SE433688B - ELECTROMAGNETIC, POLARIZED RELAY - Google Patents

Description

É 1910636-s 2 glazing with each other for the right interaction between the details of the circuit, especially in a polarized relay with its greater sensitivity.

The dice also have the advantage that it can be made completely tight, whereby for example: penetration of gases in the relay yid soldering on circuit boards 'S hindras.

Other features and advantages of the invention will become apparent from the following description and claims, the description being given in the description for embodiments of the invention with reference to the accompanying drawings.

DESCRIPTION OF FIGURES Figs. 1-4 show details included in the iron circuit in a relay according to the finding and an advantageous arrangement of the details of the iron circuit.

Pig. 5 shows a basic structure of the iron circuit and flow circuits in this.

Fig. 6 shows a traction force diagram for the iron circuit according to Fig. 5. Fig. 7 shows an advantageous plastic coating of it in the iron circuit constituent core.

Fig. 8 shows a preferred embodiment of a casting of iron. the core, permanent magnet and shunt of the circuit and the arrangement of the anchor of the circuit after the casting._ Figs. 9a, b and c show a preferred design of a spring group adapted for interaction with the grout according to Fig. 8.

Fig. 10 shows an example of a spring group for performing several relay functions.

Fig. 11 shows on a larger scale a unit of springs punched out of one 25 metal sheets. ' 10 15 20 2 pcs 30 P00 iÄ lIUAL fi Y 7910636-5 3 Fig. 1 shows in perspective view the core 1. In this year the core U-shaped with a shoulder-shaped waist portion 2 and disc-shaped legs 3, 4.

The core is suitably made by bending a straight part. Life- the portion is almost square in cross-section, the corner edges are rounded embossed to approach a round cross section. Livpartiet forms a winding part for the core coil 5 (see Figs. 2 and 3) and the longer ones the side edge surfaces 6, 7 on the legs 3, 4 constitute the polytores of the core.

This can be seen from the plan view shown in Fig. 2 and the side view shown in Fig. 3 from the left in Fig. 2, the permanent magnet 8 of the iron circuit is located between the legs 3, 4 of the core next to the coil 5 and parallel to it.

Furthermore, in the embodiment shown, the permanent magnet abuts one iron piece 9, which serves as a magnetic shunt for permanent magnetization. ten. The embodiment also shows, that the permanent magnet and also the shunt is offset closer to one leg 4. This offset gives an effect that will be explained in more detail later in the description in connection with measures for the formation of a monostable relay. A similar effect is obtained when in one embodiment of the core the distance from the axis center of the winding part to the respective polyta is slightly different. This effect must also be reported in connection with the said measures.

Fig. 3 also illustrates the placement and storage of anchors 10 for assembly. action with the polytores 6, 7. The anchor is pivotally mounted around one centrally between the shanks and parallel to these arranged storage surface 11, which may be formed at a casing around the core, e.g. as shown in Fig. 8. The anchor acts as a seesaw for abutment against one or the other polytan.

The anchor is suitably constituted by a substantially rectangular disc, and can have a design as shown in Fig. 4 for co-operation with that shown in Fig. 8 storage. In this design protrudes at the center of the rectangular the long sides of the anchor drop 12 and 13, respectively, which constitute guides in anchor bearing. Furthermore, the anchor on its upper side is opposite the bearing 11 provided with plastic shafts 14, 15 which serve as lifting means for pipe metal springs for performing the functions of the relay, eg springs arranged ii __- ~. -; 'a spring group of the kind that '7910636-5 10 15 20 25 30 and P 4 shown in fig. 9 and 1U. The anchor also has projecting portions 16 respectively 17 at their short sides and the reason for this shall be clarified in connection with the description of the embodiment according to Fig. 8, for which the anchor shown in Fig. 4 is specially designed.

The principle and simple structure of the iron circuit in a relay according to the invention with the U-shaped core, entrained bl a the permanent magnet located in the space between the legs of the core and that large polytores 6 and 7 and at the same time long winding part, with disc-shaped anchor stored above a plane through the polytones and working like a seesaw against one or the other polyta of the core.

This construction enables a significant miniaturization of the relay.

Simplified, the magnetic circuit in such a relay can be illustrated on the following way with reference to Figs. S and 6: a. No current through the coil The permanent magnet leaves a flow island. This flow is distributed in the anchor to the pole gaps P1 and P2. The force with which the anchor lies against the pole ~ surface 6 can be expressed: Bmw-of 2 2 This gives point A in the traction diagram shown in Fig. 6. About anka- -ø If the force is applied to the surface 7, the force with which the anchor rests can this polyta is expressed in the same way: '2 2 }? (2) 62 I 01 This gives point C in the traction diagram. Point B then the force is obtained which wants to pull the anchor against the polytan 6 is as great as the force that wants pull the anchor towards the surface 7 (saw anchor in the middle position). Connected all points along the movement of the anchor, the traction curve A-C is obtained. b. Current applied coil The current is applied in such a direction that the produced coil flow is pumped for a direction according to Fig. 5. In pole gap P1 a total flow is then obtained - (01 - 65) and in pole gap P2 a total flow (ßz + 65). The flow in the pole gap 1 thus decreases while the flow in pole gap P2 increases. Thus, it decreases _áÖ. 15 20 25 30 7910636-5 5 force with which the armature is pulled against the polytane 6. 2 '2 F (1) r- (0 - 65) - (02 + 05) 1 Point A is moved to point D. For the sake of simplicity from the saturation phenomenon in the iron circuit, the whole curve is moved in parallel A-C down to the curve D-E.

The curve F-G also shown in Fig. 6 will be described later in connection with conditions for obtaining a monstable relay.

With reference to Figs. 7 and 8, an advantageous one will now be described embodiment with the above-described iron circuit, in addition to the anchor, cast _i plastic.

In a plastic tool, the core is provided with a plastic coating. The core with the plastic coating is illustrated in plan view in Fig. 7. The plastic coating is made to get insulation for the coil winding and get a mount for solder tabs. In addition, the plastic coating can create pole sheets for the anchor forming the anchor surfaces of the anchor at the on and off relay.

In the plastic coating shown in Fig. 7, the web portion 2 is completely covered with plastic in addition to a narrow gap 18 formed by the insulation where support heels from the plastic tool had abutment against the core 1. The free end part ' of one leg of the core, as shown for the leg 3, which part is used for guiding in the plastic tool, is not plastic coated. The core second leg 4, on the other hand, is molded in for coating even by its free end part, whereby some length variation of the core is accommodated within the plastic tool dimensions. Polytes 6 and 7 have no plastic coating with the exception of remove a smaller surface, which is covered by a plastic tab 19 and 20, respectively which constitute the above-mentioned pole plate for the anchor. The plastic coatings on the side surfaces of the legs are preferably raised to the same height as the plastic flaps to form abutment surfaces with them the anchor. The plastic coating is further formed on the outside of the legs. mad with heels 21 and 22 respectively for solder tabs (not shown).

Fig. 8 shows in view corresponding to Fig. 3 a casting of the core 1, per- the magnetic magnet 8 and the shunt 9 in a plastic cube 23 with an i Fig. 4 shows anchor 10 stored on the upper side 24 of the dice. 7919636-s 10 15 20 25 30 35- 6 the permanent magnet and the shunt, shown in broken lines, are located molded so that a completely plastic-filled cube is formed apart the parts of the polytes 6 and 7 not covered by the plastic flaps 19, 20 and the plastic flaps are in the upper plane of the dice. Before casting the core with the coil, shunt and permanent magnet has been placed in holders (not shown) inside the dice, which are designed and suitable for the correct position of said details. for the storage of the anchor 10, the upper surface of the cube at opposite edges has two projecting, upwards arched warts 25 and on either side of these projecting edges 26, wherein the distance between the edges 26 is slightly greater than the side of the anchor. guide pins 12 and 13 (see Fig. 4). These side guide pins can, as' appears from Fig. 4 to be different widths as well as in that case the said distance between the edges 26 in order to obtain the correct placement of the anchor.

The warts 25 form a bearing line for the flat underside of the anchor, i.e. corresponds to 11 in Fig. 3. The lower edge of the adjacent ones in Fig. 4. written protruding portions 16 and 17 at the short sides of the anchor constitute the anchor stops the movement towards the top of the dice. For reasons to be reported for in connection with Fig. 9, the dice have ledges 27 on its four side surfaces, one of which, marked with line 28, is offset relative to the others. _ The iron circuit completely cast into the dice, consisting of the core 1 with its coil, the permanent magnet 8 and the shunt 9, with the armature 10 placed in its bearing guides 25, 26 on the upper side of the cube form a unit.

By placing the anchor on the outside of the dice, this can be completely removed filled in, so that inside the dice there is no cavity and none moving parts. This is essential with the small details in question about the desired miniaturization of the relay. The miniaturization increased demands on the design of the details and the correct placement semellan for the correct interaction between the details of the iron circuit, especially in a polarized relay with its greater sensitivity. The dice also have the advantage that it is completely tight, whereby the penetration of gases into Ü the dice during fasuaaning on krerskarr are prevented.

The unit can be tested with respect to the stroke, the plastic locks 14 and 15 position over the top of the dice when the anchor is switched on or off and the traction of the relay. The top of the dice can be a 0-plane, from which all measurements both inwards and outwards are based. 10 15 20 25 30 35 7910636-5 7 As previously described in connection with Fig. 4, the anchor serves Plastic shafts 14, 15 as lifting means for movable metal springs for conducting the functions of the relay. Figs. 9 and 10 show an advantageous embodiment of such springs held together in a group. A feather- group is exemplified in the following with reference to Fig. 9 described in an embodiment adapted to the dice 23.

The spring group comprises a plastic frame 29 shown in plan view in Fig. 9a, which in Figs. 9b and 9c are shown after sections I-I respectively II-II in Fig. 9a. The frame has essentially the same outer dimensions as the dice 23. The inner dimensions of the frame are adapted for attaching the frame to the dice ledges 27, 28, the frame having a shorter side wall 30 that fills out the shorter ledge 28 in one side wall of the dice, while the frame other side walls 31 are the same length and fill in the ledges 2? in the other side walls of the dice. This ensures that the spring group the pen is correctly mounted on the dice. When the frame is mounted, the support surfaces 32, which are preferably a wart or the like in each corner, towards the top of the dice 24.

In two opposite side walls of the frame are a number of flat metal springs continuously cast, which are directed towards each other for overlap in pairs. In Fig. 9a, for the sake of simplicity, only one such pair is shown.

Each pair includes a short spring 33, which is thus closest immovably attached, and a long resilient movable spring 34. Preferably As shown in Fig. 9c, the short springs 33 are molded so that they lies in a plane parallel to a ptan through the support surfaces 32, while the long springs are cast in such a way that they form an angle with said plane.

Fig. 9c also shows contacts 35 and 36 on facing surfaces at the free ends of the short and long springs, respectively. That with one spring group cooperating armature displaces, when a relay is operating, they the long springs to contact the short springs. For example, in the above described anchor 10, its plastic axes affect the long springs when the relay works. _ The part of the springs that protrudes outside the frame is bent 900 and designed for a solder end. The spring group forms a unit that can be measured and adjusted with respect to the position of the springs, contact force, etc. with the four support surfaces 32 as 0-plane 1910536-s 10 15 20 25 30 35 8 By arranging a spring group as described above, the spring the pairs arranged next to each other in a just above an anchor position flat and can perform several functions after the influence of the anchor.

Fig. 10 gives an example of such a spring group.

As schematically shown in the embodiment according to Fig. 10, seven spring pairs arranged in the spring group in the plastic frame 29. In this case, missing the middle spring pair contacts, while the other spring pairs have contacts 35 and 36. The contact functions of these contacting springs pairs are arranged so that at one frame wall there are four closures S and at the opposite frame wall two slopes S. Depending on the anchorage The position of the year - the on or off switch - is thereby obtained by a relay with four closures and two breaks. The middle contactless spring the pair, which acts as the contact springs when acting on the anchor, is arranged to serve as an extra spring load on the anchor when turned on.

Fig. 11 shows on an enlarged scale a unit 37 of seven springs punched out from a metal sheet, the springs being held together by an edge frame 38, to which the solder ends 39 of the springs are connected, and of straps 40. Figs. also illustrates with dash-dotted lines the placement of the plastic frame 29. call in this molded-in unit. To form the spring shown in Fig. 10 pair is cut in a punched unit the springs along dashed line 41 and this unit is placed on a unit as shown in Fig. 11 without cutting off. after rotation 1800. After the casting of these units in the plastic frame 29, the edge frame 38 and the strips 40 are cut away. 39 located outside the frame 29 are bent down as mentioned above and the spring the group is adjusted. Except that the springs are cohesive j these units 37 also have the advantage of forming the spring group only punched units 37 of the same shape are needed.

The basic structure of a relay according to the invention and its magnetic circuit is shown in Figs. 5 and 6. This basic construction leads to a bistable relay, in which the anchor is located with permanent power as well in the starting stroke as in the on position. In a company drawn embodiment, a relay according to the invention shall function as a monostable relay, ie it must switch on when power is switched on coil and turn off when the power is turned off. To the condition of a 10 15 20 25 30 7910636-5 f; monostable relay shall be met, the characteristics of the spring group shall is accommodated in the area between curves A ~ C and D-E in that shown in Fig. 6 the traction force diagram, ie the spring characteristic must, for example, have a in the diagram shown by the curve F-G, where all points on the spring characteristic is between the curves A-C ~ and 5-5_ The function for switching on is: The anchor is against the cut-off side because the force from the permanent the magnet (point A) holding the anchor against the cut-off side is larger than the force with which the spring group wants to push the anchor from this _ page (point F). If current is applied to the coil in the direction mentioned above, point A is moved to point D. The force that wants to keep the anchor the offset side (point D) is now less than the force exerted by the spring the group has and who wants to push the anchor against the striking side. Since no point on the spring characteristic intersects the curve D ~ E can now anchor strike against the strike side.

The function when switched off is: _ The force that holds the anchor against the strike_side (point E) is greater than the force of the spring group which wants to push away from the anchor (point G). Cup- if the current is removed, point E will be moved to point C. The force which is provided by the permanent magnet and which wants to hold the anchor against the striking side is now less than the force of the spring group (point G) who want to push away from the anchor. Because no point on feather karak ~ the intersection intersects the curve A-C, the anchor will turn off against the 'side. _ - The bistable position is affected by placing the magnet 8 and / or the shunt 9 is asymmetrical with respect to the core 1, as shown, for example in Figs. 2 and 3. The tensile force then becomes different at the poles 6 and 7.

By loading an anchor, for example the anchor 10 with several functions on one side than on the other side of the anchor, eg four and two, respectively functions as illustrated in Fig. 10, different traction is required on and off.

By inserting an extra spring without contacts, eg the middle spring the pair in Fig. 10, an additional load is obtained, whereby the spring .-...._ WV. ~ _-._. .- - I 7910636-5 10 15 20 10 the group characteristics can be shaped in good accordance with the the shape of the power curves and an extra load are obtained on that side of the anchor where several functions are available.

By choosing different thicknesses of the pole plates for the polytones, e.g. the plastic flaps 19 and 20 shown in Fig. 7 and as a result have different distance from the axis center of the winding part 2 to the poles 6 and 7 as described in connection with Fig. 3, the traction force changes at qespektive frânslag. ' In summary, the relay has been given a monostable function by taking any or combination of any of the measures to - the permanent magnet is placed asymmetrically, the permanent magnet shunt is asymmetrically positioned, ~ the contact spring load is asymmetrical, - No co-actuating spring pair is provided, - the pole plates are different thicknesses, ~ the permanent magnet is obliquely magnetized, ~ the anchor bearing is asymmetrically placed between the poles.

The methods mentioned here were used individually or in collaboration to 1 of the bistable basic structure make a monostable relay. Sam- early on they were used to get a good fit between the slopes of the curves. and thereby allow increased manufacturing tolerances.

Claims (5)

10 10 1910636-5 11 PTETKRV 1 Electromagnetic, polarized relay whose iron circuit outside the armature is cast in, comprising a coiled core with polytes, an armature cooperating with the polytes and a permanent magnet arranged in a cube, the armature being stored at the dice for switching on and off against and from the polytes, characterized in that the core (1) and the permanent magnet (8) are molded into the cube (23) in such a way that before the molding the core (1) is provided with a plastic coating for insulating the coil (5) winding and for forming the polytones (6, 7) partially covering layers (19, 20) constituting abutment surfaces (pole plates) for the anchor (10). Relay according to claim 1, wherein the core (1) is substantially U-shaped with a shaft-shaped body portion (2) and legs (3, 4) emanating from the body portion, wherein the coil (5) is wound around the body portion and wherein the same hob faces side edges. (6, 7) on the legs form polytes, characterized in that the plastic coating also covers the other I sides of one leg (4) and at least partially the corresponding sides of the other leg (3), the plastic coating on the legs (3, 4) outer surfaces are designed to form brackets (21, 22) for solder tabs and wherein preferably the plastic coating on the outside and inside of the legs (3, 4) extends up to the level of said covering layer (19, 20) on the polytes (6 , 7). Relay according to claim 1 or 2, characterized in that said covering layer (19, 20) on the polytes (6, 7) is flush with said dice side. Relay according to any one of the preceding claims, characterized in that the polytes (6, 7) extend adjacent and parallel to two opposite edges of said dice side, and that the armature (10) has a width extension substantially corresponding to the polytores (6, 7). ) length and is like a seesaw mounted around a shaft (25) with the polytes substantially parallel. Relay according to one of Claims 2 to 4, characterized in that the permanent magnet (8) is located between the legs of the core (3, 4). 7910636-5 12 6 ACCORDING TO REQUIRED requirement 5, characterized in that the permanent magnet (8) is located closer to one leg (4) of the core. Relay according to one of the preceding claims, characterized in that a magnetic shunt is molded into the cube (23) facing the side of the permanent magnet (8) facing away from the armature (10).