JP2007085464A - Bevel gear device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bevel gear device, improved in durability by devising the material quality and shape of a tooth part, and using a resin-metal composite bevel gear reduced in noise in engagement of teeth. <P>SOLUTION: The gear device includes: a resin-metal composite bevel gear 100 having a tooth part constructed so that a part in the face width direction is formed of a resin part 1 and another part in the face width direction is formed of a metal part 2; and a metal-made counterpart bevel gear 3 meshing with the above gear, wherein the pitch conical angles of the resin-metal composite bevel gear 100 and the metal-made counterpart bevel gear 3 are set to different values, and the resin part of the resin-metal composite bevel gear acts as an abut part to the counterpart bevel gear with priority. As the position of the resin part 2 of the resin-metal composite bevel gear, either the outer peripheral part side in the face width direction or the inner peripheral part side is selected by adjustment the pitch conical angle. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a bevel gear device using a resin-metal composite bevel gear suitable for automobile parts and the like.

  The resin bevel gear is used as a mating bevel gear that meshes with a metal bevel gear in order to suppress the generation of noise when the teeth mesh, and requires high strength and durability.

Conventionally, as a resin bevel gear, a ring-shaped resin molded body in which a reinforcing fiber base material is impregnated with a resin has been proposed. For example, it is the following technique disclosed in Patent Document 1.
That is, a belt-shaped reinforcing fiber base material is prepared. The belt-shaped reinforcing fiber base material is wound around the outer periphery of a metal bush to form a cylindrical body. Then, the metal bush and the cylindrical body are accommodated in a molding die, the cylindrical body is impregnated with resin, and is molded by heating to form a gear body integrated with the metal bush. Then, teeth are formed on the axial end surface of the gear body by cutting.

JP 2005-140140 A

Since the resin bevel gear is provided with teeth on the axial end face of the cylindrical body formed by wrapping the belt-shaped reinforcing fiber base material, the direction of the load applied to the teeth intersects the axial direction of the cylindrical body. It can be said that it is ideal in terms of strength.
However, since the tooth portion is composed only of resin, there is a limit in strength and durability, and further improvement has been demanded.

  The problem to be solved by the present invention is to provide a bevel gear device using a resin-metal composite bevel gear in which the material and shape of the tooth portion are devised to improve durability and reduce noise during tooth meshing. It is.

In order to solve the above problems, the present invention meshes with a gear and a resin-metal composite bevel gear having a tooth part in which a part in the tooth width direction is a resin part and another part in the tooth width direction is a metal part. A gear device including a metal mating bevel gear is configured as follows.
That is, the pitch cone angle of the resin-metal composite bevel gear and the metal mating bevel gear are set to different values so that the resin portion of the resin-metal composite bevel gear is preferentially the contact portion of the mating bevel gear. (Claim 1).

  The present invention mechanically adjusts the contact angle between the tooth surfaces of the resin-metal composite bevel gear and the mating metal bevel gear so that the contact portion of the resin-metal composite bevel gear with the mating metal bevel gear becomes the resin portion preferentially. Yes. The position of the resin portion of the resin-metal composite bevel gear can be on the outer peripheral side in the tooth width direction by adjusting the pitch cone angle (Claim 2), or on the inner peripheral side in the tooth width direction. (Claim 3).

  As described above, in the gear device according to the present invention, the resin portion of the resin-metal composite bevel gear is preferentially applied to the mating metal bevel gear, so that noise at the time of meshing of teeth can be reduced. Further, when the resin part is subjected to a high load, the resin part is deformed and the metal part is subjected to the load, so that the tooth root strength is remarkably improved as compared with the case where the tooth part is made of only the resin.

Embodiments of the present invention will be described with reference to the drawings.
FIG. 1 is a bevel gear device according to an embodiment of the present invention, in which a metal mating bevel gear 3 is engaged with a resin-metal composite bevel gear 100. FIG. 2 shows the resin-metal composite bevel gear in the case where the outer peripheral side in the tooth width direction is a resin part, where (a) shows a top view and (b) shows a longitudinal sectional view. The metal bush 2 is used for the fastening portion with the rotating shaft from the viewpoint of reliability. A stepped portion is formed around the metal bush 2, and a concave and convex shape is formed as the rotation stopper 5 of the resin portion 1, and an upper portion protrudes as the stopper 6, and a ring-shaped reinforcing fiber base material is fitted into this portion, The resin portion 1 is formed by infiltrating the liquid resin into the reinforcing fiber base in a closed mold. The ring-shaped reinforcing fiber base material is prepared by preparing a cylindrical body in which yarns such as aramid fiber, carbon fiber, and glass fiber are knitted into a cylindrical shape, and winding the cylindrical body axially from the end. is there. In addition, a sheet-shaped reinforcing fiber base material may be wound in a paper shape and overlapped at both ends to form a ring shape. In addition, as the liquid resin, a crosslinked polyaminoamide resin, a phenol resin, an epoxy resin, or the like can be used.
When forming teeth by cutting the gear body so as to include a metal part and a resin part from the reinforcing fiber substrate side, a plus angle error is given to the pitch cone angle of the mating bevel gear as shown in FIG. Thereby, the contact part 4 with the other party bevel gear 3 can be made into the resin part 1 located in the outer peripheral part side of a tooth width direction. For this reason, at the time of normal meshing, the resin portion preferentially hits the mating bevel gear, and the meshing sound between the bevel gears is reduced. In addition, when the tooth portion receives a high load, the resin portion is deformed and the metal portion is subjected to the load, so that the tooth root strength is remarkably improved as compared with the case where the tooth portion is made of resin alone.

FIG. 3 shows a bevel gear device according to another embodiment of the present invention. FIG. 4 shows the resin-metal composite bevel gear when the inner peripheral side in the tooth width direction is a resin part. A ring-shaped groove is formed concentrically with the metal bush 2, and the resin portion 1 has a concave-convex shape as a detent 5 and an upper opening that is narrower than the bottom as a retainer 6. A ring-shaped reinforcing fiber base is formed in this portion. The resin part 1 is formed by press-fitting and infiltrating the liquid resin into the reinforcing fiber base in a closed mold.
When teeth are formed by cutting the gear body so as to include a metal part and a resin part from the reinforcing fiber base side, a negative angle error is given to the pitch cone angle of the mating bevel gear as shown in FIG. Thereby, the contact part 4 with the other party bevel gear 3 can be made into the resin part 1 located in the inner peripheral part side of a tooth width direction. The reduction of the meshing noise and the improvement of the tooth root strength are as described above.

An embodiment of the present invention will be described with reference to FIG.
Example 1
In FIG. 7A, a cylindrical body 7 is prepared by knitting a yarn in which a para-aramid fiber and a meta-aramid fiber are blended at a mass ratio of 50/50 into a cylindrical shape. To a ring-shaped reinforcing fiber substrate 8. In FIG. 7B, after the metal bush 2 and the reinforcing fiber base 8 shown in FIG. 2 are arranged in the molding die 9, the inside of the die is evacuated to be in a vacuum state. The melted cross-linked polyaminoamide resin 10 was poured into this and penetrated and cured into the reinforcing fiber base 8 to obtain a gear body. The form of this embodiment has good workability because the reinforcing fiber base 8 is inserted into the outer periphery of the metal bush 2, and the formability is also good because the gate of the molding die 9 is directly connected to the reinforcing fiber base 8. It is good. The gear body is cut and chopped into predetermined dimensions so as to include a metal part and a resin part from the reinforcing fiber base side, and a plus angle error of 0 with respect to the pitch cone angle of the metal mating bevel gear 3 is obtained. A resin-metal composite bevel gear having a shaft angle of 90 ° and a width of 5 ° was obtained.

Comparative Example 1
The gear body obtained in Example 1 was cut into a predetermined size and geared so as to include the metal part and the resin part from the reinforcing fiber base side, and the angle error was 0 with respect to the pitch cone angle of the mating bevel gear. A resin / metal composite bevel gear having an angle of 90 ° was obtained.

Conventional Example 1
A plain-woven cloth using a yarn in which para-aramid fibers and meta-aramid fibers are blended at a mass ratio of 50/50 is cut to a predetermined width (1.2 times the thickness of the metal bush 2) to form a strip shape. The reinforcing fiber base material is prepared, and this belt-like reinforcing fiber base material is wound on the outer periphery of the metal bush shown in FIG. 6 to form a cylindrical body. The metal bush 2 and the cylindrical body were placed in a molding die. Thereafter, a resin bevel gear was obtained in the same manner as in Comparative Example 1.

Comparative Example 2
By cutting, a steel (S45C) bevel gear having the same shape as Comparative Example 1 was obtained.

Table 2 and FIG. 5 show the results of the meshing sound evaluation and the motoring durability evaluation using the bevel gears produced in the above examples, conventional examples, and comparative examples, respectively. The measuring method is as follows.
Engagement sound evaluation: A sound collecting microphone was installed in the meshing part of the gear, and when the gear was driven under the conditions shown in Table 1, frequency analysis was performed with an FFT analyzer, and the sound pressure was compared.

The values in Table 2 are expressed as indices when Comparative Example 2 is taken as 100.
Motoring durability evaluation: The gear was driven under the conditions shown in Table 1, and the number of cycles until the bevel gear was broken was measured. In addition, the bevel gear was set to 7 cycles in the forward direction and 7 rotations in the reverse direction.

  As is apparent from Table 2, the resin-metal composite bevel gear according to the present invention has a sound pressure level index as compared with the resin-metal composite bevel gear (Comparative Example 1) in which no angular error is given to the pitch cone angle of the counterpart bevel gear. It is small and can provide an effect of reducing the meshing sound. Further, as is apparent from FIG. 5, it can be understood that the resin-metal composite bevel gear according to the present invention can impart durability by significantly improving the fatigue life as compared with the resin bevel gear (conventional example 1).

It is a section explanatory view showing a state where the resin metal composite bevel gear according to the embodiment of the present invention hits the mating bevel gear. FIG. 2 is a resin-metal composite bevel gear according to an embodiment of the present invention, in which the outer peripheral side in the tooth width direction is a resin portion, (a) is a top view, and (b) is a longitudinal sectional view. is there. It is a section explanatory view showing a state where a resin metal composite bevel gear according to another embodiment of the present invention hits the mating bevel gear. It is the resin metal composite bevel gear which concerns on other embodiment of this invention, Comprising: When the inner peripheral part side of a tooth width direction is a resin part, (a) is a top view, (b) shows a longitudinal cross-sectional view It is a thing. It is a curve figure which shows the motoring durability evaluation result of the resin metal composite bevel gear in the Example which concerns on this invention. It is the conventional resin-made bevel gear, (a) is a top view, (b) shows the longitudinal cross-sectional view. It is explanatory drawing which shows the manufacturing process of the resin metal composite bevel gear which this invention makes object, (a) is explanatory drawing which shows the manufacturing process of a ring-shaped reinforcement fiber base material, (b) forms a resin metal composite bevel gear. It is sectional explanatory drawing which shows a mode.

Explanation of symbols

1 is a resin part 2 is a metal bushing 3 is a mating bevel gear 4 is a contact part 5 of the mating bevel gear 5 is a detent 6 is a stopper 7 is a cylindrical body 8 is a reinforcing fiber base 9 is a molding die 10 is a crosslinked polyaminoamide Resin 100 is a resin-metal composite bevel gear

Claims (3)

A gear device including a resin-metal composite bevel gear having a tooth part in which a part in the tooth width direction is a resin part and another part in the tooth width direction is a metal part, and a metal counter bevel gear meshing with the gear. And
The bevel gear is characterized in that the pitch cone angles of the resin-metal composite bevel gear and the metal mating bevel gear are set to different values so that the resin portion of the resin-metal composite bevel gear preferentially comes into contact with the mating bevel gear. apparatus.   2. The bevel gear device according to claim 1, wherein the resin-metal composite bevel gear has a tooth portion including a resin portion on an outer peripheral side in a tooth width direction and a metal portion on an inner peripheral side in a tooth width direction.   2. The bevel gear device according to claim 1, wherein the resin-metal composite bevel gear has a tooth portion in which an inner peripheral portion side in the tooth width direction is formed of a resin portion and an outer peripheral portion side in the tooth width direction is formed of a metal portion.

Images