DE3213031A1 - Device for securing the spring ends of steel helical springs in spring bodies against lifting off - Google Patents

Abstract

In order to secure the spring ends of steel helical springs against lifting off, the ends of a spring (1) are mounted in an annular groove (3) in a spring plate (2) which is constructed as a housing. <IMAGE>

Description

PATENT LAWYERS

BERLIN-DAHLEM 33 ■ PODBIELSKIALLEE 80OO MUNICH 22 ■ Wl D E N M AVER STRAS S E 49

GERB Gesellschaft für Isolation mbH & Co. KG.

BERLIN: DIPL.-INQ. R. MÜLLER-BORNER

MUNICH: DIPL.-INS. HANS-HEINRICH WEY

D1PL.-ING. EKKEHARO KORNER

Berlin, April 02, 1982

Device for securing the peder ends of steel coil springs in spring bodies against lifting

9 pages of description with 8 claims 1 page of abstract

with Fig. 1
4 sheets of drawing

MB / Se - 2? 816

BERLIN: TELEPHONE (030) 8312-88 CABLE: PROPINDUS TELEX: 184-57

MUNICH: TELEPHONE (089) 225580 CABLE: PROPINDUS TELEX: 524244

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The invention relates to a device for securing the spring ends of steel coil springs in spring bodies against lifting.

The elastically cushioned storage of machines and units as well Whole structures, especially nuclear power plants, to protect against earthquake effects is state of the art today.

In addition to the effective (resilient) coils, helical compression springs have also ineffective (dead) end turns, which the external load as centrally as possible from the spring pads in the effective turns should be transferred. The possible shapes of the end turns, such as ends laid out and ground flat, ends laid out and unmachined, are standardized (DIN 2096 Jan. 1974). According to J.Ulbricht, H. Vondraczek and S. Kindermann, "Warm-formed springs, guidelines for construction and production", Self-published by Hoesch-Werke, Hohenlimburg 1973, there are other designs such. B. ends with hobbing and curled end turns.

In the case of the spring ends according to the standard, the springs are generally only prevented from transverse displacements by means of inner or outer centering rings secured. In rare cases the spring ends become flatter with the support welded, which, however, reduces the strength of the stainless steel due to structural changes significantly impaired. The other designs of the spring ends are mainly known from vehicle construction. At the end of the spring with a rolling form, the pitch of the end coil of the spring is used to "screw it onto a spring plate with an external thread".

In the case of the curled end of the spring, the curled part is with the help

an attached washer and a screw connected to the spring pad. With clamping pieces distributed around the circumference, spring ends designed according to standards can also be held in place. However, these designs are not suitable for securing the spring against transverse loading because of the End turns local voltage peaks would occur. In vehicles, for example, the sole vertical load is caused by corresponding transverse and trailing arm reached. An earthquake-proof installation of buildings can not move for all movement under such restrictions for the spring f series its grade to be realized.

Known calculation methods, see e.g. earthquake protection of buildings according to DIN 4149 (Chapter 3: O. Henseleit, "Calculation method") January 1979, Stuttgart, for the earthquake-proof design of elastic Systems show that the vibrational response under earthquake excitation u depends, among other things, on the natural frequency of the oscillatory system. In relation to the elastically damped mounting of buildings, this is the case the relationship between the natural installation frequencies and building movements in the event of an earthquake. It is generally true that with decreasing Natural frequency, the deflection amplitudes become larger, but the acceleration amplitudes decrease. This effect comes about because the insulating function of low-frequency systems is the high-frequency and dam acceleration-intensive area of excitation suppressed, but at the same time the low-frequency range of small acceleration and large Path amplitudes may even be increased.

Since the loads on the structure and on fixtures from the 'mass forces'n and consequently from the accelerations on the system, their elastic supports are laid out for both the vertical and the horizontal

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zontal direction to low natural frequencies. Because of mostly larger horizontal component of the earthquake excitation, the horizontal storage frequency is chosen smaller than the vertical one. Man accepts large displacement oscillations overall in order to keep the seismic loads small.

All three Direction of space applied highly elastic and damping spring bodies. As an elastic element are in the spring bodies under other steel coil springs are used. The dimensioning of the steel coil spring to a low vertical natural frequency requires large spring travel and therefore high springs. The additional requirement that the horizontal number of springs should be smaller than the vertical one leads to one slim feather.

If you load steel coil springs in the longitudinal and transverse direction, so longitudinal and transverse displacements are obtained according to the number of springs the feather attack surfaces. For each movement, the applied forces generate a proportional shear stress in the wire cross-section, which leads to a Total shear stress can be summarized as the stress on the material.

The theoretically possible longitudinal and transverse deflections of the spring depend thus about the loading of the permissible shear stress of the spring material away. The practically possible transverse deflections are against it by tilting the spring, which is noticeable in the lifting of the spring ends from the sub-surfaces, has already been achieved. The admissible The spring travel up to the beginning of the tilting process decreases with increasing

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tical preload of the spring. So little loaded springs tip over rather, so that the transverse load cannot be reached up to the permissible material stresses.

The invention is therefore based on the task of making the range more possible To expand transverse deflections of the springs.

This task is fiction according to the characterizing part of the main claim specified means resolved.

Developments of the invention are given in the sub to Proverbs η.

Details, applications, and advantages of the invention are provided below based on exemplary embodiments of the subject matter of the invention shown in the drawing described in more detail. Show it:

Fig. 1 is a schematic representation of the que out steered spring

with cast spring plates,

Fig. 2 possible shapes of the annular groove for potting in one and

several ring grooves,

3 shows a spring body with releasable and non-releasable potting spring plates, and

Fig. 4 mounting options on the spring plate for biasing the

Individual springs or groups of springs.

Fig. 1 shows an upper and a lower spring plate in which the spring should be potted. It consists of a housing 2 which is provided with an annular groove 3. The ring groove should be at least the same depth the wire diameter of the spring. The end turn of the spring is inserted into the groove and with a material 4 so with the spring parts shed that a material connection between the spring and Federtellej comes about. The material connection is designed in terms of its strength so that it absorbs the clamping moments and transverse forces of the spring during transverse deflection 16 can accommodate the spring ends.

For the casting material, plastics, building materials and low-melting metals or metal alloys that do not change the structure can be used Cause spring material are used.

As FIG. 2 shows, the annular groove can have a rectangular cross section 5 or for an additional form fit z. B. have a trapezoidal cross-section or T-shaped cross-section 7.

One or more annular grooves can be made in a spring plate will. The ring grooves can have different diameters, widths and depths and are concentric for outer and inner springs (set springs) be arranged next to one another or next to one another in the case of individual springs.

Can springs, as shown in Fig. 3, with a molded spring plate detachable with the shells 8 of a spring body, e.g. by screwing 9, or permanently connected, e.g. by welding seams 10.

Additional devices can be provided on the spring plates,

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which allow individual springs to be used on spring bodies in operation
to replace. As examples, cross bores 11 for receiving a retaining clip 12 or threaded bores 13 for threaded rods 14 with turnbuckles 15 are executed in FIG.

By pouring the spring ends into the spring plates and fastening the spring plates in the upper and lower spring body shells, it becomes
It is possible to build highly elastic spring bodies with steel coil springs for large horizontal deflections with material stresses up to the permissible material stresses in all three directions of the room. This also shows the high economic value of the invention.

MB / Se - 27 816

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Claims (8)

Patent claims Device for securing the spring ends of steel coil springs in spring bodies against lifting, characterized in that the ends of a spring (1) in one housing-like, with an annular groove (3) provided spring plate (2) are attached. 2. Device according to claim 1, characterized in that the spring ends for the purpose of fastening in the annular groove (3) are shed. 3. Apparatus according to claim 1 or 2, characterized in that the annular groove (3) is adapted to the geometry of the spring end, wherein the groove depth is at least equal to the wire diameter of the spring (1). BERLIN: TELEPHONE (O3O) 8312O88 CABLE: PROPlNDUS TELEX: 1 84O57 MUNICH: TELEPHONE (O89) 22558S CABLE: PROPINDUS TELEX: 524244- 4. Apparatus according to claim 1 or 2, characterized in that the groove cross-section is rectangular, trapezoidal or T-shaped. 5. Device according to one of claims 1 to 4, characterized in that the spring plate (2) is provided with more than one annular groove (3) for receiving springs (1). 6. Device according to one of claims 1 to 4, characterized characterized in that the spring plate (2) can be detachably or non-detachably connected to the spring body shells. 7. Device according to one of claims 1 to 6, characterized in that the spring plate (2) with additional devices are equipped to preload individual springs (1) or groups of springs. 8. Apparatus according to claim 2, characterized in that the casting materials are plastics, building materials or low Melting metals and metal alloys are provided. - · 27 816