EP0391086A1 - Push button operated overload circuit breaker - Google Patents

Abstract

The invention relates to a push-button operated overload circuit breaker, especially an on-board network circuit breaker with a manual trip mechanism and a bimetallically controlled free-trip mechanism with a breaker mechanism (7), which can be operated by the push-button (41), and a bimetallic trip mechanism device, for releasing the breaker mechanism (7), which has a bimetallic strip (101) which is self-heated, is designed as an approximately U-shaped stamped part and is connected, via the circuit breaker, electrically in series in the current path. One free limb end (102) of the said bimetallic strip (101) is mounted on the inner end with respect to the housing of the one connecting tab (5), fixed in the housing, of the circuit breaker. The second free limb end (104) of the said bimetallic strip (101) is mounted on a connecting piece (106, 106') to an opposing contact (9'), fixed to the housing. The base (114) forms the deflection end of the bimetallic strip which is kinematically connected to the breaker mechanism. …<??>Between the connecting lugs (105) of the connecting piece (106, 106') for the second limb end (104) of the bimetallic strip (101) and the region of the connecting piece (106, 106') adjacent to the opposing contact which is fixed to the housing, said connecting piece has a constriction (111) which is formed by a slot passing through the plate-shaped central section of the connecting piece (106, 106') at right angles to the plane of the plate. The connecting lug (105) can be rotated about the constriction from the base side of the circuit breaker housing, by means of an adjusting screw (110) acting on the central section, in order to adjust the response threshold of the bimetallic strip (101). …<IMAGE>…

Description

The invention relates to a push-button-operated overcurrent protection switch and in particular to an on-board circuit breaker with manual release and bimetallic free release with the features specified in the preamble of claim 1.

Such overcurrent protection switches are known for example from DE-C 21 23 765 or EP-A 0 081 290. In the case of these switches, the bimetallic element of the bimetallic release device is arranged essentially parallel to the narrow side wall of the switch housing running in the pressure direction (D). The adjustment is carried out using an adjusting screw, which passes through a hole in this side wall and acts directly on the bimetal or on its connecting base.

The accuracy of the bimetal adjustment in the known switches leaves something to be desired. In addition, direct exposure to the bimetal or its connecting foot should be avoided.

In the overcurrent protection switch known from US-C-36 97 915 there is already an improvement in this regard. Here, the connection lug and the area of a connecting piece adjoining the mating contact fixed to the housing to the mating contact fixed to the housing are held in a fitting and fixed manner in corresponding bearing recesses in the housing. In addition, the bimetal is not used for adjustment, but the connector inside the housing Area is acted upon by an adjusting screw screwed into the side of the switch housing. In order to facilitate the adjustment displacement of the part of the connector inside the housing, a cross-sectional reduction in the form of depressions in the lateral surfaces of the connector is provided between the fixing area on the housing and the application area by the adjusting screw.

Furthermore, an electrical overload switch is known from DE-U-88 06 964.8, in which the strip-shaped bimetal is fastened to a connecting piece, which is also held in a fitting and fixed manner in corresponding bearing gaps in the housing. This connector has an extension which can be acted upon by an adjusting screw from the opposite side of the switch housing for adjusting the response value of the bimetal.

Starting from the above-described overcurrent protection switches according to the prior art, the invention is based on the object of further improving a push-button-operated overcurrent protection switch of the type mentioned with regard to the adjustability of the bimetal.

The solution to this problem is specified in the characterizing features of claim 1.

Between the connecting tab of the connecting piece for the second leg end of the bimetal and the area of the connecting piece adjoining the mating contact fixed to the housing, the latter has a constriction, which is formed by a slot penetrating the plate-shaped central section of the connecting piece transversely to the plate plane. The connecting tab can be rotated around the constriction by means of an adjusting screw for adjusting the response value of the bimetal. Due to this construction, the tripping value of the bimetal can be adjusted in a particularly sensitive and exact manner by bracing the two bimetal legs against each other.

The narrowing further has the advantage that the heat generated by the bimetal self-heating for tripping flows less quickly from the bimetal into the adjacent conductor parts of the assembly. This means that the nominal tripping value is more reproducible and less scattered.

Claims 2 and 3 characterize advantageous designs of the slot and the mounting of the adjusting screw in the housing. In this way, the slot can be produced particularly easily immediately when the connecting piece is punched, in the case of a realization by means of an arcuate punching. The adjusting screw is held captively in the housing by its radially protruding rim, which is supported in a housing groove, on its head.

The bimetallic assembly is fixed even better in the housing by the extension of the terminal lug at its inner end and its precise, firm fit in a corresponding housing recess.

The characterizing part of claim 5 describes a bimetallic release device which has two bimetals. As a result, a self-heated bimetal device can also be used for small nominal currents, which, in addition, does not provide any lower triggering forces in comparison with a one-piece bimetal. Due to the sandwich construction claimed, the entire bimetal device remains very compact and can be arranged and used essentially like a one-piece bimetal. The insulating layer between the two bimetals shields the latter from one another in such a way that the full current path is maintained through the total length of the two bimetals.

In claim 6, a structurally particularly simple sandwich construction is specified, which can be relied upon sige and permanent connection between the two bimetals in the form of a weld, soldering or the like. distinguished. The form-identical formation of the two bimetals is advantageous for manufacturing and storage reasons.

Due to the meandering course of the legs and the base of the U-shaped bimetals (claim 7), the response nominal current can be further drastically reduced with essentially unchanged bimetallic dimensions. In order to compensate for the mechanical weakening of the bimetal through the meandering design of the legs and the base, brace-like stiffeners are provided according to claim 8, which can be placed on said bimetal sections with the interposition of appropriate insulating layers. The bimetal device of this type thus also has essentially unchanged mechanical properties.

Claims 9 and 10 characterize a so-called fail-safe for the switch. This is advantageously integrated in the connector of the bimetallic device.

According to claim 11, the terminal lug, one or more bimetals, the connection piece, optionally provided with a fail-safe device, and the adjusting screw are combined to form a preassembled module which can be installed as a whole in the switch. This also has advantages in terms of automatic production when mounting the switch.

Claims 12 and 13 characterize an advantageous further development of the bimetallic assembly with which a rapid response of the bimetallic tripping device is achieved in the case of high currents, in particular in the event of a short circuit.

By the U-shaped extension of the connector, which flanks the U-shaped bimetal on the side, a so-called called "current loop" created, in which through the corresponding electrical and mechanical connection of the free end of the extension to the corresponding leg end of the bimetal, the current flowing through these two components in the corresponding sections in opposite directions. According to the known laws of electrodynamics, this causes a repulsion between the extension of the connector and the bimetal. Since the connector and its extension are fixed in the housing, the repulsive forces act fully on the bimetal, which is therefore deflected in its triggering direction via its normal, heat-induced deflection, and above all immediately with the onset of the high current from its rest position.

Due to the insulating layer between the extension of the connector and the bimetal specified in claim 13, these two components can be positioned particularly close to one another without the risk of an electrical short circuit, so that a particularly high repulsion effect is achieved with a very short tripping time.

It should be emphasized that with small currents, such as those that occur in the event of an overload, the dynamic effect of the "current loop" does not come into play or only to a negligible extent. In this case, the bimetal bending caused by the heating alone triggers the overcurrent protection switch.

• Fig. 1 eine perspektivische Außenansicht des Überstrom­schutzschalters,
• Fig. 2 eine perspektivische Explosionsdarstellung des Schalters, getrennt in funktionalen Baugruppen,
• Fig. 3-5 jeweils einen Längsschnitt durch den Schalter entlang der Teilungsfuge zwischen den beiden Ge­häusehalbschalen in Ausschalt-, Einschalt- und Über­strom-bedingter Auslösestellung des Schaltschlosses,
• Fig. 6 eine perspektivische Explosionsdarstellung einer Bimetallvorrichtung in einer ersten alternativen Ausführungsform,
• Fig. 7 eine perspektivische Explosionsdarstellung einer Bimetallvorrichtung in einer zweiten alternativen Ausführungsform,
• Fig. 8 eine perspektivische Darstellung der Bimetallvor­richtung nach Fig. 7,
• Fig. 9 eine perspektivische Darstellung einer Bimetall­vorrichtung mit integrierter Ausfallsicherung.
• Fig. 10 eine perspektivische Darstellung einer Bimetallvorrichtung mit "Stromschleife" und
• Fig. 11 eine perspektivische Explosionsdarstellung der Bi­metallvorrichtung nach Fig. 10.

Further features, details and advantages of the invention can be gathered from the following description, in which various exemplary embodiments of the subject matter of the invention are explained in more detail with reference to the attached figures. Show it:

• 1 is an external perspective view of the overcurrent protection switch,
• 2 is an exploded perspective view of the switch, separated in functional assemblies,
• 3-5 each a longitudinal section through the switch along the dividing joint between the two housing half-shells in the switch-off, switch-on and overcurrent-dependent release position of the switch lock,
• 6 is an exploded perspective view of a bimetallic device in a first alternative embodiment,
• 7 is an exploded perspective view of a bimetallic device in a second alternative embodiment,
• 8 is a perspective view of the bimetal device according to FIG. 7,
• Fig. 9 is a perspective view of a bimetallic device with integrated failover.
• Fig. 10 is a perspective view of a bimetallic device with "current loop" and
• 11 is an exploded perspective view of the bimetal device according to FIG. 10.

In Fig. 1 the external view of the switch according to the invention is shown. This has an approximately cuboidal housing made of insulating material, which is composed of two housing half-shells (1, 2), on the front narrow side wall (3) of which the push-button assembly (4) with its threaded neck (40) and the push-button (2) which is longitudinally displaceable in the direction of pressure (D) 41) is used. From the opposite, bottom-side narrow side wall (3 '), the two angled connecting lugs (5,6) protrude from the switch housing.

Fig. 2 shows the various functional assemblies that are incorporated in the switch. In addition to the push-button assembly (4), these are the key switch (7) and the bimetallic assembly (10), which is electrically and mechanically connected to the one connecting lug (5). Detached from the modules in Fig. 2 are still the second connection flag (6) recognizable, which carries a housing-fixed mating contact (9) of the switching path on an inner extension (8). In the lateral edge area of the upper narrow side wall (3), the locking lug (11) is rotatably held between the two housing half-shells (1, 2), which can be brought into engagement with the groove (42) on the outside of the threaded neck (40) and an anti-rotation device for represents the threaded neck (40) and the switch itself when it is installed in a control panel. Furthermore, a kinematic connecting element between the switching lock (7) and the bimetallic assembly (10) forming, frame-like release lever (12) and the adjustment cover (13) which can be snapped onto the lower narrow side wall (3 ') should be mentioned.

The centerpiece of the bimetallic assembly (10) is the bimetal (101), which is designed as a flat, U-shaped stamped and bent part and is attached with its one leg-free end (102) to the housing-internal extension (103) of the connecting lug (5). The second leg-free end (104) is welded to the bent-up connecting tab (105) of a connecting piece (106) which, at its diametrically opposite end, carries an extension (107), which is also bent upwards, with the second mating contact (9 ') of the switching path. The two mating contacts (9,9 ') are arranged with their contact surface in a plane which runs transversely to the parting plane between the two housing half-shells (1,2) and approximately parallel to the pressure direction (D). At an approximately central position, the connecting piece (106) has an arcuate punching (108), in the center of which a threaded hole (109) is made. The adjusting screw (110) can be screwed in from the bottom narrow side wall (3 ') by rotating the connecting piece (106) about the constriction (111) formed by the punched out (108) so that the two legs (112, 113) of the bimetal ( 101) can be braced against one another and the triggering value of the bimetal (101) can thus be adjusted. The base (114) of the U-shaped bimetal (101) represents its deflecting end, its deflecting movement by means of the transfer slide (14) arranged in the housing transversely to the direction of pressure (D) below the push-button assembly (4) and the release lever (12) connected to the switch lock (7) in the sense the triggering of which is transmitted.

The switch is switched on and off manually by means of the push button (41) of the push button assembly (4), which is explained in more detail below with reference to FIGS. 3-6. The essentially cylindrical push button (41) made of insulating material is provided with a blind hole-like bearing recess (43) which is open towards the interior of the housing and extends in the pressure direction (D) and with which it is additionally guided on a guide part anchored in the housing in the pressure direction (D) is. The guide part is jointly formed by a cap-shaped, made of insulating counterbearing shaped part (44) for the helical spring-like push-button spring (46) clamped between it and the actuating side bottom (45) of the bearing recess (43) and the U-shaped supporting part in the longitudinal section parallel to the pressure direction ( 47) formed. The two U-legs (48, 49) point counter to the pressure direction (D) and their free ends are in engagement with the counter-bearing molded part (44). The support part (47) has in the apex area between its U-legs (48, 49) and its U-base (50) laterally projecting tabs (51), which are supported on a corresponding housing nose (52) (Fig. 2) . The support part (47) and the counter-bearing molded part (44) are thus held in position in the housing. The counter-bearing molded part (44) has, on its opposite side walls parallel to the direction of pressure, each in the pressure direction (D), with bottom open guide slots (67) for the axis (55). Due to their design, the support (47) and counterbearing molded part (44) in turn form a guide (53) running in the pressure direction (D) for a support lever (15) which extends essentially in the pressure direction (D) and with its push-button side End (16) via a rotary slide Articulated connection is connected to the inner end of the push button (41). This articulated connection is created by the axis (55) held on two lateral projections (54) of the push button (41) through the link-like elongated hole (17) in the push button end (16) of the support lever (15). The elongated hole (17) is of an angular shape, the leg (18) pointing counter to the pressure direction (D) parallel to this direction and the leg (19) pointing in the pressure direction (D) pointing in an acute direction, counter to the locking engagement direction (20) Angle (W) run. The support lever (15) has a latching projection (21) on the side next to the elongated hole (17) which, due to the displaceability of the support lever (15) in the pressure direction (D) and its pivotability transversely to this direction, engages with the latching recess (56) in one of the U-legs (48, 49) of the support part (47) can be brought.

The end (22) of the support lever (15) pointing in the direction of pressure (D) is connected to the switch lock (7) of the switch via an axis of rotation (70). The central part of this switch lock (7) is the L-shaped contact bridge support (71), which can be displaced in the pressure direction (D) and can be pivoted in a pivot plane parallel to this, and which in its apex area is connected to the interior of the housing via the swivel joint formed by the axis of rotation (70) End (22) of the support lever (15) is connected. The approximately in the direction of pressure (D) contact bridge leg (72) carries in the region of its free end, which is arranged transversely to the direction of pressure, bridging the two mating contacts (9,9 ') fixed to the housing, serving for the contact bridge (73). This is articulated to the contact bridge support (71) via the swivel connection (74). The pivot connection (74) is additionally acted upon in the contact closing direction by a contact pressure spring (75) designed as a leg spring.

The contact bridge support (71) is designed as a double leg spring which is seated on the axis of rotation (70) Switch-off spring (77) acts against the contact closing direction. The switch-off spring (77) is supported on the one hand by an oblique projection (23) (FIG. 2) on the inside of the housing half-shells (1, 2) and on the other hand on the upper side of the pawl leg (76) running transverse to the pressure direction (D).

At the free end (78) of the latch leg (76), an articulated lever (79) is articulated at one end, which can be fixed in a latch (V) with its opposite free end (80). For this purpose, the articulated lever (79) has at its free end (80) an axis (81) which runs transversely to the pressure direction (D) and which on the one hand passes through a longitudinal opening (82) of a pawl lever (83) which is pivotably mounted in the housing and which on the other hand is laterally displaceably guided at the ends of the housing grooves (24) which run approximately transversely to the pressure direction (D). The through opening (82) has an angled portion (84) at its end remote from the switching lock, in which the axis (81) can be latched to the housing grooves (24) in cooperation with the guide. The pivotable pawl lever (83), which is acted upon by the leg spring (85) in the latching direction, is kinematically connected to the bimetal (101) via the release lever (12) and the transfer slide (14). Whose deflection is transferred via the transfer slide (14) and the release lever (12) into a pivoting movement of the pawl lever (83) against the pawl engagement direction, so that the axis (81) is released from its latching.

The mode of operation of the switch according to the invention is explained below:

In Fig. 3 the switch is shown in its off position. If the push button is actuated, the axis (55) runs in the leg (18) of the elongated hole (17) parallel to the direction of pressure until it reaches the lower side edge of the elongated hole leg, which runs obliquely to this direction (19) hits. From this position, the support lever is moved in the pressure direction (D) and at the same time applied transversely to it. As soon as the locking projection (21) on the support lever (15) overlaps the locking recess (56) on the support part (47), the support lever (15) is pivoted counterclockwise with respect to FIG. 3 and the locking projection (21) engages in the locking recess (56) a. By moving the support lever (15) in the pressure direction (D), the contact bridge carrier (71) is simultaneously moved in a rotary-sliding movement into a position in which the contact bridge (73) is in the switched-on position (FIG. 4). The contact bridge (73) is fixed in the switched-on position by the locking of the support lever (15) and the associated fixing of the axis of rotation (70) to the contact bridge support (71) and the latching (V). The axis (55) of the push button (41) is held in this position in the sloping lower leg of the elongated hole (17), since the push button spring (46) is not able to hold the push button (41) and thus the axis (55) to apply such a force against the pressure direction (D) that the latching between the latching projection (21) on the support lever (15) and the latching recess (56) in the end part (47) could be released. However, if the pushbutton (41) is pulled to actuate the switch-off, the support lever (15) is pivoted clockwise by acting on the inclined side edge of the elongated hole leg (19) by means of the axis (55), the latching projection (21) is moved out of the latching recess (56). pulled out and thus released this locking. This allows the support lever (15) to move upwards, which pulls the contact bridge support (71) and transfers the contact bridge (73) to the switch-off position (FIG. 3).

In the event of an overcurrent-related triggering of the switch via the bimetal (101), the contact bridge support (71) is released by releasing the latch (V) and rotates under the influence of the switch-off spring (77) around the axis of rotation (70) clockwise with respect to FIG. 5. The contact opening through Lifting the contact bridge (73) from the mating contacts (9,9 ') also works in the case in which the push button (41) is held in its switch-on position. So it is a real free trip.

3-6, some details of the push-button assembly (4) are explained below. The counter-bearing molded part (44) has on its upper transverse wall (58) an integrally molded pin (57) which engages from below in the helical spring-like push-button spring (46) and additionally guides it. The support lever (15) passes through the U-base (50) of the support part (47) via a transverse slot (59) with lateral play, so that the support lever (15) remains pivotable. Furthermore, a cylindrical insulating sleeve (60) is inserted between the threaded neck (40) and the push button (41) and carries at its lower end a plate-shaped insulating cover (61) running transversely to the printing direction (D). The latter delimits the interior of the switch towards the push button side and has a circular opening (68) in the center corresponding to the inner opening of the insulating sleeve (60).

The insulating sleeve (60) has on its inner wall flanking the push button (41) a projection (62) which engages in a groove (42 ') in the outer wall of the push button to prevent rotation of the push button (41). The push button is also provided on its wall with a circumferential ring shoulder (63) which limits its insertion movement by a stop on the end face of the threaded neck (40) when the push button is actuated.

In the following, the fastening of the bimetallic assembly (10) in the housing and its adjustment will be discussed in more detail with reference to FIGS. 2-5. Thus, the interior of the extension (103) on the connecting lug (5) has a plate-shaped extension (115) which fits snugly and securely in a fixing pocket (27) formed by a side partition (26) in the housing half-shells (1, 2) is held in the housing. The extension (103) and consequently the attachment point of the bimetal leg (112) are thus held in their position and precisely defined.

Likewise, the area of the connecting piece (106) adjoining the extension (107) with the mating contact (9 ′) is in the bearing gap (25) between the narrow side wall (3 ′) on the bottom side and the angular projection (28) arranged in front of it in the housing half-shells ( 1,2) held precisely and firmly. In addition to a stable fixation of the bimetallic assembly (10), this tight mounting also achieves a special positional stability of the mating contact (9 ').

As already mentioned, the essentially plate-shaped connecting piece (106) is divided into two areas by an arcuate punch-out (108), which are connected by a constriction (111). The bimetallic device is adjusted by means of the adjusting screw (110), which is introduced into a threaded hole (109) in the radial center of the punched-out area (108) in the connecting piece (106). Aligned with this threaded bore (109), the narrow side wall (3 ') on the bottom side has an adjustment bore (29) in which the adjustment screw (110) lies and is accessible from the outside. On the opposite side of the adjustment bore (29), the angle projection (28) has a semicircular recess (30) in each housing half-shell (1, 2) in which the threaded end of the adjustment screw (110) can move freely. The adjustment bore (29) has an annular circumferential support groove (31) approximately in the middle of its inner wall, in which the radially projecting ring (117) is supported on the head (118) of the adjustment screw (110). As already indicated, twisting the adjusting screw (110) thus fixed in its longitudinal axial direction tilts the area of the connecting piece (106) on the part of the connecting tab (105) by twisting around the constriction (111), whereby the two legs (112, 113) of the bimetal (101) braced against each other and the response value of the bimetal (101) is changed accordingly. After the adjustment, the adjustment screw (110) is placed through the adjustment cover (13) which can be snapped onto the housing and is designed as a cap. The latter can be permanently connected to the housing, for example, by ultrasonic welding, which effectively prevents subsequent manipulation of the switch with regard to a change in the tripping nominal value.

The constriction (111) also represents a thermal resistance that prevents the heat required to respond to the bimetal (101) from the bimetal (101) via the connecting tab (105) and the connecting piece (106) from moving too quickly towards the counter contact ( 9 ′) flows off. A quick response and an exact adjustability of the bimetal (101) is thus achieved.

In Fig. 6, a first alternative design (10 ') of the bimetallic assembly is shown, in which instead of a bimetallic (101) two again approximately U-shaped bimetals (121,122) are used. These are arranged flat on one another in the manner of a sandwich construction with the interposition of an insulating layer (123). One bimetal (121) is attached with its leg free end (102) to the connecting lug (5), the second bimetal (122) is welded with its leg free end (104) to the connecting tab (105). The remaining leg free ends (102 ', 104') of the two bimetals (121, 122) have an inward bend (124). As can be seen from Fig. 6, the two bimetals (121, 122) are identically shaped, but arranged in a mirror-inverted manner, so that their bends (124) overlap one another in the installed position. In the overlap area, the corresponding insulating layer (123) is provided with a cutout (125), as a result of which the two bends (124) of the leg ends (102 ', 104') can be welded directly to one another and thus a permanent electrical and mechanical connection between the two bimetals (121,122 ′) is created. The latter are therefore electrical connected in series. This results in a doubling of the current path through the bimetallic device, which means that tripping is also possible at lower nominal currents. Due to the arrangement of the two bimetals (121, 122) on top of one another, the resulting triggering force remains essentially unchanged compared to the simple bimetal (101). A further reduction of the nominal tripping current is possible by making the bimetals thinner, while the mechanical construction is retained by the sandwich construction.

7 and 8, a further alternative embodiment (10˝) of the bimetallic assembly is shown, in which two bimetals (131, 132) are used, the legs (112, 113, 112 ', 113') of which have corresponding punched-outs and a meandering course. This multiplies the current path through these two bimetals (131, 132) and consequently reduces the tripping nominal current to a fraction. The two bimetals (131, 132) are arranged analogously to the bimetals (121, 122) in a so-called sandwich construction with an insulating layer (123 ') between them. Their shape is also identical and their installation position is mirror-inverted. The connection of their leg free ends (102, 104) to the connecting lug (6) and to the connecting tab (105) and their leg free ends (102 ', 104') to one another is carried out analogously to the bimetals (121, 122).

Since the bimetals (131, 132) are mechanically weakened by the meandering course of their legs, clamp-like stiffeners (133) are provided in the region of their base (114) and their leg ends (102, 102 ', 104, 104'), which on the above-mentioned bimetal sections with the interposition of further insulating plates (134) sit. Here, too, the release force is almost unchanged compared to the simple bimetal (101).

It should be pointed out that the adjustment of the alternative bimetallic assemblies (10 ', 10 Fig) according to FIG. 6 or FIGS. 7 and 8 takes place analogously to the adjustment for the bimetallic assembly (10) according to FIGS. 2-5.

9 shows a further alternative embodiment (10 ‴) of the bimetallic assembly, in which a so-called fail-safe is provided. In principle, this failure protection is already known from EP-A 0 081 290. For this purpose, the connecting piece (106 ') is separated approximately in the middle into two sections (119, 120) which are electrically connected by a thin sheet metal bridge (126). The sheet-metal bridge also represents the flexible, rotatable part in the connecting piece (106 ') which corresponds to the function of the constriction (111). In addition, it is a fusible conductor which is provided with several punched-out areas (127) to reduce the cross-section of the line. In the normal state of the switch shown, at least the central, circular punch (127 ') is sealed with solder (128).

The failover mentioned works as follows:

If a normal current flows through the switch, neither the bimetal device nor the fail-safe device responds. If an overcurrent flows, the bimetal (101) bends out and releases the latch (V) in the key switch (7) (FIG. 5) via the transfer slide (14) and the release lever (12). The contact bridge (73) of the switch should now go into its off position and interrupt the current flow through the switch. If this does not take place for some reason (defect in the switch lock, contact welding), the overcurrent continues to flow through the switch, which ensures further heating of the bimetal (101) and thus the connecting piece (106 '). After a short time, the connector (106 ') and the sheet metal bridge (126) will reach such a temperature that the solder (128) melts. This further reduces the line cross section of the sheet metal bridge (126), which in turn results in significant heating of the sheet metal bridge (126) and ultimately leads to melting of the sheet metal bridge (126). The flow of current through the switch is thus permanently and irreversibly interrupted. The entire defective switch must be replaced.

10 and 11 a further alternative bimetallic assembly 10˝˝ is shown with an improved tripping characteristic at high overcurrents. In this bimetallic assembly 10˝˝, the connector 5 'has no plate-shaped extension 115, but a U-shaped extension 135 which flanks the U-shaped bimetal 101 laterally. This means that in a plan view of the plane of the bimetal 101, the bimetal 101 and the extension 135 are arranged substantially overlapping.

The free end 136 of the extension 135 is welded to the leg free end 102 of the bimetal 101. The second leg-free end 104 of the bimetal 101 is welded to the connecting tab 105 of the connecting piece 106 analogously to the embodiment according to FIG. 2.

An L-shaped insulating layer 139 is inserted between the U-leg 137 attached to the connecting lug 5 and the U-base 138 of the extension 135 and the U-leg 113 flanked by these components and the base 114 of the bimetal 101.

The construction described results in the following current flow: The current entering the terminal lug 5 runs over the extension 135 in the direction indicated by the arrows. The current enters the latter via the connection point at the free ends 136, 102 of the extension 135 or of the bimetal 101 and runs through the bimetal 101 in the direction indicated by the arrows shown there, which are respectively opposite to the current directions in the individual sections of the extension 135 runs. The stream passes over the second shear kelfreiende 104 of the bimetal 101 in the connector 106 and there arrives at the mating contact 9 'for the contact bridge 73rd

Due to the opposite current directions mentioned in the bimetal 101 or the extension 135, these two parts repel each other strongly, particularly at high currents. By fixing the terminal lug 5 'and its extension 135 in the housing, these repulsive forces act in full as additional dynamic forces on the bimetal to deflect it in the direction of release. This effect occurs especially at currents above 1000 amperes. A particularly fast switch-off time is thus achieved in the event of a short circuit.

The dynamic effect of the current loop arrangement is not effective at small currents.

Reference numerals

• 1 housing half-shell
• 2 housing half-shell
• 3.3 ′ narrow side wall
• 4 push button assembly
• 5 connecting lugs
• 6 connecting lugs
• 7 key switch
• 8 extension
• 9.9 ′ counter contact
• 10, 10 ′, 10˝, 10 ‴, 10˝˝ bimetal assembly
• 11 locking nose
• 12 release lever
• 13 Adjustment cover
• 14 transfer valve
• 15 support lever
• 16 push-button end
• 17 slot
• 18 legs
• 19 legs
• 20 direction of engagement
• 21 locking projection
• 22 end
• 23 oblique projection
• 24 housing groove
• 25 bearing gap
• 26 partition
• 27 fixation pocket
• 28 angle arrangement
• 29 adjustment hole
• 30 recess
• 31 support groove
• 40 threaded neck
• 41 push button
• 42.42 ′ groove
• 43 bearing recess
• 44 counter bearing molded part
• 45 floor
• 46 push button spring
• 47 support part
• 48 U-legs
• 49 U-legs
• 50 U base
• 51 rags
• 52 housing nose
• 53 leadership
• 54 head start
• 55 axis
• 56 notch
• 57 cones
• 58 transverse wall
• 59 transverse slot
• 60 insulating sleeve
• 61 Insulating cover
• 62 head start
• 63 ring shoulder
• 70 axis of rotation
• 71 contact bridge support
• 72 contact bridge legs
• 73 contact bridge
• 74 swivel connection
• 75 contact pressure spring
• 76 jack legs
• 77 opening spring
• 78 freeers
• 79 articulated lever
• 80 free users
• 81 axis
• 82 access opening
• 83 ratchet lever
• 84 Angle
• 85 leg spring
• 101 bimetal
• 102,102 ′ leg free end
• 103 continuation
• 104, 104 ′ leg free ends
• 105 connection tabs
• 106,106 ′ connector
• 107 continuation
• 108 die cut
• 109 threaded hole
• 110 adjusting screw
• 111 narrowing
• 112,112 ′ leg
• 113,113 ′ leg
• 114 base
• 115 extension
• 117 wreath
• 118 head
• 119 section
• 120 section
• 121 bimetal
• 122 bimetal
• 123,123 ′ insulation layer
• 124 deflection
• 125 recess
• 126 sheet metal bridge
• 127,127 ′ punched out
• 128 fusible link
• 131 bimetal
• 132 bimetal
• 133 stiffening
• 134 insulating plates
• 135 extension
• 136 freeers
• 137 U-legs
• 138 U base
• 139 insulation layer

• D printing direction
• W angle
• V latch

Claims (13)

1. Push-button-operated overcurrent protection switch, in particular on-board circuit breaker with manual release and bimetal-controlled free release with
- A switch lock (7) which can be actuated by the push button (41) and by means of which a contact bridge (73) can be moved into the contact closing or opening position with respect to two mating contacts (9, 9 ')
- A bimetallic release device for releasing the switch lock (7), which has an electrically connected in series in the current path through the switch, self-heated, as an approximately U-shaped stamped part formed bimetal (101), the
a leg-free end (102) is fastened to the inside of the housing of the one terminal lug (5) of the switch fixed in the housing,
- Second leg free end (104) on a connecting piece (106,106 ') to a housing-fixed mating contact (9') is attached and
- Base (114) with the switching mechanism (7) kinematically connected deflecting end of the bimetal (101), the connecting lug (5) and the area of the connecting piece (106,106 ') adjacent to the housing-fixed mating contact (9') fit snugly, firmly are held in corresponding bearing recesses (fixing pocket 27, bearing gap 25) in the housing,
characterized by the following features
between the connecting tab (105) of the connecting piece (106,106 ') for the second leg end (104) of the bimetal (101) and the area of the connector adjacent to the mating contact (9') piece (106,106 ′) has a constriction (111),
- Which is formed by a plate-shaped central portion of the connecting piece (106,106 ') passing through the slot plane and
- Around which the connecting tab (105) can be rotated by acting on the central section by means of an adjusting screw (110) from the bottom of the switch housing to adjust the response value of the bimetal (101). 2. Overcurrent protection switch according to claim 1,
characterized,
that the slot is formed by an arcuate punching (108) in the plate-shaped central section of the connecting piece (106). 3. Overcurrent protection switch according to claim 2,
characterized,
that a threaded hole (109) is made centrally in the central section with respect to the arcuate punching (108), into which the adjusting screw (110), which is supported on its head (118) with a radially projecting ring (117) on its head (118), in a housing groove (support groove 31) can be screwed in. 4. Overcurrent protection switch according to one of the preceding claims,
characterized,
that the connecting lug (5) has at its inner end a preferably integrally formed extension (115), which in turn is held snugly in a corresponding housing recess (fixing pocket 27). 5. Overcurrent protection switch according to one of the preceding claims,
characterized,
that the bimetallic release device has two bimetals (121, 122),
- which are arranged flat on one another in the manner of a sandwich construction with the interposition of an insulating layer (123),
- Of which one with one leg end (102) on the connecting lug and the other with one leg end (104) are attached to the connecting piece and
- Which are electrically connected in series by an electrical connection between their remaining free leg ends (102 ', 104'). 6. Overcurrent protection switch according to claim 5,
characterized,
that the opposite free leg ends (102 ′, 104 ′) of the two bimetals (121, 122) overlap one another by an inward bend (124), the insulating layer (123) is cut out in the overlap area and a direct electrical connection between the overlapping leg ends (102 ′) , 104 ') by their mutual welding, soldering or the like. is created. 7. Overcurrent protection switch according to one of the preceding claims,
characterized,
that each of the legs (112,112 ', 113,113') and the base (114) of the one or more U-shaped bimetals (131,132) have a meandering course. 8. Overcurrent protection switch according to claim 7,
characterized,
that the one or more bimetals (131, 132) each in the area of the leg-free ends (102, 102 ', 104, 104') and the base (114) are provided with clamp-like stiffeners (133) which sit on the bimetallic sections mentioned with the interposition of appropriate insulating layers (insulating plate 134). 9. Overcurrent protection switch according to claim 1 and / or one of claims 4 to 8,
characterized,
that the connecting piece (106 ') for forming the slot is separated approximately in the middle into two sections, which are connected by a narrow sheet bridge (126) forming the constriction, which at the same time, as a fusible conductor, creates a fail-safe for the switch. 10. Overcurrent protection switch according to claim 9,
characterized,
that the sheet metal bridge (126) to reduce the line cross-section is provided with one or more punched-out areas (127, 127 ') which are closed with fusible link (128) in the normal state of the switch. 11. overcurrent protection switch according to one of the aforementioned claims,
characterized,
that the terminal lug (5), one or more bimetals (101 ', 121,121', 131,132), the connection piece (106,106 '), optionally provided with a fail-safe device, and the adjusting screw (110) to a preassembled bimetallic assembly (10,10', 10˝ , 10 ‴) are summarized, which can be installed as a whole in the switch. 12. Overcurrent protection switch according to one of the preceding claims,
characterized,
that the connector (5 ') is provided with a U-shaped extension (135) which flanks the U-shaped bimetal (101) laterally and with the free end (136) of which ent speaking leg free end (102) of the bimetal (101) is electrically and mechanically connected. 13. Overcurrent protection switch according to claim 12,
characterized,
that between the attached to the connector (5 ') U-leg (137) and the U-base (138) of the extension (135) and the flanked U-leg (113) and the base (114) of the bimetal (101 ) an L-shaped insulating layer (139) is used.

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