DE9406968U1 - Small electromagnetic relay - Google Patents

Description

Dr. Kosowski, Dimiter
Buckesfelder Str.44
58509 Luedenscheid

Laux,Peter
Flotowstrasse 12
58509 Luedenscheid

Description

Electromagnetic small relay

The invention relates to a small electromagnetic relay according to the preamble of claim 1. Such relays with a volume approximately 20% larger than the invention described here currently represent the state of the art for neutral circuit board relays.

The general trend in relay technology in recent years towards a constant increase in relay efficiency, namely greater switching capacity with a smaller relay volume and lower power consumption, has led to a reduction in the height of the so-called "standing version" of neutral circuit board relays, first from approx. 25 to approx. 15 mm and then in the last 2 to 3 years from approx. 15 to approx. 12 mm. In addition, the response power of the drive system has been reduced by approx. half, while the switching capacity of the contact system remains the same. Nevertheless, the level of development of these cannot yet be described as satisfactory compared to the very inexpensive polarized relays with a height of 12 mm.

The aim was always to develop a neutral standing relay that, just like the polarized relays with the same switching capacity, can be used in the 3-T plug-in technology, where no component can be higher than 10.6 mm. However, the footprint on the circuit board, switching capacity, nominal power consumption, assignment and dielectric strength of this new relay should remain the same as the current neutral relays with a height of approx. 15 or 12 mm. This will enable a significant reduction in the overall volume of the device or system, especially for devices or systems in which a large number of relays are used.

A neutral circuit board relay that meets the requirements listed above is currently not available on the relay market. Patent G 93 03 437.7 shows a neutral relay with a height of 10.6 mm, in which the drive system is installed in such a way that the armature moves in the direction of the relay base body. However, if the drive system is mounted inversely, i.e. rotated 180° around the coil axis, in the base body (in the previous relay technology of 15 and 12 mm relays, the two drive system arrangements are common), then the position of the actuator in the relay automatically changes from the base body to the cap, which brings certain design advantages with regard to the design of the base body, as well as a technological simplification in the production of the so-called "wash-tight" version. For these reasons, the drive system was installed inversely in patent 93 15 891.2, which also eliminated the disadvantages mentioned. In order to increase the relay sensitivity and to increase the run-on times for the opener and closer, the inventors here set themselves the task of realizing a 10.6 mm relay with a significantly longer switching spring compared to the above-mentioned patents.

To fulfill this task, new electromechanical relay components or assemblies were used:

- A switching spring consisting of a T and a U-part as per Fig.2, which is operated either symmetrically at the height of the recesses on the side or as shown with a recess in the middle. The actuator is hooked into the corresponding recesses on two sides or one side (shown in dashed lines) as per Fig.2 parts 7 and 9. -A new armature retaining spring as per Fig.1 simultaneously allows simple drive system assembly.

The actuator according to Fig.l part 7 is hooked into the armature-6 and into the two symmetrical recesses or one-sidedly into the central recess (Fig. 2 parts 7 and 9 shown in dashed lines) of the switching spring-9, whereby the drive system armature-6 according to Fig.l is mounted in a space-saving manner using the armature spring-14, without the upper edge of the armature protruding beyond the upper edge of the drive system yoke-5. The armature spring-14 is also attached directly to the yoke-5 using two snap springs bent at the side. With the help of the contact spring-10,-11 and the contact spring carrier-8 from Fig.l, all previous assignments and grid patterns of the neutral relays with a height of 12 or 15 mm can be easily implemented in the base body-1.

The base body -1 and the relay cap -2 are designed so that creepage and clearance distances >8mm are achieved between the drive system and the contact system. The drive system consisting of yoke -5, armature -6, armature spring -14 and coil -3 can be assembled and tested separately using a machine and then assembled with the remaining relay parts in the base body -1 according to Fig.l by a second machine, which also carries out the final relay test.

The relay base body is designed in such a way that modern automatic encapsulation technology is possible for the "wash-tight" version. After the washing process, e.g. of the entire circuit board, the vent hole on cap -2, which is located above the contact system, should be cleared for reasons of contact life.

The connections of the contact carriers -10, -11, and the contact carrier -8 can also be implemented as SMD connections without any problems. The relay shown in Fig.l allows fully automated production.

Claims (3)

Dr.Kosowski,Di mit ter Buckesfelder Str.44 58509 Lüdenscheid Laux,Peter Flotowstraße 12 58509 Lüdenscheid Claims 1. Electromechanical neutral small relay for installation preferably on circuit boards, which has a height of 10.6 mm, characterized in that the changeover spring according to Fig. 2 consists of a half T-part and a U-part and its actuation takes place symmetrically on both sides or in the middle of the switching piece via two symmetrically arranged lateral recesses or a central recess. 2. Small relay according to claim 1, characterized in that/? an actuator according to Fig.l part 7, which is suspended in the switching spring according to Fig.2 part 9 and in the armature according to Fig.l part 6, whereby the suspension in the switching spring according to Fig.l part 9 can be carried out in the middle or at two points on the side, in that the armature is mounted in a space-saving manner using the armature spring according to Fig.l part 14, without the upper edge of the armature protruding beyond the upper edge of the yoke according to Fig.l part 5 and the armature spring according to Fig.l part 14 is attached to the yoke according to Fig.l part 5 using its two laterally bent snap springs according to Fig.l part 14. 3. Small relay according to claim 1 and 2, characterized in that the armature spring according to Fig. 1 part 14 engages with its pre-stressed central strip in the recess of the armature according to Fig. 1 part 6 and thereby prevents the armature from jumping out of its mounting, whereby at the same time a retaining force is exerted on the armature and a limitation of the armature travel is achieved.