EP3568264A1

EP3568264A1 - Tensioning device for tensioning a helical spring

Info

Publication number: EP3568264A1
Application number: EP18701674.6A
Authority: EP
Inventors: Andreas Heiko GRUNER
Original assignee: Individual
Current assignee: Individual
Priority date: 2017-01-13
Filing date: 2018-01-10
Publication date: 2019-11-20
Anticipated expiration: 2038-01-10
Also published as: WO2018130548A1; JP2020505245A; HRP20201807T1; US11148267B2; EP3568264B1; US20190358797A1; DE102017100581A1

Abstract

The invention relates to a tensioning device (01) for tensioning a helical spring (02), which is mounted on a main shaft (03) and, at a fixed end, is rotationally connected to a frame. The tensioning device (01) comprises a gear drive (05) and a holding element (19) which holds a second gear element (11) in the position of driving engagement with a first gear element (06). The tensioning device (01) further comprises a drive element. The gear drive is a bevel gear transmission, wherein the first gear element (06) is a bevel gear (06) and the second gear element (07) is a bevel gear pinion (07), and the rotational axes of the two gear elements (06, 07) extend perpendicularly to one another. The bevel gear (06) is integrally connected to a guide bushing (10); it has a central opening (09) through which the main shaft (03) extends, and a cylindrical accommodating section (12) in which the free end of the helical spring (02) is fixed.

Description

Clamping device for tensioning a coil spring

The present invention relates to a tensioning device for tensioning a coil spring, which acts as a torsion or torsion spring, wherein for tensioning the spring whose both ends

be twisted to each other, so that the spring in one

stressed state has an altered axial length compared to their relaxed state. Such tensioned coil springs serve, for example, the

Drive support of sectional doors. Sectional doors consist of several door sections that are foldably connected to each other and each have one or more run in the front rails rollers. To raise and lower the sectional door is a drive shaft which is connected to a drive, usually an electric motor. Coil springs are attached to the drive shaft. The spring force of the coil springs counteracts the self-weight force of the door to assist the rotation of the drive shaft and to relieve the electric drive. The coil spring is fixed to the drive shaft. The tension of the

Coil spring takes place during assembly by introducing a torque at the non-rotatably mounted end of the coil spring, so that the spring can be tensioned and the spring is secured in the tensioned state on the drive shaft. Due to the required large forces or moments, a supporting device for tensioning the spring is necessary. From the prior art, various devices for

Clamping springs known. In DE 10 2014 013 449 AI a strut tensioner for replacing a spring or a shock absorber of a shock absorber of a motor vehicle is described. The spring tension is achieved by two cross in the interior of the coil spring

Horseshoe-shaped spring holder of the eccentric to the spring

arranged strut clamps which move towards each other by pressing a spindle arranged on the spring strut tensioner. Thereby, the axial offset, which has each wire circumference at both ends, is reduced, which leads to the tension of the spring.

DE 10 2013 101 083 AI is concerned with an auxiliary tool for mounting a shock absorber comprising a holding assembly and a drive assembly. The auxiliary tool has a thread feed and is arranged coaxially with the spring to be tensioned. With the help of a rotary element Hilfswerk ^¬ stuff is manually rotated about the axis of rotation. The spring is relaxed or relaxed by changing the axial offset of the wire circumference.

DE 20 2012 005 626 U1 describes a pressure plate for a spring tensioner which is used to tension a coil spring of a spring shock absorber leg accommodated between a lower and an upper spring plate. The pressure plate is on the upper spring plate for the axial support of holding elements

attached, wherein the holding elements with the spring coils of the coil springs are engageable.

DE 20 2011 050 354 Ul relates to a clamping plate for a spring tensioner and spring tensioner for mounting and

Dismantling of helical compression springs, in particular on sprung running gears. In this case, the clamping plate to a contact surface for Receiving a spring segment over which an upsetting force in the axial direction can be applied to the suspension spring.

US 7,909,305 B2 describes a strut removal device. It comprises two compacting plates, which are formed so as to have a fastening region with which they are connected to a driving threaded section. Furthermore, each compressor plate has a device which is adapted to engage in a respective first coil of a

Coil spring is formed. The device is drivable with a manually generated torque.

The tensioning devices described above generate a force acting axially on the spring, without a torque acting on the spring to be clamped.

DE 10 2012 104 673 B3 relates to a tool, system and method for screwing usually two helical compression springs into a single helical spring. On the tool used for this purpose handles are out ^¬ forms, which serve to operate the tool.

US 3,651,719 teaches a torsion spring adjustment tool for overhead doors. With him, the tension of

Torsion springs vary. The tool has a split

Clamping device and can be brought into engagement with the adjustable sleeve anchor. For this purpose, circumferentially spaced rounded teeth are formed. To introduce a torque in the tool handle portions for manual operation of the tool are formed.

A disadvantage of the solutions according to DE 10 2012 104 673 B3 and US 3,651,719 is that the devices by hand must be operated. For springs that are designed for use as Torgewichtsausgleich sectional doors, much muscle power is required for tensioning the coil spring with the known devices. Due to the cramped installation situation, the aids must also be used again and again during clamping. The installation position

further requires that the operator during the

Tensioning the spring must take an ergonomically unfavorable posture. This approach leads to a not to be underestimated endangerment of the operator until the

Torsion spring can be secured in a tight end position. In some cases, it is necessary for two people to do the torsion spring installation at the same time. US 3,921,761 A describes a method and a

Device for winding torsion springs. The device comprises a torsion spring, which is fastened with a first end to a support means. A second end of the

Torsion spring is rotatable relative to the first end.

Furthermore, the device comprises a gear and a rotatable worm gear, wherein the transmission has at least one rotatable by the worm gear transmission part. The worm gear is connected to a stationary component via a support plate, which is movable relative to the gear part and the worm gear in

Holding position. Furthermore, the device has a

Drive element in the form of a cordless screwdriver or an electric motor. An object of the present invention is based on

The prior art is that tensioning coil springs less muscular and less dangerous to shape. In addition, a possible damage z. B. of

Tors be prevented when tensioning the spring.

This object is achieved by a tensioning device according to the invention for tensioning a helical spring according to the

attached claim 1.

The tensioning device according to the invention serves for tensioning a coil spring, which is mounted on a main shaft. At one end is the coil spring with a frame or

Housing part in which a bearing block is fixed

connected. The tensioning device comprises a

Toothed drive. The gear drive comprises a first gear element and a second gear element. The first transmission element is axially displaceably guided on the main shaft and rotatably connected to a free end of the coil spring. The second gear member is in driving engagement with the first gear member, d. H. the second

Transmission element drives the first gear element and puts this in rotation about the main shaft. Due to the rotationally fixed connection of the coil spring at its fixed end to the frame, the coil spring upon initiation of a torque on the with the first transmission element

connected end stretched or relaxed.

The clamping device further comprises a holding element. The holding member holds the second gear member during the clamping operation in the position of the drive engagement with the first transmission element.

The tensioning device further comprises a drive element. The drive element is on the second transmission element preferred releasably coupled to enable this for the clamping operation in rotation.

The advantages of the invention are to be seen in particular in that the clamping device for clamping by a single

Person is operable and less force must be applied by the person. This increases the safety when preloading large coil springs and it will

cheaper, faster and easier to install the coil springs with the required preload.

The gear drive of the inventive clamping device is designed as a bevel gear. So that's the first one

Gear element as a bevel gear and the second

Gear element formed as a bevel pinion. The

The axis of rotation of the first gear element and the second gear element are perpendicular to each other. The axis of rotation of the main shaft is preferably coaxial with

Rotary axis of the first transmission element arranged.

Perpendicular to this is a guide pin to the axis-centered

Storage of the bevel pinion arranged. The bevel gear has a central opening, which serves to carry out the main shaft. A central opening of the bevel pinion is used for

Recording of a guide pin and can by a

Through hole to be formed. Thus, a drive shaft, one end of which is designed as a guide pin, can be arranged in the axial passage opening of the bevel pinion.

The bevel gear is connected to a guide bush. The

Guide bush is guided axially displaceable on the main shaft, so that the guide bush is axially displaceable together with the bevel gear on the main shaft. At its outer periphery the guide bush has a guide groove. In the

Guide groove is mounted on the guide pin of the bevel pinion.

The bevel gear is integrally connected to the guide bushing. On its side facing away from the guide bush axially, the bevel gear has a cylindrical receiving section. At this receiving portion, the free end of the coil spring is rotatably mounted. The coil spring is attached to the on ^¬ acquisition portion for example by welding or riveting. The coil spring can be in another

Embodiment releasably secured to the receiving portion, for example, by being screwed. The non-rotatable

Connection of the coil spring to the receiving portion

transmits a torque acting on the bevel gear on the coil spring. Depending on the direction of rotation and the starting position of the

Coil spring biases the impressed torque

Coil spring or relax it. The occurring

Change in the axial extent of the spring causes the position of the free end of the coil spring along the main shaft between a cocked and a relaxed

End position shifts. The bevel gear, which is connected to the coil spring, so also moves between these two end positions on the main shaft. Since the bevel gear for tensioning or relaxing the coil spring with the bevel pinion in

Actuator is engaged, it is necessary that the bevel pinion engages well with the bevel gear and is moved with this. For this purpose, the tensioning device has the retaining element.

The holding element preferably comprises a bracket and a pressure plate connected to the bracket. The bracket is the guide ^¬ bushing and the bevel pinion encompassing attachable. The pressure ^¬ plate is preferably positioned to a holding force in the axial direction on a side facing away from the guide bushing and Imprint perpendicular to the axis of rotation arranged bottom surface of the bevel pinion. As a result, the guide pin on which the bevel pinion is mounted, in the guide of the

Guide bush of the bevel gear pressed. Thus, during tensioning or relaxing of the coil spring, the bevel gear remains engaged with the bevel pinion.

It is also advantageous to arrange a first counterpart between bracket and guide bushing. A second counterpart is placeable between the pressure plate and the bottom surface of the conical ^¬ pinion. The counterparts support a uniform introduction of the holding force by the holding element by sufficiently large contact surfaces form sufficiently large contact areas between the holding element and between the transmission elements. The counterparts preferably have a shape adapted to the geometry of the retaining element and the geometry of the gear elements and are formed from durable materials with regard to the acting forces. In a preferred embodiment, the drive element is formed as an electric motor. On a motor axis of the Elek ^¬ tromotors the second gear element, that is, conical ^¬ pinion mounted. Particularly preferred as well as expedient is the end of the motor axis, on which the second gear element is arranged, as a guide pin for the storage of

Bevel pinion trained. In the simplest case comes as

Drive element a hand drill or a cordless screwdriver into consideration. A preferred embodiment of the clamping device is characterized in that it further comprises locking elements. With the locking elements, the first gear member on the main shaft is rotatably fixed. A locking element can be For example, a wedge, a pin, a screw, a bolt or the like. To lock, for example, a groove in the main shaft is arranged and corresponding thereto at least one passage opening in the first gear member.

Each of the through openings preferably extends in sections radially circumferentially along the outer circumference, in the region of the guide bushing of the bevel gear, in the cylindrical receiving portion of the bevel gear or the bevel gear itself. The through holes are formed for example by holes or slots, and are used to carry out a

Locking element.

According to an expedient embodiment, the second is

Gear member detachably mounted on the first transmission element, so that the drive engagement can be canceled. To the second

To give free transmission element, preferably the bracket and the pressure plate, so the holding element, releasably attached to the

Tensioning device attached. By loosening the

Holding element eliminates the impressed on the bottom surface of the bevel pinion holding force. This dissolves the

^Guide pin of the second gear element of the guide ^¬ groove of the first gear element, so that the second gear ^¬ element is removable. The bracket is detachably connected to the pressure plate, for example by screws.

Further advantages, details and developments of the invention will become apparent from the following description of a preferred embodiment, with reference to the

Drawing. Show it:

1 shows a side view of a tensioning device according to the invention for tensioning a helical spring; 2 shows a front view of the clamping device with a holding element.

Fig. 1 shows a side view of a clamping device according to the invention Ol for tensioning a coil spring 02, which is guided on a main shaft 03. Not shown is the area in which the coil spring 02 with a fixed end rotatably connected to a housing part or a frame (not shown) is connected.

The tensioning device comprises a gear drive, which is formed by a first gear member 06 and a second gear ^¬ element 07, wherein the first gear member 06 are formed as a bevel gear and the second gear member 07 as a bevel pinion. The axis of rotation of the

Bevel gear 06 is perpendicular to the axis of rotation of the conical ^¬ pinion 07th

The bevel gear 06 is guided axially displaceable on the main shaft 03. 06 for the bevel gear has a first axial ^¬ hole 09 through which the main shaft runs 03.

The bevel gear 06 is connected at its side remote from the coil spring 02 side with a guide bush 10. The guide bush 10 is preferably integrally formed on the bevel gear and has a guide groove 11. The guide groove 11 is formed radially encircling. The directed to the coil spring side of the bevel gear 06 has a cylindrical receiving portion 12. Both in the guide bush 10 and in the receiving portion 12, the passage opening is set

09 continues. On the receiving portion 12 a rotatable during the clamping operation against the main shaft 03 end of the coil spring 02 is fixed, so that when the first gear member 06 rotates, a torque in the coil spring 02 transmits. Depending on the direction of rotation of the first gear element 06, the impression of the torque leads to clamping or

Relax the coil spring.

The bevel pinion 07 has a second axial passage opening 14. The second through hole 14 serves to receive a drive shaft 15, which at one end with a

electric drive (not shown) is formed out ^¬ forms and the free end is formed as a guide pin 16. The drive shaft 15 is rotatably connected to the bevel pinion 07 and transmits torque from the electric drive to the bevel pinion 07. The guide ^¬ pin 16 of the bevel pin 07 is arranged to guide the bevel pinion 07 in engagement with the bevel gear 06 in the guide groove 11. Bevel pinion, drive shaft and guide pin may alternatively be integrally formed.

Fig. 1 further shows a first counterpart 17 which is applied to the guide bushing 10 and one inside

having directed portion which engages in the guide groove 11. The contact surfaces of the counterpart 17 are

designed sufficiently large to sufficiently large contact ^¬ areas between a holding element 19 (Fig. 2) and the

Guide bush 10 to form. Fig. 2 shows a front view of the clamping device 01 with the holding element 19. The holding member 19 includes a bracket 20 and a pressure plate 21. The bracket 20 engages around the guide ^¬ socket 10 and the bevel pinion 07. The pressure plate 21 is on arranged the bottom surface of the bevel pinion 07. The bracket 20 and the pressure plate 21 are preferably releasably attached to release the bevel pinion 07. By the holding member 19, the bevel gear 06 engaged with the bevel pinion 07 in the drive is, in particular, when the bevel gear 06 along the main ^¬ wave 03 changes its position between a tensioned and relaxed position.

The drive engagement between the bevel gear 06 and the bevel pinion 07 can be canceled as soon as the retaining element 19 is released and thus no holding force acts on the bevel pinion 07 and the guide bush 10 of the bevel gear 06. The releasable Ver ^¬ bond can be formed for example by screws. Fig.2 also shows the drive axle 15 through the second

Passage opening 14 of the bevel pinion 07 extends and is guided in the guide groove 11. At the end of the drive shaft 15, which is arranged in the guide groove 11, the drive ^¬ shaft 15 is designed as a guide pin 16.

Furthermore, Fig. 2 shows that in addition to the first counterpart 17, a second counterpart 23 is arranged. The two counterparts 17, 23 are axially spaced with respect to the drive axis 15, arranged opposite one another, wherein the second counterpart 23 between the bottom surface of the bevel pinion 07 and the pressure plate 21 of the holding element 19 is arranged. The contact surfaces of the second counterpart 23 are formed sufficiently large to sufficiently large contact areas

between the holding element 19, in particular the pressure plate 21, and the bottom surface of the bevel pinion 07 to form. LIST OF REFERENCE NUMBERS

- Clamping device

- coil spring

- Main shaft

- - - bevel gear

- bevel pinion

- - first passage opening

- Guide bush

- Guide groove

- Recording section

- - second passage opening

- Drive shaft

- guide pin

- first counterpart

- - Holding element

- Hanger

- Printing plate

- - second counterpart

Claims

claims

1. Clamping device (Ol) for tensioning a coil spring

(02), which is mounted on a main shaft (03) and with a fixed end against rotation with a frame or

Housing part is connected, wherein the clamping device (01) comprises:

a gear drive, with a first gear ^¬ element (06), which is axially ^¬ slidably guided on the main shaft (03) and rotatably connected to a free end of the coil spring (02), and with a second transmission element (07), which with the first gear member (06) is in driving engagement to set the first gear member (06) in a rotation about the main shaft (03);

a holding member (19) which holds the second gear ^¬ element (07) in the position of the drive engagement with the first transmission element (06);

a drive element which is coupled to the second gear ^¬ element (12) to enable this in rotation;

characterized in that

the gear drive is formed as a bevel gear, wherein the first gear element (06) as a bevel gear (06) and the second gear element (07) as a bevel pinion (07) are formed, and wherein the axes of rotation of the two gear elements (06, 07) perpendicular to each other run;

the bevel gear (06) is integrally connected to a guide bushing (10) which is axially displaceably guided on the main shaft (03) and has on its outer circumference a guide groove (11) in which a

Axial guide pin (16) of the bevel pinion (07) is mounted, wherein the guide pin (16) rotatably connected to the bevel pinion (07) is connected;

the bevel gear (06) has a central opening (09), through which the main shaft (03) extends, and on which the guide bush (10) axially facing away from a cylindrical receiving portion (12), in which the free end of the coil spring (02 ) is attached.

2. Clamping device (01) according to claim 1, characterized

in that the holding element (19) and comprises a bracket (20) connected thereto, the pressure plate (21), wherein the bracket (20) engages around the guide bush (10) and the cone ^¬ pinion (07), and wherein the pressure plate ( 21) is positioned to impress in the axial direction a holding force on the bottom surface of the bevel pinion (07), so that the guide pin (16) is pressed into the guide groove (11).

3. Clamping device (01) according to claim 1 or 2, characterized

characterized in that the drive element by a

Electric motor is formed on the motor axis, the second transmission element (07) is mounted.

4. Clamping device (01) according to one of claims 1 to 3, characterized in that it further comprises a locking ^¬ element, with which the first gear element (06) on the main shaft (03) can be rotationally fixed.

5. Clamping device (01) according to one of claims 1 to 4, characterized in that the second transmission element (07) is releasably attached, so that the drive engagement can be canceled.

6. Clamping device (oil) according to claim 5, as far as this is based on claim 2, characterized in that the bracket (20) and the pressure plate (21) are releasably attached to release the second transmission element (07).