DE2838777A1 - Roller bearing for linear motion - has planar oval track for continuous row of rollers joined together by pair of flexible plastics chain belts - Google Patents

Abstract

The bearing includes a carrier (1) with a straight, flat track (2) on both its upper and lower surfaces; and an end cap forming a semicircular track is located at each end of the bearing. A continuous, flat oval path is thus provided for a row of bearing rollers which are joined together by a pair of flexible plastic belts functioning like chains. The track (2) on one side of carrier (1) has a depth less than the dia. of the rollers, thus forming a thrust surface (4) on the carrier. Both end surfaces of each bearing roller posses a blind axial hole entered by a peg (19); and each plastic belt carries a row of pegs (19) forming a chain link with the rollers. Each plastic belt pref. has its max. width where the pegs (19) are fixed, but the width tapers to a thin section to form a "hinge" between adjacent rollers. Bearing is used to guide and support slides on machine tools, or to support heavy machine parts travelling or reciprocating along a linear path.

Description

Rolling element for linear movements The invention relates to a rolling element for linear movements, consisting of a support body with an endless track for cylindrical rolling elements guided in the raceway, the raceway in the area a load zone on at least one side of the support body is flat and has a depth which is smaller than the diameter of the rolling elements.

Such rolling elements are used to guide machine slides and for moving larger machine parts. The rolling friction between the rolling elements in the area of the load zone and the track in the support body on the one hand or an associated one On the other hand, the guideway is less than the sliding friction of other elements Design that serve the same purpose.

In a known rolling element of the type described above (DE-GM 76 14 933) are the individual cylindrical rolling elements in their freedom of movement limited only by adjacent rolling elements. Especially in the field of Load zone an orderly sequence of rolling elements entering the load zone one after the other To obtain, the career path has a level above which the pending Rolling element is lifted by the following rolling elements, so that it is in the load zone got. In the area of the load zone, the rolling elements protrude with a circumferential section the support body and can accordingly on a guideway roll off.

All of this is therefore seen as disadvantageous and not proven, because the rolling elements especially when entering the load zone and in the area of the Load zones can shift or tilt against each other in such a way, that malfunctions due to lack of directional stability of the rolling element and due to increased resistance to movement cannot be ruled out.

The object of the invention is therefore to guide the rolling bodies and thus improving the directional stability of the rolling element and its resistance to movement to reduce.

This object is achieved in that the rolling elements are end face each have a blind hole for pins of chain-like connecting elements, which are guided on the track at least in the area of the load zone.

The rolling elements guided in this way are via the connecting elements coupled to one another in such a way that they are no longer independent, but only can still move together.

Tilting or displacements of individual rolling elements are practical locked out. This increases the directional stability of the Rolling element considerably improved and resistance increases due to tilted rolling elements can no longer appear. Since the connecting elements are guided in the area of the track, they serve they also serve to keep the rolling elements in the area of the raceway. As a result, you can do without special retaining strips and also simpler ones Use rolling elements, namely rolling elements with flat end faces.

In particular, the connecting elements can be closed plastic strips be on which the pins are arranged on one side and in a fixed pitch and the material weaknesses arranged between the pegs as joints exhibit. The use of plastic material for the fasteners leads at lower material costs, easier production and more favorable sliding properties. In addition, the plastic material can due to its elastic properties also replace joints, especially if material weaknesses in certain areas are provided. This allows the plastic strips serving as connecting elements also follow comparatively strong curvatures of the career path without it being too significant Constraints between the plastic band and the associated guide on the one hand and between adjacent rolling elements on the other hand can come. - A preferred embodiment is characterized in that the plastic strips are wavy in the longitudinal direction have variable height and that the greatest height in the area of the wave crests essentially corresponds to the diameter of the pin, while the smallest height in the area of the material weakening essentially the quarter diameter the tenon corresponds.

The connecting elements can be in the grooves of the side walls Be guided raceway, wherein the grooves have a cross section that at least corresponds to the largest cross-section of the connecting elements. This results in a relatively simple career path, you only need one the longitudinal cross-section of the rolling elements essentially corresponding cross-section and on the side walls arranged grooves, which are generally also rectangular in cross-section own. This considerably simplifies the manufacture of the support body.

Because only in the area of the load zone there is an exact guidance of the rolling elements is required, the grooves outside the load zone of the raceway can have a larger one Have height than the connecting elements. In particular, the grooves can extend up to extend to the bottom of the running track. This also has the advantage that the plastic straps, if they are outside the load zone, they are completely unloaded.

When using cylindrical rolling elements with flat faces, the guidance of the rolling elements can be improved in that at least in the area the load zone of the Runway over the side walls at least part of their height have a distance substantially equal to the length of the Rolling body corresponds. Then namely the end faces of the rolling elements are on the side Walls additionally guided so that canting is as good as impossible.

In the following an embodiment shown in the drawing is shown the invention explained; They show: FIG. 1 partially in a schematic representation a longitudinal section through a rolling element, FIG. 2 is a plan view in the direction of the Arrow II on the object of Fig. 1, Fig. 3 shows a section in the direction III - III by the object of Fig. 1, Fig. 4 on a larger scale partially the object according to Fig. 1.

The rolling element shown has a support body 1 with a circumferential Raceway 2 for rolling elements 3. The track 2 consists of a flat, as a load zone 4 serving section and one on the opposite side of the support body arranged, parallel to the load zone 4 extending section, which serves as the return zone 5. At the ends of the support body 1 are load zone 4 and Return zone 5 connected to one another by arcuate sections 6. In FIG. 1 shows only one of the arcuate sections 6. In the field of arcuate sections 6 are each connected to the support body 1 cover hoods 7, under which career 2 continues.

The covers 7, which are made of glass fiber reinforced plastic can have protruding tabs 8, 9, which are located on both sides of the support body 1 extend and those with notched nails 10, 11, which are in associated blind bores 12, 13 of the support body 1 are driven, are fixed on this. Screw holes 14 in the support body 1 are used to attach the rolling element to a machine part or a machine body (Fig. 2).

The rolling elements 3 are cylindrical and have flat end faces 15 and 16. Central blind bores 17, 18 are arranged on the end faces 15 and 16, respectively. engage in the pins 19 of plastic straps 20. The pins 19 are one-sided molded onto the plastic strips 20 (FIG. 4). The plastic straps 20 have a substantially rectangular cross-section with over the length of the plastic strips 20 variable height. As can be seen in particular from a comparison of Figure 4, the height of the plastic strips 20 changes in a wave-like manner, with the maximum height in the area of the pin 19 corresponds to the diameter of the pin 19 and between the pins 19 each material weakening is formed, the joints 21 form. In the area of the joints, the height of the plastic straps 20 is approximately one Quarter of the diameter of the tenons 19.

The plastic strips 20 are guided in grooves 22, 23 in the area of side walls 24, 25 of the raceway 2 are arranged. The grooves 23 in the area the load zone 4 (lower part of Figure 3) have a cross section that is substantially corresponds to the largest cross section of the plastic strips 20. In the area of the return zone 5, the grooves 22 arranged there extend to the bottom 26 of the track 2, because an exact guidance of the rolling elements 3 is not absolutely necessary in this area is.

As can be seen from Figure 3, has the raceway 2 in the area Load zone 4 has a depth that is slightly less than the diameter of the rolling elements 3, while the depth of the raceway 2 in the area of the return zone 5 is somewhat greater than the diameter of the rolling elements 3. In addition, in the area of the load zone 4 the two side walls 24, 25 of the raceway 2 at a distance that is substantially corresponds to the length of the rolling elements 3, so that the end faces 15, 16 of the rolling elements 3 on these side walls 24, 25 are additionally performed. Of the Serving as a guide portion of the side walls 24, 25 extends, however only up to the grooves 23.

When the rolling element shown in Fig. 1 in the direction of the arrow 27 (to the right in FIG. 1), those located in the area of the load zone 4 roll Rolling bodies on an associated guide track 28, which they from the return zone 5 can be fed via the curved section 6.

In the direction of displacement in front of load zone 4 is located on the cover 5 a dirt scraper 29 on the back, i.e. against the direction of displacement 27, merges into a grease holder 30. A corresponding arrangement can be found on the opposite, not shown side of the rolling element.

During the rotation of the rolling elements 3, these are always of the Plastic straps led. Constraints especially in the area of the curved sections 6 of the raceway 2 can because of the elastic properties of the plastic belts do not occur or are insignificant.

It has been shown that the roller-shaped rolling elements 3 in the area the load zone 4 of the chain-like plastic belts 20 in a straight line and in compliance a constant pitch tK. This will cause signs of wear and tear Avoided on the rolling elements by mutual grinding in the area of load zone 4, and there is a better efficiency.

The plastic strips 20 are positioned in the area of the return zone 5 zigzag so that the rolling elements 3 rest against one another and the plastic strips 20 are not loaded by the sliding forces of the rolling elements 3.

This results in a changed pitch in the area of the return zone 5 tR, where tR = tK - # t.

The dimension #t depends on the position of the joint (21) to the center line the pin (19) of the plastic band (20).

Blank page

Claims (7)

Claims 1. Rolling element for linear movements, consisting of one Support body with an endless raceway for cylindrical ones guided in the raceway Rolling bodies, the raceway in the area of a load zone on at least one side of the support body is flat and has a depth that is less than the diameter the rolling elements, characterized in that the rolling elements (3) each have an end face a blind hole (17, 18) for pins (19) of chain-like connecting elements (20) at least in the area of the load zone (4) of the track (2) on this are led. 2. Rolling element according to claim 1, characterized in that the connecting elements self-contained plastic straps (20) are where the tenons (19) are arranged on one side and in a fixed pitch and between the pins (19) have material weaknesses as joints (21) arranged in the correct manner. 3. Rolling element according to claim 1 or 2, characterized in that the plastic strips (20) have a wave-shaped variable height in the longitudinal direction have and that the greatest height in the area of the wave crests is essentially the Diameter of the pin (19) corresponds, while the smallest height in the area of Material weaknesses (21) essentially the quarter diameter of the pin (19) is equivalent to. 4. Rolling element according to one of claims 1 to 3, characterized in that that the connecting elements (20) in grooves (23) of the side walls (24, 25) the track (2) are guided and that the grooves (23) have a cross section, which corresponds to at least the largest cross section of the connecting elements (20). 5. Rolling element according to one or more of claims 1 to 4, characterized characterized in that the grooves (22) in the return zone (5) have a greater height than the connecting elements (20). 6. Rolling element according to claim 5, characterized in that the grooves (22) in the area of the return zone (5) extend to the bottom (26) of the track (2). 7. Rolling element according to one or more of claims 1-6, characterized characterized in that at least in the area of the load zone (4) of the track (2) the lateral walls (24, 25) at least over part of their height a distance have, which corresponds essentially to the length of the rolling elements (3). description