DE2139556A1 - PROTECTIVE TUBE ANCHOR CONTACT - Google Patents

Description

Protective tube armature contact The invention relates to a protective tube armature contact with a circular protective tube cross-section and perpendicular to the longitudinal axis of the protective tube movable contact tongues which overlap each other at their contacting ends.

Such tubular armature contacts with flat contact tongues are rectangular Cross-sections made of ferromagnetic material are generally known. Your activity takes place through magnetic fluxes, which the armature contacts resp.

Penetrate contact tongues. A miniaturization of these protective tube armature contacts limits are set by the iron cross-section of the contact blades, which is necessary is to provide the flux guidance required to achieve sufficient contact force to ensure.

A SchuZzrohrankerkontakt is disclosed in US Pat. No. 2,892,052 known whose magnetic members inside the protective tube over the largest In the area of their length, they have a circular cross-section that is only slightly smaller is than the inner diameter of the protective tube. At the contacting ends are understand the magnetic members with mutually facing gradations, which are overlap and each have a contact nipple.

The masses of the magnetic members to be moved are in this case Protection tube anchor contact However, relatively large, so that at Switching annoying bouncing phenomena can occur.

A reed armature contact is shown in US Pat. No. 3,315,193 and described, the per se known flat contact tongues with a rectangular cross-section having. Next to these contact tongues, namely on their inner wall of the protective tube facing side, another tongue is arranged in each case, which is made of stiffer Material as the contact tongues and is as long as this. The stiffer Tongues have a semicircular cross-section and can also be magnetic be conductive. They serve as a stop for the contact tongues for faster damping of bounce vibrations when the contact is open. The structure of this protective tube anchor contact however, it is relatively complicated because of the adjacent pairs of tongues In each case near the melting point within the protective tube with one another and with are welded to a carrier which is fused into the protective tube.

The invention is based on the object while avoiding a large Anchor ground and a complicated structure to create a thermowell anchor contact, the smallest circular with the largest possible iron cross-section in the contact tongues Protective tube cross-section allows. According to the invention this is achieved in that the contact tongues over the largest part of their length within the protective tube have a semicircular cross-section starting from their contact-making ends and face each other with their flat sides.

The protective tube armature contact described has a very small Protective tube cross-section or contact volume still have a relatively high contact force on. For example, in the case of a thermowell anchor contact of the invention with a contact volume of one third of a known protective tube armature contact and with a protective tube diameter of 2.5 mm compared to a diameter of 4 mm of the known contact with the same response power, a contact force was measured, which was only a factor of 0.8 less than with the known thermowell anchor contact.

The required spring properties are according to a training achieved according to the invention in that the contact tongues within the protective tube are embossed near the melting points.

The invention is based on an exemplary embodiment with reference to drawings in which show: FIG. 1 a protective tube armature contact, seen from the side and cut open; FIG. 2 shows the protective tube armature contact according to FIG. 1, seen from above and cut open; 3 shows the protective tube anchor contact according to FIGS. 1 and 2, in one Section through the contact point perpendicular to the longitudinal axis of the protective tube.

In the drawings there is a Schtitzrohr anchor contact with a protective tube 1, which has ellen circular QueræcLlitt. In the frontal At the ends of the protective tube 1, a contact tongue 4 or 5 is melted at 2 or 3, respectively, whose contact-making ends 6 and 7 overlap one another.

When a corresponding magnetic field is applied, the two move Contact tongues 4.5 with their contact-making ends 6.7 perpendicular to the longitudinal axis of the Protective tube 1 towards each other. . The contact tongues have inside the protective tube 1 4, 4 and 5 have a semicircular cross-section over the largest part of their length on. With this cross section, the contact tongues are 4.5 of their contact-making Ends 6.7 to 'provided almost at the melting points 2.3.

The curved sides 8.9 of the contact tongues 4.5 are the inner wall io of the protective tube 1 facing so that the contact tongues with their flat Pages 11 and 12 face each other (Fig. 3). This training enables optimal Utilization of the circular protective tube cross-section for the magnetic flux management. The necessary spring properties are given to the contact tongues 4 and 5 by means of embossing 13 or 14 conveyed, the-within the protective tube 1 near the melting points 2 and 3 are attached to the contact tongues 4,5. The contact tongues are in this zone 4.5 embossed flat, so that the low material thickness in the direction of movement of the contact tongues 4.5 gives sufficient mobility.

2 claims

Claims (2)

P a t e n t a n s p r ü c h e per thermowell anchor contact with circular Protective tube cross-section and movable perpendicular to the longitudinal axis of the protective tube Contact tongues which overlap one another at their contact-making ends, characterized in that, that the contact tongues (4,5) over the largest part of their length within the protective tube (1) starting from their contact-making ends (6,7) a semicircular cross-section have and face each other with their flat sides (11, 12). 2. Protection tube armature contact according to claim 1, characterized in that that the contact tongues (4,5) within the protective tube (1) close to the melting points (2,3) are provided with an embossing (13, 14).