KR101494905B1 - Bush bearing assembly - Google Patents

Abstract

The present invention relates to a bush bearing assembly, wherein the bush bearing assembly according to the present invention comprises: a shaft; Bush bearing; And a boss, wherein a plurality of auxiliary lubrication grooves are formed on the inner surface of the boss so as to have a longer axial length than a circumferential length of the shaft. Accordingly, it is intended to disclose a technique for providing a bush bearing assembly capable of improving lubrication and extending its service life.

Bush, bearing, boss, lubrication

Description

BUSH BEARING ASSEMBLY

The present invention relates to a bush bearing assembly for use in a joint of a mechanical device.

The bush bearings used in the joints of machinery are mechanical elements that minimize rotational friction with the shaft while supporting the weight of the shaft and the load on the shaft. Such a bush bearing is generally fixed by a boss provided at the joint of the machine.

On the other hand, in the bush bearing, lubricant is coated on the sliding surface or a lubricating groove is formed to store the lubricant in order to minimize rotational friction with the shaft. However, bush bearings coated with a lubricant or lubricant in a lubricated groove are operated for a long period of time, which results in consumption of lubricant and shortage of oil film. At this time, when the bush bearing is operated in the state of insufficient oil film, the amount of wear increases due to the rotational friction of the shaft and the bush bearing, and a seizure occurs between the shaft and the bush bearing due to the frictional heat.

Therefore, the lubricant should be periodically fed to the bushing bearing in order to prevent the oil shortage phenomenon. However, the operation of feeding the lubricant is troublesome and the operation rate of the apparatus is also decreased because the mechanism can not be operated during the feeding operation .

Accordingly, various techniques have been attempted to solve the above-mentioned problems. One of the techniques has been proposed to process a boss for supporting the movement of the bush bearing so as to additionally supply lubricant to the bush bearing.

Hereinafter, a conventional bushing bearing assembly including a boss that is adapted to supply a lubricant to the bush bearing will be described with reference to Figs. 1 and 2. Fig.

Referring to FIGS. 1 and 2, the bush bearing assembly includes a boss 100, a bush bearing 200, and a shaft 300. The boss 100 is fixedly coupled to the bushing bearing 200 to support the movement of the bushing bearing 200 and the shaft 300 is rotatably inserted into the bushing bearing 200. Lubrication grooves 201 and 202 for storing a lubricant are formed in the inner peripheral surface S ₁ and the outer peripheral surface S ₂ of the bush bearing 200 in order to minimize the rotational friction with the shaft 300.

On the other hand, when the bush bearing 200 is operated for a long time, the lubricant stored in the lubrication grooves 201, 202 is gradually consumed because the amount of lubricant that can be stored in the lubrication grooves 201, 202 formed in the bush bearing 200 is limited. As a result, a shortage of the oil film appears between the bushing bearing 200 and the shaft 300. Accordingly, when the lubricant stored in the lubricating grooves 201, 202 of the bush bearing 200 is consumed, the auxiliary lubricating grooves 101 are formed on the inner surface S ₃ of the boss 100 so as to additionally supply lubricant . That is, the inner surface S ₃ of the boss 100, which contacts the outer peripheral surface S ₂ of the bush bearing 200, is rotated by one rotation along the circumferential direction D of the shaft 300, A groove 101 is formed.

However, such conventional bush bearing assemblies have the following problems.

When the mechanical device is a large-sized machine, the width of the joint part is widened. If the width of the joint part is widened, the length of the bush bearing 200 becomes longer. If the length of the bush bearing 200 is long, the width of the auxiliary lubrication groove 101 formed on the inner surface S ₃ of the boss 100 must also be widened to efficiently supply additional lubricant to the bush bearing 200 do. When the shape of the auxiliary lubricating groove 101 formed in the boss 100 is a ring shape, the contact area between the boss 100 and the bush bearing 200 is reduced as the width thereof becomes wider, There is a problem that the bush bearing 200 is detached as the amount of clamping of the bush bearing 200 becomes weak.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a bush bearing assembly capable of maintaining the tightening amount of the bush bearings and the bosses and supplying additional lubricant to the bush bearings even when the length of the bush bearings is increased. The purpose of that is to do.

According to an aspect of the present invention, A bush bearing receiving the shaft and performing a rotational motion relative to the shaft; The bush bearing includes an inner circumferential groove formed to accommodate a lubricant on an inner circumferential surface which is a contact surface for contacting the shaft and a contact surface for contacting the bush bearing with the bush bearing, A plurality of auxiliary lubrication grooves communicating with the outer circumferential grooves are formed on an inner surface of the boss which is a contact surface for contacting the outer circumferential surface of the bush and the bush bearing, The auxiliary lubricating groove provides an axial length longer than a circumferential length of the shaft.

According to an embodiment of the present invention, a lubricant injection path may be formed in the boss so that an external lubricant may be injected into the auxiliary lubricant groove.

Further, according to an example of the present invention, the auxiliary lubricating groove may be formed in a lumbar 8-shape.

The bush bearing assembly according to the present invention has at least the following effects.

Since the inner surface of the boss has a longer axial length than the circumferential length of the shaft in the circumferential direction, additional lubrication can be supplied to the bushing bearing while maintaining the bushing and boss clamping regardless of the bushing length. The lubrication of the bush bearing assembly is improved.

In addition, since the lubricant injection path is formed in the boss so that the external lubricant can be injected into the auxiliary lubricant groove, the lubricant can be conveniently supplied to the bush bearing and the shaft even if the lubricant stored in the bush bearing is exhausted.

In addition, the lubrication of the bush bearing assembly can be improved and the lubricant can be conveniently supplied to the bush bearings and shafts, thereby minimizing the wear on the bush bearings and shafts, thereby extending the overall life of the bush bearing assembly.

Hereinafter, a bush bearing assembly according to the present invention will be described in detail with reference to the drawings.

3 is a cross-sectional view of a bush bearing assembly according to an embodiment of the present invention.

Referring to FIG. 3, a bush bearing assembly according to the present invention includes a shaft 400, a bush bearing 500, and a boss 600.

The shaft 400 is inserted into the bushing bearing 500 and rotates. At this time, the shaft 400 and the bush bearing 500 may swing from side to side in addition to rotational motion.

The bush bearing 500 receives the shaft 400 and rotates relative to the shaft 400. At this time, the lubricant is stored in each of the inner circumferential surface S ₄ and the outer circumferential surface S ₅ of the bush bearing 500 The lubricating grooves 501 and 502 are formed. That is, the inner peripheral surface S ₄ of the bush bearing 500, which is the contact surface where the bush bearing 500 contacts the shaft 400, and the inner peripheral surface S ₄ of the bush bearing 500, which is the contact surface where the bush bearing 500 contacts the boss 600 the outer peripheral surface (S _5), each of which is in communication with each other inner peripheral surface of groove 501 and the outer surface groove (502) for storing a lubricant (more specifically, the bush bearing (500), the bush inner circumferential surface formed on the inner circumferential surface (S ₄₎ of the bearing (500) The passage H connecting the groove 501 and the outer circumferential groove 502 formed on the outer circumferential surface S ₅ may be formed).

The inner circumferential surface groove 501 formed in the inner circumferential surface S ₄ serves to directly supply the lubricant between the bush bearing 500 and the shaft 400. The outer circumferential surface groove 502 formed in the outer circumferential surface S ₅ , When the lubricant stored in the inner circumferential groove 501 is consumed, the lubricant may be supplied to the inner circumferential groove 501. The inner circumferential groove 501 formed in the inner circumferential surface S ₄ and the outer circumferential groove 502 formed in the outer circumferential surface S ₅ may be formed in any shape and size as long as they communicate with each other. It is preferable that the bush bearing 500 is formed in consideration of the load applied to the bush bearing 500 and the like. The outer peripheral surface groove 502 formed on the outer peripheral surface S ₅ of the bush bearing 500 is preferably communicated with the auxiliary lubricant groove 601 formed on the inner surface S ₆ of the boss 600 described later. A detailed description will be given later.

The boss 600 receives the bushing bearing 500 and is fixedly coupled to the bushing bearing 500 to support the movement of the bushing bearing 500. A plurality of auxiliary lubricating grooves 601 are formed on the inner surface S ₆ of the boss 600. That is, the boss 600 and the outer peripheral surface S ₅ of the bush bearing 500 are formed so as to supply additional lubricant when the lubricant stored in the inner circumferential groove 501 and the outer circumferential groove 502 formed in the bush bearing 500 is consumed. the inner surface of the boss which is in contact with the contact surface (S _6), the plurality of secondary home lubricant (see 601, Fig. 4) is formed.

The plurality of auxiliary lubricating grooves 601 are formed such that the axial length b of the auxiliary lubricating grooves 601 is longer than the circumferential length a of the shaft 400 as shown in FIG. Any shape may be used as long as the axial length b is longer than the axial length a, but preferably it is formed as a loose eight-figure as shown in Fig. The number of the auxiliary lubricating grooves 601 to be formed is not particularly limited. However, the number of the auxiliary lubricating grooves 601 may be about 6 to 10 in consideration of the amount of fastening with the bush bearing 500 and the overall lubricity of the bush bearing assembly. For reference, the circumferential direction A of the shaft 400 means a direction in which the shaft 400 rotates, and the axial direction B means a direction in which the shaft 400 is inserted into the bush bearing 500 .

When the lubricant stored in the inner circumferential surface groove S 501 and the outer circumferential surface groove 502 formed in the inner circumferential surface S ₄ and the outer circumferential surface S ₅ of the bush bearing 500 is consumed, an additional lubricant is applied to the inner circumferential surface groove 501 and the outer circumferential surface groove 502, A plurality of auxiliary lubricating grooves 601 may be formed to contact or communicate with the outer peripheral surface grooves 502 formed on the outer peripheral surface S ₅ of the bush bearing 500 so as to be supplied to the grooves 502. When the plurality of auxiliary lubricating grooves 601 are formed to contact or communicate with the outer circumferential grooves 502 formed on the outer peripheral surface S ₅ of the bush bearing 500, the lubricant stored in the auxiliary lubricating grooves 601 is transferred to the bush bearing 500, of the outer surface is supplied to the outer peripheral surface grooves 502 formed in the (S _5), bush has an outer peripheral surface groove 502 formed in an outer circumferential surface (S ₅₎ of the bearing 500, an inner circumferential surface formed on its inner circumferential surface (S _4), grooves (501) and The lubricant stored in the auxiliary lubricating groove 601 of the boss 600 can be supplied between the bush bearing 500 and the shaft 400. As a result,

The plurality of auxiliary lubricating grooves 601 formed in the boss 600 are formed such that the axial length b of the auxiliary lubricating grooves 601 is longer than the circumferential length a of the shaft 400, Even if the length of the bush bearing 500 becomes longer due to the enlargement of the mechanical device, it is possible to maintain the clamping amount with the bush bearing 500, and at the same time, the inner peripheral surface groove 501 and the outer peripheral surface groove 50 formed in the bush bearing 500, So that the overall lubricity of the bush bearing assembly can be improved.

The boss 600 may be formed with a lubricant injection path L connected to a plurality of auxiliary lubricant grooves 601 so that an external lubricant may be injected into the plurality of auxiliary lubricant grooves 601. In other words. When the lubricant stored in the auxiliary lubricating groove 601 is exhausted, the lubricant should be fed to the inner circumferential groove 501 and the outer circumferential groove 502 formed in the bush bearing 500. At this time, It is troublesome to disassemble and assemble the bush bearing assembly in order to reuse the bush bearing assembly after the lubricant is fed to the outer peripheral surface groove 501 and the outer peripheral surface groove 502.

When the lubricant is injected into the auxiliary lubricant groove 601 through the lubricant injection path L formed in the boss 600 as described above, the auxiliary lubricant groove 601 is formed in the outer peripheral surface S ₅ of the bush bearing 500 The outer circumferential surface groove 502 formed in the outer circumferential surface S ₅ of the bush bearing 500 is in communication with the outer circumferential surface groove 502 and communicates with the inner circumferential surface groove 501 formed in the inner circumferential surface S ₄ , The lubricant can be conveniently fed to the inner circumferential groove 501 and the outer circumferential groove 502 formed in the bush bearing 500 without disassembling and assembling the bearing assembly. Here, the lubricant injection path L may be formed only one, but two or more lubricant injection paths L may be formed to shorten the lubricant injection time.

4 and 5, in order to facilitate the processability of the boss 600, the center portion C of the boss 600 is subjected to a casting process to form two bushing bearings 500 as shown in FIG. 3 But the overall structure of the bush bearing assembly is not limited to Fig.

In addition, the lubricant used in the bush bearing assembly according to the embodiment of the present invention may use solid lubricants such as graphite, MoS ₂ , WS ₂ , wax, polymer, and resin which have the same effect as lubricating oil in addition to lubricating oil.

In addition, the bush bearing according to the embodiment of the present invention is applicable to all assembly products including the shaft 400, the bush bearing 500, and the boss 600 that are used in the general market.

Examples of the product used as the shaft 400 include a product which is subjected to a reinforced heat treatment such as carburizing heat treatment, high frequency heat treatment, quenching treatment, steam heat treatment, nitriding heat treatment, and composite heat treatment, etc. in general carbon steel, alloy steel, structural steel, A product obtained by lubrication coating such as Cr plating, an oxide coating, MoS ₂ , or a composite plating may be used, but the present invention is not limited thereto.

The bush bearing 500 may be formed of a product made of sintered body, cast steel, cast iron, carbon steel, alloy steel, structural steel, steel bar, steel plate, nonferrous alloy, special alloy, etc., But is not limited thereto. The boss (600) uses a product suitable for each mechanical structure and operating conditions.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, And the scope of the present invention should be understood as the following claims and their equivalents.

1 is a cross-sectional view of a conventional bush bearing assembly.

2 is a cross-sectional view of a boss used in a conventional bush bearing assembly;

3 is a cross-sectional view of a bush bearing assembly according to an embodiment of the present invention.

4 and 5 are cross-sectional views of a boss used in a bush bearing assembly according to an embodiment of the present invention.

Description of the Related Art

100, 600: Boss

200, 500: Bush bearing

300, 400: Axis

Claims (3)

Axis 400; A bush bearing (500) for receiving the shaft and rotating with the shaft; And And a boss (600) into which the bush bearing (500) is inserted and fixedly coupled to the bush bearing (500) The bush bearing includes an inner circumferential groove 501 formed to store a lubricant on an inner circumferential surface which is a contact surface contacting the shaft, and an outer circumferential groove 502 formed to store a lubricant on an outer circumferential surface of the bush bearing, And, A plurality of auxiliary lubricating grooves 601 communicating with the outer circumferential surface grooves 502 are formed on an inner surface of the boss which is a contact surface between the boss 600 and the outer circumferential surface of the bush bearing 500, The auxiliary lubricating groove 601 is formed such that the axial length b of the auxiliary lubricating groove 601 is longer than the circumferential length a of the shaft, Wherein lubricant stored in the auxiliary lubricating groove (601) is supplied between the shaft (400) and the bush bearing (500). The method according to claim 1, Wherein a lubricant injection path (L) is formed in the boss (600) so that an external lubricant can be injected into the auxiliary lubricant groove (601). The method according to claim 1, Characterized in that the auxiliary lubrication groove (601) is a lumbar 8-shape.

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