WO2010043453A1

WO2010043453A1 - Chain

Info

Publication number: WO2010043453A1
Application number: PCT/EP2009/061719
Authority: WO
Inventors: Michael Bogner; Christian Hoffinger
Original assignee: Schaeffler Technologies Gmbh & Co. Kg
Priority date: 2008-10-18
Filing date: 2009-09-10
Publication date: 2010-04-22
Also published as: DE102008052276A1; DE102008052276B4

Abstract

The invention relates to a chain comprising chain links having bores (1) for guiding pins (B), and comprising guide surfaces (2) limiting the chain links, wherein the guide surfaces are engaged with a drive gear, and wherein a joint surface (3) adjoins the guide surfaces (2), and wherein at least some of the chain links have a bent groove (4) extending between the guide surface (2) and the bore (1).

Description

Name of the invention

Chain

Field of the invention

The present invention relates to a chain, which has link plates with holes for guiding bolts, and a guide surface delimiting the link plates, wherein the guide surface is in engagement with a drive wheel and wherein a joint surface is adjacent to the guide surface.

Background of the invention

A chain of the aforementioned type is known from WO2007 / 069792 A1. The chain has several tooth-shaped link plates. There are locating holes in the link plates which allow the link plates to be bolted to form a chain. Within the link plates, a straight groove extends from a tip of a tooth to the receiving bore of the bolt. This groove is intended to receive oil. Due to the tensile and compressive forces acting on the chain, the area between the receiving bore of the link plates and the bolt is particularly susceptible to wear. In order to minimize friction and thus wear, it is advantageous to use lubricants, e.g. To bring engine oil in the area between the receiving bore and the bolt.

Object of the invention

By introducing a groove in the link plate, material is removed whereby the link plates lose rigidity. However, especially in the area of the teeth, the link plates require strength, since the teeth engage in the drive wheel during the chain revolution. A weakening of the link plates on the tooth tip, as required, for example, for the introduction of a groove, can lead to eruptions on the teeth of the link plates. The invention is therefore based on the object to provide a durable chain with optimized friction conditions between link plates and bolts.

Summary of the invention

This object is achieved in that the link plates have at least one curved groove which extends between the guide surface and the bore. It offers itself there to introduce a groove, which causes a weakening of the material, since this area is least burdened with tensile and compressive forces.

It can also be provided that the curved groove has an arcuate curvature or has a circular arc shape. It is also conceivable that the curved groove is designed as a transition arc. The transition arc is a connecting element. It is characterized by the fact that it has a different radius of curvature at each point. This causes the curvature to become slower and not abruptly narrower during the transition between the individual circular arcs. The most commonly used transition arches are clothoids. A clothoid is a curve with continuously linearly increasing same-direction curvature K from K = O to K = ∞. The centrifugal forces that occur when passing through the arcuate curvature are continuously built up or broken down and not jerky.

In concrete of the invention, it is proposed that the previously described curved groove for conveying lubricants is provided. In the stressed on tensile and compressive chain chain there is a high joint wear in the area between the bolt and chain link. By introducing oil in this area a so-called floating state of the bolt can be obtained within the chain. The oiling of the chain is done either by contacting the oiled drive wheel or by spraying the chain by means of an oil mist. However, these procedures do not guarantee that the oil will be sufficiently available Dimensions reaches the Geienkfläche. Due to the relative movement of the chain links to one another, a pumping action is achieved via the designed as a curved groove lubricant channels that promote the oil from outside the chain targeted in the direction of the bolt.

It is particularly advantageous to perform the functioning as a lubricant channels grooves in a curved shape, since the adhering to the link plates oil is exposed to centrifugal forces during the circulation of the chain. The centrifugal forces acting on the oil force it on a curved path. Thus, the centrifugal forces acting on the oil can be used to advantage, running as a lubricant channel groove are also curved, so that the oil from outside the tabs is promoted by utilizing the centrifugal forces in the direction of the bolt.

There is a possibility that the degree of curvature of the groove decreases with increasing number of link plates. Depending on the axial distance a ₀ , chain pitch p and number of teeth z of the drive wheel, a different number of link plates per chain is needed. The calculation of the number of straps x ₀ for drive wheels with the same number of teeth can be determined using the following formula:

^Λ o -

P The smaller the drive wheel, the fewer points of contact between link plates and the drive wheel, which makes it difficult to absorb oil via this contact surface. To compensate for this, the number of grooves must be increased within the link plate, so that the possibility of receiving oil and to promote towards the bolt is ensured. In addition, the curvature of the groove must be designed so that the centrifugal forces acting on the oil can be used ideally.

According to a further preferred embodiment of the invention, the guide surface of the link plates on a tooth shape, each tooth shape having an inner tooth flank and an outer tooth flank and extending between the region of the tooth flank and the hole formed in the link plates a curved groove. A preferred embodiment provides two curved grooves per link plate, either being on the front or back, or one on the front and one on the back, respectively. Another preferred embodiment provides four curved grooves per link plate, two on the front and two on the back.

An increase in the number of slots per tab makes it possible to take up more oil and promote it in the direction of the bolts, but it also means an additional weakening of the link plate material.

In a preferred embodiment of the invention overlap after the chain assembly arranged in the link plates curved grooves, so that a lubricating channel with a larger diameter is formed. Another advantage of the overlapping curved grooves is that the oil can also penetrate between the link plates, whereby the friction between the link plates is reduced and thus the friction of the chain drive can be increased.

In concretization of the invention, it is proposed to produce the link plates including the grooves in a single punching process or a second sub-punching process. Depending on the quality requirement of the bore, the guide surfaces and / or the tooth flank, the surfaces just mentioned can be produced by means of fine blanking, fine blanking or regrooving.

Optionally, the chain may be e.g. be designed as a roller chain or sleeve chain.

In a preferred embodiment of the invention, the aforementioned chain is used as a timing chain in internal combustion engines.

Brief description of the drawings Embodiments of the invention are illustrated in the figures, which are described in detail below, wherein the invention is not limited to these embodiments. Show it:

FIG. 1a shows a chain link of a chain with a tooth-shaped profile and curved grooves,

FIG. 1 b another chain link of a chain with curved grooves,

Figure 2a is a schematic representation of a mounted chain in plan view, with introduced into the link plates grooves.

FIG. 2b shows an embodiment of a joint lug and an inner lug with variants for introducing the curved grooves;

FIG. 3a is a schematic plan view of a mounted chain, with grooves inserted in the link plates,

Figure 3b shows a link plate with a formed respectively on the front and back of the link plate groove.

Detailed description of the drawings

Figure 1a shows a link plate (K) with tooth-shaped profile, which has two holes (1), which are provided during chain mounting for receiving a bolt. Furthermore, the link plate (K) has a joint surface (3) which laterally delimits the link plate (K) and, in the mounted state, adjoins the joint surface (3) of an adjacent link plate (K). The tooth-shaped profile has both an inner tooth flank (5a) and an outer tooth flank (5b). In the area between the inner and outer tooth flank (5a, 5b) and the bore (1) serving to receive the bolt, a curved groove (4) is made. FIG. 2b shows a link plate (K), in FIG in the described area, two grooves (4) are arranged front and back. However, this variant is only suitable for link plates (K), from a certain material thickness, since the link plates (K) would otherwise lose rigidity.

Figure 3b shows a Ausführuπgsform which is particularly suitable for narrow link plates (K). It is envisaged to introduce two grooves (4) per link plate (K), either being located either on the front or back or only one each on the front and one on the back. The course of the grooves (4) can be formed, as shown by way of example in FIG. 3b, in such a way that a groove (4) on the front side of the link plate (K) extends from the inner tooth flank (5a) to the bore (1) while the other groove (4) on the secondary tooth profile on the back of the link plate (K) from the outer tooth flank (5b) to the bore (1) out. Furthermore, other combinations are possible which determine the position and course of the grooves (4) within the link plates (K).

The shape of the link plate (K) shown in FIG. 1b is mostly used in roller or sleeve chains. It also has two holes (1) which are provided for receiving a chain link plates (K) connecting bolt. In addition, the link plate (K) opposing guide surfaces (2) and the guide surfaces (2) laterally limiting hinge surfaces (3). The grooves (4) arranged in different numbers within the link plates (K) can likewise be formed on the front and / or rear side of the link plate (K). It is important that the grooves (4) are not formed in the area between joint surface (3) and bore (1), but between the guide surface (2) and bore (1), since the area between the joint surface (3) and the bore (1) tends to rip under heavy load.

FIGS. 2 a and 3 a show in each case a schematic structure of a chain, which consists of a middle inner link (IL), joint plates (GL) arranged on both sides and which enclose the joint and inner link Outer tabs (AL) exists. The joint and inner plates (GL, IL) can be individual tabs or tab packages. It may be advantageous to provide the outer plates (AL) with grooves (4). The abovementioned tabs are mounted non-rotatably on the basis of their mutually aligned bores by means of a bolt (B). Since the grooves (4) introduced into the joint and inner plates (GL, IL) can vary in their position and their course, different possibilities arise for overlapping the grooves during assembly.

Figure 2a shows a chain in which the hinge and inner plates (GL, IL) each have four grooves (4). In addition, here the hinge lugs (GL) differ from the inner lug (IL) in such a way that the arrangement of the grooves (4) of the hinge lug (GL) is mirror-inverted to the arrangement of the grooves (4) of the inner lug (IL). This different arrangement of the grooves (4) within the hinge and inner plate (GL, IL) has the advantage that when assembling the link plate (K) to a chain there is a multiple overlap of the grooves (4).

FIG. 3a shows a chain in which narrower link plates (K), which have only two grooves (4) per link plate (K), are arranged as described in FIG. 3b. In this embodiment of the chain all link plates (K), regardless of whether it is a joint flap (GL) or an inner flap (IL), in the same manner, bezgl. The shape and position of the grooves (4) made , This has the advantage that in the chain assembly does not have to be paid attention to different tabs or their installation position during assembly. LIST OF REFERENCE NUMBERS

1 holes

2 guiding surface

3 articular surface

4 groove

5a Inner tooth flank

5b External tooth flank

AL outer strap

IL inner flap

GL jointed plates

B bolt

K link plate

Claims

claims

1. chain comprising link plates (K) with holes (1) for guiding bolts (B), and with the link plates (K) limiting guide surfaces (2), wherein the guide surfaces are in engagement with a drive wheel and wherein on the guide surfaces (2) adjacent a joint surface (3), characterized in that at least some of the link plates (K) have a curved groove (4) extending between the guide surface (2) and the bore (1).

2. Chain according to claim 1, characterized in that the curved groove (4) has an arcuate curvature.

3. Chain according to claim 1, characterized in that the curved groove (4) has a klothoidsche curvature.

4. Chain according to claim 2 or 3, characterized in that the curved groove (4) is provided for conveying a lubricant.

5. A chain according to claim 4, characterized in that the lubricant is exposed to a centrifugal force, which undergoes an optimized promotion due to the curved shape of the groove (4).

6. Chain according to claim 1, characterized in that the degree of curvature of the groove (4) decreases with increasing number of link plates (K).

7. A chain according to claim 6, characterized in that the guide surface (2) is formed as a tooth shape, which tooth flanks (5a, 5b) up, wherein on at least one tooth flank (5a, 5b), the curved groove

(4) runs in the direction of the bore.

8. A chain according to claim 7, characterized in that in the link plates (K) introduced grooves (4) partially overlap after assembly.

9. Chain according to claim 6 and 8, characterized in that the chain is a roller chain.

10. Chain according to claim 6 and 8, characterized in that the chain is a sleeve chain.

11. Chain according to one of the preceding claims, characterized in that the link plates (K) are produced by stamping.

12. Chain according to one of the preceding claims, characterized in that the chain is formed as a timing chain for an internal combustion engine.