DE1963639A1 - Flat electromagnetic relay - Google Patents

Description

BE CONTACT COMPONENTS

GMBH.

N ü r η Td e r g

Foundry Street 3

Case: W. Minks -2

Flat electromagnetic relay

The invention relates to an electromagnetic flat relay with a magnetic core carrying the excitation coil and a magnet armature articulated on this, which moves approximately perpendicular to the coil axis and closes the support, guidance and return of which are used by several spring elements with a low spring rate, one of which in the form of a preloaded compression spring at the same time for the. required contact pressure between a moving Contact part and a stationary contact part provides.

A well-known flat relay of this type (German Auslegeschrift 1 273 069) has the advantage of high response sensitivity, because contact pressure and anchor load pressure are due to the spring action of spring elements with a low spring constant be generated. In addition, there are defined contact pressure ratios with such a flat relay, since the pressures exerted by compression springs can be precisely determined beforehand. This makes it unnecessary An adjustment of the relay contacts and thus a change in the previously determined operating values of the Relay.

There is a particular need for flat relays in devices with printed circuits, such as those in the news, signal and control technology are used. The installation of the well-known flat relay in a

Kb / b - 12/9/1969 - 2 -

109826 / HU

_ßA 0 ORIGINAL

Vi ". Minks -2 Λ -? - -

• printed circuit "causes difficulties because the relevant requirement for the smallest possible height (10.5 mm) is not met. So are hot known flat relays the movable and fixed contact parts in the form of superimposed contact spring strips attached in the longitudinal direction of the magnet core on both sides of the excitation coil and on one end of the relay led out as electrical connections. Accordingly, the overall height of the known relay is determined by the arrangement and training of the contact parts specified.

Another known flat relay (German Ä.slegeschrift 1 243 272), which is designed in the form of a rotary armature relay, results in a low overall height, that the contact system in addition to the drive system (electromagnet, armature) approximately in the direction of the coil axis is arranged. However, in the known case, the base area of the relay is relatively large, since there are two coils can be used in a plane parallel to each other. Of this Apart from that, there is the difficulty with the known relay, defined contact pressure conditions and Realize low sensitivity.

It is the object of the invention to provide an electromagnetic To create flat relay, in which the winding arrangement alone determines the overall height of the relay / its contact system and drive system, however, at particularly low, previously precisely defined operating values speak to. The solution to this problem consists in the electromagnetic type mentioned at the beginning Flaehrelais according to the invention. That the compression spring engages an angled pivot lever made of spring material, one leg of which with the armature is in a positive connection and on one

108826/141 * ^ _0R , _SINAL

ν /. Hints -2 - S -

fixed relay part is pivotally mounted, while the other Pe the leg carries the "movable contact part or forms, and that! compression spring, pivot lever, contact parts and fixed relay part are arranged approximately in the axial direction of the excitation coil. ■

In the relay according to the invention with the create Armature operatively connected actuating elements for the contact parts, namely compression spring and pivot lever Either a defining one in every position of the anchor Contact pressure, as the compression spring is constantly pretensioned to look at its rest position. In addition, can due to the use of spring elements with a low spring constant for the anchor load pressure at the same time a achieve high response sensitivity of the relay. Furthermore, the relay according to the invention results in a Saving on actuating elements, especially separate ones

> Parts to accommodate the moving contact parts and ■ leather elements are omitted. So can with the relay after the Invention the pressure spring creating the contact pressure and Swivel lever spring and the movable contact part are combined into one unit, which is practical can be accommodated in the installation space of the contact system without separate mounting parts. It is essential that this structural unit also does not change the overall height of the relay. The arrangement of the contact and actuation system approximately in the axial direction of the excitation coil results in the required Low overall height of the relay because of the winding arrangement can occupy the entire height. By forming the movable contact part in a lorm angular swivel lever spring has the advantage of that when switching a dragging movement of the moving Contact part on the stationary contact part and thus self-cleaning and low-bounce switching, the contact parts in question occurs.

109826 / UU

W. Minks -2 ■ - - V-

In an advantageous development of the invention there are several door-tensioned compression springs arranged next to one another are provided, each on an angled pivot lever attack from spring material and thus at the same time for the required contact pressure between each associated movable contact part and a stationary contact part care for. This gives the possibility of several Weak current contacts as make, break or changeover contacts to switch at low operating values, so that a large number of stop funct zone η can be fulfilled, without the overall height for a given winding arrangement

■ the relay must be enlarged.

Further details and advantages of the invention will be explained with reference to the drawing, from which a preferred Embodiment can be seen. Figure 1 shows in Longitudinal section of the relay according to the invention, while in Figure 2 of this relay in plan view with partially cut contact system and drive system shown is.

The flat relay shown in Figures 1 and 2 has a very low overall height of 10.5 mm in adaptation to the smallest distance between printed circuit boards of 15 mm and is therefore particularly suitable for installation usable in devices with printed circuit boards.

Due to the favorable arrangement of the drive system 10 and Contact system 20, the relay shown also has a relatively small footprint, such as in particular Figure 2 shows. The contact system 20 can be any Compilation of idle, work and changeover contacts included, so that the contact system can be chosen largely independently of the drive system 10. the The embodiment shown is suitable for circuits that require five switch contacts for low power.

- 5 109826/1414

ORIGINAL

¥. Minks -2 -. £ -

With the release of a "neighboring Eontaktplatz" you can however, changeover contacts for heavy current are also provided as this increases the clearance and creepage distances the adjacent contact parts are enlarged. Taking into account electrical safety, every "Any combination of weak and heavy current contacts possible. ■ ~. ■ ".

Drive system 10 and contact system 20 are mechanical and functionally interconnected. The JQ actuation system is used for the functional connection Elements actuate the contact system 20 while the mechanical connection is accomplished through the housing 40 will. The housing 40 is after the connection side of the Contact system 20 to improve ventilation open and Covered by a dust cap 50 at least over the area of the contact system. If necessary the dust cap 50 can also cover the entire Extend system.

The contact system 20 is made up of the stationary ones Contact parts 60, 70, 80 and the movable contact part 91 «The use of the relay for printed circuits suggests the connection parts 61, 71, 81 of the stationary contact parts 60, 70, 80 at intervals according to the grid according to the arrangement of the insertion openings to attach the printed circuit board. It is also advantageous if the stationary contact parts 60, 70, 80 can be assembled in a simple manner and for this purpose have fasteners of the same size. Therefore, all of the contact parts 60, 70, 80 are flat Fastening pieces 62, 72, 82 with a saw-path shape Side edges with which they are self-locking in tapering recesses 41 of the housing part 40

'_ - 6 109826 / U H

W. Minks -2, -V- '

. are inserted »so that between fastening pieces 62, 72, 82 and 'boundary walls of the recesses 4-1 If there is a strong frictional connection, the housing is 4-0 made of less hard material than the contact parts 60, 70,. 80, e.g. made of plastic.

The stationary contact parts 60, 70, 80 differ, however, in their dimensions. While the contact parts 60, 70 have a contact-making function, the contact parts 80 only act as connection parts 81 of the movable contact parts 91. Advantageously, the contact parts 60, 70 are provided with bends 63 _s 7 ″ in the contact area for making contact Contact pieces so that the contact parts 60, 70 can be manufactured in one piece. Depending on the type of equipment in the contact system 20, the bends 63, 73 of the contact parts 60, 70 work with the movable contact parts 91 in the sense of normally closed, working or changeover contacts If necessary, the bends 63 »73 can, however, be provided with contact pads, for example a silver plating, to improve the contact.

Each of the movable contact parts 91 is at the same time a spring leg of an approximately rectangular shape on its free end fork-like split pivot lever 90 from Spring material, the other Federsdi grandson 92 on his free end with the drive system 10 in a frictional connection Is connected and roughly with its middle part on the stationary contact part 80 is pivotably mounted »For this purpose, the contact part 80 has at its connection part 81 facing away from the end of a blade bearing 83 for the spring leg 92. on. At the tied end of the feather handle 92 engages the helical compression spring 100 with lower

09 8 26 / HU

BATH ORIGINAL

. ¥. Minks -2 "- if * -

Spring constant that is constantly moving towards its rest position is biased and the required contact pressure between the "movable contact part 91 and the stationary Contact part 70 "accomplished. Compression spring 100, movable Contact part 91 and spring leg 92 are advantageous Combined to form a single unit, so. that this means that individual parts can be saved. With her that The end facing away from the spring leg 92 is the helical spring 100 on the G-e housing 40, e.g. on the bearing pin 42, electrically insulated stored, in such a way that the spring axis and the spring leg 92 against the longitudinal axis of the relay are slightly inclined in every operating state. As a result, the coil spring 100 exercises on the pivot lever 90 and thus on the movable contact part 91 in all positions of the drive system 10 from a rectified torque. Due to the favorable arrangement of compression spring 100 • and pivot lever 90 within the installation space of the contact system 20 results in a further space saving.

For the frictional connection of the helical spring and pivot lever 90 existing actuation system 30 With the drive system 10, i.e. the O-shaped magnet armature 110, the insulating material part 120, which is placed on the U-web 111 of the anchor is riveted. This insulating part has on its spring leg 92 facing Side a nose-shaped port set 121 for taking the Swivel lever 90 on. At the same time, the insulating material part 120 insulates the free end of the pivot lever resting against it 90 and thus the movable contact part 91 and the stationary contact part 80 opposite the magnet armature 110.

In addition to the TJ-shaped magnet armature 110, the propulsion system includes 10 the E-shaped magnetic core I30, its middle limb 131 the bobbin 140 for the excitation coil

109826 / UU

W. Minks -2 '

wearing. For the rotatable mounting of the U-shaped. Magnet armature 110, which can be moved approximately perpendicular to the coil axis, the free ends of the U-legs 112, 113 are tiltably attached to the free ends of the outer E-legs 132, 133 of the magnet core 130. The fastening is here made in such a way that the U-web 111 of the armature 110 overlaps the free end of the central leg 131 of the magnetic core 130. For this purpose, the U-legs 112, 113 of the armature 110 and the outer E-legs 132, 133 of the magnetic core 130 out of the plane of the U-web 111 and center leg 131 perpendicular to JE W 'weils a parallel to the leg axis located axis bent out, so that each one leg of the anchor and an outer leg of the core are opposite on a piece of their lengths in a parallel arrangement with little play. In this way, in turn, a particularly space-saving structure is achieved. The bearing points are formed here by "pin-shaped upsets 134 on the outer B-legs 132, 133 of the magnet core 130 and correspondingly adapted recesses 114 at the free ends of the U-legs 112, 113 of the magnet armature 110 to accommodate these upsets. Expediently, the Bearing as a cutting edge bearing and the delimitation wall of the recesses 114 designed in the shape of a selenium. Because of the small play of the pole surfaces at the bearing points and the large area of the foil, it is guaranteed that in the magnetic circuit formed by the magnet core t30 and magnet armature 110 there is practically only a single working air gap between Anchor and core in the area of the U-web 111, so no original

desired air gap is present. . ·

In order to give the magnet armature 110 a permanent bias in the direction of the Buhelage in which the insulating part 120 with a recess 122 firmly on an AnsohiagflMö ^ e 141 of the coil body I40 are coil springs 160, 170 with a low pedestrian constant between

10982 6 / 1A14 - 9 -

¥. Minks -2 _Λ - 9 * -

Anchors and core provided * This is also the Adjustment of the position of the magnet armature 110 on the magnet core 130 accomplished. To achieve a space-saving . Arrangement, these helical springs are accommodated parallel to the coil axis between the magnetic coil 150 and the housing side wall 47; of the magnet armature 110 and on the outer E-legs 132, 133 of the magnetic core 130 attached bearings 115 or 135 »which are preferably made by punching and bending can be.

As electrical leads for the excitation of the coil 15Q serve the connection parts 151, 152, the same as the connection parts 61, 71, 81 of the stationary contact parts 60, 70, 80 in the grid dimension of the printed circuit can be arranged. However, it is also possible to use only a part of the entire connection parts, e.g. the connection parts 151, 152 for the excitation coil 150, to be attached in a grid-like arrangement. The other connecting parts are then directed away from the printed circuit board and can e.g. be part of a conventional plug connection. If, on the other hand, all connecting parts 61, * ··, 152 for one Plug connection are provided, so the Beiais by means of a separate fastening means, e.g.

Sheet metal bracket, on a slide-in unit or a base plate be held.

The magnetic core 130 is fastened in the housing 40 advantageously in the manner of a snap connection. For this purpose, the E-web 136 of the magnetic core 130 is provided with a Recess 137 for receiving a housing nose 43 and with an approach T38 for engagement in a housing recess 44 '/ see, while the middle leg 131 of the lay net core at rjoinem free end with; an appendix I 39

1 09 8 26 / HU ~

W. Minks -2

a housing shoulder 45 engages over and on an elastic, resilient G-ehäuselager 46 is applied under tension. It it is easy to see that in this way the magnetic core 130 by simply plugging it into the housing 40, ie 5 is secured against rotation and displacement without special fasteners. The housing bearing 46 is used at the same time as a stop for the bobbin 140, which thereby Is fixed shift-safe. The connection of the bobbin I-40 with the middle leg 1 3I of the Magnetic core 1 30 takes place through a simple form fit of the both bodies. '

The operation of the relay is described in more detail below; .

When the excitation coil 150 is not excited, the magnet armature becomes 110 in its starting position by the helical tension springs 160, 170 held. These coil springs continuously exert their predetermined tension on the armature 110 and bias it against the stop surface 141. The magnet armature 110 is in the starting position the movable contact parts 91 in their right operating position and establish an electrical connection with the stationary contact parts 70. For, the required Contact pressure between movable contact parts 91 and stationary contact parts 70 ensure in this operating state the helical compression springs 100.

When the excitation coil 150 is excited, the magnet armature TTO against the top of the central leg 131 of the magnetic core 130 against the spring action of the helical compression springs 100 and the tension coil springs 160, 170 sucked in. The one arranged on the U-oteg 111 of the magnetic armature 110 Insulating material part 120 moves the "spring leg" 92 In Abwarksrichtnng, - whereby the contact connections

109 826 / UTA-

W. Minks -2 .-, - M -

between the stationary contact parts 70 and the "movable Contact parts 91 canceled and contact connections between the stationary contact parts 60 and the. movable contact parts are made. In this The operating state shown in the drawing is provided by the spring legs acting as movable contact parts 91 even for the required contact pressure by compressing the helical compression springs 100 further and overbend these spring legs accordingly will. For the purpose of soft contact, the pivot levers 90, which are designed at right angles, are at their B screw compression springs 100 facing ends divided like a fork.

When the excitation coil 150 is de-energized, below the Action of the springs 91 »100, 160, 1? 0 ex- ■ The magnet armature 110 exerted unified astringent pressures back to its original position.

Appendix ι

10 claims
1 sheet drawing
1 Directory of the used

Designations ..--. ■.

1G & 826 / UU

Claims (1)

W. HiiLks -2 Claims Electromagnetic flat relay with a magnet core that carries the excitation coil and one that is hinged to it Magnetic armature that moves approximately perpendicular to the coil axis and to hold, guide and reset it several spring elements of low spring constant are used, one of which is in the form of a preloaded Compression spring at the same time for the required contact pressure between a movable contact part and a stationary one Contact part provides, characterized that the compression spring (100) engages an angled pivot lever (90) made of spring material, whose one leg (92) with the anchor (110) in kr Pf inconclusive Connection stands and iot pivotally mounted on a fixed relay part (80), while the other Spring leg (91) carries or carries the movable contact part forms, and that the compression spring (100), pivot lever (90), contact parts (60, 70) and relay part (80) approximately in the axial direction the excitation coil (150) are arranged. 2.) Relay according to claim 1, characterized in that more movable Contact part (91) and the actuation system (30) formed from compression spring (100) and pivot lever (90) cu are combined in one structural unit. J.) Relay according to claim 1 or 2, characterized in that that the pivotably mounted Feä.erschenkel (92) of the pivot lever (90) approximately in the axial direction of the excitation coil (150) runs and is connected to the compression spring (100), while the one which carries or forms the movable contact part Spring leg (91) of the pivot lever with the pivotable mounted spring legs approximately a right angle includes. O - i- - 109826 / UTA BATH ORIGINAL A-.) Relay according to one of Claims 1 "to 3, characterized in that a stationary contact part (80) which is connected to the movable contact part ( 91) is electrically connected via this spring leg. 5) Relay according to one of Claims 1 to 4, characterized in that that the compression spring (100) on the pivot lever (90) in all positions of the armature (110) a rectified Torque exerts. 6.) Relay according to claim 5, characterized in that the Compression spring (100) in the form of a helical spring with its end facing away from the pivot lever (90) at a fixed end Relay part (42) is mounted in such a way that the spring axis is slightly inclined relative to the axis of the excitation coil (150) is. 7.) Relay according to one of claims 1 to 6, characterized in that the force-locking connection with the magnet armature (110) standing spring leg (92) of the pivot ^: hebeis (90) is electrically isolated from the armature. 8.) Relay according to claim 7 »characterized in that for ) electrical insulation a on the magnet armature (110) arranged Isolierstoffter'l (120) is used, which on its side facing the pivot lever (90) has a nose-shaped port set (121) for entrainment of the rocking lever. 109826 / UU V /. ! left -2 Jb - '& - 9 ·) Relay according to one of claims 1 "to 8, characterized in that several juxtaposed prestressed Compression springs (100) are provided, each on an angled pivot lever (90) made of spring material attack and for the required contact pressure between each associated movable contact part (91) and a stationary contact part (70). 10.) Relay according to one of claims 1 to 9 »characterized in that that the spring element (s) (160, 170) used solely to reset the magnet armature (110) consist of compression springs and essentially in the direction parallel to the axis of the excitation coil (150) between this and the side walls (47) of the housing (40) are arranged. Kb / b - December 9, 1969