EP2553255A2 - Switching apparatus, starting apparatus and method for an electromagnetic switching apparatus - Google Patents

Abstract

What is described is: a switching apparatus (KH, KA, ES) with an electromagnetic switching element and a controller (4), wherein the switching element comprises two coils on a core acting on a common armature (A). In order to realize an actuation of the armature (A) in drivable fashion as quickly and simply as possible with a low energy consumption, the controller (4) is designed to have in each case one switch (S_1-6) in the current path of the coil for driving each coil.

Description

 description

title

 Switching device, starting device and method of an electromagnetic switching device

State of the art

The invention relates to a switching device with an electromagnetic switching element and a controller, wherein the switching element has two coils on a

Core with the effect on a common anchor covers. The invention further relates to a starting device for an internal combustion engine, in particular for a motor vehicle, with a starter motor, a coupling device for temporarily coupling the starter motor with the internal combustion engine and with a starter control. Furthermore, the invention relates to a method of an electromagnetic switching device, with a switching element and a controller, wherein two coils are driven on a core with effect on a common armature of the controller. Electromagnets, relays and transformers or similar inductive loads are known, with

Windings on a core, which are switched as inductive loads.

Further, a starter relay having the dual function of a shift and apply relay in a starting device for engaging a starter pinion in the ring gear of an internal combustion engine and for driving a starter motor is known to start an internal combustion engine.

It is known at starting devices, a switching principle, after which a retraction and a holding winding are arranged on a core, with a high tightening force and a high starting speed of a starter motor driven starter pinion in Engage a ring gear of the engine and to switch the starter motor with a maximum current. With the holding winding, the starter relay is kept in the closed state while the current for the pull-in winding is reduced. The holding winding is connected directly to the vehicle ground. By contrast, the intake winding is connected to the vehicle mass via the starter motor. If the

Switch for the starter motor is closed at the starter relay and the starter motor is started, reduces the feed current, since the starter motor is now applied directly to the positive pole potential of the starter battery. With this switching principle, an immediate restart is prevented, even with permanently excited starter motors, since the induced voltage of the starter motor does not allow a full feed-in current.

As an alternative, it is known to realize the relay with a single winding and to reduce the holding current by means of a current control or control, for example, a two-step control or a pulse width modulation after retraction. However, such a relay must have a large winding, namely a winding with a high number of turns for the low holding current and / or a thick electrical conductor wire for a sufficient pull-in force.

Attempts are being made to introduce starting systems in vehicles, in which the control of the starter motor and the activation of the engagement mechanism are carried out separately in order to realize start-stop systems with high availability of the internal combustion engine. In these start-stop systems, there are single-track strategies according to which the starter motor driven starter pinion is first accelerated and as far as possible synchronized with a synchronous rotational speed in the ring gear of a leaking internal combustion engine.

EP 0 848 159 B1 describes a starting device with an electronic control for a start-stop operation, wherein a starter motor and a starter relay for engaging a starter pinion in the ring gear of an internal combustion engine are separately controlled.

DE 10 2006 01 1 644 A1 describes a starting device and a starting method for starting an internal combustion engine in a start-stop operating mode. The starter pinion is, according to a particular method, at a sufficiently approximate peripheral speeds into a rotating ring gear of an outgoing one Internal combustion engine einspurbar. The single-lane relay with one winding is supplied with a current for meshing, the current for holding the starter pinion in the engaged state can in principle be reduced to zero amperes.

The applicant is a device for driving an electromagnetic switching element with a double winding and three semiconductor switches known. There are rapid turn-on and turn-off by enforcing equal and opposite energization due to certain switch positions with the same number of turns coil can be realized.

It is an object of the invention to provide a switching device, a starting device and a method for operating the switching device of the type mentioned in such a way that an actuation of the armature as quickly and easily controlled with low energy consumption.

Disclosure of the invention

According to the invention the object is achieved by the subject matter of claims 1, 7 and 8.

It is an idea of the invention to construct a switching device as efficiently as possible by implementing a transformer effect with the switching device. For this purpose, the control is designed to control each coil, each with a switch in the current path. Thus, the coils are independently switchable, at least within certain limits. The advantage for this is that an energy transfer between the two coils is utilized according to the transformatory effect, and thus the use of the electrical energy decreases. A further advantage is that the erasing power is lower than that of conventional input winding and holding winding switching devices described in the introduction, and also a complicated extinguishing circuit, e.g. a freewheeling diode on the power switch, for example, designed as a relay switching device in a starting device is not required.

According to a preferred embodiment, a first coil, a pull-in winding and the second coil is a holding coil having an electromagnetic effect on the armature. This has the advantage that for retraction of the anchor either one or both Windings can be energized, so that a fast feed with a high tightening force and a fast switching speed is achieved. To hold the armature in the retracted position, the energization of the holding winding with a significantly lower electrical energy consumption is sufficient so that the intake winding can be switched off. This results in a considerable energy saving.

To be able to design the switching device even more efficient and to achieve a higher power saving function, the coils preferably have different numbers of turns, in particular a difference in the number of turns greater than 3, wherein particularly preferably the number of turns of the pull-in winding is greater than the number of turns of the holding winding. Thus, a particularly efficient pull-in winding is created and the holding winding, based on the application, can be designed as needed. In order to switch the coils completely independently of each other and to implement the transformer effect, the coils are each separately, so independently, directly switchable to the ground potential. An intermediate or series connection with a coil and / or the starter motor is generally not provided. Advantages of switching to ground potential include, among other things, the simple and thus low-cost to be realized electronic switch - so-called Lowside- switch. Disadvantages when switching to Batteriepluspotential include the costly and thus expensive to be realized electronic switch - so-called high-side switch.

According to an alternative preferred embodiment, the coils are each separately, so independently of each other, switchable at the battery plus potential. Switches on the battery positive pole potential have the advantage that the ground connections between the coils are relatively easy to implement, since only a connection to the body or the internal combustion engine are created, which is usually very simple and thus significantly minimizes the cabling. Another advantage is that the short circuit fault tolerance can be avoided by a factor of about 10, compared to switches at ground potential. Short circuits therefore occur significantly less. According to a preferred alternative embodiment, in order to reduce the drive lines of the switching device, both coils can be driven together by a switch either at the battery plus potential or at the ground potential. The intake winding has a separate switch that can be used with the armature to switch off the

Energization of the pull-in winding is positively coupled. Thus, due to a simple mechanism, the energizing of the pull-in and hold winding is controlled. A complex electronic circuit for controlling the pull-in winding is not required. Deactivation of the pull-in winding takes place when the armature is fully retracted and, for example, has closed a switching contact or when the complete pulling in or closing of a switching contact can still safely track. Only then does the switching to the holding winding take place. The pull-in winding is thus switched off with a switch, which is preferably mechanically coupled to the armature. The wiring harness for such a switching device and the connector and interfaces are thus simplified and shortened.

The use of two coils in a switching device, which is designed to perform a transforming effect, also has the advantage that for driving the coil semiconductor switches, such as metal oxide semiconductor field effect transistors, in short: MOSFETs, can be used without them due to destroy too high extinguishing energy. Preferably, the pull-in winding is low-impedance for a high current flow and the holding winding is designed to be high-impedance for a small current consumption. When using a single coil, however, an increased temperature at the MOSFET can be achieved when switching off, which can reach several hundred degrees C from the power loss. At such temperatures, the MOSFET can be destroyed.

In the switching insert of two coils with a drive taking advantage of the transformatory effect, a power loss advantageously produces a final temperature at a significantly lower than the maximum permissible semiconductor temperature. Thus, the MOSFET is not impaired in its function and achieves a long service life. The invention is also achieved by a starting device for an internal combustion engine, wherein at least one switching device described above is designed as a switch for the energization of the starter motor. This has the advantage that the starter motor can be controlled independently of the meshing process. The independent driving of the starter motor is important in order to engage in the rotating ring gear of a leaking internal combustion engine according to a particular operating mode during a start-stop operation. The advantage of using the switching device as a switch for activating the starter motor is that the switching device can be easily controlled without having to implement a complicated electronic starter motor control based, for example, on a reduction or pulsed energization of the starting device. Such systems are known for example from DE 10 2006 01 1 644 A1. It is thus only required to turn on the switch, an increased power consumption for a pull-in winding, while the holding winding usually has a low power consumption. Thus, longer runtimes of the starter motor with little power loss for special start-stop

Strategies feasible.

According to a further preferred embodiment, the switching device is provided as a coupling device for input and output of a driven by the starter motor starter tread in a ring gear of the internal combustion engine. This has due to the implementation of the transforming effect in the switching device has the advantage that the input and output tracks with high switching times can be realized and less energy is required for meshing and holding the starter pinion. According to a further preferred embodiment, the switching device is part of a

Control of a current limiting device to control the starter motor by varying the current. About a current path with the current limiting device of the starter motor is turned on. Thus, there is no sudden or significantly reduced voltage drop at the voltage source, such as the battery. The possible voltage dip is effectively minimized. By directly energizing a second current path bypassing the current limiting device and switching off the current path with the current limiting device, the starter motor is supplied with a maximum electrical energy for starting the internal combustion engine. The switching device according to the invention as part of the drive in the current path with the current limiting device also has the Advantage to switch quickly and energy-efficient and to keep the switching state correspondingly long if necessary.

The invention is also achieved by a method of an electromagnetic switching device in that each coil is driven in a separate current path, each with a formed in the control switch. Thus, a transforming effect can be implemented on the electromagnetic switching device. It is therefore or compared to a conventional switching device with retraction and holding winding in which the pull-in winding is connected in front of the starter motor, a much lower erasing power required. Also, an erase circuit, for example in the form of a freewheeling diode, according to the prior art can be omitted. Furthermore, the coils can have significantly different numbers of turns, since a cancellation by counter-energization is not provided, but only a transmission of energy.

According to a preferred method, in particular to achieve even faster switching times, the coils are subjected to an increased voltage and a coil, in particular the feed coil, energized as a function of the level of the increased voltage. In this case, only one coil is energized, in particular from an upper voltage limit. This means that the voltage level is increased so that the current of the second coil is reduced to zero in time. This embodiment is advantageous when voltage sources with increased voltage are present.

In order to perform a simple fault diagnosis of the switching device, a first coil is energized and with the second and / or first coil voltages and currents are inductively detected and evaluated. Thus, it can be determined where, for example, the anchor is or whether a coil is defective. Such methods are easily implemented, since the coils are controlled by a controller which is programmable with a microcomputer, for example. Required for this purpose are each a current and voltage measuring device and a corresponding evaluation device that can be implemented by the microcomputer.

It goes without saying that the features mentioned above and those yet to be explained below can be used not only in the respectively specified combination but also in other combinations. Brief description of the drawings

The invention will be explained in more detail below with reference to the drawings. Show it:

1 shows a schematic circuit diagram of a starting device with three switching devices according to the invention, FIG. 2 shows a schematic circuit diagram of an alternative starting device according to the invention, FIG.

3 is a time-current-speed diagram of a procedure during a start-stop operation,

4 shows a diagram with switch-on times for a single and double winding with respect to different temperatures,

5 is a diagram of shutdown times with single and double winding with respect to different temperatures,

6 shows a current-temperature profile of a control by means of MOSFETs of a switching device according to the invention and FIG. 7 shows a current-temperature profile of a control with MOSFETs with a

Double coil and a circuit according to the prior art.

EMBODIMENTS OF THE INVENTION FIG. 1 shows a circuit diagram of a starting device 1 for an internal combustion engine of a motor vehicle. The starting device 1 comprises a starter motor 2 with a coupling device 3 and a controller 4, which drives the starter motor 2 and the coupling device 3. The controller 4 comprises a microcomputer with memory, not shown, the switch SrS ₆ shown in simplified form, in particular semiconductor switch, preferably in the form of metal-oxide field-effect transistors, in short: MOSFETs, which is in information contact, for example via an in-vehicle bus 5 with the engine control and a contact switch on the ignition. In a particularly preferred embodiment, the starting device 1 according to FIG. 1 has three switching devices ES, KA and KH according to the invention. A first switching device ES is provided as an actuator 6 in the coupling device 3. The actuator 6 actuates the lever 7, which latches a starter pinion 8 in a ring gear 9 of the internal combustion engine 10.

Each inventive switching device ES, KA, KH comprises two coils which are denoted by index ₁ and ₂ . The two coils ^ and ₂ act in each switching device in each case to a common armature Ai, A ₂ and A ₃ . Each coil i, ₂ is connected separately and directly to the ground potential of a vehicle battery, for example via the body. Each coil ₁ , ₂ is connected to a switch Si - S ₆ separately to the positive pole, the

Batteriepluspolpotenzial wired according to a shown in Fig. 1 preferred circuit arrangement according to the invention. In each current path of each coil, an electronically controllable switch Si - S _{6 is} arranged. The advantages of such a circuit arrangement with the switching devices ES, KA, KH are that the coils ₁ , ₂ can be supplied with current independently of each other and thus a transformer effect can be utilized at each switching device ES, KA, KH. Furthermore, it is important that a first coil ■ low impedance and a second coil _{2 is formed} high impedance. Thus, energy transfer from one coil to the other is possible due to the transformer effect, as is known by a transformer, when the low-resistance coil is turned off. As a result, the first coil and / or second coil no longer need to be deleted in a complex circuit in order to quickly dissolve the magnetic effect for new switching operations. For example, no free-wheeling diode is required at the switch. In addition, less energy is consumed. Preferably, the first coil is a so-called pull-in winding and the second coil is a holding winding which is on the electromagnetically actuated

Anchor Ai, A ₂ and A ₃ act to perform movement. For a feeder much power is needed and used, whereas to hold the armature in the retracted state, the energy is transferred to the holding winding, which requires little additional energy. Thus, the switching device can be operated more efficiently with short switch-on and switch-off times. The currents at the pull-in winding are for one switching device KA and KH designed as a switching actuator, for example less than 25 A (amperes), and the currents at the holding winding are less than 7 A (amperes). If the switching device ES is used as a single-track actuator, higher currents of up to 35 A are required for the pull-in winding.

Due to the transformatory effect, the energy is transferred to the holding winding when switching off the pull-in winding and degraded there. When switching off the holding winding, only a small amount of electrical energy needs to be dissipated. As a result, an extinguishing circuit is either no longer required at all or only considerably simplified.

Due to the cooperating coils a diagnosis by state analysis by means of detecting and evaluating currents and voltages on a coil while energizing the other coil is possible. It can be determined the position or movement of the armature or a fault on the coils.

The switching device KA electromagnetically switches a contact bridge KAB and is thus an electromagnetic relay to the starter motor 2 with a reduced current, which is limited by a current limiting device R _v , easy to turn, for example, a battery or an electrical system from the vehicle at startup not heavily loaded and to minimize a voltage dip.

With the switching device KH is energized by electromagnetic closing a contact bridge KHB the starter motor 2 with a maximum current after it has started. This maximum current is required for starting the internal combustion engine 10, for example. The usual, high, unwanted voltage dip is minimized since the starter motor 2 has already been accelerated to a predetermined speed. FIG. 2 shows an embodiment modified to FIG. 1, in which each switch Si,

S ₃ , S _{5 of} the pull-in winding ESi, ΚΑ-ι, KH-i, each of the switching device ES, KA, KH is connected directly to the ground potential of the battery. In addition, each switch Si, S ₃ , S ₅ with the armature A ^ A ₂ , A ₃ , positively coupled to turn off the energization of the pull-in winding ESi, KA-i, KH-i. Thus, the wiring effort is minimized, since only one plus pole side arranged switch S ₂ , S ₄ , S ₆ to turn both coils is required. Switching off the pull-in winding ESi, ΚΑ-ι, KH-i takes place almost automatically by movement of the respective armature Ai, A ₂ , A ₃ . No electronic control is required for this. This forced control is formed on the coupling device 3, on the switching device KH for direct energization of the starter motor 2 and on the switching device KA, the starter motor 2 via a

Current path with a certain limiting device R _v turns. All switching devices ES, KA, KH can be controlled via electronically controllable switches Si, S ₃ and S ₅ in the controller 4. The peripheral limitation in the form of a rectangle from the controller 4 has not been drawn in this Fig. 2 for the sake of simplicity.

3 shows in a time-current-speed diagram a time course of a special start-stop operation of the internal combustion engine 10 and the starting device 1. FIG. 3 shows a special operating mode according to which the starter pinion 8 to a certain circulating speed is accelerated and in the rotating, expiring sprocket 9 of the internal combustion engine 10 is eingespurt. Starting from a time t ₀ , the speed n _{mot of} the internal combustion engine 10 runs in a characteristic rotational speed shaft movement due to the compression and decompression behavior of the individual cylinders with speed wave troughs and tips. This is shown with the characteristic n _mot . At a defined time, for example, immediately after a switch-off signal for the internal combustion engine 10 has been sent out, the electromagnetic switching device KA is actuated, so that the starter motor 2 is energized via the current limiting device R _v , and the starter motor 2 until the time t ₂ to a fixed speed is accelerated. The current consumption of the switching device KA decreases from the time t-ι until the time t ₂ constantly from. The current consumption is considerably reduced by the use of a pull-in winding KA-i and a holding winding KA ₂ . The contact bridge KAB of the switching device KA is opened at time t ₂ , so that the starter motor 2 is no longer energized.

The speed n _S t of the starter motor 2 decreases slowly to a precalculated time t ₃ , at which the peripheral speeds of the starter pinion 8 with the ring gear 9 in a certain tolerance range are approximately equal. At a defined, precalculated time t ₂₃ between t ₂ and t ₃ , the switching device ES is energized, so that the starter pinion 8 in the outgoing sprocket 9 approximately at the time t _{3 is} caught. At the same time, the contact bridge KAB is closed by the switching device KA by energizing the double coils KA-i, KA ₂ . At time t ₄ , the direct current path is closed by the positive potential of the battery of the starter motor 2 by closing the contact bridge KH B by means of the switching device KH. At time t ₅ , the switching device KA is no longer energized. The starter motor 2 now transmits the maximum electric power to the sprocket 9 of the internal combustion engine 10 to start it again. From a time t ₆ , the internal combustion engine 10 runs by itself and does not require a starter motor 2, so that at the time t _7, the contact bridge KHB is opened again at the switching device KH. The holding winding ES _{2 of} the switching device ES is no longer energized, with the result that the starter pinion 8 spouts out of the ring gear 9. The starter motor 2 reaches its maximum speed at time t ₇ and then expires.

All double coils in all switching devices ES, KA and KH are controlled by the following method. First, feed and holding winding are energized. In a second step, the pull-in winding is switched off and the energy is transferred to the holding winding via a common core. As a result, the effect of the pull-in winding is essentially deleted. In a third step, the holding winding is turned off, the energy is dissipated in the form of heat at the semiconductor switch as a loss energy.

The advantage of the inventive switching device ES, KA and KH with two coils compared to a single winding is that after retraction of the armature Ai, A ₂ , A ₃ a complex control, for example in the form of a current control o- a current control, for example via a timing control or a pulse width modulation, to generate a holding current is eliminated. In addition, in order to achieve a high pull-in force, a large winding is necessary, which realizes a high flux with a high number of turns and is simultaneously designed for low holding currents. The result is typically winding wires with a high number of turns. This high inductances are connected, which lead to a high load of the control, especially when switching on and thus also in the control with many switching operations.

The input described, known from the prior art double winding principle with a feeder coil in the current path of the starter motor requires mandatory Windungsgleichheit of retraction and holding winding, otherwise shutdown can no longer be done because of the voltage applied to the so-called terminal 45, ie, the starter motor, induced voltage. The retraction and holding winding thus cancel each other when switching off by short-term opposite current.

In contrast, the switching device with the double winding in the circuit arrangement according to the invention has several advantages, which will be explained in more detail with reference to the following figures.

Fig. 4 shows a comparison of a switching device once with a single and a double winding respectively with applied battery potential, which corresponds to the standard application, and with an example twice as high battery potential, for example, 24 volts depending on actual temperatures of the coils. The switch-on times of a switching device with a double winding with the usual battery potential from the standard application is shown with the characteristic curve DW1. The characteristic DW2 shows the switch-on times at a high battery potential, for example of approx. 20 volts. The switching time changes only minimally. In contrast, in a single winding, shown with the curves EW1 and EW2, the turn-on times are significantly higher, depending on the temperature of the winding, and at a higher battery potential, the turn-on significantly reduced and thus show greater sensitivity to the variance of the battery potential and thus larger tolerances.

FIG. 5 shows the turn-off times, in turn, of the single and double windings as a function of the temperature of the windings. As the temperature increases, the turn-off time generally decreases. Even with the double winding results in much shorter shutdown times. The turn-off time is slightly smaller with a high battery potential. This is shown with the characteristics DWA1 and DWA2. In contrast, the characteristics EWA1 and EWA2 a switching device are shown with a single winding. These characteristics show significantly longer shutdown times for a high battery potential, and according to characteristic EWA2 a shorter switching time and thus a greater sensitivity to the variance of the battery potential and thus significantly higher tolerances. 6A, B, C show current-voltage-temperature-Ankerweg diagrams over time in a control of the switching device ES, KA and KH according to the invention by means of MOSFETs. FIG. 6A shows, over a period of time t in the millisecond range, the current profile of the pull-in winding and the holding winding over time t. At the time t-ι the pull-in winding with a current between 8 to 15 amps to the

Time t ₂ acted upon, since the pull-in winding is designed low impedance. The holding winding is designed with higher resistance and takes only a small current, which is also negative in part, between the time t-ι and t ₂ . The holding winding has a significantly higher internal resistance than the Einspurwicklung and thus lower currents, for example, by a factor ~ 4.5. A negative voltage arises as follows. Field changes that correspond to a change in energy caused by current changes in the one coil are compensated as possible in a coupled magnetic circuit by the transformer effect by the 2nd coil. This leads partly to negative currents in the holding winding, but can not completely compensate for the field changes due to the different winding ratios of the two coils. Conversely, when switching off the pull-in winding by increasing the current in the holding winding, the reduction of the magnetic field is partly compensated. At time t ₂ , the pull-in winding is switched off and the electrical energy of the pull-in winding is transmitted to the holding winding due to the transformer effect, which flows with a small holding current up to a time t ₃ . At time t ₃ , the holding winding is switched off via the electronic MOSFET switch and the current sounds completely until time t ₄ , so that no current flows through the holding winding. Fig. 6A shows that the holding and the Einspurwicklung manages with a low current for switching and switching off. The electrical energy is thus used more efficiently by implementing the transformatory effect than previously known in the art. The switching device can thus be easily controlled without complicated control or timing. An erase circuit is not or very much simplified due to the transforming effect formed. As shown in Figs. 4 and 5, the turn-on and turn-off time is reduced. Another advantage of the switching device is that a significantly lower power consumption is required, even at a high load of the starter motor 2, for example, because it was accelerated to a certain speed in start-stop operation and the starter pinion gear 8 in the ring gear 9th meshed becomes. The switching device ES is thus used as Einspurrelais. By using the double winding can be done without high current and high erase energy even with a jump start of, for example, 24 volts, for example, a series circuit of two conventional 12 volt batteries in the so-called "jump-start cases".

6B shows with a dashed line the path of the armature Ai, A ₂ , A _{3 in} time between the time points t-1 to t ₄ described for FIG. 6A. At a time t ₁₂ between t- ₁ and t ₂ , the active armature Ai, A ₂ , A ₃ , completely retracted. Somewhat offset in time after the time t ₃ at the time t ₃₁ , the armature Ai, A ₂ , A ₃ leaves the position, so that it is again in the non-energized state position at the time t ₅ .

FIG. 6B additionally shows the voltage U, which shows the fundamental voltage curve when starting an internal combustion engine. A break in the

Voltage U is achieved by switching on the starter motor via the relay and the high current consumption of the starter motor in short-circuit operation with the rotor standing still. After the starter motor turns on reduces its current consumption and the voltage U rises parallel to it. After switching off the relay and thus the starter motor, the current consumption from the voltage source U drops considerably and the

Voltage U jump back to the original output value.

FIG. 6C shows, with a continuous line EWT, the temperature at the barrier layer, the so-called junction temperature, of the respective electronic switch Si-S ₆ from the pull-in winding. The dashed line HWT shows the junction temperature at the MOSFET switch of the holding winding. FIG. 6C clarifies that, at time t ₂ at which the pull-in winding is turned off, the temperature drops by a few Kelvin due to low energy dissipation in the system

MOSFET increases since most of the energy of the feed coil is transferred to the holding coil. So there is virtually no load on the switching MOSFETs. At the time t ₃ , when the holding winding is turned off, a power loss occurs at the junction, which increases the MOSFET switch, here for example by about 40 to 50 Kelvin. Thereafter, the temperature drops quickly. Such a rise in temperature is the MOSFET switch, without significantly deteriorating the life, manageable. Fig. 7 shows in a comparison to FIG. 6, the current-temperature profile of MOSFETs when switching on and off of individual windings with a circuit according to the prior art, wherein the solid curve is the characteristic of a holding winding and the dashed line which is a pull-in winding. In this example, the magnetic fields of the individual windings are not linked and thus not coupled in a transformer. Due to the lack of transformer coupling, the energy can not be transferred to the holding coil when switching off the feed coil. Therefore, temperature rises of several 100 ° C can be recorded, which can destroy the MOSFETs very quickly. The dashed line also corresponds to the current flow of a single-winding coil with a high current level and high cut-off energy, which in turn causes a high semiconductor temperature in the MOSFETs.

All figures show only schematic not to scale representations. Moreover, reference is made in particular to the drawings for the invention as essential.

Claims

claims

1 . Switching device (KH, KA, ES) with an electromagnetic switching element and a controller (4), wherein the switching element comprises two coils on a core with effect on a common armature (Ai, A ₂ , A ₃ ), characterized in that for driving Each coil is the controller (4), each with a switch (Si _-6 ) is formed in the current path of the coil.

2. Switching device according to claim 1, characterized in that a first coil is a pull-in winding and the second coil is a holding winding with electromagnetic effect on the armature (Ai, A ₂ , A ₃ ).

3. Switching device according to claim 1 or 2, characterized in that the coils have different numbers of turns, in particular, the Windungszahldifferenz is greater than three, more preferably the number of turns of the pull-in winding is greater than the number of turns of the holding winding.

4. Switching device according to claim 1 to 3, characterized in that the coils are each separately switchable at the ground potential.

5. Switching device according to one of claims 1 to 4, characterized in that the coils are each separately switchable to the battery potential.

6. Switching device according to one of claims 1 to 5, characterized in that a switch (Si, S ₃ , S ₅ ) of the pull-in winding with the armature (Ai, A ₂ , A ₃ ) is positively coupled for switching off the energization of the pull-in winding, and in particular both coils with a switch (S ₂ , S ₄ , S ₆ ) can be controlled.

7. Starting device (1) for an internal combustion engine, in particular for a motor vehicle, with a starter motor (2), a coupling device (3) for temporarily coupling the starter motor (2) with the internal combustion engine (10) and with a starter control (4), characterized in that the starting device has at least one switching device according to one of the claims. che 1 to 6, wherein at least one switching device (KH, ES, KA) as a switch for the energization of the starter motor and / or as coupling device (3) for us to unravel one of the starter motor (2) driven starter pinion (8) in a Sprocket (9) of the internal combustion engine (10) and / or as a switch for a starter motor (2) current-limiting device (R _v ) is formed.

8. A method of electromagnetic switching device, in particular according to one of claims 1 to 6, with a switching element and a controller (4), wherein two coils are driven on a core with effect on a common armature (A) of the controller (4), characterized in that each coil in a separate current path, each with a in the control (4) formed switch are controlled.

9. The method according to claim 8, characterized in that the coils are subjected to an increased voltage and a coil is energized as a function of time of the increased voltage, in particular from a voltage upper limit only one coil is energized.

10. The method according to claim 8 or 9, characterized in that a first coil is energized and detected with the second and / or first coil voltages and currents and evaluated