CH646272A5 - Contact-spring set for electromagnetic relays - Google Patents

Description

The invention relates to a contact spring set for 45 electromagnetic relays, with an insulating body as a carrier for the individual return or contact springs, which are arranged in grooves of the carrier and are held by resilient bias.

The contact spring set for relays consists of contact springs and return springs, which are insulated in an insulating block, the contact springs are either cast in the insulating block, or this insulating block is made up of several insulating plates, which are held together by rivets or screws, with between ss the plates the contact springs are held.

The expansion of such relays by several or the modification of such relays with respect to other types of contact springs is not possible. The contact springs are firmly attached to the insulating block and can only be exchanged for other contact springs with great effort and time. The manufacture of such relays is also relatively expensive because care must be taken to secure the contact springs to the insulating block.

The object of the present invention is to propose a contact spring set of the type mentioned in the introduction, in which the individual springs are easily held on the insulating block and are easily replaceable, and the insulating block can also be expanded to accommodate a larger number of contact springs.

To achieve the object, the invention proposes two versions. In a first embodiment, the position of the return or contact springs is ensured by the fact that the respective spring has at least one recess through which a cam protrudes from the side wall of the groove.

Conversely, in a second embodiment, the position securing is formed in that the spring has at least one bent tab, which engages in a recess made in the side wall of the groove.

In both versions, it is preferred if two curved flaps or cutouts lying next to one another are provided on the spring for securing the position in order to secure the springs to be held against rotation.

With this fastening of the springs described, it is possible to equip relays as desired. The contact springs can be used in a single operation. Likewise, it is possible to hold corresponding return springs for the actuating element on the insulating block in the same way, so that all moving parts on the insulating block can be inserted and held in the insulating block in a single operation.

Several embodiments of the present invention will now be described in more detail with reference to the drawings. Advantages of the invention emerge from the drawing and its description.

Show it:

1 shows a longitudinal section in detail of a first embodiment of the fastening of a tongue in a groove,

FIG. 2 front view of the spring,

FIG. 3 second embodiment of the fastening,

FIG. 4 shows a schematic representation of a third embodiment of a fastening,

FIG. 5 detailed view of a cross section through an insulating block with four contact springs and a return spring,

6 shows a section through a fourth embodiment of a fastening according to line VI-VI in FIG. 7,

FIG. 7 section along line VII-VII in FIG. 6,

FIG. 8 section through a fifth embodiment of a fastening along the line VIII-VIII in FIG. 9,

FIG. 9 section along the line IX-IX in FIG. 8,

FIG. 10 partial section with partial side view of a further embodiment according to a partial section X-X in FIG. 11,

FIG. 11 top view of the embodiment according to FIG

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In Figure 1, a groove 3 is shown in an insulating block, wherein a contact spring 1 is non-positively on the side walls 6 of the groove. The non-positive contact is achieved by the spring preload, which in the exemplary embodiment can be inserted from above into the opening 4 of the groove in the direction of arrow 11. A cam 8, which is connected to the side wall 6 and which engages in an associated recess or opening 7 within the spring 1, serves to secure the position. The spring is thus simply pushed into the opening 4 of the groove 3 using its own pretension and engages there with the recess or opening 7 via the cam 8.

FIG. 2 shows an example of such a spring, which can be designed with two legs and has two recesses or openings 7. This ensures an even better position securing, because now two cams 8 engage in the corresponding recesses 7 and thereby secure the spring 1 against pivoting. The spring 1 can also have an elongated hole 18 through which the screw engages

5 holds the insulating plate 17 of the insulating block 13 together according to the exemplary embodiment in FIG.

Figure 3 shows another embodiment of the attachment; Here, the position securing is selected such that a tab 9 projects from the spring 2 and engages in an associated bore 10 within the side wall 6 of the groove 3. Of course, a plurality of tabs can also be arranged and the tabs can also be attached to the contact spring 2 in other directions, preferably facing each other.

FIG. 4 shows that the non-positive connection of the tongue 1, 2 in the groove 3 can also take place in that the tongue has several corrugations, the corrugations being non-positively attached to the side wall 6 of the groove 3. Bent flaps 9 or corresponding cutouts or openings with assigned cams 8 can then also be used to secure the position.

FIG. 5 shows, as a further exemplary embodiment, the fastening of four contact springs 1 and a return spring 2 in an insulating block 13. In the exemplary embodiment shown, the insulating block 13 can consist of an integral part in which the grooves 3 are embedded.

The contact springs 1 can be held by a common tool and pushed together non-positively in the grooves 3, where they are then locked to the associated position locks. This type of fastening has the essential advantage that the contact springs can be exchanged for any other contact springs.

The grooves 3 of the insulating block 13 can also be produced in that the grooves are formed by insulating plates which are spaced apart from one another, the springs, in turn, being pushed together into the grooves, held by a common tool.

The insulating block is thus constructed in a modular manner, because the insulating plates 17 can be strung together in any number at a distance and therefore any number of grooves 3 can be produced in which any number of contact springs 1 can be inserted. In order to ensure the cohesion of the insulating plates 17, the insulating plates 17 have at least one common bore 15 through which a threaded screw (not shown in more detail) engages, which engages in a thread arranged on the yoke of the relay. In the illustrated exemplary embodiment, the threaded screw would be inserted into the bore 15 from the side 19, with, for example, on the opposite side 20 would be the yoke of a relay coil, the threaded screw engaging the thread on the yoke. To secure the position of the insulating block 13 on the yoke, cams, e.g. Cam 14 is provided on the insulating block 13, which engages in an associated recess on the yoke. This makes it possible to produce any number of contact spring sets in a modular manner. The advantage here is that the actuating element, which extends through all the insulating plates 17 and rests on the contact springs 1 with corresponding cams, is actuated by a common return spring 2, which exerts a force on the actuating element

646 272

exercises in the direction of arrow 21. If the insulating block 13 is now extended by stringing together additional insulating plates 17, the actuating element, which can be designed as a simple actuating rod, can be replaced by a longer one, the same return spring 2 still being usable, since it in turn can only be snapped into the groove 16 is attachable.

Of course, it is also possible to replace the return spring 2 with other return springs of higher or lower spring constant.

The described attachment of the contact springs I and the return spring 2 ensures a modular structure of the insulating block, the insulating block being changeable as desired. The change is made either by the fact that contact springs of a different function or a different design or a different spring constant can be used, or by the fact that the return springs can be replaced. Furthermore, the insulating block can be changed or shortened as desired, so that the number of contact spring sets can be increased or decreased in a simple manner - without further aids or operations.

FIG. 6 shows a fastening similar to that of FIG. 1. However, a cam 22 is provided which has a round profile according to FIG. 7 and rises in a wedge shape in cross-section in the direction of arrow 11 (insertion movement). This results in a particularly simple fastening, because the end of the contact spring 1 lying in the direction of the arrow 11 gets into the obliquely rising surface of the cam 22 when it is pushed in and can easily overcome this cam. The cutout 7 then snaps over the cam 22, so that the contact spring 1 is held in the groove 3 of the insulating block 13 in an extraordinarily secure manner and requires little assembly.

Figures 8 and 9 show that the cam can have a square or rectangular profile instead of a round profile. An essential feature of this exemplary embodiment is that the cam 23 attaches directly to the side of the groove 3, that is to say it is not arranged in the center of the groove 3 according to, for example, FIG. It is also essential that the cutout 24 in the contact spring 1 attaches to the edge of the contact spring 1. This results in a particularly simple and inexpensive manufacture of the recess 24.

Figures 10 and 11 show the attachment of a return spring 2 in the groove 3 of the insulating block 13. Here, a recess 9 is provided with slightly widening cross-sectionally widening side walls, in which the tab 25 engages, which by punching out a recess 9 according Figure 11 is obtained from the material of the return spring 2. The tab 25 is resiliently attached on one side to the return spring 2 and engages resiliently in the recess 9 of the insulating block 13. Due to the slightly wedge-shaped upward, widening side walls of the recess 9, the flap 25 is locked particularly securely within the recess 9 of the insulating block 13.

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Claims (8)

646 272 1. Contact spring set for electromagnetic relays, with an insulating body as a carrier for the individual return or contact springs, which are arranged in grooves of the carrier and are held by resilient bias, characterized 5 in that the position securing of the return (2) or contact spring (1) is achieved in that it has at least one recess (7, 24) through which a cam (8, 22, 23) protruding from the side wall (6) of the groove (3) engages (Fig. 1.5, 6-9). io 2. Contact spring set for electromagnetic relays with an insulating body as a carrier for the individual return or contact springs, which are arranged in the grooves of the carrier and held by resilient bias, characterized in that the position securing of the return (2) is or contact spring ( 1) in that it has at least one bent tab (10, 25) which engages in a recess (9) made in the side wall (6) of the groove (Fig. 3, 4, 10, 11). 2nd PATENT CLAIMS 3, characterized in that the grooves (3) of the insulating body (13) are formed between spaced-apart insulating plates (17). 3. Contact spring set according to claim 1 or 2, characterized in that two adjacent flaps (10, 25) or recesses (7, 24) on the spring (1, 2) are provided for securing the position (Fig. 2). 4. Contact spring set according to one of claims 1, 2 or 5, characterized in that the cam (8, 22, 23) increases in a wedge-shaped cross section in the direction (11) of the insertion movement of the spring (1, 2) (Fig. 6-9). 5. Contact spring set according to claim 4, characterized in that the mutual fastening of the insulating plates (17) takes place in such a way that the insulating plates (17) have at least one common bore (15) through which a threaded screw is intended to engage, which in a Yoke of the relay arranged thread is intended to engage. 6. Contact spring set according to one of claims 1, 4 or 7. Contact spring set according to claim 1 or 3, characterized in that the recess (24) in the spring (1,2) attaches to the edge of the spring (1,2), (Fig. 8.9). 40