DE4236690A1 - Tool for compressing helical coil springs - has plates mounted on opposite ends of telescopic strut compressed by screwed spindle - Google Patents

Abstract

The tool for springs, used in the suspension systems of motor vehicles, consists of two similar pressure plates (26) and a screwed spindle (8) which is installed in a telescopic housing. Each pressure plate has a central concave spherical recess (30) with a square central hole (32). A V shaped slot (34) extends from the hole (32) to the edge of the plate. The telescopic housing carries a boss (16,18) each end of convex spherical form. These bosses receive the recesses of the plates (26) with the spring held between the plates. USE/ADVANTAGE - Tool for compressing helical coil springs to facilitate the installation of the springs of motor vehicle suspension systems.

Description

The present invention relates to a spring tensioner for Coil springs, especially large motor vehicle axle springs, as in The preamble of claim 1 is described.

Spring tensioners of this type, which are intended to be large Attaching or releasing motor vehicle axle springs is complicated Construction that leads to rather high production costs, so that known spring tensioners are very expensive.

The invention has for its object a spring tensioner in the preamble of Provide claim 1 type to be provided by simple means, despite the The fact that it is cheaper to produce improves security at Attachment and removal leads, especially with large motor vehicle axle springs.

The spring tensioner according to the invention is essentially as a result characterized in that the two pressure plates are shaped identically and one Have side opening to the central opening that the pressure plates on one rear end, d. H. opposite the side opposite the coil spring have a concave spherical support surface around the central opening and that the support surfaces of the end region and the clamping part made of convex, spherical wings consist of the wings of the pressure plates fit. This gives you a spring tensioner that is cheaper to produce and which nevertheless leads to increased security, because the cooperating, spherical wings automatically to correct any small axial deviations that would otherwise lead to accidents could, if the secure connection of the spring tensioner with one of the Printing plates would be lifted. It is also an advantage that the Printing plates are identical as this simplifies use and costs for Production and storage reduced.

The spring tensioner is preferably equipped so that the central one Opening of the printing plates angular, preferably square, is that Guide tube has an identical shape as that of the central opening, and that the clamping part in connection with the supporting surface is a fastening element which is shaped to conform to the central opening, d. H. to the  very thick side edges of the central opening will be good and steady Connection around the clamp connection and the fastener ensured because the connection allows some mobility, being low Corrections in the axial direction during the joint movement between the corresponding spherical wings can occur.

To have a good and constant connection with the printing plates too ensure the spring tensioner is preferably designed so that the Clamp part is angular on the outside, preferably square, and that the width of the Side opening to the central opening is less than the width of the central opening, but wider than the thickness of the clamping part.

The spring tensioner is particularly advantageously designed so that the Connecting element constantly covers the threaded shaft, which is simple is achieved in that the clamping part, the connecting element and the Guide tube have a common cross section and collapsible can act that the clamping part against the Carrying surface has protruding edges at one end, which are designed so that they are with locally depressed edge regions of an end region of the tubular connector cooperate and that the Connection element at an opposite end area also has protruding edges which are designed so that they are local with the indented edge areas of the guide tube interact.

The invention is explained below with reference to the figures, wherein

Fig. 1 shows a side view of an embodiment of a spring clamp according to the invention,

Fig. 2 shows the embodiment of a printing plate for a spring compressor according to the invention,

Fig. 3 shows the pressure plate shown in Fig. 2 from the opposite side,

Fig. 4 shows an embodiment for the connection between the clamping part and the connecting element by a spring tensioner according to the invention.

The spring tensioner 2 , which is shown in Fig. 1, contains a guide tube 4 with an end portion 6 , in which a threaded spindle 8 with a spindle head 10 and a screw portion 11 is articulated so that the threaded spindle 8 freely through the guide tube 4 and extends through a connecting element 12 to a clamping part 14 which is equipped with an internal thread for the threaded spindle 8 .

At the transition between the end region 6 and the guide tube 4 with a square cross section, a convex, spherical supporting surface 16 is provided around the guide tube 4 . Compared to the connecting element 12, the clamping part 14 is provided with corresponding convex, spherical support surfaces 18 around a fastening element 20 which, like the guide tube 4 , has a square cross section.

The clamping part 14 , which also has a substantially square cross-section ( Fig. 4), is articulated to the guide tube 4 by a connecting element 12 which relatively loosely matches the outside of the clamping part 14 or the inside of the guide tube 4 , so that these parts can interlock telescopically.

When the spring clamp 2 is loosened, that is, when the clamp member is moved away 14 by rotation of the threaded spindle 8 of the guide tube 4, follows the connecting element, as the clamping member 14 has with respect to the support surface 18 protruding at an end portion edge 22, which with the inner portions interact from locally pressed-in edge regions 24 of the tubular connecting element 12 . The protruding edges 22 of the clamp connection 14 are produced by cutting away elongated edge regions 26 in the outer region of the clamp part 14 .

In a very similar manner, pressed-in edge regions 24 of the guide tube 4 interact with projecting edges 22 of the connecting element 12 , so that the threaded spindle 8 is covered or protected by the connecting element 12 , even if the spring tensioner 2 is positioned with an upwardly pointing spindle head 10 .

The spring tensioner 2 contains two identical pressure plates 26 which are provided with a concave, spherical support surface 30 at a rear end 28 ( FIG. 2), ie opposite the side ( FIG. 3) which is intended for connection with a helical spring , which has the same radius as that of the wings 16 and 18th The spherical support surface 30 is arranged concentrically around the central square opening 32 and loosely fits the outer cross section of the guide tube 4 or the connecting element 20 . The pressure plates 26 have a radial side opening 34 to the central opening 32 and a larger V-shaped side cutout 36 .

The side opening 34 has a width which is less than the diameter of the central opening 32 and which is somewhat greater than the thickness of the clamping part 14 , ie that the corresponding pressure plates 26 are laterally guided around the clamping part 14 when the spring tensioner 2 is mounted before the Pressure plates 26 or the spring tensioner 2 are axially offset until a secure connection to the support surfaces 16 or 18 is reached.

Claims (4)

1. Spring tensioner for coil springs, especially large motor vehicle axle springs, which consists of two loose, plate-like pressure plates ( 26 ) with a central opening ( 32 ) and a threaded spindle ( 8 ), which is provided with a spindle head ( 10 ) and a screw area ( 11 ) , and which is rotatably mounted with an end region in a guide tube ( 4 ), with a support surface ( 16 ) for one of the pressure plates ( 26 ), with a clamping part ( 14 ) with an internal thread for the threaded spindle ( 8 ), with a support surface ( 18 ) for the other pressure plate ( 26 ) and a connecting piece ( 12 ) which can be displaced between the guide tube ( 4 ) and the clamping part ( 14 ) in a non-rotatable manner in the axial direction, preferably outside the clamping part ( 14 ) and inside the Guide tube ( 4 ), characterized in that the pressure plates ( 26 ) have an identical shape and a lateral opening ( 34 ) in the direction of the central opening ( 32 ), i ate the pressure plates ( 26 ) on a lower side ( 28 ), ie opposite the side opposite the coil spring, around the central opening ( 32 ) have a concave, spherical support surface ( 30 ), and that the support surfaces ( 16, 18 ) of the end surface ( 6 ) and the clamping part ( 14 ) consist of convex, spherical support surfaces which match the support surfaces ( 30 ) of the pressure plates ( 26 ). 2. Spring tensioner according to claim 1, characterized in that the central opening ( 32 ) of the pressure plates ( 26 ) is angular, preferably square, that the guide tube ( 4 ) and the central opening ( 32 ) have an identical shape, and that the clamping part ( 14 ) in connection with the support surface has a fastening element ( 20 ) which has a shape that matches the central opening ( 32 ). 3. Spring tensioner according to claim 1, characterized in that the clamping part ( 14 ) is angular on the outside, preferably square, and that the width of the side opening ( 34 ) towards the central opening ( 32 ) is less than the width of the central opening ( 32 ) and greater than the thickness of the clamping part ( 14 ). 4. Spring tensioner according to claim 1, characterized in that the clamping part ( 14 ), the connecting element ( 12 ) and the guide tube ( 4 ) have a common cross section and are telescopically displaceable that the clamping part protrudes relative to the support surface ( 18 ) at one end Has edges ( 22 ) which are designed such that they cooperate with locally pressed-in edge regions ( 24 ) of an end region of the tubular connecting element ( 12 ), and that the connecting element ( 12 ) also has projecting edges at an opposite end region which are formed in this way that they interact with locally depressed edge areas of the guide tube.