DE3535617A1 - DIVIDED SLIDING BEARING, IN PARTICULAR CONNECTING ROD BEARINGS, FOR MEDIUM AND LARGE ENGINE - Google Patents

Description

The invention relates to split plain bearings, in particular Connecting rod bearings, for medium and large engines, with remaining ones Holding devices for detachable holding together of the plain bearing parts directly over their parting surface in the support wall of the slide bearing parts, preferably in pairs, are arranged.

There are split plain bearings of this type from DE-OS 29 24 552 known in which pin-like, resilient connecting brackets inside the retaining wall as remaining holding devices are used. Need these pin type connector clips but considerable dexterity to keep them in the locked position bring or from this position again to be able to solve.

DE-OS 21 45 371 and DE-OS 31 30 557 are plain bearings known, in which on the outside of the support wall the slide bearing parts holding elements, for example holding clips or Seeger circlips are attached, that reach over the parting surfaces of the slide bearing parts. The attachment of such holding elements when installing the Plain bearing parts is complicated, time consuming and difficult, especially if the location is only relative is difficult to access.

From DE-OS 31 30 557 it is also known that the detachable To keep the slide bearing parts together by improving that in addition to those on the outside of the retaining wall retaining elements to be attached also inside the  Retaining wall inserted, simple pin-like connector elements be provided. These pin-like connector elements give the plain bearing parts a fixed mutual support, but make additional holding elements necessary and complicate the assembly of the plain bearing parts.

In contrast, it is an object of the invention to split plain bearings, especially connecting rod bearings, for medium and large engines on the remaining holding devices for detachable holding together of the plain bearing parts significantly improve that the fixtures are attached effortlessly can be and the assembly of the plain bearing parts by these holding devices is not complicated.

This object is achieved in that each Holding device an elastic around the slide bearing Prestressed, annular tension element, which in one on the outside of the support wall of the slide bearing parts formed, radial, circumferential annular groove housed sunk is.

This measure advantageously becomes an installation aid created that holds the camp together when the Bearing cover fitted or when removing the connecting rod is removed.

Another advantage is that during the replacement the piston of the peg from contamination and Damage is protected.

It has surprisingly been found that such, the plain bearing encompassing, elastically prestressed, ring-shaped tension elements particularly light on the outside of the retaining wall the slide bearing parts attached and in itself on the outer Circumferential surface of the plain bearing all around extending annular grooves can be inserted sunk.  

In particular screwing in plain bearing parts between the bearing holder and the journal, for example one Crankshaft is extended by such all around Traction elements not difficult. Rather, the tension element even before screwing the plain bearing part into it outer groove. That way the plain bearing encompassing, ring-shaped tension elements are at simple, easy construction still suitable, substantial Exert holding force and clamping force on the slide bearing parts, so that the plain bearing parts by the under elastic preload encompassing the plain bearing Tension element or tension elements held together securely and be fixed.

In a preferred embodiment of the invention, the tension element with its ends to a closed ring closable. This allows the pulling element to still in opened condition around the pin to be stored or loop the shaft to be supported and before inserting it of the slide bearing parts to form a ring, in which then the plain bearing parts with the on the outside the groove attached to the support shell. Here the tension element can be formed by a helical tension spring be. It is also possible to pull the tension element out in its Longitudinally elastic elastic plastic wire or Form plastic hose. In the latter case, it should weldable plastic are used so that Ends of the plastic wire forming the tension element or Plastic hose can be welded together.

The radial grooves or grooves are preferred with at least one extending axially to the end face of the plain bearing Provide excavation groove. By means of this excavation groove the elastically tensionable tension element using a tool undermined and from around itself around the plain bearing  extending receiving groove can be lifted. If that Tension element through plastic hose or plastic wire is formed, one can also replace the excavation groove Receiving groove for the traction element crossing access groove be provided so that a cutting tool, for example a knife, brought in the transverse direction to the tension element can be used to release the pulling element of the holding device cut through.

The combination is particularly advantageous in the context of the invention of the outer peripheral surface of the plain bearing tensioned tension element with at least one directly in the Wall of the slide bearing parts arranged connector element, that in the manner of a tangential direction in the Wall of a plain bearing part used with a press fit Pen is formed over the interface in a tangential direction in the wall of the other Sliding bearing part engages recess with sliding fit. These connector elements not only prevent any mutual axial and radial movement of the slide bearing parts relative to each other, but also form also a safe guide device for contracting the slide bearing parts through the elastically preloaded Tension elements. Because these traction elements and pin-shaped Plug connection elements in the area of the parting surfaces are arranged parallel to each other, that of the connector function exercised management function in that the slide bearing parts along this Guiding to the exact superposition of their dividing surfaces contracted by the tension element or the tension elements will.

Embodiments of the invention are as follows explained in more detail with reference to the drawing. Show it:  

Figure 1 shows a slide bearing according to the invention with a pair of tension elements in side view.

Fig. 2, the slide bearing of Figure 1 in front view, partially broken away.

Fig. 3 shows the area 3 of FIG. 1 in an enlarged view and modified embodiment and

Fig. 4 is a partial section along the line 4-4 in FIG. 1.

The exemplary embodiments shown in the drawing are two-part slide bearings, namely connecting rod bearings 10 , which are intended in particular to be screwed into the corresponding bearing receptacles between the respective journal part of the crankshaft and the respective bearing receptacle after the crankshaft has been inserted. The two slide bearing parts 11 and 12 are formed on the outer circumferential surface of their support wall 13 with a pair of annular grooves 14 extending parallel to one another and parallel to the end faces of the bearings. In each of these ring grooves 14 , an elastically prestressed annular tension element 15 is inserted, which encompasses the entire slide bearing 10 in an annular manner. In the example of FIGS. 1 and 2, the annular tension element is formed by a coil tension spring 16 , the end regions of which can be screwed together to form a closed ring. In order to be able to lift the pulling elements 15 from the annular grooves 14 in order to release the holding device formed in this way, each annular groove 14 is connected to a lifting groove 17 which extends to the respective end face 18 of the respective slide bearing part 11 or 12 and is essentially the same depth as the annular groove 14 has. The excavation groove 17 can be made relatively flat in the region of the end face 18 and can adapt to the depth of the annular groove 14 . Although lifting grooves 17 are only shown on the slide bearing part 12 in FIG. 1, each of the two sliding bearing parts 11 and 12 can have such lifting grooves. There may even be several excavation grooves 17 distributed over the circumference.

In the example of FIG. 3, the tension element 15 is formed by a weldable, elastic plastic wire 19 , the ends of which are welded together at 19 a . This plastic wire 19 is also biased in its longitudinal direction. It is not necessary to remove this holding device from the annular groove 14 , since it is cut through for the sake of simplicity. When reassembling the bearing, a new plastic wire 19 is used to form the tension element.

Instead of the plastic wire 19 , a plastic tube could also be used to form the tension element 15 , it being possible for the ends of the plastic tube to be welded together to form a closed ring.

When using a pulling element to be cut when the holding device is released, an access groove 20 , for example a knife guide groove, can be provided instead of the lifting groove 17 , which crosses the ring groove and may have a somewhat greater depth than the ring groove 14 .

The depth of the annular grooves 14 is such that the tension element received by the respective annular groove is completely sunk into the annular groove 14 .

As can be seen from FIG. 2, the connection point 16 a , 19 a of the tension elements 16, 19 is arranged offset by an angle λ with respect to the separating surfaces 21 of the slide bearing parts 11 and 12 , for example by an angle of 45 °.

As can be seen from FIGS. 1, 2 and 4, in a special embodiment of the invention, the combination of the tension element 15 or pair of tension elements 15 stretched over the outer circumferential surface of the slide bearing 10 with at least one connector element arranged directly in the support wall of the slide bearing parts 11 and 12 22 provided. A pair of such connector elements 22 is preferably provided on each separating surface 21 . The connector elements 22 have the shape of a pin extending in the tangential direction, which is inserted with one end with a press fit into the support wall of a plain bearing part, for example the plain bearing part 11 , and over the separating surface 21 in a tangential direction in the wall of the other slide bearing part, for example the slide bearing part 12 , engages recess 23 with a sliding fit.

Although according to the illustration of FIG. 1, the width of the annular groove 14 may be matched to the thickness of the tension member 15 that even the tension element 15 11 and 12 prevents a substantial axial mutual displacement of the plain bearing parts on their parting surface 21, provide the plug connector elements 22 is still improved lateral support and guidance of the slide bearing parts 11 and 12 to one another and, above all, the generation of shear effects in the area of the separating surfaces 21 through the side surfaces of the annular grooves 14 on the inserted tension elements 15

For mounting a sliding bearing according to Fig. 1 to 4, for example, to a crankshaft, first needed for the slide bearing 10 are tension elements 15 in the region of each of the slide bearing 10 embraced shaft portion or spigot closed annularly around these. The slide bearing parts 11 and 12 are then attached between the respective crankshaft part and the tension elements 15 .

• Reference symbol list
  10 connecting rod bearings
  11 plain bearing part
  12 plain bearing part
  13 retaining wall
  14 grooves
  15 tension element
  16 coil tension spring
  16 a connection point
  17 excavation groove
  18 end face
  19 plastic wire
  19 a connection point
  20 access groove
  21 dividing surfaces
  22 connector element
  23 recess

Claims (8)

1) Split slide bearing, in particular connecting rod bearings, for medium and large engines, in which the remaining holding devices for detachably holding the slide bearing parts across their separating surface are arranged directly in the support wall of the slide bearing parts, preferably in pairs, characterized in that each holding device has a slide bearing ( 10 ) encompassing, elastically prestressed, annular tension element ( 15 ), which is recessed in a radial, circumferential annular groove ( 14 ) formed on the outside of the support wall of the slide bearing parts ( 11, 12 ). 2. Split plain bearing according to claim 1, characterized in that the tension element ( 15 ) can be closed with its ends to form a closed ring. 3) Split slide bearing according to claim 1 or 2, characterized in that the tension element ( 15 ) is formed by a helical tension spring ( 16 ). 4) Split slide bearing according to claim 1 or 2, characterized in that the tension element ( 15 ) is formed from in its longitudinal direction elastically tensionable plastic wire ( 19 ) or plastic tube. 5) Split slide bearing according to claim 4, characterized in that the plastic is weldable. 6) Split slide bearing according to one of claims 1 to 5, characterized in that the radial annular grooves ( 14 ) with at least one axially extending up to the end face ( 18 ) of the slide bearing ( 10 ) extending lifting groove ( 17 ) is provided. 7) Split slide bearing according to one of claims 1 to 4, characterized in that the radial annular groove ( 14 ) is provided with at least one access groove ( 20 ) crossing it. 8) Split slide bearing according to one of claims 1 to 7, characterized by the combination of the tension element ( 15 ) stretched over the outer circumferential surface of the slide bearing ( 10 ) with at least one connector element ( 22 ) arranged directly in the support wall of the slide bearing parts ( 11, 12 ). which is designed in the manner of a pin inserted in the tangential direction into the support wall of one slide bearing part ( 11 or 12 ) with a press fit and which extends over the separating surface ( 21 ) in a tangential direction in the support wall of the other slide bearing part ( 12 or 11 ) attached recess ( 23 ) engages with a sliding fit.