EP2141717A2 - Switching device with release component - Google Patents

Abstract

The device has a releasing component (AE) for releasing a switching unit (SE). The releasing takes place by moving a control part (8) in one of two positions, so that a switching body (1) is moved in the position and a circuit is opened, when the switching body and the control part are found in the other position, and when a pre-set releasing condition i.e. over current, exists. An actuating device (14) and the control part in the latter position are distanced from each other around a predetermined distance (D), when the actuating device is provided without existence of the condition. The releasing component is designed as an electromagnetic actuating releasing component.

Description

The invention relates to a switching device, and in particular a switching device with a triggering device for the automatic triggering of the switching device.

Switching devices with a tripping device generally comprise the provision of electromagnetically controlled tripping devices for triggering the switching device, starting from a switched-on state and according to the detection of the presence of a predetermined tripping or switch-off condition.

In some cases, however, a safe triggering (disconnection) of the switching device is not guaranteed, for example, in the case of an electromagnetic tripping device, the magnetic force applied by the triggering device is not sufficient to perform the shutdown or complete. This leads to a reduced reliability of the switching device.

In this case, it is possible to form a tripping device by means of enlarged and more efficient coils for generating an increased magnetic force, but this leads to higher costs and larger dimensions in terms of dimensions and a greater weight.

The invention is based on the object, a switching device with a triggering device such that even with a triggering device with a reduced size and reduced power safe release of the switching device is guaranteed.

According to the invention this object is achieved by a switching device according to the features specified in claim 1.

In detail, according to the invention, the switching device comprises a switching unit, which has a switching body which is movable between a first and a second position, with a plurality of contact elements arranged thereon, which in a movement from the first to the second position in contact with the plurality of contact elements opposite fixed contact elements be closed to close a circuit, and a relative to the switch body between a first and a second position movable control part for holding the switch body in its second position when the control part has reached its second position, and a trip unit for triggering the switching device, when the switch body and the control part are in their respective second position, and when a predetermined triggering condition exists, by moving the control part by means of an actuating device of the trip unit in the first position, whereby the Shift body placed in its first position and the circuit is opened, wherein the actuating device are spaced apart in the second position by a predetermined distance without the presence of the predetermined triggering condition and the control part.

It is possible in this way to achieve a safe triggering or switching off the entire switching device and even under unfavorable conditions to ensure, since the actuating device of the trip unit is arranged at the predetermined distance to the control part of the switching unit. By activating the trip unit in the presence of the predetermined trip condition (detecting the presence of the predetermined trip condition), the trip unit in conjunction with its actuator sets the switch unit to the tripped state. In detail, the trip unit, the control part that holds the switch body of the switching unit in its second position and thus in the on state (closed circuit), in the first position of the control part of the switching unit, which also offset the switch body in its first position and the plurality of closed Contacts are opened, so that also the circuit is opened.

Due to the predetermined distance between the actuating device of the trip unit and the control part of the switching unit, a sufficient amount of energy can be provided for offsetting the control part from the second position (holding the switch body in its second and thus switched-on position) to the first position a smaller dimensioned trip unit is able to bring the control part safely from its second position in its first position and thus safely trigger the switching unit and the entire switching device or turn off.

According to further embodiments, the switching device may comprise a trip unit in the form of an electromagnetically actuated trip unit.

The electromagnetically actuated trip unit may comprise at least one magnetic coil and at least one magnetic core. In particular, the electromagnetically actuated trip unit may comprise at least one coil, which is supplied in response to the presence of the predetermined triggering signal, a current for energizing the coil, and at least one magnetic core, on which the actuating device is arranged, wherein the magnetic core with the actuating device in the excitation the coil moved in its direction of action is for displacing the control part of the switching unit from its second position to its first position.

In particular, in the presence of the predetermined triggering condition, the magnetic core can be moved with the actuator by at least the predetermined distance in the direction of the control part, so that a shock is applied to the control part of the switching unit, wherein the impact takes place with a predetermined kinetic energy.

Further, the magnetic core and the actuator of the trip unit can be held in a rest position by spring force in the absence of the predetermined triggering condition, and can be accelerated in the direction of the control part to overcome the predetermined distance in the presence of the predetermined triggering condition.

In this case, in particular the direction of movement of the control part between its first and second position, and the direction of movement of the switching body between its first and second position to each other form a predetermined angle. This angle may preferably be 90 ° C.

Further, the switch body of the switching unit may comprise a pin, and the control part of the switching unit may have a predetermined depression, wherein the control part mechanically holds the switch body in its second position upon reaching its second position by the pin of the switch body in engagement with the recess of the control part arrives. In detail, the switch body and the control part of the switching unit can each be pressed by spring force in their respective first position.

Further, the trip unit may have a magnetic core formed as a flywheel, and it may be held in a predetermined rest position by means of a spring force, the magnetic core in the absence of the predetermined triggering condition.

The switching body of the switching unit may further comprise a pin, and it may be formed in the control part of the switching unit a backdrop, wherein upon movement of the control member between the first and second position and upon movement of the switch body between the first and second positions of the pin of the switch body is guided by the backdrop of the control part.

It can determine the first and second position of the control part and the first and second positions of the switch body, the first and second positions of the control part and the switch body of the switching unit are coupled to each other in the control part formed gate.

The gate in the control part of the switching unit can determine two rest positions for the pin of the switch body, which correspond to the respective first and second positions of the control part and the switch body of the switching unit.

• Fig. 1 eine Gesamtansicht der Schaltvorrichtung mit der Schalteinheit und der Auslöseeinheit gemäß einem ersten Ausführungsbeispiel der vorliegenden Erfindung,
• Fig. 2 eine Darstellung der in Fig. 1 gezeigten Schalteinheit gemäß dem ersten Ausführungsbeispiel mit geöffneten Schaltkontakten,
• Fig. 3 eine Gesamtansicht der Schaltvorrichtung mit der Schalteinheit und der Auslöseeinheit gemäß einem zweiten Ausführungsbeispiel der vorliegenden Erfindung, und
• Fig. 4 eine vergrößerte Darstellung eines Teils der Schalteinheit gemäß Fig. 3 zur Veranschaulichung der in dem Steuerteil der Schalteinheit ausgebildeten Kulisse.

The present invention will be described below in detail by way of embodiments with reference to the figures. Show it:

• Fig. 1 an overall view of the switching device with the switching unit and the trip unit according to a first embodiment of the present invention,
• Fig. 2 a representation of in Fig. 1 shown switching unit according to the first embodiment with open switch contacts,
• Fig. 3 an overall view of the switching device with the switching unit and the trip unit according to a second embodiment of the present invention, and
• Fig. 4 an enlarged view of a part of the switching unit according to Fig. 3 to illustrate the trained in the control part of the switching unit backdrop.

A first embodiment of the present invention will be described below with reference to FIG Fig. 1 and 2 described.

Fig. 1 shows an overall view of the switching device according to the present invention, wherein the switching device comprises a switching unit SE and a trip unit AE.

The switching unit SE comprises a switch body 1, to which a key element 2 and a contact bridge carrier 3 are rigidly secured. The contact bridge carrier 3 carries a contact bridge 4, are arranged on the contact elements 5. The contact elements 5 are provided in the form of a plurality of contact elements (a plurality of contact elements) which are away from each other by an appropriate insulating distance. The contact bridge electrically connects (galvanically) the plurality of or the plurality of contact elements.

If the switching unit SE and thus the switching device are closed, so that a circuit is closed in the desired manner, then the plurality of contact elements 5, which are arranged on the contact bridge 4 of the switching unit SE, moved in a corresponding manner (in the Fig. 1 and 2 down) so that they come in contact with another plurality of fixed contact elements 6, which are arranged on respective fixed contact element carriers 7. In the contacted (adjacent or closed) state of the plurality of contact elements 5 and the fixed contact elements 6 are the respective contact elements 5 and 6 resiliently. The key element 2, the switch body 1, the contact bridge carrier 3 and the contact bridge 4 with the plurality of contact elements 5 arranged thereon are essentially rigidly connected to one another.

The switching unit SE further comprises a control part 8, which is arranged in such a way at the switching body 1 of the switching unit SE that a mechanical operative connection can be formed.

The respective longitudinal axes (substantially symmetry axes) of the switch body 1 and the control part 8 of the switching unit SE can form a predetermined angle to each other, which is for example preferably 90 ° C. In the in the Fig. 1 and 2 shown respective position of the switch body 1 and the control part 8 of the switching unit SE, the preferred angle of 90 ° C is given, wherein the arrangement of the switching unit SE is not fixed thereto.

The switch body 1 of the switching unit SE is in its longitudinal direction, the vertical direction in the Fig. 1 and 2 corresponds, by means of a first spring 9 in the illustration in the Fig. 1 and 2 biased upwards (pressed). Further, the control part 8 is biased by a second spring 10 in its longitudinal direction, which, as shown in the Fig. 1 and 2 towards the left.

The trip unit AE is in the present embodiment of the switching device according to the invention, for example, as an electromagnetic trip unit and comprises at least one magnetic core 11 which is inserted into at least one coil 12 (solenoid) in its longitudinal direction relative to the spool 12 movable and guided by guide elements, not shown , The coil 12 is supplied via corresponding electrical leads 13 with electrical power and in particular with an electrical current which generates a magnetic field in the coil 12. The Fig. 1 and 2 For example, show an embodiment with a coil (magnetic coil) and a magnetic core, but also a plurality of coils or multi-part coil of the coil 12, and further may be provided as the magnetic core 11 more or more parts and interconnected Magnetkeme.

With the magnetic core 11 inserted into the coil 12, an actuator 14 is fixedly connected, which, upon supplying the current to the coil 12 via the leads 13 together with the magnetic core 11 performs a movement in the longitudinal direction of the magnetic core 11 and the actuator 14.

To achieve a predetermined rest position of the magnetic core 11 and thus also the fixedly connected to the magnetic core 11 actuator 14, a third spring 15 is provided which exerts a bias on the magnetic core in the direction of its rest position. The bias by the third spring 15 is carried out as shown in FIG Fig. 1 in the longitudinal direction of the magnetic core 11 and the actuator 14 to the left.

Thus, as shown in FIGS Fig. 1 and 2 the switch body 1 in conjunction with the key element 2, the contact bridge carrier 3, the contact bridge 4 and the plurality of contact elements 5 and the control part 8 of the switching unit SE and the magnetic core 11 in conjunction with the actuator 14 of the trip unit AE perform movements along its longitudinal axis, wherein each by a spring (in the Fig. 1 and 2 a first spring 9 and a second spring 10 of the switching unit SE, and a third spring 15 of the trip unit AE) exerts a corresponding bias on the respective component in a preferred direction.

The function and operation of the switching device with the switching unit SE and the trip unit AE will be described below.

In the illustration in Fig. 2 the switching unit SE is shown in such an arrangement, in which the plurality of contact elements 5, which form by their arrangement on the contact bridge 4 and the contact bridge carrier 3, the switch body 1 and the key element 2, the movable contacts, from the fixed contact elements 6 to the fixed Kontaktträgem 7 are separated. The circuit is open in this case, and there are in terms of the possible movement in their respective longitudinal direction, both the switch body 1 (in conjunction with the key element 2, the contact bridge carrier 3 and the contact bridge 4) and the control part 8 in a respective first position , The first position of the switch body 1 (in conjunction with the other components 2, 3, 4 and 5 attached thereto) is shown in FIG Fig. 2 in the upper position, and the first position of the control part 8 is as shown in FIG Fig. 2 in the right position.

Now, the switching device and in particular the switching unit SE is operated by a user to turn on (close) the circuit by the user to the key element 2 in Fig. 2 presses down against the biasing force of the first spring 9, then moves the arrangement of the switch body 1, the key element 2, the contact bridge carrier 3 and the contact bridge 4 with the associated contact elements 5 against the spring force or biasing force of the first spring 9 in the illustration in Fig. 2 down, so that the (movable) contact elements 5 come into contact with the fixed contact elements 6 and rest elastically or resiliently. In this way, the circuit is closed in the desired manner, and it has reached the switching body 1 with the other components arranged thereon its second position.

Is the switch body 1 according to in the movement upon actuation of the key element 2 by the user Fig. 2 moved from its first position (top) to its second position (bottom), then by the biasing force of the second spring 10, in the Fig. 1 and 2 in the direction of the left on the control part 8, a movement of the control part 8 from its first position (right in the Fig. 1 and 2 ) moved to the left to its second position, wherein a arranged on the control part 8 of the switching unit SE and protruding therefrom pin 16 passes into a formed on the pin 16 side of the switch body 1 recess 17 and therefore with this recess, the pin can be engaged. If the pin 16 of the control part 8 passes through the respective longitudinal movements of the switch body 1 and the control part 8 in the recess 17 of the switch body 1, then the pin 16 in the recess 17 assumes a stable position, so that the switch body 1 with respect to his in the Fig. 1 and 2 in the vertical direction possible movement by the engagement of the pin 16 of the control part 8 and in conjunction with in the Fig. 1 and 2 is set and held to the left-acting biasing force of the second spring 10.

The switch body 1 and the control part 8 are mechanically locked against each other in this position, which is the respective second position for both components.

The switch body 1 and the control part 8 thus hold by the mechanical engagement of the pin 16 with the recess 17 and the respective biasing forces of the first and second springs 9 and 10 in their respective second position.

As a result of this locking, the switch body 1, with the further components arranged thereon and in particular the contact elements 5, maintains its position against the biasing force of the first spring 9, so that in a stable manner the circuit via the plurality of (movable) contact elements 5 and the fixed plurality of contact elements 6 is safely closed.

If there is a predetermined triggering condition (switch-off condition for switching off the switching device) with regard to the switching device and in particular the tripping unit AE and this is detected by evaluation devices or control devices, not shown, then the coil 12 of the tripping unit AE is supplied with a corresponding electrical current via the electrical leads 13 so that the coil 12 is able to build up a corresponding magnetic field which acts directly on the magnetic core 11 and thus also on the actuating device 14.

When a magnetic field is built up by the coil 12 in conjunction with the supplied current, the magnetic core 11 (in conjunction with the actuator 14 attached to the magnetic core 11) starts moving against the biasing force of the third spring 15 as shown in FIG Fig. 1 and 2 to the right in the direction of the control part 8.

Are located at this time the control part 8 and the switch body 1 in their respective second position, as in Fig. 1 is shown and wherein the pin 16 of the control part 8 has come into contact with the corresponding provided in the switch body 1 recess 17, and are the magnetic core 11 and attached to the magnetic core 11 actuator 14 due to the bias of the third spring 15 in their Rest position (far left in the illustration in Fig. 1 ), then located between the right end of the actuator 14 and the left end of the control part 8, which lie in their longitudinal direction on a common line and can be moved along this straight line, a predetermined distance D.

As described above, by means of the magnetic field generated by the coil 12, the magnetic core 11 as shown in FIG Fig. 1 moved to the right, and thus likewise moves the actuator 14 to the right, then takes place an acceleration of the interconnected components (magnetic core 11 and actuator 14) in the direction of the control part 8 along the predetermined distance D. This means that during movement are accelerated over the predetermined distance D of the magnetic core 11 and the actuator 14 by the force exerted by the magnetic force and thus absorb kinetic energy, so that the actuator 14 together with the magnetic core 11 of the trip unit AE after overcoming the predetermined distance D to the left end of the control part 8 impinge and exert a shock on the control part 8. This is a substantially elastic shock depending on the materials used with a predetermined by the dimensioning of the elements involved kinetic energy, so that during acceleration of the magnetic core 11 together with the actuator 14 over the predetermined distance D accumulated kinetic energy almost completely the control part 8 is transmitted, which at this time in its second position (left in the Fig. 1 and 2 ) and thus in the locked state with the switch body 1 via the pin 16 and the recess 17 is located. The switch body 1 is also in its second position (bottom in Fig. 1 and 2 , Circuit closed).

If the magnetic core 11 in conjunction with the actuator 14 exerts a (predominantly elastic) impact with the predetermined kinetic energy on the control member 8, then the control member 8 is biased counter to the biasing force by the second spring 10 (preload direction to the left in FIGS Fig. 1 and 2 ) moved to the right or shifted so that due to the magnetic core 11 and the actuator 14 of the trip unit AE on the control part 8 transferred kinetic energy of the pin 16 of the control part 8 together with the control part 8 is able to leave the previously stable seat in the recess 17 of the switch body 1, after which the control part 8 as shown in the Fig. 1 and 2 moved right towards its first position. As a result of the movement of the control part 8 as a result of the shock by the magnetic core 11 and the actuator 14 of the trip unit AE to the right, the mechanical locking of the control part 8 is repealed with the switch body 1, moves by the biasing force of the first spring 9 of the switch body 1 in Connection with the contact bridge 4, the plurality of contact elements 5, the contact bridge carrier 3 and the key element 2 as shown in the Fig. 1 and 2 upward, so that the multiple (movable) contact elements 5 no longer touch the plurality of fixed contact elements 6 and thus the circuit is opened. The switch body 1 with the further components arranged thereon thus again takes up its first position (switching unit SE switched off), the control part 8 likewise having its first position (on the right in FIGS Fig. 1 and 2 ) and in this position, the pin 16 of the control part 8 on one side of the switch body 1 by the bias of the second spring 10 is applied ( Fig. 2 ).

After exerting the shock by the actuator 14 of the trip unit AE on the control part 8 of the switching unit SE returns after switching off the power to the coil 12 of the trip unit AE and the associated cancellation of the magnetic field of the magnetic core 11 and thus also the actuator 14 in conjunction with the bias by the third spring 15 in the rest position (initial position), which, as shown in the Fig. 1 and 2 Located on the left side.

In this way, the switching unit SE, which is in a stable locking state and in the switched-on state, is unlocked and thus triggered. The circuit is opened. The control part 8 and the switch body 1 return to their respective first position. In detail, thus, the control part 8 and the switch body 1 of the switching unit SE respective first and second positions, which are coupled together and accessible via relative movements to each other.

Due to the predetermined distance D between the actuating device 14 of the trip unit AE and the control part 8 of the switching unit SE, it is possible, even with a provided for a lower power and with a smaller size and a smaller weight (dimensioned) trip unit AE safe switching or Triggering to ensure that by the predetermined distance D even with a weaker magnetic field of the coil 12, the trip unit AE is able to exert a sufficiently large impact on the control part 8 of the switching unit SE to trigger the switching unit SE.

During the movement of the magnetic core 11 during the magnetic field formed in the coil 12 over the predetermined distance D, an acceleration is achieved during this time of covering the predetermined distance D achieved by the magnetic core 11 in conjunction with the actuator 14, a predetermined kinetic Energy is collected so that the effective and reliable tripping or shutdown is ensured. Due to the predominantly elastic impact of the combination of the magnetic core 11 and the actuating device 14 on the control part 8 of the switching unit SE almost in motion, the entire kinetic energy accumulated from the acceleration of the components 11 and 14 is transferred to the control part 8, so that counter to the prestressing force the second spring 10 and despite the stable seat of the pin 16 of the control part 8 in the recess 17 of the switch body 1 of the switching unit SE (second position) unlocking and thus a displacement of the control part 8 from its second position to its first position (circuit is open , Representation in Fig. 2 ) is possible.

For receiving the sufficient kinetic energy during the movement by at least the predetermined distance D, the magnetic core 11 is preferably designed as a flywheel. Since the trip unit AE with the magnetic core 11, which has the function of a solenoid, is arranged such that the predetermined distance D between the actuator 14 and the control part 8, at the beginning of the movement of the magnetic core 11, only the flywheel of the magnetic core 11 including the actuator 14 must be accelerated by the formed in the coil 12 magnetic field, so that collected on the path of movement over the predetermined distance D (predetermined) kinetic Energy of the entire mass (flywheel) of the magnetic core 11 and the actuator 14 is able to trigger the control part 8 from its stable second position corresponding to a rest position, so that in the sequence of the switch body 1 also from its second position to its first position (in the Fig. 1 and 2 above), which opens the circuit.

The movements of the individual components (switch body 1, control part 8 and magnetic core 11 with actuator 14) is in the Fig. 1 and 2 indicated by arrows.

For triggering the switching device and in particular the switching unit SE according to the Fig. 1 and 2 it is required that a predetermined triggering condition (Abschaltbedingung) is detected. It must therefore be determined in detail whether the predetermined triggering condition exists when the switching device is in the on state. If the predetermined triggering condition prevails, then the coil 12 is supplied with current via the supply lines 13 for initiating the triggering process.

The triggering condition may be, for example, a predetermined fault, an overcurrent, an overvoltage or the like, wherein after detecting these faulty states of the coil 12 of the trip unit AE, a corresponding current for triggering the switching unit SE is supplied. This corresponding current can thus have the function of a switch-off signal (OFF signal), and it serves the switching device as a circuit breaker.

However, the switching device according to the invention with the switching unit SE and the trip unit AE can also be provided in household appliances, such as washing machines or dryers, wherein after switching by the user by pressing the key element 2 of the switching device of the circuit and thus the entire device can be turned on. If, according to a predetermined operation of the device, the operation has ended or a certain measure has been completed, then the switching device with the switching unit SE can be triggered in an automatic manner and thus the power supply to the device can be switched off.

In the arrangement of the switching device according to the invention in a household appliance, such as a washing machine or a tumble dryer, it is possible by the arrangement described above in detail in conjunction with the predetermined distance D provide a smaller-sized and thus less expensive trip unit AE, which nevertheless in is able to cause an effective triggering and thus a reliable shutdown of the device. This results in advantageously smaller dimensions of the entire switching device.

If the device is to be switched off completely on the part of the user irrespective of the presence of a triggering condition (switch-off condition), another switching device (pushbutton, not shown) may also be provided by means of which the coil 12 of the triggering unit is predetermined after manual operation by the user A current is supplied to AE, so that the above-described triggering operation with the device on (switch body 1 and control part 8 are in their respective second position) in addition to the above-described possibility of automatic shutdown can also be performed with a manual operation by a user.

Basically, therefore, a pulse size or pulse power, which is exerted by the impact of the actuator 14 on the control part 8, on the way of the magnetic core 11 and the actuator 14 over the predetermined distance D in the direction of the control part 8 during acceleration (power supply through the Spool 12), wherein in conjunction with the path over at least the predetermined distance D for the acceleration of the Magnetkems 11 and the actuator 14, a smaller electrical power (current) is provided for the coil 12 of the trip unit AE. In particular, this power or current supply to the coil 12 of the trip unit AE can last a predetermined time. The accumulated kinetic energy during acceleration of the magnetic core 11 and the actuator 14 over at least the predetermined distance D is sufficient to effect an effective and safe triggering (disconnection) of the switching unit SE. In the de-energized state, that is, when the coil 12 of the trip unit AE is turned off, the magnet core 11, together with the actuating device 14, returns to its (in Fig. 1 on the left side) rest position back.

In the presentation in the Fig. 1 and 2 the switching unit SE is designed as a single pole for generating a connection or disconnection within a circuit. However, the switching device according to the invention with the switching unit SE can also be multi-pole and thus designed for a variety of circuits.

The movement paths of the correspondingly movable components such as the control part 8, the switch body 1 and the magnetic core 11 (in conjunction with each other arranged thereon components) are linearly guided and limited by corresponding stops, but this to simplify the illustration in the Fig. 1 and 2 not shown.

Compared with known solutions of the prior art, it is not necessary in the present invention, at the start of movement of the magnetic core 11 (together with the actuator 14) to apply a large force that would be required if between the control part 8 of the switching unit SE and the actuating device 14 of the trip unit AE no predetermined distance would be provided, but the actuator 14 would rest against the control part 8 in the idle state and equal to the beginning of the movement of the triggering process, the control part 8 would have to be accelerated. According to the present invention is thus by the trip unit AE in conjunction with the coil 12 and one of this coil 12 supplied current to apply only a lesser force capable of imparting sufficient kinetic energy to the magnetic core 11 and the actuator 14 of the trip unit AE during acceleration beyond the predetermined distance D to perform the triggering operation. The immediate acceleration thus acts only on the magnetic core 11 and the actuator 14 of the trip unit AE.

The above-described switching device with the switching unit SE and the trip unit AE can also be used in conjunction with a standby controller. In this case, a triggering criterion can be defined via the standby state control device, on the basis of which triggering of the switching device then takes place in the manner described above. In particular, from a standby state with a low power consumption, for example, after a waiting period, an automatic transition to a de-energized state in which after the waiting time, the predetermined trigger condition (switch-off criterion) is present or fulfilled, so that an automatic triggering of the switching device is performed and the device is then switched to the de-energized state.

Furthermore, a triggering condition can also be generated in connection with a computer system (EDP, personal computer, host computer, server and the like) if, after the execution of a program or upon detection of a specific operating state of the computer or of the system to be monitored or controlled, an automatic Triggering (switching off) is required. The triggering can be performed reliably with the above-described switching device with the release unit AE with lower power.

With reference to the Fig. 3 and 4 Hereinafter, a second embodiment of the present invention will be described.

The in the Fig. 3 and 4 specified components of the switching device with the switching unit SE and the trip unit AE are denoted by the same reference numerals like in the Fig. 1 and 2 referred to, provided that the corresponding components perform substantially the same function.

Fig. 3 shows an overall view of the switching device according to the invention according to the second embodiment with a switching unit SE and a trip unit AE. In the same manner as in the first embodiment, the switching unit SE comprises a switch body 1 on which in its upper portion a key element 2 is arranged, which can be actuated by a user (actuation by depression of the key element 2). With the switch body 1 (differing from the structure of Fig. 1 and 2 ) directly a contact bridge 4 is connected, which carries a plurality of contact elements 5 in the same manner as in the first embodiment. The plurality of contact elements 5, which are considered to be the movable contact elements, arrive at a closing of the switching device and in particular the switching unit SE in contact with fixed contact elements 6, which are fixed to a fixed contact element carrier 7.

Fig. 3 shows the state of the switching unit with closed circuit and thus the closed multiple contact elements 5 and 6.

In the switch body 1, a control part 8 is provided in a similar manner as in the first embodiment in the present second embodiment, which is in operative connection with the switch body 1 according to an arrangement still described below.

As in the first embodiment, both the switch body 1 and the control part 8 to each other perform relative movements. In detail, the switch body 1 can perform a running in its longitudinal direction movement, this according to the Fig. 3 and 4 takes place in the vertical direction. Relative to this, the control part 8 is movable in a predetermined manner, wherein preferably the movements of the switch body 1 and the control part 8 substantially perpendicular to each other.

The control part 8 and the switch body 1 are guided in a corresponding manner by mechanical elements, not shown, such that both components can perform a reciprocating (sliding) movement. A biasing force in the upward direction (in Fig. 3 ) is exerted by a first spring 9 on the switch body 1.

The tripping unit AE according to the second embodiment also comprises a arranged in a coil 12 and designed as a flywheel magnetic core 11, and a fixed thereto or integrally formed with the magnetic core 11 actuator 14. Via leads 13, the coil 12, a current or an electric power are supplied, so that the coil 12 can generate a corresponding magnetic field for actuating the magnetic core 11.

On one side of the actuating element 14 opposite side of the magnetic core 11 of the magnetic core 11 is tapered in its dimensions transversely to the direction of movement (effective direction) and carries a third spring 15, by means of which the magnetic core 11 at normally switched coil 12 (no magnetic field) a predetermined rest position (the position as in Fig. 3 shown) occupies.

The operation of the trip unit AE is the same as that of the first embodiment, so that a further description of the function of the trip unit AE is omitted.

The following is a description of the operation of the switching unit SE according to the second embodiment.

In the same way as in the first embodiment, both the switch body 1 and the control part 8 take mechanically coupled positions with each other, wherein each of the components can take a first and a second position.

It is assumed in the following description that first, the switching unit SE is in an off state, in which both the switch body 1 and the control part 8 are in their respective first position and the movable multiple contact elements 5, on the electric conductive contact bridge 4 are arranged, are not in contact with the fixed plurality of contact elements 6 and thus the circuit is open.

Notwithstanding the first embodiment, the control part 8 in a region adjacent to the switch body 1 on a predetermined manner arranged backdrop, the positions and the movement (in the Fig. 3 and 4 a vertical movement) of the switch body 1 can influence. For this purpose, the switch body 1 in the region of the arrangement of the link K on a pin S, wherein in the relative to each other taking place reciprocating movement of the control part 8 and the switch body 1 of the pin S moves within the predetermined backdrop K. In particular, the gate defines K endpoints of the relative movement between the control part 8 and the switch body 1 and further defines two stable resting points, wherein a first point P1 is disposed at the upper end of the link K. Are located relative to each other, the switching body 1 and the control part 8 in such a position that the pin S of the switch body 1 occupies the point P1, then both the switch body 1 and the control part 8 are in their respective first position. The arranged in the control part 8 backdrop K is also referred to as a heart curve.

In this position, the electrical contacts or the movable and the fixed plurality of contact elements 5 and 6 and thus the circuit are open.

Now intends a user to operate the switching device and in particular the switching unit SE, then the user will exert a compressive force on the key element 2 and press the key element and arranged thereon (firmly connected) switch body 1 down. In this case, the bearing body, not shown, and guided in its movement follows 1 a move down according to the Fig. 3 and 4 , so that the pin S of the switch body 1 moves within the gate K down to a lowermost point P2, wherein in connection with this movement, the control part 8 by the leadership of the pin S by means of the backdrop K a slight reciprocating movement across to move the switch body 1 performs.

If the user releases the key element 2 after the pin S of the switch body 1 has reached the point P2 of the link K, then the switch body 1 is moved upward as a result of a bias by a first spring 9, so that within the link K the pin S of the switch body 1 reaches a point P4, this point P4 is a stable rest point in the course of the backdrop K. The reaching of the point P4 by the pin S represents both the switching body 1 and the control part 8 reaching the respective second position.

If the user intends to interrupt the circuit again, this requires a renewed actuation or depression of the key element 2 and thus of the switch body 1, so that within the slot K of the control part 8 of the pin S of the switch body 1 down to a point P3 moves, and then the pin S moves within the gate K after releasing the key element 2 by the user due to the biasing force by the first spring 9 up to a point P5, which has the point P1 at which the movement cycle has begun , is identical.

During the movements of the pin S of the switch body 1 in the arranged in the control part 8 backdrop K leads synchronously with the pin S of the switch body 1 movements in its longitudinal direction (in the Fig. 3 and 4 in the vertical direction). The control part 8 is subjected to the determined by the backdrop K measure a reciprocating motion. This is in the Figures 3 and 4 indicated by arrows for the respective relative movements to each other.

The point P4 within the path defined by the link K is a stable position, which for the switch body 1 and the control part 8, the respective second Position represents, and the point P1, which is identical to the point P5, represents the respective first position for the switch body 1 and the control part 8. In the respective first position, the contacts and thus the circuit are opened, while at the respective second position Position the plurality of contact elements 5 and 6 and thus the circuit is closed.

It is thus according to the arrangement of Fig. 3 and 4 the switching device of the second embodiment possible that the user after switching on or off the switching device by re-pressing (depressing) of the key element 2 can set the respective associated reverse operating state of the switching device manually.

The triggering of the switching device and in particular of the switching unit SE in connection with the tripping unit AE will be described below.

The actuating device 14, which is arranged on the magnetic core 11 or integrally formed therewith, has in the same manner as in the first embodiment in the idle state of the trip unit AE between the outer end of the actuator 14 and the control part 8, when this is in the second position , a predetermined distance D.

Thus, the switching unit SE is in the on state, that is, both the switch body 1 and the control part 8 are in their respective second position, in which the pin S of the switch body 1 is located at the stable point P4 of the link K, and is present the predetermined triggering condition (trip or switch-off) of the coil 12 of the trip unit AE via the leads 13 supplied an electric power or an electric current, then begins opposite to the biasing force by the third spring 15 of the magnetic core 11 in conjunction with the actuator 14, according to the representation in the Fig. 3 and 4 to move to the right to overcome at least the predetermined distance D and the control part 8 to give a (predominantly elastic) shock.

In the same way as in the first embodiment, therefore, during the movement along the path over the predetermined distance D in the direction of the control part 8, the magnetic core 11 in conjunction with the actuator 14 by the built-up in the coil 12 magnetic field kinetic energy by the magnetic core 11 and the actuator 14 are accelerated, so that in the movement after overcoming the predetermined distance D in the direction of the control part 8 of the magnetic core 11 and the actuator 14 have received such a (predetermined) kinetic energy that the force exerted on the control part 8 shock sufficient to the control part 8 by a small amount as shown in the Fig. 3 and 4 shift to the right, so that the pin S of the switch body 1 is no longer stable against the point P4 of the backdrop K, but within the backdrop K, starting offset from the point P4 to the left or moved. The switch body 1 is then no longer held by the control part 8 in conjunction with the pin S and the link K in its second position.

By the action of the biasing force of the first spring 9, the switch body 1 is moved upward, so that moves in the gate K of the control part 8 of the pin S of the switch body 1 up to the point P5 or P1. During this movement, which was triggered by the (predominantly elastic) impact of the trigger unit AE on the control part 8, the previously in contact multiple contact elements 5 and 6 are separated and thus interrupted the circuit.

It can with the in the Fig. 3 and 4 specified and described above structure of the switching device according to the second embodiment in the same manner as in the first embodiment can be achieved that a safe triggering (switching off) of the switching device is ensured, so that even with a smaller sized trip unit AE by the formation of the magnetic core 11 as a flywheel and the arrangement of the predetermined distance D between the actuator 14 and the control part 8 sufficient kinetic energy can be applied to ensure safe triggering.

In addition to the possibilities of switching on the switching device and triggering of the switching device by means of the trip unit AE can with the arrangement according to the second embodiment, the user directly make a shutdown manually, as described in detail above.

The predetermined release conditions are the same as those of the first embodiment, and also in the present case, an application in the industrial sector or in household appliances, such as washing machines or dryers, is possible. Also by means of triggering by the trip unit AE from a standby state with in some cases very low power consumption, a transition to a completely de-energized state (complete shutdown) of the device can be achieved.

The trip unit AE of the switching device according to the invention can also be activated by means of a controller of a control device or a personal computer by detecting the presence of the trigger condition and the coil 12 of the trip unit AE, a corresponding current is supplied.

The advantages achieved by the arrangement of the switching device according to the second embodiment are the same as those of the first embodiment.

Claims (13)

Switching device, with: a switching unit (SE) comprising a switch body (1) movable between a first and second position with a plurality of contact elements (5) disposed thereon in contact with the plurality of contact elements (5) when moving from the first position to the second position ) opposed fixed contact elements (6) are brought to close a circuit, and a relative to the switch body between a first and a second position movable control part (8) for holding the switch body (1) in its second position, when the control part (8) has reached his second position, and a trip unit (AE) for triggering the switch unit (SE) when the switch body (1) and the control part (8) are in their respective second positions, and when a predetermined trip condition exists by offsetting the control part (8) by means of an actuator (14) the trip unit (AE) in the first position, whereby the switch body (1) is placed in its first position and the circuit is opened, wherein the actuating means (14) are spaced apart from each other by a predetermined distance (D) without the predetermined triggering condition and the control member (8) in its second position. Switching device according to claim 1, wherein the trip unit (AE) is an electromagnetically actuated trip unit. Switching device according to claim 2, wherein the electromagnetically actuated trip unit (AE) at least one coil (12), which is supplied in response to the presence of the predetermined triggering condition, a current for generating a magnetic field through the coil (12), and at least one magnetic core (11 ), on which the actuating device (14) is arranged, which is displaced by the magnetic field of the coil (12) in its direction of action for displacing the control part (8) of the switching unit (SE) from the second position to the first position. Switching device according to claim 3, wherein together with the magnetic core (11) in the presence of the predetermined triggering condition the actuating device (14) moves by at least the predetermined distance (D) towards the control part (8) of the switching unit (SE) and onto the control part (11). 8) a shock with a predetermined kinetic energy is applied. Switching device according to claim 1, wherein the magnetic core (11) and the actuating device (14) of the tripping unit (AE) are held in a rest position by spring force in the absence of the triggering condition, and in the presence of the predetermined tripping condition the magnetic core (11) and the actuating device (14 ) in the direction of the control part (8) of the switching unit (SE) to overcome the predetermined distance (D) are accelerated. A switching device according to claim 1, wherein the direction of movement of the control member (8) between the first and second positions thereof, and the direction of movement of the switch body (1) between the first and second positions thereof are at a predetermined angle to each other. A shift device according to claim 6, wherein said predetermined angle is 90 °. Switching device according to claim 1, wherein the control part (8) has a pin (16) and the switch body (1) has a predetermined depression, wherein the control part, upon reaching its second position, mechanically holds the switch body in its second position, in that the pin (16) of the control part (8) engages with the recess (17) of the switch body (1). Switching device according to claim 1, wherein the switch body (1) and the control part (8) are each pressed by spring force in their respective first position. A switching device according to claim 1, wherein the tripping unit comprises a magnetic core (11) designed as a flywheel, and the magnetic core is held in a predetermined rest position by means of spring force in the absence of the predetermined tripping condition. Switching device according to claim 1, wherein the switch body (1) has a pin (S), and in the control part (8) a link (K) is formed, and wherein during a movement of the control part (8) between its first and second position, and during a movement of the switch body (1) between the first and second position of the pin (S) through the gate (K) is guided. A switching device according to claim 11, wherein the gate (K) formed in the control part (8) determines the first and second positions of the control part and the first and second positions of the switch body (1), and wherein the respective first and second positions of the control part and Switch body are coupled together. Switching device according to claim 11, wherein the link (K) in the control part (8) determines two rest positions (P1, P4) for the pin (S) of the switch body (1) corresponding to the respective first and second positions of the control part and the switch body ,

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