DE2707794A1 - ELECTRIC SNAP SWITCH - Google Patents

Description

LEINWEBER & ZIMMERMANN

270779A

PATENT LAWYERS

Dipl.-Ing. H. Leinweber Dipl.-Ing. Heinz Zimmermann Dipl.-Ing. A. Gf. v. Wengersky

RoMfital 7, 8000 some 2

2. Ascent (Kustermann-Passage) Telephone (089) 2603989 Telex 528191 lepatd Telegr. Addr. Leinpat Munich

^ February 23, 1977

Under signs

mar sign

Z / Kg - P460
Spokesperson ϊ ~ Schuh AG., Aarau (Switzerland)
Electrical snap switch

The present invention relates to an electrical snap-action switch with a normally closed contact, its movable contact part is attached to a spring spring which, when triggered, by moving the contact part attached to it into an open position the normally closed contact opens, and with a normally open contact, the movable contact part of which is one-sided at the free end clamped spiral spring element is attached, which spiral spring element is coupled to the spring spring so that when Opening the normally closed contact the normally open contact is closed, as well as a use of this snap switch in a thermal Trigger.

Such snap switches are known. In particular, they have the disadvantage that their mode of operation is strong

709849/0651

depends on the properties of the leaf spring element.

The ^present: rfindung now aims to eliminate this "hteil, s represents Mh thus the Aui'gibe, a l.chnappGchalter the einean, <: to create ext 3 ihnten kind, practically in the Zigenochaften of Plattfederelenentes of the make contact not affect exercise the functioning of the pipe.

According to the invention, this task is essentially this is with the liuh ^ front closed and the work contact open the spring spring the leaf spring element in a tensioned doorway hit, so that the von Blattfederelenent on the Sprinc; feder Force exerted in the direction of the opening movement dee at the Snringfeder attached contact parts acts.

This snap switch is used in a thermal release, then this invention piemase is characterized by at least one actuating element actuated by at least one Spring spring acts and the latter triggers, u-n the rest contact to open and close the working contact.

In the following, execution examples of the subject matter are explained in more detail using the invoice.

7Q9849 / UÜ51

ORIGINAL INSPECTED

It shows schematically:

1 shows a snap switch of a known type,

2 shows a force-displacement diagram for a snap switch according to Fig. 1,

3 shows a snap switch according to the present invention,

4 shows a force-displacement diagram associated with the snap switch according to FIG. 3,

Fig. 5 shows a clamped spring spring in plan view, Fig. 6 shows the spring spring according to Fig. 5 in Seitenansi c:

7 shows a section along the line VII-VII in FIG. 5,

8-12 different types of clamping of the spring spring in a representation corresponding to FIG. 7,

1.3 and 14 embodiments of an adjustable clamping point for the spring spring,

15 in front view, and

16 shows a top view of a snap-action switch built into a housing.

In Fig. 1, a snap switch of known type is shown. One at one end in a clamping point 1 clamped spring spring 2 carries at its free end the movable contact part 3a of a break contact 3, the other contact part 3b is stationary. To trigger the

709849/0651

Spring spring 2 is a release slide, shown only schematically 4, which presses on the middle tongue 2a of the spring 2 when it is through a current flowing through, not shown Bimetal elements are actuated when the currents are too high. One clamped on one side at a clamping point 5 Leaf spring 6 carries at its free end the movable contact part 7a of a working contact 7, its other contact part 7b is stationary. The spring 2 and the leaf spring 6 are via a slidably guided plunger 8 to the common Movement coupled with each other. When the normally open contact 7 is open, the leaf spring 6 is completely or almost entirely in the relaxed state, in which it exerts no or only a small pressure force on the plunger 8.

If the spring 2 is triggered, the normally closed contact 3 is opened. Through this opening movement of the Spring spring 2, leaf spring 6 is deflected via plunger 8 and normally open contact 7 is closed.

In Fig. 2, the release force F acting on the spring 2 is a function of the path X. of the release slide 4, the spring force F .. of the spring 2 is a function of the process X _ft

until it is triggered and then in function of the / • / opening path of the contact part 3a and that on the plunger 8

Acting spring force F of the leaf spring 6 is shown as a function of the VegesX until it is triggered and then as a function of the ^ Yschlussweges Xs of the contact part 7a. The con-

709849/0651

clock force at the normally closed contact 3 results in ixus of the vectorial sum of the spring forces F ,, .. and F _1,. The spring force F ₁ is

Ko Ks Ks

in the closed position of the normally closed contact 3 is equal to zero, if the leaf spring 6 is in the open position of the normally open contact 4 in the completely relaxed state. If the spring force F .. is negative and equal to the spring force ρ , the spring spring 2 tilts (point K, Fig. 2). From this point on , the spring force F must be greater than the spring force F. This condition is in Fig. 2 only up to the point A x \ S

Fulfills. This point A is a stable point of the snap switch. Depending on the spring characteristics of the leaf spring 6 lies this point A with a smaller or larger closing path X

of the contact part 7a. The functioning of this known snap switch is therefore heavily dependent on the properties of the Leaf spring 6 and is influenced, among other things, by tolerance problems I of leaf spring 6.

In FIG. 3, in a representation corresponding to FIG. 1, a snap switch according to the present invention is shown Invention shown. Corresponding parts in FIGS. 1 and 3 are denoted by reference numerals in FIG compared to the reference numbers used in FIG. 1 are larger by the number 10. Instead of the plunger 8 in FIG. 1 are the spring spring 12 and the leaf spring 16 with one

Koppelungycrgan 19 coupled to each other, which is attached to the spring spring 12 is attached and when the normally closed contact holds the leaf spring 16 in a tensioned position, in deader Contact part 17a is lifted from contact part 17b. Irn In contrast to the embodiment according to FIG. 1, there is the leaf spring 16 with the normally closed contact 13 in the tensioned state, in which it exerts a tensile force on the spring 12 F "exercises, which is always greater than zero. When leaving

Ks

release the spring 12, the normally closed contact 13 is opened, wherein the coupling member 19 is the free end of the leaf spring

first takes t and then
16Y releases so that it can relax and the normally open contact * 17 is thereby closed. The spring force of the tensioned leaf spring 16 itself is used to close the working contact 17, while in the known snap switch according to FIG. 1 the spring force of the spring spring 2 is used to close the working contact 7.

The force-displacement diagram according to FIG. 4 belonging to the snap switch according to FIG. 3 corresponds to that of FIG. 1. F is the release force acting on the spring 12. The contact force at the normally closed contact 13 results here from the vectorial sum of the spring force F _v .. der

KO

Spring spring 12 and the spring force F of leaf spring 16.

Ks

The spring spring 16 tilts when the spring force F ₁ ... is still po-

KO

is positive and equal to the spring force F (point K, Fig. 4).

709849/0651 ^Ks

The spring 12 moves when triggered in a End position, not shown, in which the normally closed contact 13 is open and the normally open contact 17 is closed. This end position can be given by a stop, not shown, or by the free bending of the spring 12. The functioning of such a spring is described, for example, in Swiss patent specification 537 088. When resetting the spring 12 in the end position shown in Fig. 3, which is automatically or by a return member can take place, the leaf spring 16 is tensioned, whereby the working contact 17 is opened.

In the snap switch according to FIG. 3, the spring stiffness has the leaf spring 16. practically no longer has any influence on the tilting behavior of the spring 12.

In FIGS. 5-7, the spring 12 is shown in plan view, in side view or in section. Such a one Spring spring is e.g. in the already mentioned Swiss patent specification 537 088 and in the French patent specification 1 274 608. The spring 12 is clamped at one end in the clamping point 11 and carries the contact part 13a at its free end. At the clamped end, the spring 12 has two essentially parallel ones Legs 12b, 12c, between which the central tongue 12a is

709849/0651

_ΛΑ -

is arranged, which is shorter than the legs 12b, 12c. the Both legs 12b, 12c are at their ends between two connected to one another by means of screws 22, the clamping point 11 forming bearing plates 20,21 clamped. The ends of the legs 12, 12c are secured by rivet bolts 23 held biased in an approximated position. In this way it is achieved that the spring 12 of the end position shown in Fig. 6 jerks to the right in its other, not shown end position, when on the Tongue 2a a force F (Fig. 6) is exerted. By loading

limits the tilting movement of the spring 12 can be an automatic Resetting of the spring 12 can be achieved as soon as the force F disappears. However, the spring 12 tilts

in their dead center position, the reset must be carried out by a suitable reset device.

In order to improve the automatic resetting of the spring 12, the legs 12b, 12c are clamped asymmetrically in that the clamping plate 20 protrudes forwards by the amount a against the tongue 12a over the clamping plate 2 \ (FIG. 6).

Various embodiments of the clamping point 11 are shown in FIGS. 8-12. In the embodiments according to FIGS. 8-10, the lateral outer edge sections of the legs 12b, 12c are at an angle ^ K

70984440.651

bent away from the rest of the leg section in the tilted state. In Fig. Δ the bearing plate 20 is below for this purpose this angle o (bevelled. In Fig. 9 the over the bearings Plate 20 protruding lateral outer edge sections of the legs 12b, 12c bent upwards. In the embodiment according to Fig. 10 have both bearing plates 20,21 bevelled at the angle O ^ Surfaces between which the bent up lateral outer edge sections of the legs 12b, 12c are held. In the embodiment according to FIG. 11, the outer edge sections of the legs 12b, 12c are between the bearing plates 21 and 20a, and 20b, respectively, while the inner edge portions the legs 12b, 12c by the angle CX from the clamped outer edge sections are bent away.

In Figure 12, each leg 12412c is in one Storage purple, or 111b held. Any storage purple, 111b consists of two bearing plates 120a, 120b, or 121a, 121b, which hold the corresponding legs 12 £ 12C between them and are screwed together. The two bearings lilac or 112a are in their mutual by means of a screw 122 Distance adjustable.

13 and 14 show two spring springs 12 with an adjustable, pivotable clamping point 11. The two bearing plates 20, 21 are supported at one end via a compression spring 24 on a stationary part 25. In

709849/0651
- 9 -

the Lagcrp] old 20,21 is screwed in a screw 26, which extends through the spring 24. By turning the screw 26, the bearing plates are 20,21 from Fixed part 25 moved away or towards this, whereby a change in the position of the bearing plates 20,21 is achieved. At the other end, the bearing plates 20, 21 are over half a

70-9 & A9- / 06 51

spherical support member 27 is supported on a stationary part 28. This spherical support forms the stationary one The pivot point for the bearing plates 20, 21 when they are changed in their position by means of the screw 26.

In FIGS. 15 and 16, a snap switch according to FIG. 3 is shown in a front view and in plan view, respectively Housing 29 of a thermal relay shown installed. The spring 12 of the snap switch is as in the 5-7 shown. Bearing plates 20, 21 are attached to the housing wall 29a of the housing by means of the screws 22 29 attached. A connection terminal 30 is attached to the bearing plate 21. The stationary contact part 13b of the Break contact 13 is attached to a connection terminal part 31 which is screwed to the housing wall 29a. The stationary contact part 17 b of the normally open contact 17 is also attached to a connection terminal part 32, which is screwed to the housing 29. The clamping point 15 of the leaf spring 16 is connected to a connection terminal 33.

The longitudinal axis L._ of the spring 12 encloses an acute angle Lj with the adjacent housing wall 2Sa to which the spring 12 is attached (FIG. 16). In this way a space-saving arrangement is achieved. As Fig. 15 shows, the jumping

709849/0651
- ίο -

spring 12 and the leaf spring 16 are arranged so that, in a front view, the longitudinal axes L. _o , or 1, of the springs 12 and 16 include an obtuse angle.

In the embodiment according to FIGS. 15 and 16, the spring 12 and the spiral spring 16 are arranged so that that the spring 12 with the normally closed contact 13 on the Koppe lungse lines t 19 to the free end of the Leaf spring 16 exerts a compressive force in order to tension the spiral spring 16, while in the embodiment according to FIG the spring spring 12 tensions the leaf spring 16 by tensile force.

The snap-action switch shown has two electrically separate switching points, which are controlled by the normally closed contact 13 and the normally open contact 17 are formed.

The snap-action switch shown and described is particularly suitable for a thermal relay, e.g. for the protection of motors can be used.

- 11 -

709849/0651

Blank page

Claims (15)

Patent claims: Electrical snap-action switch with a normally closed contact, the movable contact part of which is attached to a spring spring which, when triggered, opens the normally closed contact by moving the contact part attached to it into an open position, and with a normally open contact whose movable contact part is attached to the free end of a cantilevered spiral spring element, which The spiral spring element is coupled to the spring spring in such a way that the normally open contact is closed when the normally closed contact is opened, characterized in that when the normally closed contact (13) and normally open contact (17) are closed, the spring (12) holds the leaf spring element (16) in a tensioned position, _{so that the force OV g} ) exerted by the leaf spring element (16) on the spring spring (12) acts in the direction of the opening movement of the contact part (13a) attached to the spring spring (12). 2. Snap switch according to claim 1, characterized in that the spring (12) clamped at one end is and carries the contact part (13a) at the free end. 3. Snap switch according to claim 1 or 2, characterized in that that a coupling element (19) is attached to the end of the spring (12) carrying the contact part (13a), which acts on the end of the spiral spring element (16) carrying the contact part (17a), around this end when the normally closed contact is closed (13) to be deflected by compressive or tensile force. 4. Snap switch according to claim 3, characterized in that the clamping points (11, 15) of the spring (12) and the leaf spring element (16) with respect to the direction of movement of the movable contact parts (13a, 17a) of the rest or Working contact (13, 17) are arranged opposite one another. - 12 7098 A 9/0 G51 ORIGINAL INSPECTED 5. Snap switch according to claim 2, characterized in that the spring spring (12) has two substantially parallel legs (12b, 12c) which are clamped at their end and between which a release tongue (12a) is arranged, which serves as a point of attack for a the spring (12) releasing force (F _A ) is used. 6. Snap switch according to claim 5, characterized in that that the ends of the legs (12b, 12c) between two bearing elements (20, 21) are held. 7. Snap switch according to claim 6, characterized in that the one bearing element (20) in the direction against the free The end of the spring (12) protrudes by an amount (a) over the other bearing element (21). 8. Snap switch according to one of claims 5 to 7, characterized in that the outer or inner edge portion of the clamped end of each leg (12b, 12c) relative to the rest of the leg section in the tilted state by one Angle (Ό are angled. 9. Snap switch according to claim 2, characterized in that the clamping point (11) of the spring spring (12) through Pivoting is changeable in their position. 10. Snap switch according to claims 6 and 9, characterized in that the bearing elements (20, 21) at one end are supported on an adjusting mechanism (24, 26) and are rotatable at the other end as seen in the longitudinal direction of the spring (12) are stored. 11. snap spring according to claim 5, characterized in that the end of each leg (12b, 12c) in a storage (111a, 111b) is held, the two bearings (111a, 111b) are adjustable in their mutual distance by an adjusting screw (122). - 13 709849/0651 12. Snap switch according to claim 11, characterized in that that each bearing (111a, 111b) is formed by two bearing elements (12Oa, 120b; 121a, 121b) connected to one another, between which the end of a leg (12b, 12c) is held. 13. Snap switch according to one of claims 1 to 12 for use in a thermal release, characterized by a triggering element (14) which can be actuated by at least one bimetal element and which, when actuated, acts on the spring (12) acts and the latter triggers to open the normally closed contact (13) and to close the normally open contact (17). 14. Snap switch according to claim 13, characterized by arrangement in a housing (29) of the thermal release, wherein the longitudinal axis (L ^) of the spring (12) with the neighboring Wall (29a) of the housing (29) encloses an acute angle (ß). 15. Snap switch according to claim 13 or 14, characterized in that the longitudinal axes (L ^ * L ^) of the spring spring (12) or the spiral spring element (16) in a direction perpendicular to these two longitudinal axes (L ^ * Lia) include an obtuse angle when seen. 709849/0651