EP0496212B1 - Switch mechanism for an electrical switch - Google Patents

Abstract

The invention relates to a switch mechanism for an electrical switch, the switch contacts of which switch are operated independently of the user. The switch mechanism is characterised by the following features: - a switch lever which interacts with a switch bush in a rotationally fixed manner and can pivot over part of a circle, - a switch shaft (22) which interacts in a positively locking manner with the switch bush, with play in the circumferential direction, - a spring support, which interacts in a positively locking manner with the switch bush, with play in the circumferential direction, - at least one spring, which acts on the spring support, the spring snapping over during rotation of the spring support, and the switch bush acting against the rotation direction of the switch lever until the point at which it snaps over, and acting in the rotation direction of the switch lever from the point at which it snaps over, - a bell crank (29), which is pretensioned by a spring, for operating the switch, the switch shaft interacting in a positively locking manner with a lever arm of the bell crank, with play in the circumferential direction, and the bell crank snapping over during the rotation of the switch shaft in order to initiate the switching process. In the switch mechanism according to the invention, the bell crank is moved as far as the point at which it snaps over via the switch lever, the switch bush and the switch shaft. Once it has passed this point, it is relieved of tension as a result of the spring force exerted on it and initiates the switching process. At the same time, the spring force which is exerted on the spring support acts in such a manner that the switch lever is moved into its switching position which represents the switching position of the bell crank. <IMAGE>

Description

The invention relates to a switching mechanism for a fuse switch in the form of a strip.

A switching mechanism for an electrical switch is known from DE-B 1 021 053, which forms the closest prior art.

For example, switchgear for fuse switch are known, in which the switching takes place with non-positive contact. The rear derailleurs are usually operated by means of a shift lever which is pivoted through an angle of approximately 90 ° for switching. Switchgear designs are known in which the switching lever after the fuse switch has been switched on remains in the switched-on position or those in which it is automatically returned to its starting position, so that the switching state ON or OFF is only partially recognizable as an optical display.

Fuse switch disconnectors are used in the form of strips, with the narrow fuse switch disconnectors generally being arranged immediately adjacent to one another. When the switching lever pivots from the switched-off position, in which the switching lever is aligned with the longitudinal axis of the strip, to the switched-on position, in which it is perpendicular to it and remains in it, the disadvantage is that the neighboring strip is covered by the switching lever is so that their accessibility is hindered. In contrast, when the switch lever pivots in the main plane of the strip, the switch lever projects forward when the fuse switch is switched on. In both of the variants mentioned, the good visibility of the switching state of the fuse switch is countered by the lack of user-friendliness.

It is an object of the present invention to provide a switching mechanism for an electrical switch with the switching contacts being operated independently of the user. A preferred further development is intended to ensure, in the case of a fuse switch, that it is optimally accessible in two switch positions with the switch lever in a different position.

The switching mechanism according to the invention is characterized by the features of patent claim 1.

In the switching mechanism according to the invention, the switching sleeve is correspondingly taken along when the switching lever is pivoted, for example from the OFF position of the switch. The result of this is that the selector shaft is carried along by the switching sleeve, that is to say is also pivoted. The selector shaft can be directly in the OFF position of the shift lever and the shift sleeve in positive engagement with the shift sleeve or only after a certain pivoting of the switching sleeve come into contact with a switching sleeve stop, which takes the switching shaft with it. However, the selector shaft is preferably already in the OFF position of the shift lever and the shift sleeve in positive engagement with the shift sleeve. Due to the positive connection between the switching sleeve and the spring carrier, the spring acting on it acts against the pivoting movement of the switching lever. The game between the switch sleeve and the spring carrier is expediently chosen so that the spring is biased from the OFF position immediately after initiation of the pivoting movement in the shift lever. However, it may also be possible to initially bridge a certain amount of play between the spring support and the switching sleeve before the positive connection between the spring support and switching sleeve takes place and the spring is thus preloaded. As a result of the positive locking of the switching sleeve and the switching shaft, the latter is pivoted so that one lever arm of the toggle lever is carried along. It is referred to in this context considered advantageous if the positive connection between the shift sleeve and the shift lever is only achieved after reaching a certain pivoting angle of the shift lever from its OFF position. This makes it possible to open or close a cover of the electrical switch, in particular a fuse switch, in an intermediate position of the switching lever, for example in order to replace a fuse after the cover has been opened. As soon as the positive connection between the shift sleeve and the shift shaft is established, the shift shaft is taken along in accordance with the further pivoting movement of the shift lever and the one lever arm of the toggle lever can be pivoted up to the snap-in position of the toggle lever. In this context, it is considered advantageous if the positive connection of the control shaft to the one lever arm of the toggle lever takes place only after the control shaft has been pivoted through a certain angular range from its initial position. - After the snap point of the toggle lever is reached, it is suddenly transferred to its other end position by the spring assigned to it. This sudden change in position of the toggle lever triggers the switch actuation, and the switch contacts of the switch can be acted upon directly or indirectly by the toggle lever. What is important is the relationship between the relaxation process of the toggle lever in relation to the relaxation process of the spring assigned to the spring support, which reaches its dead center position approximately when the snap-in point of the toggle lever is reached. If the rocker arm exceeds its snap position before the shift lever has transferred the spring to its dead center position, this leads to one lever of the toggle lever bridging the circumferential play of the shift shaft and moving it further in the previous sense of rotation, and thus also the shift sleeve and the spring support. Either this movement described leads during the relaxation of the toggle lever pretensioned by the spring to exceed the dead center of the spring assigned to the spring carrier, or else the switching mechanism is designed from the outset in such a way that the dead center of the spring interacts with the snap point of the toggle lever. In both cases, the relaxation of the spring leads to the fact that the spring carrier from the ingested Stop against the other stop moving in the direction of rotation is moved to the switching sleeve, with the result that the switching sleeve and thus the shift lever are pivoted by means of the spring into the end position, which corresponds to the ON position. - The switching process from the ON position of the switch to its OFF position takes place in the opposite sense.

According to a special embodiment of the invention it is provided that the shift lever can be pivoted through an angle of 180 °. Such a design is particularly useful in fuse switch switches in a strip design, so that the switch lever is oriented in the longitudinal direction of the strip in both switching positions and adjacent fuse switch strips remain freely accessible.

The shift lever is advantageously fixed in its two end positions and stops are provided for limiting its swivel angle. For this purpose, a shift knob can be firmly connected to the shift sleeve, which receives the shift lever in a rotationally fixed manner, a cam of the shift lever engaging in recesses in the housing in its rotational end positions and locking the shift lever, as well as coming out of the recess when the shift lever is raised, and pivoting the shift sleeve by means of the Shift lever allowed. The switching sleeve advantageously penetrates a housing wall of the switching mechanism, stops in the housing wall and on the switching sleeve are effective in the two rotary end positions of the switching lever.

According to a special embodiment of the invention, the switching sleeve has two diametrical guide pins, each guide pin engaging in a circumferential groove of the spring carrier which extends over a pitch circle. The switch sleeve should be able to rotate through an angle of approximately 120 ° relative to the spring bracket. The switching bridge preferably has a recess with a rotationally symmetrical inner recess region and two circular sector-shaped outer recess regions arranged diametrically to these, the inner recess region serves to receive a rotationally symmetrical part of the control shaft, and a pin part of the control shaft arranged radially on both sides of the rotationally symmetrical part engages in the outer peripheral regions. The selector shaft thus has in the region of its end facing the switching bridge a toggle extending perpendicular to its axis of rotation, which interacts with the outer diametrically arranged recess areas and via which the torque is introduced into the switching shaft or the switching bridge. The selector shaft should be rotatable through an angle of approximately 90 ° relative to the selector bridge.

The spring support is expediently designed with a recess corresponding to the cross-sectional shape of the selector shaft, with which the part of the selector shaft interacting with the selector sleeve is aligned in an intermediate position in the outer recess area. This configuration has the particular advantage that, in the intermediate position, the end projecting into the space between the switching sleeve and the spring carrier can be assembled or disassembled. This results in increased assembly security. The spring support advantageously has two diametrically arranged bearing journals, each bearing journal pivotably receiving a guide rod extending radially to the latter, the free end of which passes through a guide recess in the housing, the respective guide rod being inserted through the associated spring designed as a compression spring and which Spring is supported on the housing and on the guide rod. Both springs act on the spring carrier in such a way that they act on it with a moment in the same direction of rotation.

According to a particular embodiment of the invention, it is provided that the end of the selector shaft facing away from the shift lever has two eccentrically arranged switching pins which, with play in the circumferential direction, enclose a bolt arranged parallel to the bearing axis of the toggle lever, the one lever arm of the toggle lever being made up of two Swing arm formed is formed, and the Bolt connecting the ends of the rocker facing the two trunnions. The two switching pins are advantageously arranged concentrically to the axis of rotation of the switching shaft and enclose a circular sector of approximately 90 ° with one another, furthermore the toggle lever is tilted when the axis of rotation is rotated from approximately 60 to 70 °.

Constructively, the toggle lever is advantageously designed so that one lever arm can be pivoted about an axis fixed to the housing. The end of the lever arm facing away from the selector shaft is connected in an articulated manner to the other lever arm of the toggle lever, the end of which facing away from the connecting joint can be pivoted about an axis parallel to the housing-fixed axis of the one lever arm. Furthermore, for the articulated connection of the two lever arms, one lever arm is provided in its longitudinal direction with an elongated hole which penetrates a pin of the other lever arm. A pressure ring surrounds the one lever arm and rests on the pin, and a pressure spring is also provided which is supported on the side facing away from the pin on the pressure ring and on a switch shaft-side attachment of the one lever arm. Instead of a fixed connection of the pin with the other lever arm, the latter can also axially establish the relatively long slot in a lever arm and a relatively short slot introduced perpendicularly to the longitudinal extent of the other lever arm, which optimizes the tilt point of the toggle lever. One lever arm should be pivotable by an angle of approximately 40 to 45 ° and the other lever arm by an angle of approximately 70 to 80 °.

According to a special embodiment of the invention it is provided that the other lever arm interacts positively with play in the circumferential direction with a rotor rotatably mounted in the housing, the axis of rotation of which coincides with the axis of rotation of the other lever on the housing, the pivoting range of the rotor being limited by two stops. The rotor serves the purpose of triggering the actual switching process, which means that the switching takes place only indirectly via the toggle lever.

The pivoting angle of the rotor is expediently approximately 35 °. In connection with the use of a rotor for triggering the circuit, it is considered advantageous if two connecting rods are articulated on the circumferential area of the rotor which can be rotated via the pitch circle on one rotor side, and two actuating slides arranged parallel to one another and displaceable in the longitudinal direction thereof are provided. An actuating slide is articulated at the other end of the respective connecting rod and receives a contact bridge for connecting to a current path. The connecting rods are articulated on the rotor in such a way that the contact bridges perform opposite movements with respect to the same current path when the rotor moves over the pitch circle.

Further features of the invention are shown in the description of the figures, it being noted that all features and combinations of features are essential to the invention.

Figur 1

eine schematische Seitenansicht eines elektrischen Sicherungslastschalters in Leistenbauweise mit einem Schaltwerk,

Figur 2

einen Längsmittelschnitt durch den Deckel des Sicherungslastschalters im Bereich des Schalthebels,

Figuren 3a und 3b

räumliche Ansichten der Schaltbüchse von oben (Figur 3a) bzw. unten (Figur 3b),

Figuren 4a und 4b

räumliche Ansichten des Federträgers von oben (Figur 4a) bzw. unten (Figur 4b),

Figur 5

eine räumliche Ansicht der Führungsstange,

Figuren 6a und 6b

räumliche Ansichten des Schaltknaufes von oben (Figur 6a) und unten (Figur 6b),

Figuren 7a und 7b

räumliche Ansichten des Schalthebels von oben (Figur 7a) und unten (Figur 7b),

Figuren 8a,8b,8c,8d

das Schaltwerk in unterschiedlichen Stellungen des Kniehebels und des Rotors,

Figuren 9a,9b,9c,9d

für die Schaltstellung nach den Figuren 8a bis 8d entsprechende Schaltstellungen der beiden Schaltzapfen der Schaltwelle und des mit diesen zusammenwirkenden Bolzens der Kniehebelschwinge,

Figuren 10a, 10b, 10c, 10d, 10e

einen Schaltzyklus des Schaltwerkes zwischen der AUS-Stellung und der EIN-Stellung zur Verdeutlichung des Zusammenwirkens der Schaltbüchse, des Federträgers und der Schaltwelle.

In the figures, the invention is illustrated using an embodiment, without being limited to this. It shows:

Figure 1

1 shows a schematic side view of an electrical fuse switch in the form of a strip with a switching mechanism,

Figure 2

a longitudinal central section through the cover of the fuse switch in the area of the switch lever,

Figures 3a and 3b

three-dimensional views of the switching sleeve from above (FIG. 3a) or below (FIG. 3b),

Figures 4a and 4b

spatial views of the spring support from above (Figure 4a) or below (Figure 4b),

Figure 5

a spatial view of the guide rod,

Figures 6a and 6b

spatial views of the shift knob from above (FIG. 6a) and below (FIG. 6b),

Figures 7a and 7b

spatial views of the shift lever from above (Figure 7a) and below (Figure 7b),

Figures 8a, 8b, 8c, 8d

the rear derailleur in different positions of the toggle lever and the rotor,

Figures 9a, 9b, 9c, 9d

for the switching position according to FIGS. 8a to 8d, corresponding switching positions of the two switching pins of the switching shaft and of the bolt of the toggle linkage arm cooperating with them,

Figures 10a, 10b, 10c, 10d, 10e

a switching cycle of the rear derailleur between the OFF position and the ON position to illustrate the interaction of the switching sleeve, the spring support and the control shaft.

The electrical fuse switch disconnector 1 shown in FIG. 1 consists of three switch modules 2 which can be actuated via a common switching mechanism 3 arranged between two switch modules 2. The switch modules 2 and the switching mechanism 3 are connected to a cover 4 and a base part 5, which extend over the entire length of the strip. Each switch module 2 has an NH fuse link 6 with two contact blades 7, which are inserted into Lyra contacts 8. The lines 9 and 10 carry current to the fuse link 6 or away from it. Each line 9 and 10 has two separate, permanently arranged contact tracks 11 and 12, and by means of the switching mechanism according to the invention, contact bridges which move or move towards one another and which, in their switching position shown in FIG. 1, connect the two associated contact tracks 11 and 12, two actuating slides 15 and 16, which are arranged parallel to one another and are movable in the opposite direction to one another, are also provided. The one actuating slide 15 has axially displaceable in it the two contact bridges 13, which are each biased by two springs 17 in the closed position. The other actuating slide 16 accommodates the other two contact bridges 14 in an axially displaceable manner, each of these contact bridges 14 is biased into their closed position by means of a spring 18, in which they close diametrically to the other associated contact bridge 13 on the contact tracks 11 and 12 comes to lie. For the sake of simplicity, the springs 17 and 18 and the guide column of the contact bridges 13 and 14 in the actuating slides 15 and 16 are only illustrated in the switch module 2 shown on the left in FIG. In this regard, the other switch modules 2 are mirror images. As can also be seen from FIG. 1, the actuating slides 15 and 16 of the two switch modules 2 adjacent to the switching mechanism 3 are connected in an articulated manner to a rotor 20 via connecting rods 19. The actuating slide 15 and 16 of the two immediately adjacent switch modules 2 are also articulated to one another via connecting rods 21.

In the area of the switching mechanism 3, a switching shaft 22 passes through the cover 4. The switching shaft 22 can be pivoted in a manner yet to be described by means of a switching lever 23, the end of the switching shaft 22 facing this is provided with a pin 24 which is pressed into a through-bore and which is pressed extends radially outwards on both sides of the control shaft 22. The end of the control shaft 22 facing away from the pin 24 has a circular sector-shaped plate 24 extending perpendicular to the control shaft 22, the center of which coincides with the axis of rotation 26 of the control shaft 22 (see also the illustration in FIG. 9 for the description below). In the peripheral area, the circular sector-shaped plate 25 has two eccentrically arranged switching pins 27 and 28, which are directed towards the rotor 20. A toggle lever 29 interacts with the rotor 20 and the control shaft 22 (see also FIG. 8 for the description below). A lever arm 30 of the toggle lever 29 is mounted in the switching mechanism 3 about an axis 31 fixed to the housing. The end of the lever arm 30 facing away from the control shaft 22 is articulated to the other lever arm 32 of the toggle lever 29 by providing the lever arm 30 with a relatively long slot 33 in the longitudinal direction thereof. The other lever arm 32 is provided with a relatively short slot 46 perpendicular to its longitudinal direction. A pin 54 with thickened ends passes through both elongated holes 33 and 46, whereby the two lever arms are connected to one another in an articulated manner. A pressure ring 35 encloses the Lever arm 30 and abuts the pin 34. A compression spring 36 is supported on the side facing away from the pin 34 on the pressure ring 35 and an extension 37 on the switching shaft side of the lever arm 30. The end of the lever arm 32 facing away from the pin 34 can be pivoted about an axis 38, which also represents the axis of rotation for the rotor 20. This end of the lever arm 32 passes through a sector-shaped recess 39 in the rotor 20 which is delimited in the pivoting direction of the rotor 20 by two stops 40 and 41. These allow the lever arm 32 to pivot relative to the rotor 20 by an angle of approximately 35 °. The pivoting range of the rotor 20 is limited to approximately 35 ° in that a stop 42 fixed to the housing projects into the path of two projections 43 of the rotor 20. The lever arm region 44 facing the selector shaft 22 is designed as a rocker formed from two lever branches, the free ends of which connect a bolt 45 which penetrates the space between the two switching pins 27 and 28 of the selector shaft 22.

With regard to the following description of the components arranged in the cover area of the switching mechanism 3, reference is made to the illustration in FIGS. 2 to 7 and 10.

FIG. 2 shows a housing base 47 and a housing cover 48 which can be inserted therein, the housing cover 48 being provided with flange projections 49 which extend outside over the housing base 47. In the nested position of the housing base 47 and housing cover 48 shown in FIG. 2, the housing can be inserted into a recess in the cover 4, so that the two flange attachments 49 rest on the surface of the cover. The reference number 50 in FIG. 1 illustrates screwing points, in the area of which the connection between the housing cover 48 and thus the housing base 47 with the cover 4 takes place. The illustration in FIG. 2 shows that a switch sleeve 51 is received by the housing cover 48, which interacts with a spring support 52. The switching bridge 51 can be rotated by 180 ° in the housing cover 48 between two stops 53 and has on its side facing the housing base 47 two diametrical guide pins arranged on the switching sleeve diameter 54 and 55, each guide pin 54 or 55 engaging in a circumferential groove 56 or 57 of the spring carrier 52 extending over a pitch circle. The arc of the respective circumferential groove 56 or 57 is dimensioned such that the switching sleeve 51 can be rotated relative to the spring support 52 by an angle of approximately 120 °. As can further be seen from FIGS. 3 and 4, the side facing away from the circumferential grooves 56 and 57 and thus the switching sleeve 51 between the adjacent ends of the circumferential grooves 56 and 57 has two diametrically arranged bearing journals 58 and 59 connected to the spring support 52 which a recess 60 is arranged in the circular disc-shaped spring support 52. The recess 60 has a rotationally symmetrical inner recess region 61 as well as slit-shaped recess regions 62 extending from it and directed towards the bearing pins 58 and 59. The cross section of the recess 60 corresponds to the cross section of the selector shaft 22 with the pin 24 penetrating it vertically, so that the selector shaft 22 Cover with the recess 60 can be passed through this. Furthermore, the switching sleeve 51 has a recess 63 on its side facing the spring support 52, with a rotationally symmetrical inner recess region 64 and two circular sector-shaped outer recess regions 65 arranged diametrically to the latter, the inner recess region 64 serving to receive the rotationally symmetrical part of the switching shaft 22 and the pin 24 protruding from this on both sides into the outer recess areas 64. The end of the switching shaft 22 facing the switching sleeve 51 is additionally mounted radially in a recess 66 of the switching sleeve 51. The sector of the outer recess areas 65 extends over such an angle that the switching shaft 22 can be rotated relative to the switching bridge 51 by an angle of approximately 90 °. Relative to the contact of the switching shaft 22 on the wall 67 of the outer recess region 65 which hinders its rotation counterclockwise, its pin 24 is aligned with the two guide pins 54 and 55. When the pin 24 is in contact with the other wall 68, the pin 24 is in alignment of the shift lever 23. This is by means of the shift knob shown in Figures 6 69 attached, which can be plugged onto the switching sleeve 51 and firmly connected to it. In this case, a shoulder 70 arranged transversely to the longitudinal extent of the shift lever 23 on the underside of the shift knob 69 engages in a groove 71 of the shift sleeve 51, two pins 72 having an internal thread penetrating recesses 73 in the shoulder 70 and connecting the parts there by means of screws, not shown become. In a radially extending recess 74 in the shift knob 69, the shift lever 23 is pivotally mounted about an axis 75, the shift lever 23 having a latching nose 76 at a short distance from the axis 75, which only in the two switching positions offset by 180 ° ON-OFF in can engage two corresponding recesses 77 of the housing cover 48.

As can be seen from FIGS. 2, 4 and 5, a guide rod 78 is pivotally attached to the bearing pins 58 and 59, respectively, which freely passes through a guide recess 79 at its other end. For drawing reasons, only one of the guide rods and only the bearing pin 59 is shown in FIG. A compression spring 80 is supported on an enlarged section of the guide rod 78 facing the bearing journal 58 or 59 and the housing cover 48 in the region of the guide recess 79. The reduced in thickness, essentially T-shaped area of the guide rod 78 passes through the compression spring 80 and guides it. The length of the respective guide rod 78 is dimensioned such that it passes through the guide recess 79 in each operating position of the bearing pins 58 or 59.

The mode of operation of the switching mechanism described so far and also that of the electrical fuse switch in the form of a strip are described below:

To actuate the switch, it is first necessary to lift the switching lever 23, that is to say to pivot it away from the cover 4, so that the latching lug 76 disengages from the associated recess 77 in the housing cover 48. The kinematic relationships of the components in the lid area before the introduction of a Pivotal movement in the shift lever 23 result from the illustration in FIG. 10a. In this starting position, which corresponds to the switch position OFF, the axis designated by reference number 81 in FIG. 10a is aligned with the longitudinal axis of the shift lever 23. Because of the rotationally fixed connection of the shift lever 23 to the shift sleeve 51, the two guide pins 54 and 55 lie on the longitudinal axis 31 Because of the compression springs 80 which cooperate with the guide rods 78, the spring support 52 is given a torque which biases it into the OFF position in the switching position shown, so that the guide pins 54 and 55 abut the clockwise trailing end of the circumferential groove 56 and 57, respectively reach. In this position, the bearing journals 58 and 59 are located near their bottom dead center when the compression springs 80 are only slightly pretensioned. The journal 24 of the selector shaft 22 is in a position perpendicular to the longitudinal axis 81, the journal 24 on the respective clockwise wall the recess 63, thus the trailing wall 68. The slot-shaped recess area 62 of the spring support 52 is arranged in the clockwise direction at an angle of 60 ° to the pin 24. In the representation corresponding to the OFF position according to FIG. 10a, the drive for the switching mechanism, which is represented by the switching shaft 23 and the two guide pins 54 and 55, is in a defined starting position of 0 °, while the switching shaft representing the switching process is located 22 is in a position perpendicular to this, the position of the pin 24 of the control shaft 22 by definition also being designated 0 °. Figure 10b illustrates that when the drive rotates 60 °, the switch remains in the 0 ° position, but in this position the slot-shaped recess areas 62 in the spring support 52 come into congruence with the pin 24 of the control shaft 22, so that the control shaft 22 also the pin 24 could now be pulled out of the structure created by the switching sleeve 51 and the spring support 52 or, conversely, inserted into it. When the drive swivels through 90 °, the pin 24 of the selector shaft 22 comes in System with the wall 67 of the recess 63, so that the switching shaft 22 is pivoted with a further pivoting of the drive. During the pivotal movement of the drive, the springs 80 are biased more and more. FIG. 10d illustrates the kinematic conditions when the drive is pivoted by 150 ° and the switch by 60 °. In this position of the drive, the journals 58 and 59 of the spring support 52 are aligned with the longitudinal axis 81, so that a further pivoting of the drive would result in the guide rods 78 snapping over, with the result that the spring support 52 solely due to the relaxing effect of the springs 80 would be suddenly moved counterclockwise, the guide pins 54 and 55 would come out of contact with the circumferential limit of the circumferential grooves 56 and 57.

The kinematic conditions within the drive are superimposed on those of the switch, the following description refers to the representation of FIG. 10 in addition to that of FIGS. 8 and 9. FIGS. 8a and 9a show the switch position 0 °, that of the drive position from 0 to 90 °, in which it acts as a freewheel with respect to the switching shaft 22, the arrangement of the toggle lever 29 and the pin 45 relative to the two switching pins 27 and 28. In this position, the clockwise stop 42 of the rotor 20 lies on the stop 42 fixed to the housing to which, due to the articulation of the actuating slides 15 and 16 via the connecting rod 19 with the rotor 20, the contact bridges 13 and 14 are in the switched-off position. In this position of the rotor 20, the lever arm 32 bears against the stop 41, and the bolt 45 also bears against the switching pin 27 which leads in the sense of the direction of rotation of the switching shaft 22. When the control shaft 22 and thus the pin 24 penetrating it radially from the position shown in FIG. 10c is rotated by an angle of approximately 25 °, the control pin 28 bears against the bolt 45 and can move it in parallel with the further pivoting movement of the control shaft 22, until it has reached the tipping point shown in FIGS. 8b and 9b at about 60 °. Have in this the lever arms 30 and 32 of the rocker arm 29 slightly exceed the tilt axis corresponding to the axis 26, the compression spring 36 having been preloaded by means of the pressure ring 35 due to the movement of the pin 34 associated with the lever arm 32 in the slot 33 of the other lever arm 30. At the tipping point, the rotor 20 is in the unchanged position and the lever arm 20 bears against the stop 40 of the rotor 20. After slightly exceeding the tipping point, the compression spring 36 suddenly relaxes and moves the lever arm 32 together with the rotor 20, so that after a rotation of about 35 ° in its other end position shown in FIG. 8c, the clockwise projecting projection 43 on the stop fixed to the housing 42 comes to the plant. This position corresponds to the switched-on position of the switching bridges 13 and 14 shown in FIG. 1. The release of the compression spring 36 after the tipping point has been exceeded means that the lever arm 30 and thus the pin 45 assigned to the switching shaft 22 is also pivoted, so that it is removed from the switching pin 28 is moved away on the other switching pin 27. In the exemplary embodiment, the kinematics of the toggle lever 29 is designed with respect to the kinematics of the cover components assigned to the shift lever 23 such that the tipping point of the toggle lever 29 coincides with the snap point of the guide rods 78 acted on by the compression springs 80, as shown in FIGS. 8b and 9b. This leads to the fact that simultaneously with the triggering of the switching process by means of the toggle lever 29, the spring support 52 is suddenly moved further in the drive direction, so that the guide pins 54 and 55 connected to the switching sleeve 51 in the circumferential grooves 56 and 57 run counter-clockwise as viewed in the counterclockwise direction Limitations of these circumferential grooves 56 and 57 are moved and the spring support 52 takes the switching sleeve 51 and thus the switching lever 23 in its drive position of 180 ° during the final phase of relaxation of the compression springs 80, which is illustrated in FIG. 10e by the position of the guide pins 54 and 55 that come to rest on the longitudinal axis 81. About the movement of the switching sleeve 51, the pin 24 and thus the switching shaft 22 is taken into the switch position 90 °, which on the one hand from the Representation of Figure 10e and that of Figures 9d can be seen.

The switching mechanism according to the invention thus only allows the switching contacts 13 and 14 to be actuated independently of the user. Movement is applied to an intermediate link, in the present case the toggle lever 29, which triggers the switching process after the tipping point has been reached, regardless of whether the switching lever 23 is acted upon. On the other hand, the snapping of an actuator assigned to the switching lever 23, in the present case the guide rods pretensioned by means of the compression springs 80, means that the switching lever is forced into its position representing the switched-on state after the fuse switch has been switched independently. - The switching process from the ON position to the OFF position is reversed to that described above.

The invention is not limited to the fact that the tilt point of the toggle lever 29 coincides with the snap point of the guide rods 78. It only has to be ensured that the toggle lever 29 can be acted on by means of the switching shaft 22 until it reaches its tipping point. Since the positive connection between the shift shaft 22 and the shift lever 23 is released after the snap-in point of the guide rods 28 has been exceeded, the snap-in point can also be later than the tipping point. In this case, either the shift lever 23 continues to act on the switching sleeve 51, so that it moves the guide rods 28 via the positive point with the spring support 52 over the tipping point or the relaxing toggle lever reaching the tipping point acts by means of the bolt 45 on the switching shaft 22 assigned switching pin 27, which in turn acts via the pin 24 and the switching sleeve 51 on the spring support 52, which moves the guide rods 78 over the snap point. Basically, because of the inertia of the system, it is also conceivable that the snap point of the guide rods 78 is a few angular degrees before the tipping point of the toggle lever 29, so that until the rotor 20 is transferred from the switched-off to the switched on position of the shift lever 23 has moved the guide rods 78 in their snap point.

Claims (17)

1. A switch arrangement (3) for a safety-load switch (1) in strip form with a switch behaviour of the switch contacts (13, 14) of the switch which is independent from the actuator, comprising the following features:

   - a switch lever (23), which non-rotationally co-operates with a switch box (51) and which is pivotal over part of a circle;

   - a switch shaft (22), which positively co-operates with the switch box (51) in the presence of a play in the peripheral direction;

   - a spring carrier (52), which positively co-operates with a play of the switch box (51) in the peripheral direction;

   - at least one spring (80) which loads the spring carrier (52), and that the spring (80) toggles over during the rotation of the spring carrier (52) and loads the switch box (51) up to its toggle point against the rotary direction of the switch lever (23) and from its toggle point onwards in the rotary direction of the switch lever (23);

   - a springloaded toggle lever (29) for operating the switch, and that the switch shaft (22) positively co-operates with a play in the peripheral direction with a lever arm (30) of the toggle lever (29) and the toggle lever (29) toggles over during rotation of the switch shaft (22) so as to trigger the switch process.
2. A switch arrangement according to Claim 1, with the switch lever (23) being pivotal around an angle of 180°.
3. A switch arrangement according to Claim 1 or 2, with the switch lever (23) set in its two end positions and with stops (53) provided for limiting its pivot angle.
4. A switch arrangement according to one of Claims 1 to 3, with the switch box (51) being mounted in a housing (48) of the switch arrangement so as to be rotatable around the pivot angle of the switch lever (23), and with two diametral guide pins (54, 55), and that each guide pin (54, 55) engages a peripheral groove (56, 57) of the spring carrier (52) which extends over part of a circle.
5. A switch arrangement according to Claim 4, with the switch box (51) being rotatable by an angle of approximately 120° relative to the spring carrier (52).
6. A switch arrangement according to one of Claims 1 to 5, with the switch box (51) comprising a cutout (63), with a rotation-symmetrical inner cutout area (64) as well as diametrically thereto two circular-sector shaped outer cutout areas (65), and that the inner cutout area (64) serves to accommodate a rotation-symmetrical part of the switch shaft (22), and a pin portion (24) of the switch shaft (22) which is arranged on both sides radially to the rotation-symmetrical part which engages the outer cutout areas (65).
7. A switch arrangement according to Claim 6, with the switch shaft (22) being rotatable around an angle of approximately 90° relative to the switch box (51) .
8. A switch arrangement according to Claim 6 or 7, with the spring carrier (52) having a cutout (60), which corresponds with the cross-sectional shape of the switch shaft (22) and by means of which the portion of the switch shaft (22), which co-operates with the switch box (51), is seated in an intermediate position against the outer cutout area.
9. A switch arrangement according to one of Claims 1 to 8, with the spring carrier (52) comprising two diametrically arranged mounting pins (58, 59), and that each mounting pin (58, 59) pivotally accommodates a thereto radially extending guide bar (78) which passes with its free end through a guide cutout (79) in the housing (48), and that the respective guide bar (78) is pushed through an associated spring (80), which is a pressure spring, and the spring (80) is supported against the housing (48) and on the guide bar (78).
10. A switch arrangement according to one of Claims 1 to 9, with the end of the switch shaft (22) facing away from the switch lever (23) comprising two eccentrically arranged switch pins (27, 28) which include between themselves with play in the peripheral direction a bolt (45), which is arranged parallel to the housing-based mounting axis (31) of the toggle lever (29), and that the one lever arm (30) of the toggle lever (29) is designed to be a toggle composed of two lifting loads, and that the pin (45) connects the ends of the toggle which are oriented towards the two switch pins (27, 28).
11. A switch arrangement according to Claim 10, with the two switch pins (27. 28) being arranged concentrically to the rotary axis (26) of the switch shaft (22) and to include between them a circle sector of 90°, and toggling of the toggle lever (29) is carried out with a rotation of the rotary axis by between 60 and 70°.
12. A switch arrangement according to one of Claims 1 to 11, with the one lever arm (30) of the toggle lever (29) being pivotal around a housing based axis (31), and with the end of the lever arm (30) which is facing away from the switch shaft (22) being hinged to the other lever arm (32) of the toggle lever (29), its end which is facing away from the connecting hinge being pivotal around a housing based axis (38) which runs parallel to the housing based axis (31) of the one lever arm (30), and that furthermore for the purpose of a hinged connection of both lever arms (30, 32) the one lever arm (30) is in its longitudinal direction provided with a relatively long elongated hole (33), and the other lever arm (32) comprises a relative short elongated hole (46) vertically to its longitudinal direction, and a pin (34) passes through both elongated holes (33, 46) whilst being axially fixed; furthermore, a pressure ring (35) surrounds the one lever arm (30) and abuts the pin (34), and a pressure spring (36) is provided which supports itself at the side facing away from the pin (34) on the pressure ring (35) and on an extension (37), at the side of the switch shaft, of the one lever arm (30).
13. A switch arrangement according to Claim 12, with the one lever arm (30) being pivotal around an angle of between approximately 40 and 45°, and the other lever arm (32) around an angle of between approximately 70 and 80°.
14. A switch arrangement according to Claim 13, with the other lever arm (32) positively co-operating, with a play in the peripheral direction, with a rotor (20), which is rotatably mounted in a housing (3) and the rotary axis (38) of which coincides with the rotary axis (38) at the housing of the other lever arm (32), and that the pivot range of the rotor (20) is defined by two stops (43).
15. A switch arrangement according to Claim 14, with the pivot angle of the rotor (20) being approximately 35°.
16. A switch arrangement according to Claim 14 or 15, with the peripheral area of the rotor (20), which is rotatable over part of a circle, being provided on one side of the rotor with two hinged connecting bars (19), as well as two operating slides (15, 16), which are arranged parallel to each other and displaceable in their longitudinal direction, and that a respective operating slide (15, 16) is hinged to the other end of a respective connecting bar (19) and accommodates a contact bridge (13; 14) for the purpose of connecting to a current path (9, 10), and the connecting bars (19) are hinged to the rotor (20) in such a manner that the contact bridges (13, 14) perform, during a movement of the rotor (20) over part of a circle, counter-movements relative to said current path (9; 10).
17. A switch arrangement according to one of Claims 1 to 16, with the switch box (51) being firmly connected to a switch toggle (69) which non-rotationally accommodates the switch lever (23), and that a cam (76) of the switch lever (23) in its rotary end positions engages cutouts (77) of the housing (48) and rotationally secures the switch lever (23) and leaves the cutout (77) when the switch lever (23) has been raised and permits pivoting of the switch bridge (51) by means of the switch lever (23).

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