JP2014142070A - Compound slide bearing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a slide bearing which has a synthetic resin bearing layer with sintered metal as a base material, and can obtain precise and stable rotation torque, and to provide the high-accuracy slide bearing usable as a slide bearing which receives a relatively-large radial load and an axial load such as, for example, rotating shafts of a compressor for a room air conditioner and a compressor for a car air conditioner, and transmissions of an automobile and a construction machine.SOLUTION: A resin layer 2 is integrally formed by being laminated on the inside diameter face side of a sintered metal-made base material 1 of a cylindrical slide bearing, the resin layer 2 is composed of a resin component obtained by blending a fibrous filling material into an aromatic polyether ketene resin, the fibrous filling material 3 is oriented so that a length direction of a fiber intersects with a rotation direction of a bearing at angles of 45 to 90 degrees, and the resin layer 2 is formed with a thickness of 0.1 to 0.7 mm, thus forming a compound slide bearing. The wear damage of a mating material caused by both-end edges of the fiber is reduced, and a friction coefficient is stabilized. By this constitution, there can be provided the compound slide bearing which has the synthetic resin layer 2 with sintered metal as the base material 1, and can obtain precise and stable rotation torque.

Description

  The present invention relates to a sliding plain bearing which is used for a sliding bearing with stable lubricity and high rotational accuracy, and in particular, a resin layer made of an aromatic polyether ketone resin (PEK resin) using a sintered metal as a base material. .

  Conventionally, a sliding bearing in which a porous sintered metal is impregnated with oil is known as a sliding bearing with high rotational accuracy. If this sliding bearing is used by impregnating a sintered metal-based porous material with oil, the oil can be continuously supplied to the sliding interface. Is possible.

  The mating material with which such a sliding bearing comes into contact is usually the same metal material as that of such a sliding bearing, so there is no concern of so-called “drumming or missing” due to differences in linear expansion, and the processing accuracy is increased. Suitable for applications that require rotational accuracy.

  In addition, as a plain bearing having a self-lubricating property other than the above, a solid lubricant such as tetrafluoroethylene resin (PTFE), graphite, molybdenum disulfide, or a lubricating oil or wax is blended in the resin. Things are known.

  However, the sliding bearing used by impregnating the porous sintered metal with oil may wear the mating material when the shaft or the mating material to be fixed is a soft material, and the supply of lubricating oil is interrupted. In some cases, metal contact may occur.

  In particular, when a resin material with better sliding properties is used as the material for the sliding bearing, if the counterpart material is a soft material, the shaft will be stiff due to shrinkage and expansion of the resin without attacking it. In addition, it is necessary to set a large clearance between the bearings, which causes a problem that rotation accuracy is deteriorated.

  For this reason, a metal is used as the outer peripheral portion of the bearing, and a resin layer is formed by insert molding a resin material on the sliding portion of the outer peripheral portion of the bearing, and at least the surface of the outer peripheral portion of the bearing is in contact with the resin layer. A fine concave portion is provided on the surface portion of the outer peripheral portion of the bearing, and (the linear expansion coefficient of the resin material) × (the thickness of the resin layer) in the resin layer is 0.15 or less, and the total apparent area occupied by the concave portion is A high-accuracy plain bearing having a surface area of 25 to 95% of the surface portion of the outer periphery of the bearing in contact with the resin layer is known (Patent Document 1).

  Further, in such a high-precision sliding bearing, the gate trace at the time of injection molding may adversely affect the bearing performance, and the processing of the gate trace may increase the production process, resulting in poor productivity.

  In order to cope with such a problem, there is known a high-precision sliding bearing that employs insert molding through a tunnel gate when a resin layer is formed on a sintered metal (Patent Document 2).

  Such a high-precision sliding bearing is used for a photosensitive drum, a developing unit, a supporting unit for a fixing unit, or a carriage bearing of a copying machine or a printer.

JP 2003-239976 A JP-A-2005-333781

  However, the above-described conventional high-accuracy plain bearings have a problem that sufficient characteristics regarding the wear resistance of the resin layer have not been obtained, and therefore, it is difficult to use in high load and high rotation parts.

  For example, the above-mentioned conventional high-accuracy plain bearings can be used for precise rotation to support the rotating shafts of compressors for room air conditioners and car air conditioners, and to support the rotating shafts of transmissions such as automobiles and construction machinery. There is a problem that it is difficult to use as a sliding bearing for which accuracy is required and for receiving a large radial load or axial load.

The present invention solves the above-mentioned problems, and is to provide a sliding bearing having a synthetic resin bearing layer with a sintered metal as a base material and capable of obtaining a precise and stable rotational torque. It is a high-precision sliding bearing that can be used as a sliding bearing that receives a relatively large radial load or axial load, such as a rotary shaft of an air conditioner compressor or a car air conditioner compressor, or a transmission of an automobile or a construction machine.
In other words, in order to enable the above-mentioned use, by providing a high-accuracy plain bearing having improved load resistance, heat resistance, low friction characteristics, and wear resistance characteristics that are lacking in conventional high-precision slide bearings. is there.

  In order to solve the above-mentioned problems, in the present invention, a resin layer is integrally provided on a sintered metal base material of a sliding bearing, and the resin layer is formed by adding a fibrous filler to an aromatic polyether ketone resin. It consists of a blended resin composition (PEK resin composition), and the fibrous filler is oriented so that the length direction of the fiber intersects 45 to 90 degrees with respect to the rotation direction of the bearing, and the resin layer is This is a compound plain bearing provided with a layer thickness of 0.1 to 0.7 mm.

  The composite sliding bearing according to the present invention configured as described above includes a fibrous filler in the aromatic polyether ketone resin forming the resin layer, and the fiber length direction intersects with the rotation direction of the bearing. Is blended in a state of being oriented and dispersed so as to be 45 to 90 degrees, thereby reducing the chance that the opposite ends of the fiber become edges and causing wear damage to the mating material, and the friction coefficient during rotation of the bearing is reduced. The torque becomes smaller and the torque fluctuation of the bearing is low and stable. Thus, a composite sliding bearing having a precise and stable bearing torque having a synthetic resin bearing layer using a sintered metal as a base material is obtained.

  In addition, in order to disperse the fibrous filler that is reliably oriented as described above in the resin layer, the resin layer is a resin layer integrated by injection molding over the base material. Is preferred.

Furthermore, in order to disperse such a fibrous filler in a stably oriented state, the resin layer is a resin having a thickness of 1/8 to 1/2 of the thickness in the axial direction of the substrate. In order to disperse the particles so that the crossing angle is 45 to 90 degrees by injection molding or the like, the fibrous filler is a fiber having an average fiber length of 0.02 to 0.2 mm. It is preferable that it is a filler.
Further, in order to achieve adhesion with such a resin layer and to ensure the required thermal conductivity of the base material, the base material should be a base material having a theoretical density ratio of 0.7 to 0.9. preferable.
Since such a sintered metal base material is used, heat is easily radiated from the resin layer to the bearing base material and from the bearing base material to the outside. Further, since the surface is uneven, the surface area is large, the anchor effect with the resin layer is high, and the adhesion strength can be increased.

  By forming a resin layer made of a resin composition of an aromatic polyether ketone resin on the base material by injection molding, particularly by insert molding, the resin layer becomes uneven on the surface of the sintered metal during injection molding. Since the true joint area increases by deeply biting in, the adhesion strength between the resin layer and the bearing base material is improved. Furthermore, since the true bonding area between the resin layer and the bearing base is increased and there is no gap between the resin layer and the sintered metal, the heat of the resin layer is easily transferred to the bearing base.

  In addition, since the resin layer is thin-molded on the surface of the sintered alloy having high dimensional accuracy, a bearing with high dimensional accuracy can be obtained.

  By making the average fiber length of the carbon fibers in the resin composition of the aromatic polyether ketone resin 0.02 to 0.2 mm, stable melt fluidity even in thin-wall insert molding of 0.1 to 0.7 mm Can be secured.

Further, by setting the melt viscosity at a resin temperature of 380 ° C. and a shear rate of 1000 s ⁻¹ of the resin composition of the aromatic polyether ketone resin to 50 to 200 Pa · s, 0.1 is applied to the surface of the sintered metal substrate. It is possible to smoothly perform a thin insert molding of ~ 0.7 mm.
When molding, since the sintered metal as the base material is not impregnated with oil, the adhesion strength between the resin layer and the bearing base material is not hindered.

  Adhesiveness between the resin layer and the bearing substrate can be improved by using a sintered alloy containing iron as a main component and an iron-based sintered alloy having a copper content of 10% or less as the material of the bearing substrate. .

  Then, by setting the shear adhesion strength between the bearing substrate and the resin layer to 2 MPa or more, the resin layer does not peel from the bearing substrate even when used as a sliding bearing under high PV conditions.

  In the composite sliding bearing of the present invention, since the resin composition of the aromatic polyether ketone resin is employed in the resin layer, it is excellent in friction and wear characteristics, seizure resistance, various chemical resistances, and oil resistance.

  By applying steam treatment to the iron-based sintered metal base material, it is possible to remove deposits (oil, etc.) during the sintering process (molding, re-pressing), so the adhesion between the resin layer and the bearing base material is strong. Is stable.

  Preferably, the resin composition contains 5 to 30% by volume of carbon fiber and 1 to 30% by volume of a tetrafluoroethylene resin as essential components, and the balance is a resin composition of an aromatic polyetherketone resin. The carbon fiber is preferably a PAN-based carbon fiber.

  Moreover, it is preferable that the said composite sliding bearing is what provided the said resin layer in the 1 or more side surface chosen from the internal diameter side of a cylindrical or a cylindrical bearing base with a flange, an outer diameter side, and an end surface side.

  Since the composite sliding bearing of the present invention is a composite sliding bearing in which a 0.1 to 0.7 mm thick resin layer made of a PEK resin composition is formed on a sintered metal substrate, a cylindrical bearing for supporting a radial load, a radial bearing Even when a bearing that supports a load and an axial load and a thrust washer that supports an axial load are used, the bearing has high heat dissipation, small deformation and wear, and a low friction coefficient.

  In addition, this composite sliding bearing can be used as a bearing in which hydraulic oil, refrigerator oil, lubricating oil, transmission oil, engine oil, brake oil, or grease, or grease is interposed.

  In the composite sliding bearing of the present invention, a resin layer made of a resin composition in which a fibrous filler is oriented in a predetermined direction on an aromatic polyetherketone resin is provided on a sintered metal base with a predetermined thickness. Therefore, it has excellent load resistance, heat resistance, low friction characteristics and wear resistance characteristics, and the oriented fibers can reduce wear damage of the mating material and stabilize the friction coefficient. There is an advantage that a sliding bearing having a synthetic resin bearing layer as a material and capable of obtaining a precise and stable rotational torque can be obtained.

  Moreover, since the layer thickness of the resin layer is 1/8 to 1/2 of the thickness of the sintered metal substrate or the thin wall is 0.1 to 0.7 mm, the heat due to frictional heat generation is increased. Easily escape from the friction surface to the bearing base, hardly store heat, has high load resistance, and the amount of change is small even under high surface pressure. As a result, the real contact area on the friction surface is reduced, the frictional force and frictional heat generation are reduced, and there is an advantage that wear is reduced and the increase in the friction surface temperature is suppressed.

  Further, by using a resin composition comprising a high heat resistance aromatic polyetherketone resin with a continuous use temperature of 250 ° C. for the resin layer, a composite sliding bearing having excellent frictional wear characteristics and creep resistance characteristics can be obtained.

  By setting the density of the sintered metal to the theoretical density ratio of the material of 0.7 to 0.9, it is possible to secure surface irregularities for obtaining adhesion and at the same time have the required denseness. The thermal conductivity of the material can be secured.

  Furthermore, since the resin composition of the aromatic polyether ketone resin has 5 to 30% by volume of carbon fiber and 1 to 30% by volume of PTFE resin as the essential components and the remainder is an aromatic polyether ketone resin, the high PV Even under the conditions, deformation and wear of the resin layer, damage to the counterpart material is small, and resistance to oil and the like is high.

By setting the melt viscosity at a resin temperature of 380 ° C. and a shear rate of 1000 s ⁻¹ of the aromatic polyetherketone resin composition to 50 to 200 Pa · s, 0.1 to 0 on the surface of the sintered metal substrate. It is possible to smoothly perform .7 mm thin insert molding.

  By using PAN-based carbon fiber as the carbon fiber, the elastic modulus of the resin layer is increased, and deformation and wear of the resin layer are reduced. Furthermore, the true contact area of the friction surface is reduced, and frictional heat generation is reduced.

  This composite plain bearing has a versatility to withstand one or more of radial load and axial load by providing a resin layer on a predetermined surface, and it can be used as a slide bearing for liquid lubrication lubricated with oil or grease. There is an advantage that it is possible to withstand and secure high-precision rotational stability.

The perspective view which notches and shows a part of compound rolling bearing of 1st Embodiment Sectional drawing of the compound rolling bearing of 1st Embodiment Sectional drawing of the composite rolling bearing of 2nd Embodiment Sectional drawing of the compound rolling bearing of 3rd Embodiment Sectional drawing of the composite rolling bearing of 4th Embodiment

Embodiments of the present invention will be described below with reference to the accompanying drawings.
As shown in FIGS. 1 and 2, in the first embodiment, a resin layer 2 is integrally provided on the inner surface of a sintered metal base 1 of a cylindrical sliding bearing. The fibrous filler 3 has a mean crossing angle of 90 degrees with respect to the rotational direction of the bearing, that is, an orthogonal state. The resin layer 2 is a composite sliding bearing provided with a layer thickness of 0.1 to 0.7 mm.

  Further, the second embodiment shown in FIG. 3 can be used as a cylindrical bearing that supports a radial load by forming a resin layer 5 on the outer diameter side of a sintered metal base 4 of the bearing.

  In the third embodiment shown in FIG. 4, a resin layer 7 is provided on the inner diameter side of a cylindrical sintered metal base material 6 with a flange of a bearing, and supports a radial load and an axial load at the same time. It is something that can be done.

Further, the fourth embodiment shown in FIG. 5 is a composite sliding bearing in which a resin layer 9 is provided on one side of a thrust washer-type sintered metal base material 8 that supports an axial load.
When molding the resin layers 2, 5, 7, and 9 on the predetermined surfaces of the sintered metal bases 1, 4, 6, and 8 of these bearings, the resin melt flow direction is the direction of movement of the sliding bearing. 1 to 4, there is a method of forming a resin by providing a pin gate, a disk gate, a film gate, etc. so that the molten resin flows in one direction from the bearing end face of FIG. 1 to the other end face.

  In the thrust washer of FIG. 5, a disk gate may be provided on the inner diameter side.

  When using the above-mentioned bearing as a bearing for sliding parts where hydraulic oil, refrigeration oil, lubricating oil, transmission oil, engine oil, brake oil, etc., or grease is present, form a lubricating groove on the friction surface of the resin layer Thus, more stable low friction and low wear characteristics can be obtained.

  That is, the composite sliding bearings of these embodiments form a resin layer in which the resin melt flow direction at the time of molding is 45 to 90 degrees with respect to the movement direction of the sliding bearing on the sintered metal base, By making the surface and the bearing base material a sintered alloy, a heat radiation effect of frictional heat generation is obtained with high adhesion to the resin layer.

  By using the PEK resin composition for the resin layer, the continuous use temperature is 250 ° C., and a composite sliding bearing having excellent heat resistance, oil / chemical resistance, creep resistance, and friction and wear characteristics is obtained. In addition, PEK resin has high toughness, mechanical properties at high temperatures, and excellent fatigue resistance and impact resistance, so there is a risk of peeling from the sintered metal substrate due to friction, shock, vibration, etc. during use. There is no.

  PEK resin, fibrous filler (glass fiber, carbon fiber, aramid fiber, whisker, etc.), solid lubricant (PTFE, graphite, molybdenum disulfide, etc.), inorganic filler (calcium carbonate, calcium sulfate, mica, talc, etc.) ) Can improve creep resistance, no lubrication, and friction and wear characteristics in oil lubrication.

  Fibrous fillers, inorganic solid lubricants (graphite, molybdenum disulfide, etc.) and inorganic fillers have the effect of reducing the molding shrinkage of the PEK resin composition. Therefore, there is also an effect of suppressing the internal stress of the resin layer at the time of insert molding with the bearing base material.

  In addition, solid lubricants (PTFE, graphite, molybdenum disulfide, etc.) are non-lubricated and have low friction even under conditions where the lubricating oil is dilute, improving seizure properties.

In forming the resin layer, since the melt flow direction of the resin at the time of molding the resin is 45 to 90 degrees with respect to the movement direction of the sliding bearing, needle-like or fibrous fillers (glass fiber, carbon fiber, aramid) When blending fibers, whiskers, etc.), these fillers are oriented at 45 to 90 degrees with respect to the direction of motion of the sliding bearing. Needle-like or fibrous fillers have a sharp edge with an edge of 90 ° or less, so when the filler edge is in the direction of movement of the sliding bearing, it physically wears the mating material in sliding contact. It is easy to damage and the coefficient of friction is difficult to stabilize. However, in the present invention, these fillers are 45 to 90 degrees with respect to the direction of movement of the sliding bearing, so that it is difficult to wear damage the mating material in sliding contact, and the friction coefficient is stable. The orientation of the fibrous filler is preferably closer to 90 degrees because wear damage due to the edge of the filler is less and the friction coefficient is stable. If it is 80-90 degree | times, it is especially preferable.

The thickness of the resin layer of the composite sliding bearing, that is, the radial or axial thickness along the direction of receiving a load is 0.1 to 0.7 mm. Alternatively, the thickness of the resin layer is 1/8 to 1/2 of the thickness of the sintered metal substrate.
When the thickness of the resin layer exceeds 0.7 mm or exceeds 1/2 of the thickness of the sintered metal substrate,
Heat due to friction is difficult to escape from the friction surface to the bearing base, and the friction surface temperature increases. Further, the amount of deformation due to the load increases, the true contact area on the friction surface also increases, the frictional force and the heat generated by friction increase, and the seizure property also decreases. When the resin thickness is less than 0.1 mm or the resin layer thickness is less than 1/8 of the thickness of the sintered metal base material, durability during long-term use, that is, life is shortened.

  In order to form a resin layer on a sintered metal substrate, a method in which a material formed by injection molding or extrusion molding of a PEK resin molding is fixed to the sintered metal substrate by heat fusion, adhesion, press fitting, etc., gold There is a method in which a sintered metal substrate is inserted into a mold and a PEK resin composition is injection molded. Further, this can be finished to a required resin thickness by machining.

A method of forming a resin layer by insert molding is preferable because it is the cheapest and has relatively high dimensional accuracy. In the case of insert molding, the resin thickness is preferably 0.1 to 0.7 mm in consideration of moldability by injection molding or the like. If the resin thickness is less than 0.1 mm, insert molding is difficult. If the resin thickness exceeds 0.7 mm, sink marks occur and dimensional accuracy decreases. In consideration of heat dissipation of frictional heat to the bearing base material, the resin thickness is preferably 0.2 to 0.5 mm.
When high dimensional accuracy is required, a relatively inexpensive bearing can be obtained even if the resin thickness is finished by machining after insert molding.

  Examples of the material of the sintered metal substrate used in the present invention include iron-based, copper-iron-based, copper-based, and stainless-based materials. When a sintered metal base material is inserted into the mold and the PEK resin composition is injection-molded, the mold temperature is 160 to 200 ° C and the resin temperature is 360 to 410 ° C.

If the sintered metal has oil adhesion or oil impregnation, the oil residue decomposes and gasifies during the injection molding, and the oil residue is present at the interface, so the adhesion between the resin layer and the sintered metal is reduced.
Therefore, these sintered metal substrates must be sintered without impregnation with oil. In addition, when oil is used in the process of forming or repressing (sizing) a sintered metal, it must be a non-oil-impregnated sintered bearing from which the oil has been removed by solvent washing or the like.

In the sintered metal substrate used in the present invention, the density of the sintered metal is 0.7 to 0.9 in terms of the theoretical density ratio of the materials. The theoretical density ratio of the material is the ratio of the density of the sintered metal base material when the theoretical density of the material (density when the porosity is 0%) is 1. If the theoretical density ratio is less than 0.7, the strength of the sintered metal is lowered, and the sintered metal is cracked by the injection molding pressure at the time of insert molding. When the theoretical density ratio exceeds 0.9, the unevenness is reduced, so that the surface area and the anchor effect are lowered, and the adhesion with the PEK resin layer is lowered. More preferably, the theoretical density ratio of the materials is 0.72 to 0.84.

  Since the sintered metal base material used for this invention is a sintered metal which has iron as a main component, adhesiveness with a PEK resin layer becomes high. Since copper is inferior in adhesiveness (adhesiveness) with resin than iron, the copper content is preferably 10% or less. More preferably, the copper content is 5% or less.

  Sintered metal with iron as its main component is an effect that removes oil and deposits adhering to the sintered surface or penetrating into the sintered body unintentionally during the molding or re-pressing (sizing) process by applying steam treatment Therefore, variation in adhesion with the PEK resin layer is small and stable. Moreover, rust prevention can also be provided to a sintered metal base material. The conditions for the steam treatment are not particularly limited, but a method of spraying steam heated to about 500 ° C. is common.

  In the present invention, the shear adhesion strength between the sintered metal substrate of the composite sliding bearing and the PEK resin layer is 2 MPa or more (surface pressure 10 MPa, safety factor at friction coefficient 0.1 is 2 times or more). In order to obtain a sufficient adhesion strength against the frictional force during use, a shear adhesion strength of 2 MPa or more is preferable. Furthermore, in order to raise a safety factor, 3 Mpa or more is preferable.

  Moreover, in order to further enhance the shear adhesion strength between the sintered metal substrate and the PEK resin layer, the sintered metal surface on which the resin layer is formed may be provided with physical stoppers such as irregularities and grooves, and rotation prevention. good.

  The PEK resin composition used in the present invention preferably contains 5 to 30% by volume of carbon fibers and 1 to 30% by volume of PTFE resin, with the remainder being PEK resin.

Examples of the PEK resin include PEEK (polyetheretherketone resin), PEK (polyetherketone resin), PEKKK (polyetherketoneetherketoneketone resin), and the like. As PEEK, PEEK (90P, 150P, 380P, 450P, etc.) manufactured by Victrex, KetaSpire manufactured by Solvay Advanced Polymers (KT-820P, KT-880P, etc.), VESTAKEEEP (1000G, 2000G, 3000G, 4000G) manufactured by Daicel Degussa. Etc.).
Examples of PEK include PEEK-HT manufactured by Victrex, and examples of PEKKK include PEEK-HT manufactured by Victrex.

In order to set the melt viscosity at a resin temperature of 380 ° C. and a shear rate of 1000 s ⁻¹ of the PEK resin composition to 50 to 200 Pa · s, it is preferable to employ a PEK resin having a melt viscosity of 150 Pa · s or less under the above conditions. Examples include PEEK 150P, 90P, 150G, 90G manufactured by Victrex, and KetaSpire KT-880P manufactured by Solvay Advanced Polymers.

In order to obtain a resin thickness of 0.2 to 0.5 mm by insert molding, the melt viscosity at a resin temperature of 380 ° C. and a shear rate of 1000 s ⁻¹ of the PEK resin composition should be 50 to 200 Pa · s. It is preferable for precise molding and orientation of the fibrous filler at a predetermined angle. For this purpose, it is preferable to employ a PEK resin having a melt viscosity of 130 Pa · s or less under the above conditions, and examples include PEEK 90P and 90G manufactured by Victrex.
Even if the melt viscosity is a high viscosity less than the above-mentioned predetermined range or a low viscosity exceeding the above-mentioned predetermined range, it is not easy to surely obtain the desired effect on the precise moldability and the orientation of the fibrous filler.

The carbon fiber as a representative example of the fibrous filler used in the present invention may be either a pitch-based or PAN-based material classified from raw materials, but a PAN-based carbon fiber having a high elastic modulus is better. preferable. The firing temperature is not particularly limited, but is 1000 to 150 than that obtained by firing at a high temperature of 2000 ° C. or higher to form graphite.
A carbonized product fired at about 0 ° C. is preferable because it is difficult to wear and damage the sliding partner metal even under high PV.

The average fiber diameter of the carbon fibers is 20 μm or less, preferably 5 to 15 μm. For thick carbon fibers exceeding the above range, extreme pressure is generated, so the effect of improving the load resistance is poor, and when the sliding contact material is an aluminum alloy and steel without quenching, the wear damage of the counterpart material increases. It is not preferable.
The carbon fiber may be a chopped fiber or a milled fiber, but a milled fiber having a fiber length of less than 1 mm is preferred in order to obtain stable thin-wall formability.

The average fiber length of the carbon fiber is preferably 0.02 to 0.2 mm. If the thickness is less than 0.02 mm, a sufficient reinforcing effect cannot be obtained, so that the creep resistance and wear resistance are poor. When it exceeds 0.2 mm, the ratio of the fiber length to the thickness of the resin layer becomes large, so that the thin formability is inferior. In particular, when insert molding is performed with a resin thickness of 0.2 to 0.7 mm, if the fiber length exceeds 0.2 mm, the thin moldability is impaired. In order to further improve the stability of thin-wall molding, an average fiber length of 0.02 to 0.1 mm is preferable.

Carbon fiber is preferable because the orientation of the resin in the melt flow direction is strong when the resin layer is formed.
The fibrous filler is oriented at a crossing angle as close to a right angle as possible at 45 degrees or more with the movement direction of the sliding bearing, so that the edges at both ends of the fiber are oriented at right angles to the movement direction. As a result, it is possible to reduce wear damage of the mating member due to the edges of both ends of the fiber and to stabilize the friction coefficient.
In this case, it is preferable that 50% or more of the crossing angle of the fibers per unit area of the fibrous filler in an arbitrary cross section of the resin layer, or an average crossing angle is within the range of the predetermined crossing angle.

  In particular, a carbon fiber having a small diameter and a relatively short length is selected. In this case, if the edges of the carbon fiber are along the movement direction of the sliding bearing, for example, if the crossing angle is less than 45 degrees, Severely damaged. For this reason, when thin and short carbon fibers are used, when the resin is melt-molded, the flow direction of the molten resin is set to a right angle or a near right angle to the movement direction of the sliding bearing, and the length direction of the fiber is set to the bearing direction. Orientation to intersect at 45 to 90 degrees with respect to the rotational direction is extremely advantageous in order to stabilize the durability and bearing torque low.

  Commercially available carbon fibers usable in the present invention include pitch-based carbon fibers manufactured by Kureha Co., Ltd .: Kureka M-101S, M-107S, M-101F, M-201S, M-207S, M-2007S, C- 103S, C-106S, C-203S, and the like. Moreover, as a similar PAN-based carbon fiber, manufactured by Toho Tenax Co., Ltd .: Besfight HTA-CMF0160-0H, HTA-CMF0040-0H, HTA-C6, HTA-C6-S, or Toray Industries, Inc .: Torayca MLD-30 , MLD-300, T008, T010, and the like.

The PTFE used in this invention may employ any of molding powder by suspension polymerization, fine powder by emulsion polymerization, and regenerated PTFE. In order to stabilize the fluidity of the PEK composition, It is preferable to employ recycled PTFE that is difficult to be fiberized by shearing and hardly increases the melt viscosity. Regenerated PTFE is a powder that has been irradiated with a heat-treated powder (heated history added), γ-rays or electron beams. For example, a powder obtained by heat-treating molding powder or fine powder, a powder obtained by further irradiating this powder with γ-rays or an electron beam, a powder obtained by pulverizing a molding powder or a molded product of fine powder, and then a γ-ray or electron beam. There are types such as irradiated powder, molding powder or fine powder irradiated with gamma rays or electron beams.

  Furthermore, as PTFE that does not aggregate, does not fiberize at the melting temperature of the PEK resin, has an internal lubrication effect, and can stably improve the fluidity of the PEK resin composition, It is more preferable to use PTFE irradiated with a line or the like.

  As a commercial product of PTFE, Kitamura Co., Ltd .: KTL-610, KTL-450, KTL-350, KTL-8N, KTL-400H, Mitsui DuPont Fluorochemical Co., Ltd .: Teflon 7-J, TLP-10, Asahi Glass Co., Ltd. Manufactured: Fullon G163, L150J, L169J, L170J, L172J, L173J, Daikin Industries, Ltd .: Polyflon M-15, Lubron L-5, Hoechst: Hostaflon TF9205, TF9207, and the like. Further, PTFE modified with a side chain group having a perfluoroalkyl ether group, a fluoroalkyl group, or other fluoroalkyl may be used.

Among PTFE irradiated with γ rays or electron beams among the above, Kitamura Co., Ltd .: KTL-610, KTL-450, KTL-350, KTL-8N, KTL-8F, Asahi Glass Co., Ltd .: Fullon L169J, L170J, L172J, L173J, etc. are mentioned.
As described above, the reasons for the blending ratio of carbon fiber 5 to 30% by volume, PTFE 1 to 30% by volume as essential components, and the balance being PEK resin are as follows.

  When the blending ratio of the carbon fiber exceeds 30% by volume, the melt fluidity is remarkably lowered, making it difficult to form a thin wall, and when the sliding contact material is an aluminum alloy or an unquenched steel material, it is because of wear damage. . Further, if the blending ratio of the carbon fibers is less than 5% by volume, the effect of reinforcing the composition is poor, and sufficient creep resistance and wear resistance cannot be obtained.

  When the blending ratio of PTFE exceeds 30% by volume, the wear resistance and creep resistance are lowered from the required levels. Further, when the blending ratio of PTFE is less than 1 part by volume, the composition does not have sufficient lubricity imparting effect, and sufficient sliding characteristics cannot be obtained.

In addition, well-known additives for resins as listed below may be blended with the lubricating resin composition to such an extent that the effects of the present invention are not impaired.
(1) Friction property improver: graphite, boron nitride, molybdenum disulfide, tungsten disulfide, etc. (2) Colorant: carbon powder, iron oxide, titanium oxide, etc. (3) Thermal conductivity improver: graphite, metal oxide Powder

  The means for mixing and kneading the above raw materials is not particularly limited, and only the powder raw material is dry-mixed with a Henschel mixer, ball mixer, ribbon blender, ladyge mixer, ultra Henschel mixer, etc. Melting and kneading can be performed with a melt extruder such as an extruder to obtain molding pellets (granules). In addition, a side feed may be used for charging the filler when melt kneading with a twin screw extruder or the like. As a molding method, extrusion molding, injection molding, heat compression molding, or the like can be adopted, but injection molding is particularly preferable in terms of manufacturing efficiency. Moreover, you may employ | adopt processes, such as an annealing process, for a physical property improvement with respect to a molded article.

The composite sliding bearing of the present invention comprises a resin composition having a thickness of 0.1 to 0.7 mm and a sintered metal substrate. The resin layer is made of a PEK resin composition. Since the PEK resin composition is used as a friction surface, it is excellent in frictional wear characteristics and creep resistance, and since sintered metal is used as a bearing base material, it is excellent in heat dissipation of frictional heat and load resistance. Therefore, for example, it can be used as a sliding bearing for a compressor for a room air conditioner / car air conditioner, a transmission of an automobile, a construction machine, or the like.

  The composite sliding bearing of the present invention is not particularly limited in shape, and can support either a radial load, an axial load, or both. Further, the position of the resin layer formed on the bearing base material is not particularly limited.

[Examples 1 to 22, Comparative Examples 1 to 13]
The bearing base materials used in the examples and comparative examples are shown together in Table 1, and the raw materials for the resin layers used in the examples and comparative examples are collectively shown below.
The melt viscosity of the aromatic polyether ketone resin is a measured value at a Capillograph manufactured by Toyo Seiki Co., Ltd., φ1 × 10 mm capillary, a resin temperature of 380 ° C., and a shear rate of 1000 s ⁻¹ .

(1) Aromatic polyether ketone resin [PEK-1]
Victrex: PEEK 90P (melt viscosity 105 Pa · s)
(2) Aromatic polyetherketone resin [PEK-2]
Victrex: PEEK 150P (melt viscosity 145 Pa · s)
(3) Aromatic polyetherketone resin [PEK-3]
Victrex: PEEK 450P (melt viscosity 420 Pa · s)
(4) PAN-based carbon fiber [CF-1]
Toray Industries, Inc .: Trading card MLD-30 (average fiber length 0.03 mm, average fiber diameter 7 μm)
(5) PAN-based carbon fiber [CF-2]
Toho Tenax Co., Ltd .: Beth Fight HTA-CMF0160-0H
(Fiber length 0.16mm, fiber diameter 7μm)
(6) Pitch-based carbon fiber [CF-3]
Made by Kureha: Kureka M-101S
(Average fiber length 0.1 / 2 mm, average fiber diameter 14.5 μm)
(7) Pitch-based carbon fiber [CF-4]
Made by Kureha: Kureka M-107S
(Average fiber length 0.7 mm, average fiber diameter 14.5 μm)
(8) Calcium carbonate powder [CaCO ₃ ]
Nichichi Kogyo Co., Ltd .: NA600 (average particle size 3 μm)
(9) Graphite [GRP]
TIMCAL JAPAN Co., Ltd .: TIMREX KS6 (average particle size 6 μm)
(10) Tetrafluoroethylene resin [PTFE]
Kitamura Co., Ltd .: KTL-610 (Regenerated PTFE)
(11) Bronze powder [BRO]
Fukuda Metal Foil Powder Industry Co., Ltd .: AT-350 (copper tin alloy powder)

  The raw materials were dry-blended using a Henschel dry mixer at the blending ratio (volume%) shown in Tables 2 and 3, and melt-kneaded using a twin-screw extruder to produce pellets.

With this pellet, a resin layer having a thickness of 0.2 to 1 mm on the inner diameter of a cylindrical bearing substrate (φ31 × φ35 × 20 (mm)) under the conditions of a resin temperature of 380 ° C. to 400 ° C. and a mold temperature of 180 ° C. Was formed by insert molding, and a cylindrical composite slide bearing (φ30 × φ35 × 20 (mm)) supporting a radial load as shown in FIG. 1 was produced. When molding a compound slide bearing, nine pin gates were provided on the end face of the bearing and injection molded so that the melt flow direction of the resin layer was perpendicular to the direction of motion of the slide bearing.

(1) Shear adhesion strength test A cylindrical composite slide bearing in which a resin layer-Example a is insert-molded with a thickness of 0.5 mm is used for the bearing base diameter shown in Table 1, and a shear adhesion strength test is performed. went. The bearing base was fixed, an axial shearing force was applied to the inner diameter resin layer, and the load at which the resin layer peeled from the bearing base was measured. The value obtained by dividing the load by the apparent bonding area between the resin layer and the bearing base material is defined as shear adhesion strength, and is shown in Table 4.

  Table 4 also shows the presence or absence of bearing base material cracking when 30 composite sliding bearings were produced by insert molding.

(2) Seizure resistance test Bearing base material-radial-in-oil type tester for composite sliding bearing (φ30 × φ35 × 20 (mm)) in which the resin layer of Table 2 or Table 3 is formed on the inner diameter of Example E A seizure resistance test was carried out. After running-in for 30 minutes under the oil supply conditions in Table 5, the time from oil supply stop, oil discharge and seizure was measured. Seizure was defined as the time until the bearing outer diameter temperature increased by 20 ° C. or the torque increased twice.

The seizing time is shown in Tables 6 and 7. The following sliding bearings were added to the comparative examples.
As the sliding bearing made of a single resin, a sliding bearing made of only a resin (φ30 × φ35 × 20 mm) obtained by injection molding only the composition a in Table 2 was used.
In addition, the three-layer composite slide bearing is a three-layer composite slide bearing (φ30 × φ35 × 20 mm, resin composition) in which a porous sintered layer with a backing is impregnated with a PTFE resin composition (10% by volume of carbon fiber). The material layer was 0.05 mm). When the predetermined resin layer thickness shown in Table 6 could not be formed by insert molding, a thick product was injection molded and finished to a predetermined thickness by machining.

(3) Wear test Wear amount after operating for 30 hours under the oil supply conditions in Table 5 using a radial in-oil tester for the same compound plain bearing (φ30 × φ35 × 20 (mm)) as the seizure resistance test Was measured.

(4) Melt Viscosity Capillograph manufactured by Toyo Seiki Co., Ltd., φ1 × 10 (mm) capillary, resin temperature 380 ° C., melt viscosity at a shear rate of 1000 s ⁻¹ were measured and shown in Table 6 and Table 7.

As shown in Table 4, in Examples 1 to 9, there was no crack in the bearing base material during insert molding, and 1.5.
The shear adhesion strength was at least MPa. In particular, the density of the sintered metal is 0.7
In Examples 1 to 7, which are ˜0.9, the shear adhesion strength was 2 MPa or more.

On the other hand, in Comparative Example 1 in which the density of the sintered metal was a theoretical density ratio of 0.67, cracks in the bearing base material occurred during insert molding. In the steel machined product, the shear adhesion strength was very low (Comparative Example 2).

  When the predetermined resin layer thickness shown in Table 7 cannot be formed by insert molding, a thick product was injection molded and finished to a predetermined thickness by machining. Since Comparative Examples 10 and 12 were abnormally worn within 30 minutes, the seizure resistance test could not be performed.

As shown in Table 6, in Examples 10 to 22, the seizure time was 30 minutes or more, the wear amount was 10 μm or less, and the seizure resistance and the wear resistance were excellent. In Examples 10 to 14, 16 to 20, and 22 having a melt temperature of 200 Pa · s or less at a resin temperature of 380 ° C. and a shear rate of 1000 s ⁻¹ , a predetermined resin layer could be formed by insert molding.

Further, as shown in Table 7, the conventional bearings of Comparative Examples 12 and 13 (single resin bearings, three-layer composite sliding bearings) were seized immediately after a seizure time of less than 1 minute, and the amount of wear. Was also big.
Although it is a compound slide bearing, the comparative examples 3-10 whose resin layer composition is outside the scope of claims had a seizing time as short as less than 26 minutes and a large wear amount of 20 μm or more.
Moreover, although the composition of the resin layer was within the claimed range, the composite sliding bearing having a thickness exceeding 0.7 mm had a seizure time of less than 1 minute and a very large wear amount.

1, 4, 6, 8 Sintered metal base material 2, 5, 7, 9 Resin layer 3 Fibrous filler

As shown in Table 6, in Examples 10 to 22, the seizure time was 30 minutes or more, the wear amount was 10 μm or less, and the seizure resistance and the wear resistance were excellent. In Examples 10 to 14, 17 to 20 , 22 and Reference Examples having a melt temperature of 200 Pa · s or less at a resin temperature of 380 ° C. and a shear rate of 1000 s ⁻¹ , a predetermined resin layer could be formed by insert molding.

Claims (10)

  A resin layer is integrally provided on a sintered metal base of a slide bearing, and this resin layer is made of a resin composition in which a fibrous filler is blended in an aromatic polyether ketone resin in a dispersed state, and the fibrous layer The filler is characterized in that the length direction of the fiber is oriented so as to cross 45 to 90 degrees with respect to the rotation direction of the bearing, and the resin layer is provided with a layer thickness of 0.1 to 0.7 mm. Compound plain bearing.   The composite sliding bearing according to claim 1, wherein the resin layer is a resin layer that is injection-molded on a base material.   The composite sliding bearing according to claim 1 or 2, wherein the resin layer is a resin layer having a thickness of 1/8 to 1/2 of the thickness of the base material in the axial diameter direction. The fibrous filler is a fibrous filler having an average fiber length of 0.02 to 0.2 mm.
A compound plain bearing as described in.   The composite plain bearing according to claim 1, wherein the base material is a base material having a theoretical density ratio of 0.7 to 0.9. The composite sliding bearing according to claim 1, wherein the resin composition is a resin composition having a melt temperature of 50 to 200 Pa · s at a resin temperature of 380 ° C. and a shear rate of 1000 s ⁻¹ .   7. The resin composition according to claim 1 or 6, wherein the resin composition contains 5 to 30% by volume of carbon fiber and 1 to 30% by volume of a tetrafluoroethylene resin as essential components, and the balance is an aromatic polyether ketone resin. The compound sliding bearing described.   The composite sliding bearing according to claim 7, wherein the carbon fiber is a PAN-based carbon fiber.   The composite slide bearing according to any one of claims 1 to 8, wherein the resin layer is provided on one or more side surfaces selected from an inner diameter side, an outer diameter side, and an end surface side of a cylindrical or flanged cylindrical bearing base material. The compound sliding bearing described.   The composite sliding bearing according to claim 9, wherein the composite sliding bearing is a sliding bearing for liquid lubrication lubricated with oil or grease.

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