SU860926A1 - Apparatus for winding and training helical springs - Google Patents

Description

one

The invention relates to the field of winding spiral springs and can be used in instrument making ..

At present, machines are used for winding spiral springs mechanically on special trimmers. After winding, the springs are recovered, i.e. they are left in the wound state for several hours, then the springs are heat treated. The disadvantages of these machines are the long cycle of manufacturing the spring, as well as the need for special mandrels for each type of spring. These deficiencies are mainly determined not by the machine design, but by the winding method.

A machine for winding and re-winding spiral springs is known, which allows winding the spring onto a special mandrel representing. a cylindrical body 1. The mandrel is enclosed in a cylindrical drum coaxial with it, having a window for supplying wound wire. The drum protects the spring from opening after the end of the winding, in it it is kept for the necessary time.

Despite a number of advantages, this machine has all the drawbacks inherent in mechanical methods of winding, and just because of the need for special mandrels and a long spring production cycle.

The aim of the invention is to increase the performance of the device.

5 The goal is achieved by the fact that in the device for winding and zevolivanie, containing a means for winding and zavolivanie, the latter consists of a horseshoe magpire with a movable part for

10 changes in the air gap, bias winding placed on the magnetic core, and two clamps with current leads; one of which is fixed at one of the ends of the magnetic circuit in the center of its cross section, while the movable part of the magnet has an axial channel, and the current lead of the second clamp is freely placed in the channel of the magnetic circuit.

20 In FIG. 1 shows a general view of the device; in fig. 2 is a view A of FIG. one; in fig. 3 is a section BB in FIG. 2

The proposed device uses the effect of coagulation in a spiral spring 25 under the action of the magnetoelectric forces of a rectilinear conductor with a current placed in a magnetic field in case one end of the conductor is rigidly fixed 30 and attached to the other.

The described device consists of a fixed horseshoe-shaped magnetic core 1 and a cylindrical base magnetic core 2. The base magnetic core can freely move along the aperture of the fixed magnetic core. This is done in order to facilitate the filling of the wire to be rolled up by lifting the moving part of the magnetic circuit. Movable and stationary magnetic cores are made of a material having a high magnetic permeability.

The bias winding 3 is designed to create a magnetic flux F in the air gap. connected to the source terminal of nostr nvdgo .- voltage. The current lead 6 is freely suspended by a flexible conductor 8 connected to a terminal of a constant voltage source. The flexible conductor passes through a hole in the movable magnetic core and is in the lowered state in order to provide minimal mechanical resistance when winding the helix. In order to clamp the wire piece 4, it is necessary to insert its end with an effort into the wedge slot of the collet conductor (see Fig. 3).

The device works as follows.

First clamp the wire segment in the collet current leads. To facilitate this process, the movable part of the magnetic circuit is raised to the upper position. After the wire is clamped, the movable part of the magnetic circuit is lowered, and the air gap in the magnetic core becomes minimal. This is done in order to obtain the maximum magnetic flux Φ at low currents in the bias winding. If a direct current is passed through this winding, then a magnetic field of a certain direction arises in the air gap of the magnetic core, having induction B. If a direct current / is passed through conductor 4 placed in this magnetic field, then each element of length D2 of the conductor will act the force q according to the rule of the "left hand, i.e. AZ - / - 5.

Under the action of a uniformly distributed load, the original straight-line segment of the conductor 4 is rolled up into a coil spring. As the conductor deforms, the load q will continue to act along the normal to the elastic line. The configuration of the spring will depend on the rigidity of the conductor, the current strength in it, as well as the magnitude and distribution of the magnetic zero in the air gap of the magnetic circuit.

If we reduce induction B, but at the same time increase the current in the conductor by the same amount, the spring geometry will not change. By increasing the current, the nconductor will begin to heat up. At sufficiently high currents, the conductor can be heated to the temperature of plastic deformations, and the process of thermal springing of the spring will occur. Using high temperature, it is possible directly in the process of winding to produce heat treatment (for example, hardening of the spring). Technical and economic efficiency

The proposed device consists in the absence of special mandrels required for mechanical winding methods, as well as a reduction in the duration of the spring production cycle. Besides,

It is possible to obtain springs of special configurations by varying the intensity of the magnetic field along the length of the conductor.

Claims (1)

1. USSR author's certificate No. 161329, cl. In 21F 35/00, 1964. 0 .l