DE1244958B - Magnetically controllable protective tube changeover contact - Google Patents

Description

Magnetically controllable protective tube changeover contact # The invention relates on a protective tube changeover contact, in which the changeover contact spring from a at least partially held from permanent magnet material existing break contact piece will. The break contact piece exists in the known protective tube change contacts mostly made of non-magnetic material, while the working contact piece is made of magnetizable Material. When the relay coil is excited, the changeover contact spring is switched from Normally open contact tightened; after the relay coil is de-energized, it returns to - their rest position back by spring force.

A protective tube contact relay is already known (US Pat. No. 2 264 022) in which the two counter-contacts that cooperate with the changeover contact spring are partially made of permanent magnet material. However, these permanent magnets serve to polarize the relay and not to reduce bouncing. Furthermore, a polarized protective tube changeover contact is known (German utility model 1819 078), in which a changeover contact spring is attached to a break contact piece made of permanent magnet material and is held by this in the rest position. With this design, in which there is no closed magnetic circuit between the normally closed contact piece and the changeover contact spring, and the small dimensions of the permanent magnetic normally closed contact piece, no noticeable reduction in bouncing is achieved and is not intended there.

The subject of the invention is a protective tube changeover contact of such a type Design that largely prevents the changeover spring from bouncing.

According to the invention this is achieved in that the normally closed contact piece so far formed from permanent magnet material and so next to the changeover contact spring is arranged that the permanent magnetic flux of the normally closed contact piece on the changeover contact spring closes inside the protective tube. This is despite relatively small Permanent magnet generates a magnetic flux of such magnitude that the bouncing is largely is prevented. This results in a greater possibility of using the protective tube contact in circuits of telecommunications technology as well as an increase in the service life of the contact. Furthermore, when the relay coil is energized, there is a magnetic repulsion effect between causes the normally closed contact piece and the changeover contact spring, whereby a lower Excitation power is required.

An advantageous structure of such a changeover contact results from the fact that the changeover contact spring and the working contact piece have end faces for making contact that run obliquely to the longitudinal direction of the protective tube. According to a further invention, a ferromagnetic contact material is applied to the surface of the break contact piece which makes contact with the changeover contact spring. Further details of the invention can be found in the description. An embodiment of the invention is shown in the drawing. The protective tube change contact consists of a flat protective tube 1, preferably made of glass, into which a working contact piece 2, designed as a flat spring and made of soft magnetic material, is melted. The connection end 3 of the working contact piece 2 is led out to one side of the changeover contact. A flat changeover contact spring 4, also made of soft magnetic material, is melted on the other side of the protective tube 1. It has a meandering part 5 which allows the contact end 6 to move. The changeover contact fields 4 and the working contact piece 2 have end faces 7 and 8, respectively, which run obliquely to the longitudinal direction of the changeover contact, for making contact with one another.

In addition to the changeover contact spring 4, the flat normally closed contact piece 9 is melted into the glass tube. At least part 10 of this contact piece consists of a permanent magnet material. The connection ends 11 and 12 of the normally closed contact piece 9 and the changeover contact spring 4 are led out of the glass tube on the side opposite the normally open contact piece 2.

In the rest position, the changeover contact spring 4 rests against the normally closed contact piece 9 by spring force, and the contact surfaces 13 and 14 touch one another. If the relay coil, not shown and pushed over the protective tube contact, is excited in the corresponding current flow direction, the changeover contact spring 4 is repelled by the permanently non-magnetic normally closed contact piece 9 and attracted by the normally open contact piece 2; the contact is made between the contact surfaces 7 and 8.

If the excitation of the relay coil ceases to exist, the contact piece 2 and the changeover contact spring 4 become non-magnetic again and the latter returns to its rest position by spring force. When it hits the normally closed contact piece 9 , the changeover contact spring 4 is held in place in addition to the spring force by the magnetic flux of the permanent magnetic normally closed contact piece 9 , and bouncing movements are largely slowed down as a result.

The excitation of the relay coil, not shown, can also be in the opposite direction Current direction take place at such a level that the between the normally open contact piece and the switching contact spring running between the latter and the magnetic flux the normally closed contact piece predominating permanent magnetic flux, so that here too, as with opposite excitation, switching the protective tube changeover contact he follows.

A contact material can be applied to the contact surface 14 of the normally closed contact piece 9 , a ferromagnetic contact material being used to avoid a non-magnetic gap between the normally closed contact piece and the changeover contact spring.

Claims (2)

Claims: 1. Magnetically controllable protective tube changeover contact, in which the changeover contact spring is held by a break contact piece consisting at least partially of permanent material, characterized in that the break contact piece (9) is so far formed from permanent magnet material and so next to the changeover contact spring (4 ) is arranged that the permanent magnetic flux of the normally closed contact piece (9 ) closes via the changeover contact spring (4) within the protective tube (1). 2. Protective tube changeover contact according to claim 1, characterized in that the changeover contact spring (4) and the working contact piece (2) have end faces (7 or 8) for making contact which extend obliquely to the longitudinal direction of the protective tube. 3. Protection tube change contact according spoke 1, characterized in that a ferromagnetic contact material is applied to the switching contact spring (4) making contact with the surface (14) of the break contact piece (9). Considered publications: German utility model No. 1819 078; U.S. Patent No. 2,264,022; Bell laboratory. Record, May 1963, pp. 200 to 202.