JPH1171470A - Preparation of slide receiving member and preparation of melding material for slide receiving member - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prepare a slide receiving member (thrust washer) maintaining strength (particularly flexural strength) and slidability at a high level by using a molding material prepared by optimizing the compounding of a phenolic resin, a reinforcing fiber and graphite and forming in a paper making manner. SOLUTION: As the essential components, (a) a phenolic resin powder, (b) an aramid fiber and (c) a graphite powder are dispersed in water and formed in a paper making manner to obtain a sheet molding material. This molding material is punched in the shape of a doughnut which is then subjected to molding under heat and pressure to obtain a slide receiving member. Each component is selected in such a range that the phenolic resin is 25-35 wt.%; the aramid fiber 30-40 wt.%; and the graphite is 25-35 wt.%.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for manufacturing a resin-made sliding receiving member (for example, a thrust washer, a bearing, a gear). Further, the present invention relates to a method for producing a molding material for molding a sliding receiving member.

[0002]

2. Description of the Related Art Thrust washers made of resin are, for example,
It is used as a sliding receiving member between a transmission retainer and a transmission case, and requires sliding characteristics and strength. Since a compressive force is applied to the sliding surface so as to rub the surface from an oblique direction, the bending strength is particularly required in addition to the compressive strength. Since the tooth surface of the gear meshing with the mating gear is also the same sliding surface as described above, similar characteristics are required. Conventionally, as a method for manufacturing a thrust washer, there is the following technique.

(1) A phenolic resin, a reinforcing fiber and graphite are mixed and kneaded to prepare a granular molding material, which is injection molded to form a thrust washer. Aramid fibers and glass fibers are used in combination as the reinforcing fibers, but the amount of the aramid fibers for increasing the strength is limited to at most about 5 wt%, and reinforcing fibers mainly composed of glass fibers are used. This is because, when the content of the aramid fiber is increased, the high strength aramid fiber is not cut in the cylinder of injection molding or in the gate, but is entangled with the screw and stays in the gate. (2) A phenolic resin, a reinforcing fiber and graphite are mixed and kneaded to prepare a granular molding material, which is compression molded to form a thrust washer. In the compression molding of a granular molding material, even if the aramid fiber is mainly used as the reinforcing fiber, there is no problem as in the case of the injection molding, so that improvement in strength can be expected. However, because the aramid fiber has high strength, it is not easily cut by the shearing force of the mixing and kneading process for producing a granular molding material, and the phenol resin entangled with the aramid fiber becomes a large lump, and the reinforcing fibers are uniformly dispersed. It is difficult to produce a granular molding material. (3) A phenolic resin powder, a reinforcing fiber, and a graphite powder are essential components, and a molding material formed by dispersing the phenol resin powder in a liquid and forming a paper is heated and pressed to form a thrust washer. A combination of aramid fiber and glass fiber has been proposed as a reinforcing fiber (Japanese Patent No. 2570524).

[0004]

In the production method (1), a large amount of aramid fibers cannot be blended. If the glass fiber content is increased in order to ensure strength, the graphite content must be reduced inevitably, so that good slidability cannot be ensured. On the other hand, if the content of graphite is increased to ensure slidability, the strength of the glass fiber cannot be ensured because the content of glass fiber must be reduced. According to the production method (2), good strength and slidability can be expected, but they are still insufficient. Good strength and slidability can also be expected with the production method of (3) above, but improvement in slidability cannot be expected as long as glass fiber is used as the reinforcing fiber, and strength and slidability are maintained at a high level. There is no disclosure of the optimal formulation to do so. The use of glass fiber acts to increase the coefficient of kinetic friction, and there is a limit in improving the sliding characteristics.

[0005] The problem to be solved by the present invention is to optimize the blending of phenolic resin, reinforcing fiber and graphite, and to use a molding material produced by papermaking to achieve a high level of strength (particularly bending strength) and slidability. Is to manufacture the sliding receiving member maintained at the above. Another object of the present invention is to produce a molding material for the sliding receiving member.

[0006]

In order to solve the above-mentioned problems, a method according to the present invention comprises: (a) a phenolic resin powder; (b) substantially aramid fibers as reinforcing fibers;
(C) Graphite powder is used as an essential component, and a molding material formed by dispersing these in a liquid is heated and pressed into a predetermined shape to produce a sliding receiving member. Each component is phenolic resin 2
5-35 wt%, aramid fiber 30-40 wt%, graphite 25
Each is selected within the range of ~ 35 wt%. As described below, the sliding receiving member manufactured by the above method can increase the strength (bending strength) by integrating various actions, and can improve the sliding property by reducing the dynamic friction coefficient. it can.

First, substantially using only high-strength aramid fibers as reinforcing fibers contributes to increasing the strength of the sliding receiving member. In addition, in the molding material in which the aramid fiber dispersed in the liquid is formed, the length direction of the aramid fiber and the surface direction of the molding material substantially coincide with each other throughout the thickness direction. In a sliding receiving member formed by heating and pressing this molding material in the thickness direction,
The direction of the aramid fibers is maintained. That is, the surface direction of the sliding receiving member and the length direction of the aramid fiber are substantially the same over the entire thickness direction of the sliding receiving member. Also, in the case where the formed molding material is formed into a cylindrical shape and the gear is formed by applying pressure while heating in the axial direction, the length direction of the aramid fiber is along the circumferential direction of the cylindrical forming material, The molding material is filled into the molding space which forms the gear teeth while maintaining the state. Therefore, the tooth surface direction of the formed gear and the length direction of the aramid fiber match well.
These states are extremely convenient for increasing the bending strength of the sliding receiving member. In the sliding receiving member formed by injection molding, the length direction of the reinforcing fiber and the surface direction of the sliding receiving member coincide with each other on the surface, but the length direction of the reinforcing fiber and the thickness of the sliding receiving member are internally formed. The direction matches. Therefore, it cannot be said that the reinforcing fibers are effectively acting to increase the bending strength of the sliding receiving member. Further, in a sliding receiving member formed by compression molding of a granular molding material, the length direction of the reinforcing fibers is not aligned in a specific direction. Since the reinforcing fibers are oriented in random directions, it cannot be said that the reinforcing fibers effectively act to increase the bending strength of the sliding receiving member.

As described above, in the method according to the present invention, the aramid fiber can be effectively used to improve the bending strength of the sliding receiving member. Therefore, even if a large amount of graphite is blended, the decrease in strength is small. A large amount of graphite can be blended to reduce the coefficient of dynamic friction and ensure good slidability. Aramid fibers do not act in the direction of increasing the coefficient of kinetic friction like glass fibers. The use of substantially only aramid fibers as reinforcing fibers has also led to improved slidability. In addition, since the length direction of the aramid fiber substantially coincides with the surface direction of the sliding receiving member, this also contributes to reducing the dynamic friction coefficient of the sliding receiving member. As described above, in the sliding receiving member formed by compression molding of the granular molding material, the length direction of all the reinforcing fibers does not always coincide with the surface direction of the sliding receiving member on the surface. . Since the reinforcing fibers are oriented in a random direction (some are oriented in the plane direction of the sliding receiving member and some are oriented in the thickness direction), they are disadvantageous in reducing the dynamic friction coefficient.

[0009] The mixing ratio of the aramid fiber and the graphite is in an optimum range for maintaining both strength and slidability at a high level. Lower limit of blending amount of phenolic resin 2
5 wt% is an amount necessary for good molding. However, since the phenol resin works in the direction of increasing the dynamic friction coefficient, it is necessary to limit the blending amount to 35% by weight or less.

[0010]

DESCRIPTION OF THE PREFERRED EMBODIMENTS In carrying out the method according to the present invention, the particle diameter of the phenol resin powder is 1 to 100 μm.
However, there is no particular limitation as long as it can be dispersed during papermaking. The particle size of the graphite powder is suitably from 1 to 50 μm, but is not particularly limited as long as it can be dispersed during papermaking. Further, the aramid fiber has a fiber diameter of 5 to 20 μm and a fiber length of 1 μm.
The thickness is suitably 6 mm, but is not particularly limited as long as it can be dispersed at the time of papermaking. At the time of papermaking, substantially aramid fibers are used as phenol resin powder, graphite powder, and reinforcing fibers, but other additives such as coloring agents may be appropriately compounded. The forming of the molding material is performed by dispersing the above components in water. These can be laid on a wire mesh to form a sheet-like molding material. Dry after papermaking.

When a thrust washer is formed, the above-mentioned sheet-shaped molding material punched into a predetermined shape that can be directly charged into a molding die is charged into the die, and is heated and pressed in the thickness direction. Details are as described in Examples described later.

When the gear is formed, the above-mentioned sheet-shaped molding material is formed into a cylindrical shape, charged into a molding die, and then heated and pressed. A metal bush is arranged at the center. The pressing direction is the axial direction of the cylindrical molding material. By this pressurization, the cylindrical molding material fills the molding space that forms the gear teeth. The formed gear is subjected to cutting if necessary to adjust the shape and dimensions of the gear. In the above method, the gear teeth may not be formed by molding, but may be formed later by cutting. In this case, first, a heat-press molding is performed to press the cylindrical molding material in the axial direction to produce a disk-shaped molded product. Then, teeth are formed around the disk by cutting.

[0013]

【Example】

Examples 1 to 5, Comparative Examples 1 to 3, and Conventional Example 1 Phenol resin powder (particle diameter: 7 to 13 μm, manufactured by Kanebo “Bellpearl S890”) and straight (chopped) aramid fiber (diameter: 13 μm, fiber length: 3 mm) Graphite powder (particle size 1
To 20 μm) and a coloring agent were dispersed in water at the compounding ratio (weight ratio) shown in Table 1, and this was paper-formed to obtain a sheet-like molding material. In the conventional example 1, glass fibers (diameter 9 μm, fiber length 3 mm) were used as reinforcing fibers in addition to aramid fibers. The molding material from which moisture was removed by drying after papermaking had a thickness of 6 mm and a unit weight of 1450 g / m ² . The drying was performed in a temperature range (normal temperature) at which the curing reaction of the phenol resin did not proceed. This molding material has an outer diameter of 68 mm and a hole diameter of 58.
Three doughs punched into a donut shape of 3 mm are stacked and heated and pressed (direct pressure forming), and the outer diameter is 70 mm, the hole diameter is 56 mm,
A 3 mm thick thrust washer was used. The characteristics are shown in Table 1.

[0014]

[Table 1]

Conventional Examples 2 and 3 Phenol resin and chopped aramid fiber (fiber diameter 13
μm, fiber length 3 mm), glass fiber (fiber diameter 9 μm, fiber length 3 mm) and a colorant were mixed and kneaded at the mixing ratio (weight ratio) shown in Table 2 to obtain a granular molding material. This was injection molded into a thrust washer having the same dimensions as the above example. The characteristics are shown in Table 2. The compounding amount of aramid fiber is
It was set close to the limit that could be used for injection molding.

Conventional Example 4 Phenol resin and chopped aramid fiber (fiber diameter 13
μm, fiber length 3 mm) and a colorant were mixed and kneaded at the mixing ratio (weight ratio) shown in Table 2 to obtain a granular molding material. This was compression-molded to form a thrust washer having the same dimensions as in the above embodiment. The characteristics are shown in Table 2.

[0017]

[Table 2]

Tables 1 and 2 show the following. Comparative Examples 1 and 2 show that strength and slidability cannot be maintained at a high level unless the aramid fiber and the graphite powder are in the range of the predetermined mixing ratio. Comparative Example 3 shows that when the blending amount of the phenolic resin increases, the sliding property decreases, and the blending amount of the aramid fiber decreases as the blending amount of the phenolic resin increases, and the strength also increases. It shows that it decreases. Conventional Example 1 shows that the use of glass fiber is disadvantageous in securing sufficient strength and lowers the slidability even when a molding material formed by papermaking is used. Conventional examples 2 and 3 show that in the case of injection molding, the amount of aramid fiber must be reduced, and strength and slidability cannot be ensured.
Conventional Example 4 shows that the strength and slidability are not sufficiently ensured when compression molding of a granular molding material is performed despite the use of only aramid fibers as the reinforcing fibers.

[0019]

As is clear from Tables 1 and 2, according to the method of the present invention, phenol resin powder and aramid fiber and graphite powder as essential components are essentially used as reinforcing fibers.
By dispersing these in water and forming the molding material by heating and pressing, and by specifying the mixing ratio of phenol resin powder, aramid fiber and graphite powder, for sliding with excellent strength and excellent sliding properties A receiving member can be manufactured.

Continued on the front page (51) Int.Cl. ⁶ Identification code FI F16C 33/24 F16C 33/24 Z

Claims (4)

[Claims] 1. A molding material formed by dispersing in a liquid a paper material comprising (a) a phenolic resin powder, (b) an aramid fiber substantially as a reinforcing fiber, and (c) a graphite powder as essential components. It is formed by heating and pressing into a predetermined shape. The content of phenol resin is 25 to 35 wt%, the content of aramid fiber is 30 to 40 wt%, and the content of graphite is 25 to 3
A method for manufacturing a sliding receiving member, wherein each member is selected within a range of 5 wt%. 2. The method of manufacturing a sliding receiving member according to claim 1, wherein the sliding receiving member is a thrust washer, and the formed molding material is pressed in a thickness direction thereof. 3. The method of manufacturing a sliding receiving member according to claim 1, wherein the sliding receiving member is a gear, and the formed molding material is formed into a cylindrical shape and is pressed in the axial direction. 4. An essential component comprising (a) a phenolic resin powder, (b) substantially an aramid fiber as a reinforcing fiber, and (c) graphite powder, and disperse these in a liquid to form a paper. The content of phenol resin is 25-35 wt%, the content of aramid fiber is 30-40 wt%, and the content of graphite is 25-3.
A method for producing a molding material for a sliding receiving member, wherein the molding material is selected within a range of 5 wt%.