing the relationship between a composition of a composition for sliding members, friction coefficient (micro | micron | mu), and an abrasion loss.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Scroll compressor 25 Slide bush 26 Cylindrical part 50 of slide bush 50 Movable scroll 53 Movable scroll protrusion 70 Lubrication part

Claims (7)

Containing a fluororesin, a binder, and two or more kinds of antiwear agents ,
Of the two or more types of antiwear agents, at least one antiwear agent is a fluoride of at least one of calcium fluoride, strontium fluoride, and magnesium fluoride,
At least one other antiwear agent is an antiwear particle of at least one of aluminum oxide, zirconium oxide, silicon oxide and silicon nitride;
The binder is 100 parts by weight or more and 500 parts by weight or less, the fluoride is 50 parts by weight or more and 200 parts by weight or less, and the wear-resistant particles are 1 part by weight with respect to 100 parts by weight of the fluororesin. The composition for a sliding member, which is 100 parts by weight or less . In claim 1,
The fluororesin is polytetrafluoroethylene,
The composition for a sliding member, wherein the binder is a polyamide-imide resin. In claim 1 ,
The composition for a sliding member, wherein the binder is 300 parts by weight, the fluoride is 75 parts by weight, and the wear-resistant particles are 25 parts by weight with respect to 100 parts by weight of the fluororesin. object. In claim 1 ,
A composition for a sliding member, wherein the wear-resistant particles are aluminum oxide. A sliding member having a coat layer formed on the surface of a metal substrate,
The said coating layer is comprised with the composition for sliding members in any one of Claim 1 to 4 , The sliding member characterized by the above-mentioned. A fluid machine comprising the sliding member according to claim 5 . In claim 6 ,
A fluid machine, wherein the sliding member is a bearing member.