DE2218494B1 - Electromagnetic relay - Google Patents

Description

3 4

the overall height can expediently because of the nesting of the magnet system and the necessary safety distance rib or a contact wall is provided that a the contact springs cannot be kept as small as desired the. In addition, of course, this relay has all the contact springs. That way it can Disadvantages of the layered contact springs, for example 5 magnet system during assembly without subsequent show the tolerance summation. Adjustment in a precisely defined position opposite The object of the invention is to provide a set of contact springs. The fastenilais with a common fastening element from supply can by screws, by entangling Insulating material for contact springs and a magnet system on a fastening tab or on another train that it can be done with an extremely low overall height io known manner. To the anchor of the is suitable for use on printed circuit boards and the magnet system must be secured against being thrown away in addition, simple assembly, which continues to be good in one embodiment of the invention Functional control and, if necessary, a wall of insulating material provided so that the anchor Replacement of individual parts permitted. This is done between this wall and the magnet yoke in one achieved according to the invention in that the insulating material 15 is mounted in a narrow gap. In addition, the insulating body is designed as a flat body, the sub-fabric body verseite all around with raised walls serves as the soldering side and on the top of which everyone will see, so that it forms a housing, the Ie functional elements of the relay next to each other or only to be closed with an attached cover are. essen is.

This relay construction according to the invention has the advantage that the assembly can be taken from the following description of an embodiment and simply both by hand and by machine, for example, in particular from the advantage that the assembly is very efficient. It shows
can be carried out. The fact that Kontaktfe- F i g. 1 a relay according to the invention from above, see actuator and magnet system in one, partially in section,
Level are arranged on the insulating body, as Fig. 2 is a section AB from Fig. 1,
they can be used independently of one another, ju- F i g. 3 one opposite to FIG. 1 modified stare or exchanged. The fastening form of the contact actuation,
The individual parts are expediently produced in FIG. 4 and 5 the fastening of the magnet system,
on ribs that are perpendicular to F i g on the insulating material. 6 the arrangement of relay armature, actuation in its main direction of expansion are provided. 30 link and return spring,

The contact springs are preferably in each case between. 7 another option for connecting

between two ribs of the insulating body attached, formation of return spring and actuator,

whereby the fastening method is gluing, pressing in. 1 and 2 is the basic structure

sen or the like comes into question. The simplest way is to recognize the construction of the relay according to the invention. It

probably an anchoring by means of laterally supported 35 initially consists of an insulating body 1, the

Rag. All electrical connections of the Kontaktfe- is designed as a flat part and in which all radio

countries and the coil are expediently stored in tion elements of the relay. That's how it is

Breakthroughs in the insulating body to the soldering side of the hinged armature magnet system with the yoke 2 through a

led out. For this purpose, screw 3 on a stable contact wall 4 of the insulation

Additional embodiment, the contact springs angled 40 lierstoffkörpers 1 attached. The magnet system itself

shaped so that it consists of the usual parts with one leg, in addition to the yoke 2

Form a soldering lug and with the perpendicular to it from the coil core 5, the coil body 6, the

standing leg as a contact leg parallel to the winding 7 and the one mounted on the yoke edge

Base plane of the insulating body are movable. Angle anchor 8. Under the head of the screw 3 is

In the preferred embodiment, a shim 9 is provided every 45 to reduce the specific

Contact springs individually between mounting ribs see pressure present, which is simultaneously with a

of the insulating body used. However, it is also possible to connect lug 10 (see Fig. 4) as a ground connection.

an embodiment is conceivable in which several hen can be.

Contact springs as a prefabricated block, for example, the contact springs 12, 13 and 14 are arranged in two rows as an overmolded contact spring set, symmetrically arranged in opposite directions in the isohen, and insert the relay body and corresponding fixing ribs 15 of the insulating body 1 are anchored between fixing ribs - anchored. The individual contact springs are winkelden. shaped, so that for example the Konin one embodiment, is further provided for clock-spring-a and a hen that the contact springs in two rows counterrotating 55 resilient contact legs 12 forms a soldering b 12 grandchildren 12th The Lötfig are arranged so as to be α with their free ends 12 of the leg Isolierden face each other in an opening. 11 All solid contact body 1 led to the underside of the relay and that of the relay can then be shared between one another and can thus be inserted into a printed circuit board.
The contact springs are actuated by means of a slider. This slide can 60 the armature 8 via a slide 16, which is attached to a return spring 17 with at the same time as an insulating partition between one end on the armature 8 and the opposite end of the contact spring. serve so that the distances between the two contact This return spring 17 is supported on both sides of the spring rows can be kept very small. Isolierstoffkörper 1 off and determines when not energized.

its entire armature movement parallel to the basic According to F i g. 1 the contacts are operated as indirectly

level of the insulating body takes place. Formed for fastening saturated internal pressure contacts, so that at

5 6

In the non-excited magnet system, the normally closed contact springs spring 21, 22 and 23, which in turn can be actuated by a 14 due to their own bias on the slide 16. The contacts are these fixed central contacts 13, while sometimes not designed as internal pressure contacts, much more the working contact springs 12 by cams 16 α more the central contact spring 21 is biased against a rest slide 16 under the action of the return spring 5 contact 22 and can when energized 17 of the mating contacts are lifted. When the magnet system is actuated against a working contact 22, the slide 16 will be pressed.

gen shifted the spring force of the return spring 17, The F i g. 4 and 5 show in excerpts the command

and the cams 16 a raise the normally closed contact springs stigung of the magnet yoke 2 with the screw 3 on

14 from their mating contacts 13. As a result, an abutment wall 4 of the base body 1 can be placed on this

NEN now the normally open contact springs 12 due to the way the magnet system is in a defined way

close to their own bias. Brought distance to the contact springs. With the

The angled contact spring screw 3 becomes a terminal lug 10 at the same time

are either made from one piece or from attached, with which the potential of the magnet system

composed of two parts. For example, 15 can be brought out of the relay. In a

possible, the solder leg 12 α to achieve a cavity between yoke 2 and screw 3 is

stable attachment in the insulating body 1 from also an adhesive or resin droplets 24 inserted-

a material of greater thickness to manufacture and then fills, so that in addition to the screw connection

the spring leg 12 b is made of a very thin material and an adhesive connection.

weld on. In addition to the type shown, all 20 in Fig. 6 is further-

Contact springs individually in the insulating material body make up the connection between armature 8 and slide 16

anchor, an embodiment is also possible, shown at and return spring 17. The slider 16

which engages several contact springs in a block with two pins 25 in corresponding recesses

injected and jointly in the insulating body 1 fixations 26 of the armature 8 and at the same time with a

be sustained. Between the oppositely arranged 25 round pins 27 in a hole 28 of the return spring 17.

The slide 16 is also the contact spring sets. In this way, the slide 16 has very little friction

arranged in such a way that it leads between an insulating wall,

see the contact spring ends. A version with even lower wear and friction

In the area of the anchor bearing, a wall 18 is shown in FIG. 7. Here the slide 16 has a valve

Insulating body 1 so close to the angle anchor 8 30 gel pin 29, which is in an embossed dome 30 of the

brought up as a limit stop that engages even with return spring 17.

strong vibrations and impacts on the armature. This is due to the chosen arrangement principle

kerlager cannot disengage. The relay is clear and simple in structure and results in a

Outer walls 19 of the insulating body 1 are exceptionally good space utilization with good electrical creep

pulled up all around so that a housing 35 and air gaps. All parts are from one side

is formed, which can be easily assembled into the base body with a cover 20, whereby both

is to be locked. inexpensive manual assembly as well as good pre-

FIG. 3 shows a somewhat suspension compared to FIG. 1 for mechanized assembly.

modified contact arrangement with the contacts.

1 sheet of drawings

Claims (13)

1 2 yoke (2) and a contact wall (18) of the insulating body (1) is mounted. Claims: 14. Relay according to one of claims 1 to 13, characterized in that the Isolierstoffkör- 5 per (1) all around with raised walls (19) 1. The electromagnetic relay is insulated, which has a cover (20) Form lierstoffkörper as a common fastening closable housing. supply organ for the contact springs and the magnet system, characterized in that,
that the insulating body as a flat body (1) io
is formed, the underside of which as a soldering side
serves and on the top of which all functional elements (2,8,12,13,14,16,17) of the relay are arranged next to one another. The invention relates to an electromagnetic 2. Relay according to claim 1, characterized in 15 cal relay with an insulating body as common drawn, that the flat body (1) with ribs samem fastening member for the contact springs and (15) and attachment walls (4) for fastening the magnet system. Functional elements (2, 12, 13, 14) is provided. The use of a single body of insulating material 3. Relay according to claim 2, characterized in which both the contact springs and draws that the contact springs (12, 13, 14) each 20 the magnet system at predetermined fastening parts can be used individually between two ribs (15) of the insulation, offers in many ways lierstoffkörpers (1) are anchored. Respect advantages over the most common 4. Relay according to one of claims 1 to 3, relays with separately mounted contact spring sets, characterized in that the electrical combines the only later with the magnet system Connections (12 a) of the contact springs (12) and 25 are. So on the one hand the assembly effort of the magnet system in openings (11) of the less, the fewer individual parts who use insulating material (1) are led to the soldering side. on the other hand, no manufacturing 5. Relay according to one of claims 1 to 4, tolerances between the magnet system and the individual, characterized in that the contact springs sum NEN contact springs when all parts loading (12) are angular and each 30 already their predetermined place in the base erein solder leg (12 d) and keep in touch. legs (12 b) form. Such a relay with a single plastic 6. Relay according to claim 5, characterized in that the body as a fastening element is already shown in the figure, that the contact legs (12 δ) see parallel Auslegeschrift 1805 583 described. All too The basic plane of the insulating material body (1), however, this known construction has a very are moveable. tall, albeit narrow, construction on so that they 7. Relay according to claim 5 or 6, characterized for certain areas of application, for example to indicate that the contact legs (12 b) consist of use on circuit boards, not in question thin spring material and comes from. In addition, the assembly of the existing solder leg 40 is still relatively difficult, since the contact springs of both (12 d) are welded on. Sides of the insulating body are to be attached and 8. Relay according to claim 1 or 2, characterized in this also first in the transverse direction and then indicates that several contact springs must be used in the longitudinal direction,
Anchored together in a prefabricated block For use on printed circuit boards, and are attached to the insulating body (1). 45 mostly relays with an E-shaped magnet system 9. Relay according to one of claims 1 to 8, usually in which the armature and the Kontaktfedurch characterized in that it moves in two rows at right angles to the plane of the printed circuit board ordered contact springs (12, 13, 14) are each other. With these relays the functional parts face with their free ends. because of the low permissible overall height, often in one 10. Relay according to claim 9, characterized marked 50 cumbersome and difficult to assemble manner draws that the opposing are arranged one above the other. Knowing Movable contact springs (13) due to a fault in an individual part or even the disintegration, Such an individual part changes between the two rows of contact springs without any change arranged slide (16) can be actuated. the rest of the one is nested in this way 11. Relay according to one of claims 1 to 10, 55 construction completely impossible. Because of the low height, characterized in that a hinged armature, these relays can only be fitted with a very magnetic system (2,5, 6,7, 8) on the insulated number of contact springs so that the material body (1) is attached Anchor ends. Such a relay is described, among other things, in the movement parallel to the ground plane of Isolierstoff- German Auslegeschrift 1 948 725,
body (1) takes place. 60 Another way to design a flat relay 12. Relay according to one of claims 1 to 11, is in German Offenlegungsschrift 2,016,903 characterized in that the magnet system is shown. There is a relay with a lying folding (2,5,6,7,8) described by an abutment wall (4) in the anchor magnet system, in which two innierter Distance to the fastening ribs (15) nested, mutually offset Konder Contact springs (12,13,14) is held. clock spring sets are operated together. These 13. Relay according to claim 11 or 12, characterized in that the contact spring sets are conventionally characterized in that the _{layered on the yoke (2) gela- 6} type, so that also here the exchanged magnet armature (8) is not possible between an edge of the individual contact springs . Even