RU2275270C1 - Compression spring producing method - Google Patents

Abstract

FIELD: manufacture of helical compression springs operating at impingement of their turns in condition of elevated temperatures.

SUBSTANCE: after coiling spring with pitch exceeding pitch of ready spring, the last is subjected to heat treatment and shot-blast hardening. Then spring is compressed by action of axial load consisting of 10 - 300 F₃ where F₃ - spring force at maximum deformation. It is possible to perform secondary compression of spring by action of load increased in proportion to relation of target camber to camber value caused by first load. Spring may be subjected to action of vibration loads. In order to satisfy high demands made to force parameters of spring the last is dressed after twisting and ends of spring are ground and chamfered.

EFFECT: possibility for making springs with accurate and stable in time elastic characteristics.

4 cl

Description

The invention relates to methods for manufacturing helical compression springs, working with collisions of coils, from ordinary, hardened or polished wire before winding. It can be used in the manufacture of springs operating both at ordinary and at high temperatures.

There is a method of manufacturing vehicle suspension springs with a favorable distribution of residual stresses over the coil section obtained as a result of plastic precipitation by tearing, which is performed by compressing the spring with a maximum deformation force of F ₃ for 6- ÷ 48 hours, and shot blasting [1]. This method increases the service life and increases the strength of the spring, but it is applicable only for the manufacture of springs with a large diameter of the coil section (for suspension springs with a diameter of d≥12 mm), since the influence of hardening on load relaxation is negligible. In addition, this method is not suitable for the manufacture of springs working with collisions of coils: during the operation of a vehicle, collisions of coils occur and, due to contact reactions, the spring loses its height and force parameters.

For the same reason, the manufacturing method [2] of VAZ car suspension springs is also unsuitable: winding, heat treatment, shot blasting, cold sludge by triple compression, applying a protective coating. The cold draft used in this case by short-term triple compression of the spring with the maximum deformation force F _{3 is} usually used to eliminate the unevenness of the pitch of the coil of the spring and some stabilization, including to check for cracks and the quality of the previous operations. According to the magnitude of the change in the height of the springs that occurred, it is supposed to judge the quality of the technological process. But due to insufficient time to stabilize the precipitation — 6–48 hours is recommended — this method does not guarantee the stability of the suspension springs and does not give a complete picture of the quality of the springs.

A known method of manufacturing highly loaded compression springs, including coil springing, heat treatment, grinding of the ends, shot blasting, heat shrinkage and triple cold draft, characterized in that the heat shrinkage is carried out at a temperature of 200 ÷ 250 ° C [3]. The method is as follows. A spring-strengthened wire feed machine is fed to the spring-winding machine and the spring is wound in increments greater than the pitch of the finished spring. Then, the furnace is tempered at a temperature of 410 ° C. Further, the ends are grinded in heat-treated springs. After 100% light control and washing, a shot-blasting hardening is carried out on a chamber-type shot-blasting machine and subsequent heat shrinkage by the maximum deformation force F ₃ at a temperature of 240 ° C in a special furnace. Then, after washing and triple precipitation, the chamfers at the two ends of the spring are removed according to the requirements of the drawing. Recent operations are phosphating, preservation and packaging. With this sequence of technological operations, the magnitude of relaxation of load when zealing for 48 hours at a temperature of 130 ° C is 2 ÷ 4%.

However, this method has disadvantages. It is not suitable for springs operating in a dynamic mode with collisions of coils due to the occurrence of contact reactions in the coils, leading to premature settling of the springs and loss of geometric and power parameters. Moreover, grinding of the coils and chamfering at the ends of the springs after heat treatment violates the structure of the material of the springs created by heat treatment, which reduces their quality - these operations should be performed before heat treatment. And the so-called triple draft of the springs due to insufficient time to stabilize the draft does not guarantee the quality of the spring. Therefore, this method, as described above, is not acceptable for springs working with collisions of coils. However, the presence in it of some operations and the order of their execution allows us to take it as a prototype.

The technical result to which the invention is directed is to develop a technological process that allows to improve the quality of manufacturing springs with accurate and stable over time elastic characteristics when working springs with collisions of coils.

The technical result is achieved due to the presence of new operations of the technological process and their new sequence, namely: the essence of the invention lies in the fact that the method of manufacturing compression springs, including winding the spring with a step greater than the step of the finished spring, heat treatment, shot blasting, characterized in shotblast that after hardening, the step of pressing an axial load spring 10 ÷ 300 F _3, F _3, where - the spring force at maximum deformation, and compact re-load, is proportional increased with respect to the desired rainfall sediment from the application first loads. In this case, the load can be vibrational. Upon reaching a predetermined spring height, re-pressing is not necessary. With increased requirements for the power parameters of the spring after winding, dressing and grinding of the ends with the removal of bevels on them.

Thanks to the pressing operation, plastic spring hardening takes place: a favorable stress state is created on the surface and inside the spring coils, which counteracts the occurrence of precipitation during the spring operation, and the use of the proportional application of the load method [4] ensures the accuracy of spring production in height and load. The load application time is seconds or fractions of a second. For a more uniform distribution of the load over the cross section of the coil of the spring, it is applied vibrationally [5].

The determination of the allowance for the draft of the spring and the load is known and covered in the literature: the allowance should be greater than the sum of the allowance for draft in the above technologies and the draft during operation of the spring in the product - approximately 1.5 allowances for normal regrowing, and specified by testing the springs [6].

When implementing the proposed method, the resistance of the springs is increased by 1.5 ÷ 2 times relative to the springs made using the above methods.

The method is as follows. A conventional, hardened or polished wire is fed to the spring-winding machine and the spring is wound with a step exceeding the step of the finished spring. They perform heat treatment of the springs — quenching and tempering, and carry out shot-blasting hardening. After the shot-blasting hardening, the operation of pressing the spring with an axial load in the range of 10–300 F ₃ and repeated load, increased in proportion to the ratio of the required draft to draft from the application of the first load, is performed. Then - applying a protective coating and measuring the parameters of the spring, preservation and packaging. In the manufacture of springs that are especially accurate in terms of power parameters, after winding, they are corrected and the ends are ground with chamfering.

Note: heat treatment of a spring means its hardening with subsequent tempering in accordance with the conditions adopted for a particular brand of spring steels [7].

Information sources

1. Patent EP 0645462 A1, CL C 21 D 9/02, 03/29/95.

2. Semakov V. About the variety of models of suspension springs for VAZ automobiles, their production, operation and interchangeability // At the wheel. 1998. No. 5, p. 244-245.

3. Patent RU 2208056 C2, C 21 D 9/02, 02/08/2001.

4. A.S. USSR 554915, M.cl. B 21 F 35/00, 07/10/07.

5. A.S. USSR 580474, M.cl. G 01 M 13/00, B 21 F 35/00, 1976.

6. Zemlyanushnova N.Yu., Tebenko Yu.M. Improving the quality of the springs. Stavropol: SevKavSTU, 2001, 93 p.

7. Rakhstadt A.G. Spring steel and alloys. M.: Metallurgy, 1982, 400 p.

Claims (4)

1. A method of manufacturing compression springs, including winding the spring in increments greater than the pitch of the finished spring, heat treatment, shot blasting, characterized in that in order to achieve spring stability and reduce height deviations after shot blasting, the spring is pressed by an axial load within 10-300 F ₃ , where F ₃ - spring force at maximum deformation. 2. The method according to claim 1, characterized in that a repeated load is applied to the spring, increased in proportion to the ratio of the required draft to draft from the application of the initial load. 3. The method according to claim 1 or 2, characterized in that the load is applied vibrationally. 4. The method according to claim 1 or 2, characterized in that after winding, the spring is straightened and its ends are polished with chamfers removed.