DE6920653U - ELECTROMAGNETIC RELAY - Google Patents

Description

The invention relates to a flat electromagnetic relay with a coil body made of electrically insulating material.

There are known designs of flat relays which use an E-shaped yoke on the middle bar of which the coil sits and whose coil body also serves as a carrier for the contact spring sets. The movement of the armature, which connects the two outer bars in a U-shape, is transmitted to the spring contacts via an actuating bar.

Another known design uses the same operating principle as the design described above, but the wire spring sets used sit on a separate carrier plate which is attached to the relay yoke by clips. Both versions have the disadvantage that, due to the use of several leaf or wire spring sets and due to a complicated structure with many individual parts, separate magnetic circuit and its own electrical circuit, they require a large amount of assembly, material and adjustment, which inevitably makes the relay more expensive.

The object of the invention is to create a flat relay with a changeover contact specifically for printed circuits with small external dimensions and with as few individual parts as possible.

This object is achieved according to the invention as described in more detail in claim 1 and in a further embodiment of the invention in claims 2-8.

An embodiment of the invention is shown in the drawing and is described in more detail below:

Fig. 1 shows the top view of the relay with the second half-shell removed. Fig. 2 shows the side view of the complete relay.

The relay is mechanically constructed from a coil body made of insulating material, which is divided in its longitudinal direction into two "H" -shaped half-shells (1). These half-shells (1) have recesses and depressions on their side facing each other, which serve to connect the other components, namely relay yoke (2), connector (12), armature (3), coil (14) and contact connections (7) to record. The yoke (2) consists of ferromagnetic material and is U-shaped. In the energized state, the relay closes the magnetic circuit via the two yoke leg ends (4, 5), an armature (3) which is cranked in the exemplary embodiment and also consists of ferromagnetic material. The armature is mounted in such a way that the free armature end magnetically attracted by the first arm (4) of the yoke (2) pivots about an axis of rotation at the other armature end which practically coincides with the end of the second yoke arm (5). To hold it, the anchor has two lateral arms (9) at its supported end, which are embedded in slots of the two half-shells (1) running transversely to the anchor longitudinal direction so that they are positively gripped in the directions transverse and longitudinal to the anchor longitudinal axis. The anchor is fixed perpendicular to the longitudinal and transverse direction of the anchor by a leaf spring (10) which presses the anchor onto the face of the second yoke leg (5). The fork-shaped leaf spring (10) is attached to the armature in such a way that it forms a "V" with the supported armature end and protrudes beyond the armature axis of rotation. A connection piece (12), which also serves as a power supply, presses the armature in the direction of the second yoke leg (5). The axis of rotation of the armature is formed by the edge (11) of the yoke leg end face (5) on the winding side. When it has fallen off, the armature rests on the face of the yoke leg (5) with almost no air gap; when it is tightened, a wedge-shaped air gap is formed.

As a result of the offset arrangement of the clamping point of the leaf spring (10) to the axis of rotation of the armature on the winding-side edge (11) of the yoke leg end face, a torque arises against the armature tightening direction, which causes the armature to exert a force on the normally closed contact when the coil is not energized. The shape of the connecting piece (12) has the effect that it encloses the supported armature end as well as the associated yoke leg (5) and thus prevents the armature (3) from falling out of the support when subjected to shock loads. The free armature end carries a contact (6) in its extension, which moves between two passive contact pieces (7) when the relay is actuated and thus forms the changeover contact. The contact pieces (7) as well as the coil connections (14) are accommodated between the two coil body halves in recesses (8) and protrude in the form of a pin from one coil body half for soldering into the printed circuit.

The magnetic circuit and the electrical circuit are linked in that the armature is used for both circuits. The electrical circuit leads from the connection piece (12) via the leaf spring (10) to the center contact (6) on the armature, from there to the normally closed or normally open contact (7), depending on the armature position. The coil body flanges are shaped in such a way that their surface also forms the boundaries of the relay in the form of a cuboid and that all components necessary for the relay to function are housed within these boundaries. A dust protection cap (13), which engages in grooves in the bobbin flange, serves as a cover.

The advantages achieved with the invention are that the relay can be manufactured with as few individual parts as possible and that assembly consists only of plugging the coil body halves together with the yoke, connector and four power connector parts. After winding the coil, which holds the coil body halves together, the armature is locked into place by a sliding movement without tools.

Claims (8)

1. Electromagnetic relay with a bobbin made of electrically insulating material, characterized in that the bobbin consists of two "H" -shaped half-shells 1 dividing it in the longitudinal direction and enclosing a "U" -shaped yoke 2 made of ferromagnetic material and in which a flat, straight or bent, ferromagnetic armature closing the magnetic circuit between the two yoke limb ends is mounted in such a way that the free armature end magnetically attracted by the first limb 4 of the yoke 2 pivots about an axis of rotation at the other armature end, which practically coincides with the end of the second yoke limb 5 coincides with the fact that the armature carries a contact 6 in the extension of its free end and between two passive contact pieces 7, which are fastened in recesses between the two half-shells 1 of the coil body, forms a changeover contact in accordance with the armature movement and that in further recesses 8 of the half-shells 1 connector Pieces for supplying the coil current and for the electrical connection of the relay armature 3 can be used. 2. Electromagnetic relay according to claim 1, characterized in that the armature 3 at its mounted end has two lateral arms 9 which are formed in the transverse to the armature longitudinal direction, so formed slots of the two coil body halves 1 that they are in the directions transverse and longitudinal to The armature longitudinal axis can be positively grasped and that the armature is fixed perpendicular to the armature longitudinal and transverse direction by a spring 11 which presses the armature onto the end face of the second yoke leg 5. 3. Electromagnetic relay according to claim 1 and 2, characterized in that the axis of rotation of the armature is formed by the winding-side edge 11 of the yoke leg end face, that the armature 3 rests in the fallen state on the end face of the yoke leg 5 with almost no air gap and that when the Armature forms a wedge-shaped air gap. 4. Electromagnetic relay according to claim 1 to 3, characterized in that a leaf spring 10 is attached to the armature so that it forms a "V" with the mounted armature end and that the free end of the leaf spring protrudes beyond the armature axis of rotation and serves as a power supply Connection piece 12 is pressed in the direction of the second yoke leg 5. 5. Electromagnetic relay according to claim 4, characterized in that the leaf spring 10 is fork-shaped. 6. Electromagnetic relay according to claim 4 and 5, characterized in that the connecting piece 12 touching the leaf spring 10 completely or partially encloses the supported armature end and the yoke arm 5 assigned to it, thus preventing the armature 3 from falling out of the bearing when exposed to shock. 7. Electromagnetic relay according to claim 1 to 6, characterized in that the bobbin flanges are shaped so that their surface at the same time form the limits of the relay in the form of a cuboid and that all components necessary for the function of the relay are located within these limits. 8. Electromagnetic relay according to claim 1 to 7, characterized in that the dust cap 13 engages in grooves in the bobbin flanges.