EP1141986B1 - Disconnect switch - Google Patents

Abstract

The invention relates to a disconnect switch for the load circuit of a battery of a motor vehicle. Said disconnect switch has a movable contact element (81, 126, 205) and a stationary contact element (64, 121, 204). The movable contact element is fixed in a locked position by a locking mechanism. A shape-memory alloy thermoelement (4, 104, 215) is used as a means for opening the locking mechanism, said element contracting itself upon being heated.

Description

• einem Gehäuse,
• einem mit einer Polklemme verbindbaren Eingangsleiter,
• einem mit dem Laststromkreis verbindbaren Ausgangsleiter,
• einem feststehenden und einem beweglichen Kontakt zur Herstellung einer Schaltverbindung zwischen dem Eingangsleiter und dem Ausgangsleiter,
• einem beweglichen Kontakt tragenden, zwischen einer Öffnungsposition und einer Schließposition umschaltbaren, durch Federkraft in die Öffnungsposition vorgespannten Kontaktträger,
• einem Verriegelungsmechanismus, der den Kontaktträger in der geschlossenen Stellung fixiert, und
• einem Mittel zum Öffnen des Verriegelungsmechanismus.

The invention relates to a disconnector for the load circuit of a vehicle battery with the following features:

• a housing,
• an input conductor that can be connected to a pole terminal,
• an output conductor that can be connected to the load circuit,
• a fixed and a movable contact for establishing a switching connection between the input conductor and the output conductor,
• a contact carrier which carries a movable contact and can be switched between an open position and a closed position and is biased into the open position by spring force,
• a locking mechanism that fixes the contact carrier in the closed position, and
• a means for opening the locking mechanism.

Such a circuit breaker is already in DE 197 01 933 C1 described. This known disconnector has as Contact carrier a contact rocker that rotates in the housing is stored and the movable contact indirectly via a acts as a lever arm contact spring. To reset the contact rocker in the open position is a tear spring intended. The locking mechanism consists of a Arm and a pawl, the pawl locked the actuating arm on the contact rocker and the actuating arm preloads the contact rocker in its closed position.

As a means of opening the locking mechanism is a Electromagnetic system used with an anchor, which with the pawl is coupled. The magnet system opens excited, whereby the pawl unlocks the actuating arm and the contact rocker into the open position through the tear spring brought.

From the not yet published registrations with the official File numbers 198 32 573.8 and 197 41 919.4 are further Battery disconnector known to open the Locking mechanism uses an electromagnet system becomes.

In the first-mentioned application there is the locking mechanism from a toggle mechanism, the anchor of the Electromagnetic system for opening the locking mechanism attacks the middle knee joint.

In the second application, the mobile contact arranged on a rocker and as a locking mechanism between the contact rocker and a fixed bearing Buckle spring clamped. The buckling spring is in the switched-on state the contact rocker is almost stretched and clamped into its switch-on position in front. As a means of opening the locking mechanism a magnet system is also used, the Anchor acts on the central area of the buckling spring. Should he Locking mechanism will be released, the electromagnetic system controlled and the armature moves the buckling spring about their dead center, so that it bends sideways and the The contact rocker jumps to the open position.

The locking mechanism is used in all of the above-mentioned disconnectors about the armature of an electromagnetic system solved. The electromagnetic system is used in a vehicle battery the disadvantage that the strong The armature of the electromagnetic system can also move without excitation and thus there is a risk that the load circuit is unwanted is switched off. Furthermore, the electromagnetic system a high proportion of the weight as well as the total Manufacturing cost of the disconnector. Especially when Automotive engineering strives to make the weight as low as possible to keep possible and due to the high number of pieces also the Reduce the cost of small components.

DE 32 32 466 A1 describes a switching arrangement in motor vehicles known in which a relay contact as an overcurrent protection is trained. The fuse consists of a fixed and a movable contact, the latter on End of a cantilevered hot wire is arranged and over a spring is pressed against the fixed contact. The feather is arched and on one side with the heat wire fixed in a bracket and on the other side connected to its free end of the heat wire so that it presses the movable contact against the fixed contact. at Overcurrent, the hot wire heats up and contracts. The arched spring jumps through the contraction of the Heat wire in the opposite deflection and thereby opens the contact.

This type of overcurrent protection is for a battery disconnect switch unsuitable because the contacts are only by spring force the arcuate spring are pressed together and it at high currents, as they occur when starting the engine, for Sparking and thus welding of the contacts occur would.

Starting from DE 197 01 933 C1, the invention is the Task based on a disconnector for the load circuit to show a vehicle battery, which is inexpensive is manufactured, has a low weight and less as sensitive to shock as the electromagnetic systems.

This object is achieved in that the Means for opening the locking mechanism a thermocouple is made of a shape memory alloy, which is when heated contracts.

The thermocouple is connected to a sensor system, which for example in the event of a short circuit or a vehicle crash this is powered. The current warms up the thermocouple and opens the locking mechanism through its contraction.

The thermocouple is inexpensive to purchase has a low weight and is therefore not prone to impact.

It is only through the locking mechanism that it is possible Thermocouple in a disconnector for the load circuit Use the vehicle battery. By fixing the movable Contact in the closed position via the locking mechanism the contacts are pressed together so strongly that even high currents, such as during the starting process, can flow.

A preferred locking mechanism has a tensioning element on that in its extended position the movable Presses contact against the fixed contact, whereby to open the Locking mechanism the thermocouple so on the clamping element acts that this bends sideways.

In one embodiment, the locking mechanism is as Toggle lever tensioning device formed, wherein the tensioning element a first lever engaging the contact carrier and one there is a second lever mounted in the housing, which has a middle knee joint are connected to a toggle lever, which in approximately stretched condition the contact carrier in locked in its closed position.

In an alternative embodiment, the movable contact arranged on a contact rocker, which between a Closed position and an open position is pivotable and biased in the open position by a tear spring is. This locking mechanism is used as a tensioning element an articulated spring between the contact rocker and a fixed bearing clamped, on the middle area of which acts the thermocouple. The buckling spring points against the effective direction of the Thermocouple on a preferred deflection, this Deflection by the thermocouple is limited to one dimension is less than the change in length of the thermocouple. When switched on, the almost stretched The contact rocker forwards into its switch-on position, while the break spring when the thermocouple responds by the contraction of the thermocouple above its dead center is moved and by the tear spring while moving the rocker switch back to the off position is bent.

The thermocouple conveniently reaches over an actuating arm on the trained as a toggle or kink spring Clamping element, in a preferred embodiment the actuating arm also serves as a return spring is designed for the thermocouple.

In a further embodiment, the locking mechanism has a sliding pin and a pivoting one Lever open, the pin the contact carrier with the movable Press contact into its closed position. The Swiveling lever locks the pen in its closed position Position and is used to open the disconnector by Contraction of a thermocouple that engages this lever, pivoted so that the movable pin releases what the biased contact carrier in the open position pivots and moves the pen.

Due to the length of the sliding lever, the unlocking force be reduced very much. The contraction is enough of the thermocouple to deflect the lever this is advantageously deflected several times via deflection rollers, so that a longer length of the thermocouple and thus a major change in length in contraction is available stands.

In this embodiment, provision is advantageously made of the thermocouple, that is, stretching the thermocouple after contraction, by manually operated Means and not, as in the embodiments described above, by a return spring so that during contraction of the thermocouple is not the force of the return spring must be overcome and thus the entire contraction force is available.

The use of a thermocouple as a means of opening the locking mechanism has the advantage that this in Compared to the electromagnetic system, much less space stressed and thus the entire disconnector essential lighter in one that is adapted to a pole terminal of the vehicle battery, the pole terminal arranged self-recessing housing can be. The space saving enables that in the Housing additional components such. B. sensors or a electrical evaluation circuit can be arranged.

Further advantageous embodiments of the invention result itself from the subclaims.

Figur 1

die einzelnen Baugruppen einer ersten Ausführungsform eines erfindungsgemäß gestalteten Trennschalters in perspektivischer Darstellung,

Figur 2

die Spannwerkbaugruppe mit Thermoelement des Trennschalters von Figur 1 in teilweise montiertem Zustand,

Figur 3

die Polklemmenbaugruppe von Figur 1 in halbmontiertem Zustand,

Figur 4

eine Draufsicht auf den Trennschalter von Figur 1,

Figur 5

den Trennschalter von Figur 1 in montiertem Zustand, jedoch mit offenem Deckel,

Figur 6

eine alternative Ausführungsform eines Trennschalters in einem Gehäuse, von dem nur der Sockel gezeigt ist,

Figur 7

den Trennschalter von Figur 6 in einer Explosionsdarstellung,

Figur 8

das Spannwerk des Trennschalters von Figur 6 in Explosionsdarstellung,

Figur 9

den Trennschalter von Figur 6 in einer Draufsicht mit vereinfachter Darstellung im Bereich des Spannwerks,

Figur 10

eine vereinfachte Skizze des Trennschalters von Figur 6 nach manueller Abschaltung,

Figur 11

eine vereinfachte Skizze des Trennschalters von Figur 6 nach automatischer Abschaltung,

Figur 12

eine dritte Ausführungsform eines Trennschalters in schematischer Darstellung,

Figur 13

einen Trennschalter gemäß Figur 12 in geöffnetem Zustand und

Figur 14

einen Teil des Trennschalters gemäß Figur 12 in einer Stellung während der Schließbewegung.

The invention is explained in more detail below with reference to exemplary embodiments shown in the drawings. Show it

Figure 1

the individual assemblies of a first embodiment of a disconnector designed according to the invention in a perspective view,

Figure 2

the tensioning assembly with thermocouple of the disconnector of Figure 1 in a partially assembled state,

Figure 3

2 in the semi-assembled state,

Figure 4

2 shows a plan view of the disconnector from FIG. 1,

Figure 5

1 in the assembled state, but with the cover open,

Figure 6

an alternative embodiment of a circuit breaker in a housing, of which only the base is shown,

Figure 7

6 in an exploded view,

Figure 8

the clamping mechanism of the disconnector of Figure 6 in an exploded view,

Figure 9

6 in a plan view with a simplified representation in the area of the tensioning mechanism,

Figure 10

a simplified sketch of the circuit breaker of Figure 6 after manual shutdown,

Figure 11

a simplified sketch of the circuit breaker of Figure 6 after automatic shutdown,

Figure 12

a third embodiment of a circuit breaker in a schematic representation,

Figure 13

a disconnector according to Figure 12 in the open state and

Figure 14

a part of the disconnector according to Figure 12 in one position during the closing movement.

The disconnector shown in Figures 1 to 5 has one particularly simple construction. It is in a plastic case 1 housed, which is connected to a pole terminal assembly 2 becomes. From above, a plastic housing 1 Tensioner assembly 3 used with an integrated Thermocouple 4 interacts. In addition, in the housing an input conductor 5 and an output conductor 6 are inserted. Finally, the housing 1 from the top with a Cover 7 are tightly closed (Figure 5).

The plastic housing 1 has one of a base plate and side walls limited control room 11, which the functional parts of the disconnector. Inside the plastic case is also by a curved partition 12th a space for receiving a pole terminal 21 is left out. There too the cover 7 has a corresponding recess 71, can the closed and sealed housing with the disconnector placed on the battery pole with the pole clamp 21 in this way be that the pole terminal or a corresponding Clamping screw 22 remain accessible from the outside. The pole terminal 21 interacts with a clamp shoe 27, which with a Base plate 24 is riveted from sheet metal. At the front end lies with a U-bend 25 on the pole clamp 21, where it is fixed via the clamping screw 22. The plastic case 1 is placed on the base plate 24 and hot stamped, whereby the entire battery disconnect switch is on both sides supported on the pole terminal. For better cross stiffening the base plate also has a continuous, vertical turn at the front.

A round pin 26 is molded onto the pole terminal shoe 27, the upwards through the plastic housing 1 protrudes into the control room 11. About this pin 26 is the Battery power on the inside riveted input conductor 5 in led the inside of the disconnector. This entrance ladder 5 is made of copper sheet and is bent in a U-shape. On Leg 51 is with a round hole 52 on the pin 26 attached and riveted. The round cross section of the cone 26 is opposite to the bottom of the housing 1 sealed an O-ring 53 washproof. On the leg 51 of the input conductor 5 there is also a ferrite ring 54, in the slot a current sensor, preferably a Hall sensor, inserted to monitor the battery current will (not shown). This can, for example, cause a short circuit be detected as a pulse to switch off the Disconnector is used. The current sensor can directly on a vertically installed (not shown) PCB must be soldered. The electronics of one Printed circuit board is used, for example, to evaluate the short circuit signal or also to display the over the current sensor detected battery currents for battery management.

On a vertically bent leg of the input conductor 5 is a strand 10 for forwarding the current to one movable contact 81 welded. This moving contact 81 is fastened in a contact spring 8, which is fixed to the housing is clamped. The strand 10 is two superimposed flat strands, which means in the direction of actuation of contact 81 good flexibility with large Conductor cross sections is guaranteed. The contact spring 8 is designed as a flat spring clamped on one side; the Contact tear force, the contact path and the contact force and the overstroke are applied via this one spring; this one part takes over the functions of a contact spring, a return spring and a contact rocker. The movable contact 81 is approximately in the middle of the free spring length the contact spring 8 attached. The free spring end 82 is bent and formed into a hook 83 with which the contact spring is in engagement with the tensioner.

The tensioning unit assembly 3 consists of a toggle lever tensioning unit, which is arranged on a carrier plate 31. The contact spring 8 is on a tab bent vertically upwards 38 of the support plate 31 attached. Furthermore from the Carrier plate 31 a square pin 39 bent vertically upwards, which is the fixed pivot point for the clamping mechanism serves. The toggle lever of the tensioner is correspondingly two bent sheet metal parts, namely a first lever 32 and a second lever 33 is formed. On the first lever 32 are two hinge pins 32a cut free in hinge holes of the U-shaped second toggle lever 33 lie and with these form a middle knee joint 37. The second toggle 33 has further hinge holes 33b with which this second lever mounted on the mentioned square pin 39 is. The first lever 32 has on its outer, i.e. the end of the middle knee joint facing an eyelet-shaped recess 32b, which with the hook-shaped end portion 83 of Contact spring 8 interlocks. In the hinge holes 33a and 33b of the second lever 33 and in the hook-shaped end section 83 of the contact spring are the respective pivot pins or the eyelet edge of the first lever when tensioned of the knee joint with their edges. These work at the moment of release when the middle knee joint is moved over the dead center, like a cutting edge bearing, whereby the bearing friction at the moment of release is very low is and requires only a small release force.

The thermocouple 4 is in the form of a wire within the Tensioner assembly between a suspension 41 and an operating arm 42 excited. The suspension 41 is a rag which is perpendicular to the support plate 31 of the tensioner assembly projects. The operating arm 42 is on the opposite Side of the toggle lever system on a perpendicular to the Carrier plate 31 arranged upwardly curved laps 34 and acts on the toggle lever system in the buckling direction. By doing Tab 34 has a recess 34a through which on the one hand the actuating arm bent at the end with its End surface acts on the knee joint 37 and through which on the other hand, the thermocouple from the suspension 41 to the actuating arm 42 is performed. For attaching the thermocouple on the actuating arm 42 there is an additional holder 43 provided. The actuating arm 42 is resilient, so that he always the thermocouple with a certain Preloaded. The tab 34 serves on the opposite Side of the actuating arm 42 also as a contact edge the toggle tensioner in the tensioned state.

To trigger the tensioning mechanism, the thermocouple 4 is connected via two Lines, not shown, are energized. As a result of the current, the thermocouple heats up and contracts. By contraction of the thermocouple Front of the cranked actuating arm 42 in the amount of Knee joint 37 pressed on the second lever 33. The operating arm 42 pushes the knee joint 37 over its dead center and is then due to the restoring force of the contact spring 8 fully depressed.

On the second lever 33 is behind the swivel fixed to the frame on the pin 39 a switching flag 35 bent upwards protrudes through a hole 72 in the lid 7 or from the outside is accessible and so for manual switching on and off serves. With the help of a screwdriver or similar Tool, the switch flag 35 can be flipped to the Tension the toggle lever again and the contact spring closed again close (manual restart after electrical triggering). The reverse is also a manual shutdown possible. The switching flag 35 is in a recessed area in the lid, which is sealed to the outside with a sealing plug 73 can be. This plug 73 can also to be sealed to restart when continuing Prevent short circuit; in this case it is guaranteed that not the user of a vehicle, but only the workshop personnel after the short circuit has been remedied or a check of the circuit the load circuit again can turn on.

On the outside of the housing 1 is the one already mentioned Output conductor 6 attached. This is L-shaped, wherein a leg 61 over a sawtooth contour in a corresponding Bag attached to the outside of the housing 1 while a leg 62 is hot stamped on the housing is fixed. Through this fixation, the forces one screwed to the output conductor 6 via a bolt 63 Battery cable added; at the same time the whole through the L-shaped bend of the output conductor Housing stiffened. On the leg 62 is from the inside a fixed contact 64 is fastened through a round opening 15 protrudes into the interior of the housing. Carrying out 15 for this fixed contact 64 is sealed with an O-ring 16, so that the housing is closed wash-tight at this point is. The fixed contact 64 consists, for example, of a Round copper part with plated or welded contact material.

On the housing 1 there is also an additional emergency power connection 9 arranged and connected to the input conductor 5. It is used to maintain emergency circuits, for example for a hazard warning system, even after the Circuit breaker.

The function of the disconnector should be repeated once again are briefly described. The knee lever is tensioned in the idle state, with the middle knee joint 37 slightly over the dead center is pressed outwards and the first lever 32 on the Tab 34 abuts. This state is shown in Figure 4. The Contact spring 8 is against its bias in the Closed position pressed, the movable contact 81 is on the fixed contact 64. When the thermocouple 4 is excited the actuating arm 42 is pulled in the direction of the toggle lever system and pushes the middle one with its cranked face Knee joint 37 over the dead center. Beyond dead center the toggle lever with the contact and Tear force of the contact spring 8 deflected, and the spring contact will be opened. The contact spring 8 and the toggle 32, 33 then take the dashed position shown in Figure 4 on.

Through the translation via the toggle mechanism, the high contact and tear forces of the contact spring with relative small triggering forces and thus switched off with a thermocouple become; the proportion of frictional force is low. To switch it on again manually, the knee lever must be cocked again be, the lever 33 by means of the switching flag 35, is moved to the rest position as described above.

The thermocouple 4 is resilient due to the restoring force trained actuating arm 42 stretched again.

An alternative embodiment is shown in FIGS. 6 to 11 presented the invention.

This battery disconnect switch has a housing with a Housing base 111 and a housing cap 112, which on the Free space of a car battery in the area of a connection terminal is adjusted. Accordingly, the housing has a recess 113 for the battery terminal 114, which is a known structure owns and by means of a screw 115 on a battery pole, usually the positive pole of a vehicle battery, can be clamped. The battery clamp is connected via an extension 116 114 connected to an input conductor 117, which in Form of a rail is made of a highly conductive material and integrally with a base plate 117a in one of the Housing base 111 formed switching space 119 can be used. There is also an emergency power supply on this input conductor 117b integrally formed, even after the battery disconnector has responded a supply of safety-relevant Functions, e.g. Hazard warning light, car phone, etc., with a low power consumption can be ensured. Below an output conductor 120 is arranged on the housing base 111, through the insulating base 111 from the input conductor 117 is separated and in the present example two connections 120a and 120b for load circuits. Still is a contact carrier 120c is integrally formed on the output conductor, which through an opening in the housing base 111 in the Control room is guided and carries a fixed contact 121.

The base plate 117a is via various screws 122 and Insulating washers 123 attached to the housing base 111 (Figure 7) and also has a bent support plate 124, on which one strand 125 is welded, the other End is connected to a movable contact 126. This movable contact 126 is a contact spring 127a worn, which integrally with a tear spring 127b formed by a flat spring 127 and on a contact rocker 128 is attached. The contact rocker 128 is on one Bearing journal 148 pivoted. The tear spring 127b is biased towards a contact opening and with her supported free end on the support plate 124.

The actual release system is arranged in the control room 119. It consists of a thermocouple 104 in the form of a Wire, which is between a bracket 129 and an operating arm 130 is excited. The bracket 129 is a pin formed, which over a flat console 134 on the Base plate 117a is attached. Console 134 is preferably made made of insulating material and has on one side a vertically raised essentially perpendicular to Thermocouple system wall 135. In the system wall 135 is formed a recess 135a through which the Thermocouple passes through. Between the system wall 135 and the bracket 129 is a deflection 131 on the console 134 arranged, which is positioned so that the thermocouple 104 substantially perpendicular through the recess 135a in the contact wall 135 runs.

A guide pin 136 is also on the base plate 117a for a slide 137 and a bearing axis 138 for one Switch button 139 attached. The slide 137, which is U-shaped Sheet metal is bent, forms a vertical with its front edges Notch 137a parallel to a corresponding notch 128a is opposite a rocker switch 128. Between the two Notches 137a and 128a a longitudinal spring 141 is clamped; it is determined by the force of the contact spring 127a and the tear spring 127b pressed against the slide 137. The Buckling spring 141 is between the deflection 131 and the contact wall 135 arranged and has an opening 141a, through which the thermocouple 104 is passed through. The buckling spring 141 is slightly bent towards the wall 135 and has a preferred deflection towards it, so that it will move back in this direction after relaxation. The deflection in its preferred direction is Middle section in the switch-on position shown in FIG. 9 just a few tenths of a millimeter. In this almost stretched The condition of the buckling spring can also be that exerted by the slide 137 Transfer force to the contact rocker 128 and the contact closed against the restoring force of the tear spring 127b hold. On the other hand, a slight contraction is sufficient the thermocouple to the buckling spring 141 from the contact wall 135 and pull them over the dead center or their stretched Length to move so that they are opposite Can bend side. On this opposite Side is not limited.

The rotary switch mentioned serves to actuate the slide 139, which is mounted on the bearing axis 138. He owns one eccentric driver pin 142 which is on a driver edge 143 of the slide 137 slides along. The bearing axis 138 of the rotary switch is in the extension of the straight spring 141, and the slide 137 is over an elongated hole 144 on the guide pin 136 parallel to the straight one Buckling spring 141 guided while the driver edge 143 extends approximately perpendicular to it. However this driver edge 143 on both sides of the extension line limited to the buckling spring 141, so that there is an asymmetrical swivel range. At a Turning the rotary switch 139 clockwise reaches the Driver pin 142, the limit 143a according to Figure 10 and enables the slide 137 to be reset to one withdrawn switch-off position under the influence of Tear spring 127b. When the rotary switch pivots 139 takes the driver pin counterclockwise 142 a position at a limit 143b according to FIG. 9, which is only slightly opposite the dead center caused by through the buckling spring 141 and the axis of rotation 138 formed line is moved, so that in this position the Slider locked in an advanced switch-on position becomes.

The thermocouple 104 is used to trigger the disconnector a trigger signal in the form of current is supplied, which is shown in the Example using an electronic evaluation circuit 150 is generated in an electronics room 151 of the housing 111, 112 is housed. It is about not shown Lines connected to the thermocouple 104 and maintained for example sensor signals from an acceleration sensor, in the vehicle for the deployment of an airbag is. In addition, the disconnector can also be used for Overload will be triggered. For this purpose is in the housing the circuit breaker a current sensor in the form of a Hall element 152 housed the one with the input conductor 117 encompassing ferrite ring 153 from the battery Load current measures. If a specified one is exceeded A corresponding threshold becomes in the evaluation circuit 150 Excitation pulse given to the thermocouple 104, which the Disconnector triggers.

The function of the battery disconnector according to the invention is explained with reference to Figures 9 to 11. Figure 9 shows the switched on state. The rotary switch 139 is opposite twisted clockwise so that the driver pin 142 abuts the limit 143b and the slide 137 in locked in its on position. According to the principle of one Tilting tensioner is the articulated spring 141 that on the system wall 135 rests, stretched in the longitudinal direction, being due to its almost stretched condition, the elasticity of the Transfers slide to the contact rocker 128 and the Restoring forces of the tear spring 127b and the contact spring 127a overcomes. The contact rocker 128 is therefore in Closed position, d. that is, the movable contact 126 is in contact the fixed contact 121 and closes the load circuit.

If the disconnector is to be switched off manually, then the rotary switch 139 clockwise to the position shown in FIG Figure 10 rotated so that the driver pin 142 in the slide 137 abuts the boundary 143a, the buckling spring 141 by the force of the tear spring 127b and the contact spring 127a is shifted to the left in FIG Slider 137 in its retracted switch-off position suppressed. The contact rocker 128 is then in its open position, wherein it abuts a stop pin 146. The state according to FIG. 10 shows the contact rocker 128 in one Opening position, d. that is, the movable contact is 126 separated from the fixed contact 121, that is, the load circuit is open. Thus, according to Figures 9 and 10, the load circuit manually by turning the rotary switch 139 back and forth turned off.

As soon as the thermocouple from the electronic evaluation circuit 150 receives a trigger signal in the form of current, the thermocouple 104 contracts and pulls the buckling spring 141 over the dead center so that they face the opposite Can bend side. Since they are on this page its deflection is not limited, it is limited by the Tear spring 127b in connection with the contact spring 127a so far bent that the contact rocker its opening position takes on the stop pin 146. The buckling spring 141 is then bent as shown in Figure 11. The thermocouple 104 is after the end of the current signal by the as a return spring trained actuating arm 130 stretched again. The buckling spring 141 remains deflected, however, and the load circuit remains open even though the rotary switch 139 with the The driver pin 142 remains switched on and the slide 137 holds in its advanced switch-on position.

The contact rocker must be used to switch the load current on again be excited again. This is done by resetting the Slider 137 in the off position by the rotary switch 139 first rotated clockwise according to Figure 10 becomes. The buckling spring relaxes and lies down again in its preferred position on the contact wall 135 according to FIG. 10 on. By supporting the buckling spring on the system wall will move to its switch-on position when the slide moves further 9, the slide stroke on the contact rocker 128 transmitted, and this is excited.

A third embodiment variant is shown in FIGS of a battery disconnect switch. The figures show only the essential features of the battery isolator in schematic form. This battery isolator has a partially shown housing 201, in which a with an input conductor, not shown, of a terminal connected 202 leads, which has a switching contact with one of the Housing leading output conductor 203 is connected. The Switch contact consists of a fixed contact 204 and a movable contact 205, which on a pivotable Contact carrier 206 is arranged. The swiveling contact carrier 206 is biased by a spring 207 in the open position and via a locking mechanism in the closed Position fixed. The locking mechanism consists of a slidable pin 208, which in the closed position the contact carrier 206 against the Force of the spring 207 presses into the closed position. The pencil 208 is slidably received in a holder 209 and has a projection above and below the bracket 210 and 211, which are arranged so that in the Closing position of the upper projection 210 on the bracket 209 abuts and the lower projection 211 at the opening position is pressed against the bracket 209 via the spring 207. In the closed position is pin 208 about an axis 213 pivoted lever 212 locked, the front 214 of the pivotable lever 212 with the top of the projection 210 engages and thus opposes the pin 208 holds down the force of the spring 207. The locking mechanism thus consists of the slidable pin 208 and the pivotable lever 212.

The pivotable lever engages on its pivotable end a thermocouple 215, the other end on a bracket is set. In the illustrated embodiment the thermocouple 215 fixed on the input conductor 202, however electrically insulated from this. The thermocouple 215 is connected to two power lines 216 and 217, which via a sensor system or an electrical evaluation circuit in the event of a short circuit or a vehicle impact with electricity be charged. The thermocouple 215 is over three pulleys 218 snake-shaped, which also leads to smallest space a thermocouple with a relatively large length can be used. To open the locking mechanism the thermocouple is supplied with current as already mentioned, whereupon it contracts and the lever 212 around the axis 213 pivots and thus the projection 210 on the pin 208 releases. The pin 208 is over the contact carrier 206 and by the force the spring 207 is pushed up and the movable contact 205 also pivots with the contact carrier 206 upwards, which opens the make contact. Due to the deflections 218, the thermocouple 215 is in one long length available, which also makes the lever 212 can be chosen accordingly long. This is only a minor one Force to open the locking mechanism and to Swinging out of the lever 212 required. This power is without further realizable with a thermocouple.

Figure 13 shows the open position of contacts 204 and 205. To close contacts 204 and 205 is in the housing 201 arranged a button 219, which on the one hand over a Handle 220 when pushing the sliding pin 208 in his Closing position presses and which at the same time via an L-shaped Arm 221 engages behind the pivotable lever 212 so that this is also pivoted back into its locking position becomes. By pivoting lever 212 back thermocouple 215 is simultaneously stretched. The pencil 208 stands in the direction of the push button 219 above the upper one Projection 210 slightly so that the pivotable lever 212th when pushing the push button 219 against this protruding Part strikes. An overstretching or overstretching of the thermocouple 215 is therefore not possible. The push button 219 is via a compression spring 222 which engages on the bracket 209 always biased in its open position and must therefore be pressed against the spring force of the spring 222. By manually stretching the thermocouple 215 the thermocouple is not the force of a contraction Overcome return spring, creating full contraction force of the thermocouple is available.

Claims (28)

1. A disconnector for the load current circuit of a vehicle battery, having the following features:

   a housing (1; 111, 112, 201),

   an input conductor (5; 117, 202) connectable to a pole terminal (21, 114),

   an output conductor (6; 120, 203) connectable to the load current circuit,

   a fixed contact (64, 121, 204) and a movable contact (81, 126, 205) for making a switching connection between the input conductor (5, 117, 202) and the output conductor (6, 120, 203),

   a contact carrier (8, 128, 206) which carries the movable contact (81, 126, 205), may be switched between an open (contact-breaking) position and a closed (contact-making) position, and is pretensioned into the open position by spring force,

   a locking mechanism which fixes the contact carrier (8, 128) in the closed position, and

   a means of opening the locking mechanism,

      characterised in that the means of opening the locking mechanism is a thermocouple (4, 104, 215) made from a shape memory alloy which contracts on heating.
2. A disconnector according to Claim 1, characterised in that the locking mechanism has a clamping element (32, 33; 141) which in its extended position presses the movable contact (81, 126) against the fixed contact (64, 121) and in order to open the locking mechanism the thermocouple (4, 104) acts on the clamping element (32, 33; 141) such that the latter flexes away laterally.
3. A disconnector according to Claim 2, characterised in that the thermocouple (4, 104) acts on the clamping element (32, 33; 141) by way of an actuating arm (42, 130).
4. A disconnector according to Claim 3, characterised in that the actuating arm (42, 130) is constructed as a restoring spring for the thermocouple (4, 104).
5. A disconnector according to one of Claims 2 to 4, characterised in that the locking mechanism is constructed as a toggle lever clamping system and the clamping element comprises a first lever (32) acting on the contact carrier (8) and a second lever (33) mounted in the housing, these levers being connected by way of a central toggle joint (37) to a toggle lever which in the approximately extended condition locks the contact carrier (8) in its closed position.
6. A disconnector according to one of Claims 1 to 5, characterised in that the contact carrier is an elongate spring contact (8) clamped at one end in the housing and carrying in the central region of its length the movable contact (81) and engaging at its free or movable end (82) with the outer end of the first toggle joint lever (32) to form a first rotary joint.
7. A disconnector according to Claim 6, characterised in that the free end (82) of the spring contact (8) and the outer end of the first lever (32) engage in one another in the form of a hook (83) and an eye (32b).
8. A disconnector according to one of Claims 5 to 7, characterised in that the thermocouple acts by way of the actuating arm (42) approximately perpendicular to the axis of extension of the toggle lever on the central toggle joint (37) and moves the latter beyond the dead centre point when the thermocouple (4) contracts.
9. A disconnector according to one of Claims 5 to 8, characterised in that the actuating arm (42) is formed by an angled leaf spring whereof the angled end presses on the toggle joint (37) when the thermocouple contracts.
10. A disconnector according to one of Claims 5 to 9, characterised in that a switch-off key mounted in the housing (1) acts on the central toggle joint (37) and enables the contacts to be opened manually.
11. A disconnector according to Claims 5 to 10, characterised in that the second lever (33) is prolonged beyond the outer end mounted fixed to the housing to form a switching lug (35) which is accessible through an opening (72) in the housing for manual actuation.
12. A disconnector according to one of Claims 1 to 4, characterised in that the contact carrier is a contact rocker (128), the contact rocker (128) being pivotal between a closed position and an open position and being pretensioned into the open position by a breaking spring (127b), and a flexing spring (141) being clamped as a clamping element between the contact rocker and an abutment (137), the thermocouple (104) acting on the central region of the flexing spring (141), which has a preferential direction of bending in opposition to the direction of action of the thermocouple (104), this bending being limited by the thermocouple (104) to an amount smaller than the change in length in the thermocouple such that in the switched-on condition of the disconnector the almost extended flexing spring (141) pretensions the contact rocker (128) into its switched-on position, whereas when the thermocouple (104) responds the flexing spring (141) moves beyond its dead centre point as a result of contraction of the thermocouple (104) and is bent by the breaking spring (127b) in opposition to its preferential direction of bending with simultaneous movement of the contact rocker (128) into the switched-off position.
13. A disconnector according to Claim 12, characterised in that the abutment for the flexing spring (141) is formed by a slide element (137) which is movable in the longitudinal direction of the flexing spring (141) and which as a result of a manual actuation member (139) is switchable between a switched-off position, in which the flexing spring (141) can adopt its extended position or preferential direction of bending in the open position of the contact rocker (128), and a switched-on position in which the extended flexing spring (141) pretensions the contact rocker (128) into its closed position.
14. A disconnector according to Claim 13, characterised in that the slide element (137) is guided approximately parallel to the extended flexing spring (141) by a longitudinal guide (136, 144) and is pretensioned into the switched-off position by the breaking spring (127b) via the flexing spring (141).
15. A disconnector according to Claim 13 or 14, characterised in that there serves as the manual actuation member a rotary switch (139) whereof the shaft (138) of rotation stands perpendicular to a line prolonging the extended flexing spring (141) and which acts by means of an eccentric entraining peg (142) on an entraining edge (143) of the slide element (137) running transversely to the line of prolonging, with a pivoting range which is asymmetric with respect to the line of prolonging.
16. A disconnector according to one of Claims 12 to 15, characterised in that the movable contact piece (126) is connected to the input conductor (117) by way of a flexible line (125).
17. A disconnector according to one of Claims 12 to 16, characterised in that the movable contact piece (126) is connected to the contact rocker (128) by way of a spring contact (127a) constructed as a flat spring (127).
18. A disconnector according to one of Claims 12 to 17, characterised in that there serves as the breaking spring (127b) a flat spring (127) connected to the contact rocker (128) and pretensioned against a stationary stop (124).
19. A disconnector according to Claim 18, characterised in that the spring contact (127a) and the breaking spring (127b) are constructed as portions of a one-piece flat spring (127).
20. A disconnector according to one of Claims 12 to 19, characterised in that the contact rocker (128) is mounted to rotate on a stationary bearing peg (148).
21. A disconnector according to one of Claims 1 to 20, characterised in that the voltage source is a vehicle battery, and in that the thermocouple (4, 104) may be triggered by a short circuit sensor (152) and/or an acceleration sensor.
22. A disconnector according to one of Claims 1 to 21, characterised in that the housing (1; 111, 112) is arranged on a pole terminal of the vehicle battery, leaving a recess free for the pole terminal (21, 114).
23. A disconnector according to one of Claims 1 to 22, characterised in that at least one sensor (122) is arranged in the housing (1, 111, 112).
24. A disconnector according to Claim 23, characterised in that a current sensor (152) is arranged in the housing (111, 112) and is coupled to the input conductor (117) and, in the event of a current threshold being exceeded, supplies current to the thermocouple (104).
25. A disconnector according to one of Claims 1 to 23, characterised in that an electrical evaluation circuit (150) is arranged in the housing (1, 111, 112) to trigger the thermocouple (4, 104).
26. A disconnector according to Claim 1, characterised in that the locking mechanism has a displaceable pin (208) and a pivotal lever (212), the pin (208) pressing the contact carrier (206) into its closed position and the lever (212) locking the pin (208) and, in order to open the locking mechanism, the thermocouple (215) being connected to the pivotal lever (212) such that when the thermocouple (215) contracts the pivotal lever (212) releases the pin (208) and the pretensioned contact carrier (206) moves into the open position.
27. A disconnector according to Claim 1 or 26, characterised in that the thermocouple (215) is deflected by way of deflection rollers (218).
28. A disconnector according to Claim 1 or 26, characterised in that the thermocouple (215) is reset by manually operable means (219, 213, 212).

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