DE29822209U1 - Threaded spindle drive for a spring tensioner with a safety pin that shears off in the event of an overload - Google Patents

Description

Stenger, Watzke & Ring I ₄ .;* * j _#>: ;*Ka*V^i//-iecirich-Ring ₇₀

&Oacgr;-40547 Düsseldorf

PATENT ATTORNEYS

DIPL-ING. WOLFRAM WATZKE

DIPL-ING. HEINZ J. RING

_{QR 1?nn} DIPL-ING. ULRICHCHRISTOPHERSEN

Our reference: DIPL-ING. MICHAEL RAUSCH

. DIPL-ING. WOLFGANG BRINGMANN

Hazet-Werk Hermann Zerver Patent Attorneys

GmbH & Co. KG european patent attorneys

Güldenwerther Bahnhofstrasse 25-29
42857 Remscheid

Date 10 December 1998

Threaded spindle drive for a spring tensioning device with an overload

shearing safety pin

The invention relates to a threaded spindle drive for a spring tensioning device provided with two spring tensioning elements, each for receiving a spring coil of a helical spring to be tensioned, with a threaded spindle that is rotatably mounted in a guide tube and additionally supported by an axial bearing relative to the guide tube, which is provided with a coupling section in the area of its free end facing away from the threaded section, onto which a corresponding coupling section of a drive part provided with a drive polygon is placed, wherein the two coupling sections are connected in a form-fitting manner via a locking pin that passes through both coupling sections and shears off in the event of an overload of the threaded spindle drive, with a longitudinal axis arranged transversely to the axis of the threaded spindle.

A threaded spindle drive for a spring tensioner with these features is known from DE 28 13 381 C2. The threaded spindle is rotatably mounted in a head part of a cylindrical guide tube by means of an axial thrust bearing. In order to rotate the threaded spindle and thus drive the spring tensioner when tensioning and relaxing the coil spring, the threaded spindle is provided with a separate drive part in the area of its spindle head, which is mounted with an axially extending receiving bore on a coupling section of the threaded spindle by means of a coupling pin in a way that is almost free of play and non-rotatable. The first spring tensioning element of the spring tensioning device is fixedly attached to the guide tube, whereas the second spring tensioning element is coupled to a spindle nut which is tightened by the

Telephone (0211) 572131 ■ Telex 8588429 pate d · Telefax (02&Pgr;) 58 8225 ■ BHF-Bank, Düsseldorf CBLZ 300205 00) 40113 276

Threaded spindle is driven. By turning the threaded spindle, the spring tensioning element on the spindle nut side is moved towards the fixed spring tensioning element, so that the coil springs clamped between the two spring tensioning elements are compressed.

The drive part is provided with a polygonal drive at its end and is attached to the threaded spindle using the coupling pin. The coupling pin, which is made of solid material, also serves as overload protection and is sheared off if the coil spring is compressed to a block and the threaded spindle continues to rotate. After the coupling pin has been sheared off, no more actuating torque can be transmitted to the threaded spindle via the polygonal drive, so that the spring tensioning device cannot be over-tightened. This is to prevent the threaded spindle and in particular its thread from being damaged.

However, it has been shown in practice that the coupling pin only offers very inadequate overload protection and may not even shear off when the coil spring is compressed to a block and an attempt is made to continue to transfer a high machining torque to the threaded spindle via the drive polygon. In the worst case, this can lead to the second spring element coupled to the threaded spindle tearing out, which would result in an explosive expansion of the coil spring compressed to a block. Serious injuries to the operating personnel could result.

Another disadvantage is that the coupling pin, which serves as a coupling element between the threaded spindle and the drive part, is subject to certain signs of wear, particularly when an impact wrench is used to actuate the spring tensioning device, which, if used frequently, can lead to the coupling pin shearing off after a while without the coil spring being tensioned to the block.

The insertion of a coil spring into the corresponding spring holder of a motor vehicle is usually carried out under spatially unfavourable conditions. If the coupling pin shears off in the event of an overload, i.e. if the

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If the coil spring is tensioned to the block, the spring tensioning device can generally be removed from the corresponding spring holder of the motor vehicle together with the coil spring without any problem. However, if the coupling pin has sheared off due to wear, it is not possible to remove the coil spring together with the spring tensioning device from the spring holder of the motor vehicle. In this case, it is no longer possible to operate the spring tensioning device any further, as the rotationally fixed connection between the drive part and the threaded spindle is no longer possible. Due to the spatially unfavorable conditions on the motor vehicle, it is usually not possible to replace the sheared coupling pin on the spot with a new, undamaged coupling pin. In such a case, the threaded spindle must then be turned with pliers or another auxiliary tool to release the spring tensioning device after removing the drive part. The disadvantage of this is that it often damages the spindle head and in order to ensure that the spring tensioning device can continue to be used safely, the entire spindle drive must be replaced.

The present invention is therefore based on the object of creating a threaded spindle drive that ensures reliable overload protection.

To solve this problem, it is proposed that the locking pin in a threaded spindle drive of the type mentioned above be provided with at least one predetermined breaking point in the form of a recess.

The invention thus provides a safety pin for the event of an overload, which, in comparison with the coupling pin known from DE 28 13 381 C2, is not made of solid material over its entire length, but advantageously has at least one defined predetermined breaking point in the form of a recess for overload protection.

According to an advantageous embodiment of the invention, the locking pin has two predetermined breaking points in the form of a recess each, with the two recesses being arranged opposite each other at the respective end of the locking pin. According to this development of the invention

the locking pin is made of solid material only in its middle section and has a corresponding strength, whereas the two ends of the locking pin, each with a recess, are correspondingly weakened. According to a further advantageous proposal of the invention, the predetermined breaking recesses are blind holes with a longitudinal axis parallel to the axis of the locking pin, whereby the locking pin is symmetrical both with respect to its longitudinal axis and with respect to its perpendicular bisector. In the event of an overload, both ends of the locking pin are no longer able to transfer the applied torque to the threaded spindle due to their material weakening and shear off.

According to a further advantageous proposal of the invention, the drive part and the threaded spindle of the spring tensioning device are coupled to one another via the locking pin in such a way that, after the weakened ends have been sheared off, the inner section of the locking pin, which is made of solid material, is still present, so that the pressure sleeve subject to the full spring load is still secured.

According to a further advantageous proposal of the invention, the pressure sleeve is connected to the cylindrical pin of the threaded spindle via a screw thread. This ensures that the pressure sleeve cannot accidentally come loose from the threaded spindle even if the locking pin is completely lost.

According to a further advantageous proposal of the invention, the drive part has a circumferential groove in the area of the receiving hole for the locking pin, in which a rubber ring is arranged. This rubber ring advantageously ensures that the locking pin is centered in the receiving hole and that it cannot fall out of it. Furthermore, after removing the rubber ring, a damaged locking pin can be easily replaced with a new, undamaged locking pin.

Further details and advantages of the invention emerge from the following description based on the drawings. In the drawings:

Fig. 1 shows a sectional view of a spring tensioning device provided with two spring tensioning elements;

Fig. 2 shows a detail of the spring tensioning device according to Fig. 1 in the area of the drive;

Fig. 3 shows the details of the spring tensioning device according to Fig. 2, but with the drive part separated from the spring tensioning device.

The spring tensioning device consists of a spindle shaft 3 provided with two clamping jaw holders 1, 2 and two spring tensioning elements in the form of clamping jaws 4, 5 placed on the clamping jaw holders 1, 2. The clamping jaws 4, 5 are provided on their mutually facing end faces with spring receptacles 6 (not shown in detail) for gripping a coil spring 7. The spring to be tensioned is shown in a highly stylized manner in Fig. 1.

To compress the spring 7, the spindle consists of an outer housing 8 and a spindle shaft 3 guided in it. The spindle shaft 3 is a cylinder provided with machined guide surfaces 10, which can slide axially in a bore 11 of the outer housing 8. The first clamping jaw holder 1 is screwed onto the outer end of the spindle shaft 3. A groove 12 for a key 13 seated in the outer housing 8 ensures that the inner and outer housing of the spindle cannot twist. To prevent dirt and moisture from penetrating the guide gap, the guide surface 10 is sealed off from the outer housing 8 by means of a sealing lip 14.

To generate the axial adjustment movement of the spring tensioning elements, a bearing bush 15 is inserted into the end of the outer housing 8, in which a threaded spindle 16 provided with an external thread is doubly mounted. The threaded spindle 16 is provided outside the double bearing with a cylindrical coupling section 17 arranged on a pin 9 of the threaded spindle, which is connected in a rotationally fixed manner to a drive part 19 via a locking pin 18 serving as a coupling element. The drive part 19 has axially one behind the other a coupling section 20 corresponding to the coupling section 17 and a drive section with a polygonal drive 21, preferably

a hexagon, drive section 22. The coupling section 17 is formed by a pressure sleeve 23 of the threaded spindle, which is arranged between the pin 9 formed in one piece on the threaded spindle 16 and the coupling section 20 formed on the drive part 19. The length of the locking pin 18 serving as a coupling element is dimensioned such that it simultaneously passes through the pin 9, the pressure sleeve 23 and the outer coupling section 20. The pressure sleeve 23, designed in the manner of a ring, is supported axially with its one end face 24 on the outer bearing 25 of the double bearing. Fig. 2, which is an enlarged partial view of Fig. 1, shows details of the threaded spindle drive in the area of the drive part 19. The locking pin 18 is designed differently along its length. The middle section of the locking pin 18 is made of solid material and has a corresponding strength, whereas the two ends of the locking pin 18 are provided with blind holes 26 and are correspondingly weakened. The area around the bottom of the blind holes 26 determines the location along the length of the locking pin 18 where the tendency to shear off in the event of overload is greatest. The locking pin 18 is designed symmetrically both with respect to its longitudinal axis and its perpendicular bisector. A rubber ring 27 arranged in a circumferential groove of the drive part 19, whose inner diameter is equal to the length of the locking pin 18, ensures that the locking pin 18 is centered and cannot fall out of its receiving hole. The locking pin 18 is part of the overload protection for the threaded spindle drive. This overload protection becomes important when the spring to be tensioned is compressed to the block and an attempt is nevertheless made to continue rotating the threaded spindle 16. In such a case, the ends of the locking pin 18 are no longer able to transfer the corresponding torque from the hexagonal drive part 19 to the threaded spindle 16 due to their material weakening, so that the pin 18 shears off on both sides, namely near the bottom of the blind holes 26.

As a result of this shearing, the positive connection between the drive part 19 and the threaded spindle 16 is interrupted and the drive part 19 can be pulled off the spring tensioning device with the remaining stumps of the locking pin 18, as shown in Fig. 3. However, the inner section of the locking pin 18 is still present, so that the

The pressure sleeve 23, which is subject to full spring loading, is secured on the inner coupling section 17 of the threaded spindle 16. The security is further enhanced by the fact that the pressure sleeve 23 is connected to the otherwise cylindrical pin 9 of the threaded spindle 16 via a screw thread 28 and in this way cannot easily detach from the threaded spindle 16 even if the locking pin 18 is completely lost.

In the outward-facing end face of the drive section 22 of the drive part 19, an axial bore 29 is arranged through which, if the drive part 19 cannot be easily released from the spring tensioning device in the manner shown in Fig. 3, a screw can be screwed in to assist in the axial removal of the drive part 19.

List of reference symbols

1 clamping jaw holder

Clamping jaw holder

Spindle shaft

Clamping jaw

Clamping jaw

Spring mount

Coil spring

8 Housing

cone

10 Guide surface 11 Bore 12 Groove 13 Key 14 Sealing lip 15 Bearing bush

17 Coupling section

18 Locking pin

19 Drive part

20 Coupling section

21 drive polygon

22 Drive section

23 Pressure sleeve

24 Front face

25 warehouses

26 Blind hole

27 Rubber ring

28 screw threads

29 Axial bore

16 Threaded spindle

Claims (8)

Protection claims 1. Threaded spindle drive for a spring tensioning device provided with two spring elements (4, 5) for receiving each one spring coil of a helical spring (7) to be tensioned, with a threaded spindle (16) which is rotatably mounted in a guide tube and additionally supported by an axial bearing (25) relative to the guide tube and which is provided with a coupling section in the area of its free end facing away from the threaded section (17) is provided, onto which a corresponding coupling section (20) of a drive part (19) provided with a drive polygon (21) is placed, wherein the two coupling sections (17, 20) are positively connected via a locking pin which passes through both coupling sections (17, 20) and shears off in the event of an overload of the threaded spindle drive (18) with the longitudinal axis arranged transversely to the axis of the threaded spindle, characterized, that the locking pin (18) has at least one predetermined breaking point in the form of a recess. 2. Threaded spindle drive according to claim 1, characterized in that two predetermined breaking points are provided in the form of a recess each, the two recesses being arranged opposite one another at the respective end of the locking pin (18). 3. Threaded spindle drive according to one of claims 1 and 2, characterized in that the recess is a blind bore (26) with a longitudinal axis lying parallel to the axis of the locking pin (18). 4. Threaded spindle drive according to one of claims 1 to 3, characterized in that the coupling section (17) is formed by a pressure sleeve (23) via which the threaded spindle (16) is supported axially relative to the guide tube (8), wherein the locking pin (18) passes through both the drive part (19) and the pressure sleeve (23) as well as a pin (9) of the threaded spindle (16) enclosed by the pressure sleeve (23). 5. Threaded spindle drive according to claim 4, characterized in that the pressure sleeve (23) is connected to the cylindrical pin (9) of the threaded spindle (16) via a screw thread (28). 6. Threaded spindle drive according to one of the preceding claims, characterized in that the drive part (19) has a circumferential groove in the region of the receiving bore for the locking pin (18). 7. Threaded spindle according to claim 6, characterized in that a rubber ring (27) is arranged in the circumferential groove. 8. Threaded spindle drive according to claim 7, characterized in that the inner diameter of the rubber ring (27) is equal to the length of the locking pin (18) CH/BK/wi