DE102006029928B3 - Electronic switching device for switching high electric current, has isolating unit connected between control connection of switching unit and load supply of another switching unit, where isolation unit decouples switching units - Google Patents

Abstract

The device (K) has two semiconductor switching units (T1, T2), each with two load supplies (DT1, ST1, DT2, ST2) and a control connection (GT1, GT2). A control unit is provided for switching the switching device, and is coupled with the connection (GT1), where the control unit produces a control signal for activating or deactivating the unit (T1). An isolating unit (EM) is connected between the connection (GT1) and the supply (ST2) of the other switching unit. The isolation unit decouples the unit (T2) from unit (T1), when the unit (T1) is operated by the control signal in a locked condition.

Description

The The invention relates to an electronic switching device, the first semiconductor switching element having a first load terminal, a second load terminal and a first control terminal, a second Semiconductor switching element with a third load terminal, a fourth Has load terminal and a second control terminal. The second and the third load connection is electrically interconnected. It is provided a control means, with which the switching device is conductive or blocking switchable.

A generic switching device is from the US 4,663,547 known. The switching device described therein comprises an electrically conductive connection between the first control terminal of the first semiconductor switching element and the fourth load terminal of the second semiconductor switching element. The first semiconductor switching element is designed as a self-conducting junction field effect transistor JFET (junction field effect transistor), while the second semiconductor switching element is formed as a self-locking, voltage-controlled MOSFET (Metal Oxide Semiconductor Field Effect Transistor). This interconnection of the first and the second semiconductor switching element is also referred to as a cascode circuit. The electronic switching device is used for switching a high electric current and is also designed for a high reverse voltage. The first and the second semiconductor switching element consist of silicon (Si) and ensure a high switching speed due to the high charge carrier mobility in the silicon.

As can be readily seen, the control means of such a cascode circuit are designed such that a blockage of the cascode circuit is reliable even if the control means fails unforeseen. In the arrangement of the US 4,663,547 the control of the cascode circuit is performed by driving the MOSFET with a positive voltage at its control terminal. When the MOSFET is turned off, the voltage applied to its third load terminal, the drain terminal, rapidly increases. When the so-called pinch-off voltage of the normally-on junction field effect transistor is reached, the junction field effect transistor turns off and blocks the voltage applied to the cascode circuit (ie, the first load terminal or drain of the junction field effect transistor). This control allows uncomplicated control of the entire cascode circuit.

The However, known from the prior art control has a Series of disadvantages. So is a control only with low frequencies possible. Although could the junction field effect transistor for driving with high Frequencies are combined with a very fast MOSFET. In such a design must however parasitic Components, in particular inductors and charge storage, considered which resonant circuits can form when switching. The Episode can undesirable Be vibrations, whereby a trouble-free operation of the junction field effect transistor prevents becomes. This problem falls all the more into the Weight, if instead of the silicon-based junction field effect transistor used a semiconductor switching element made of the semiconductor material silicon carbide (SiC) is used is at which much higher Voltage rise rates can occur.

The The cascode circuit known from the prior art still permits not the direct control of the junction FET, about its switching speed adjust. The primary Switching element, which ultimately the switching speed of the cascode circuit is determined, is formed by the MOSFET. A subsequent change the switching speed of the cascode circuit is not possible.

Around the well-known cascode circuit with lower speeds can switch a resistor is built into the line to the control terminal of the MOSFET become. However, this involves the problem that the MOSFET into the so-called avalanche state, if the reverse voltage of the MOSFET before reaching the pinch-off voltage the junction field effect transistor is applied.

The Insert a resistor in the supply line to the control terminal of the junction field effect transistor to set the switching speed is possible in principle in In practice, however, associated with high losses. Furthermore can due to the interconnection of junction field effect transistor and MOSFET of the Resistance can not be adapted without problems to the components.

In the realization of a control means for a cascode circuit must further be considered that the reverse voltage of the MOSFET is selected in a similar order of magnitude as the pinch-off voltage of the junction field effect transistor, especially in a slow operation, otherwise between the Control terminal and the source terminal formed diode of the junction field effect transistor can be damaged. This thus basically requires an adaptation of the MOSFET to the junction field effect transistor. On the other hand, the over the load path of the MOSFET voltage applied not be significantly greater than the pinch-off voltage of the junction field effect transistor, otherwise a defect of the junction field effect transistor is possible.

From the DE 101 01 744 C1 a switching device is known, which contains at least one MOSFET switching element, at least one JFET protection element and control means, wherein the JFET protection element is electrically connected in series with the switching element and limits the electric current to a maximum current, and the control means the maximum current of the protection element at or after the switch-on of the switching element at least on an average over time, to at least one increased value and then again to at least one lower value.

Out the description became clear that the state of the art known cascode circuit in practice with various problems is afflicted. The object of the present invention is to provide a specify electronic switching device, which the above Does not have problems.

These Task is by a generic electronic switching device solved, which according to the invention the features in that the control means is connected to the first control terminal of the first Semiconductor switching element is coupled to which a through the Control means producible first control signal for switching on or off of the first semiconductor switching element can be applied, and that a decoupling means is provided, which between the first control terminal of the first Semiconductor switching element and the fourth load connection interconnected is and a decoupling of the second semiconductor switching element of causes the first semiconductor switching element when the first semiconductor switching element brought into a blocking state by the first control signal is or will.

in the Contrary to the prior art is an immediate control of the first semiconductor switching element, which is independent of a control of the second switching element can take place. there it is ensured that the electronic switching device in Case of a defect of the control means reliably enters a blocking state. allows this is achieved by the intended decoupling means. The direct Driving the first semiconductor switching element allows a easy adjustment of the switching speed. Furthermore, about the Uncoupling a defined turn off possible.

advantageous embodiments arise from the dependent ones Claims.

According to one embodiment is located at the second control terminal of the second semiconductor switching element in a normal operation the switching device to a second control signal, which is the second Semiconductor switching element conductively switches. This ensures that the control of the cascode circuit according to the invention exclusively via the first semiconductor switching element takes place. Only in a non-intended condition the switching device, e.g. a defect of the tax means, goes the second semiconductor switching element in a blocking state, whereby simultaneously switching off the first semiconductor switching element is effected.

According to one another embodiment is the decoupling means by a semiconductor switching element or Switching network formed, which is adapted to the first control terminal of the first semiconductor switching element with the fourth load terminal to connect, if an error occurs and an electrical Connection between the first control terminal of the first semiconductor switching element and the fourth load terminal when the switching device regular is operated. The decoupling means can thus be formed by an "ideal switch".

Prefers it is when the decoupling means formed by at least one diode is. It is provided that a diode terminal of at least a diode having the first control terminal of the first semiconductor switching element and a cathode terminal of the at least one diode with the fourth Load connection is coupled.

The Providing the diode allows on the one hand the immediate control the first semiconductor switching element and on the other hand allows the blocking the first semiconductor switching element in case of failure of the control means or another, unforeseen mistake. Furthermore, the protects Diode the control terminal of the first semiconductor switching element against too big positive tensions.

According to one another embodiment it is provided that the decoupling means has a blocking voltage, the bigger or is equal to the reverse voltage of the second semiconductor switching element.

The Decoupling agent can be outside the actual cascode circuit comprising the first and the second semiconductor switching element, are arranged, which in particular the switching characteristics of the cascode circuit in an advantageous manner can be influenced.

According to a further embodiment, the control means is designed as a driver circuit, which is connected to the first control terminal of the first semiconductor switching element via a resistor, with which the slope of the voltage level of the control signal is adjustable.

According to one another embodiment is connected to the second control terminal of the second semiconductor switching element coupled to a further control means, which the second semiconductor switching element in a normal operation the switching device switches substantially permanently conductive, the switching second semiconductor switching element in an error case blocking, and the second semiconductor switching element at a power-on the switching device with a predetermined delay of one locks in a conductive state. The further control means For example, after switching on the circuit device according to the invention a time-delayed Activation of the second semiconductor switching element effect, so that it is ensured that the first semiconductor switching element is correct by the generation of a corresponding drive signal by the Control means is in a blocking state. This can be Einschaltspitzen or the like. Be avoided.

In a further embodiment the first semiconductor switching element is preferably as a self-conducting Field effect transistor, in particular as a junction field effect transistor (Junction Field Effect Transistor, JFET), formed. Prefers the first semiconductor switching element consists of the semiconductor material Silicon carbide (SiC).

In a further embodiment is the second semiconductor switching element as a self-blocking MOS field effect transistor (Metal Oxide Semiconductor Field Effect Transistor) ausgebil det. The second semiconductor switching element preferably consists of the semiconductor material Silicon.

The Use of silicon carbide as semiconductor material for the first Semiconductor switching element has the advantage that such a Semiconductor switching element is high temperature and high voltage capability. The on-resistance of such a semiconductor switching element is smaller by a factor of 20 to 30 than in a comparable one Silicon-based semiconductor switching element. This can be done achieve very high switching speeds and low losses. In conjunction with the control according to the invention is a trouble-free operation even at high frequencies from 200 kHz to 1 MHz possible.

The Invention will be explained in more detail with reference to FIGS. Show it:

1 an electrical equivalent circuit diagram of an electronic switching device according to the invention, and

2 an exemplary embodiment of one in the circuit according to 1 used decoupling agent.

1 shows the equivalent circuit of an electronic switching device. A cascode circuit K has, in a known manner, a first semiconductor switching element T1 and a second semiconductor switching element T2. The first semiconductor switching element T1 is designed as a self-conducting high-voltage field effect transistor, in particular as a junction field effect transistor, wherein this consists of the semiconductor material silicon carbide. The second semiconductor switching element T2 is formed as a self-locking low-voltage MOSFET, which consists of the semiconductor material silicon. In a known manner, the first semiconductor switching element T1 has a first load terminal DT1 (hereinafter referred to as drain terminal), a second load terminal ST1 (hereinafter referred to as source terminal) and a first control terminal GT1 (hereinafter referred to as a gate terminal). In a corresponding manner, the second semiconductor switching element T2 comprises a third load terminal DT2 (drain terminal), a fourth load terminal ST2 (source terminal) and a second control terminal GT2 (gate terminal). The source terminal ST1 of the first semiconductor switching element T1 and the drain terminal DT2 of the second semiconductor switching element T2 are electrically interconnected at a node Kn1.

The Cascode circuit K may be formed as a component. In this In this case, the cascode circuit has a drain D, a source S and a first control terminal G1 and a second control terminal G2 on. The drain terminal D is through the drain terminal DT1 of the first semiconductor switching element T1 formed. The source terminal S of the cascode circuit K is through the source terminal ST2 of the second semiconductor switching element T2. The first control connection GT1 of the first semiconductor switching element T1 is connected to the first control terminal G1 of the cascode circuit K coupled. In a similar way the second control terminal GT2 of the second semiconductor switching element T2 connected to the second control terminal G2 of the cascode circuit K.

With the drain terminal D is coupled to a supply line L1, at which a voltage Vin is present. With the source connection S the cascode circuit K is coupled to a supply line L2, to which a reference potential GND is applied.

One Control means SM1 is over a resistor R to the first control terminal G1 of the cascode circuit K interconnected. The control means SM1 is connected via a supply potential connection VP1 with an operating voltage + Vbb and a supply potential connection VP2 supplied with an operating voltage of example 0V. The Control means SM1 is formed as Trei berschaltung, which a Voltage with negative polarity the first control terminal G1 of the cascode circuit K can perform (Signal S1).

Furthermore, a decoupling means EM is connected to the first control terminal G1, which is further coupled to the source terminal of the cascode circuit K. The decoupling means comprises the functionality of an "ideal" switch and is preferably formed by one or more diodes connected in series with each other. This is exemplary in 2 shown. Here, an anode terminal of the diode D with the control terminal G1 and a cathode terminal of the diode D with the source terminal S of the cascode circuit K is connected.

Of the second control terminal G2 of the cascode circuit K is either direct with the supply potential VP1 or via another control means SM2 connected to this. The second control means SM2 has a so-called start / stop functionality on, wherein the control means SM2 as the n-type MOSFET in a normal operation of the cascode circuit with a positive voltage so that it is conductive. Only in an irregular operation the switching device, the second control means SM2 switches the second Semiconductor switching element T2 blocking by the gate terminal GT2 to the potential of the source terminal ST2 of the second semiconductor switching element is brought. The functionality is given even in the absence of the second control means SM2, e.g. if an error in the control of the electronic switching device is present. As soon as a separation of the gate terminal GT2 or of the second control terminal G2 of the cascode circuit K from the supply potential terminal VP1 is present, the second semiconductor switching element T2 goes into the blocking operation.

Of the Operation of the electronic invention Switching device is as follows: in the normal state of the cascode circuit or switching device is the second semiconductor switching element T2 always turned on. The switching on and off of the cascode circuit is exclusively via the first control means SM1 made, which the first semiconductor switch T1 over the adjustable in size Resistor R is supplied with a voltage signal. Advantage of this Control is that during the switching operation of the first semiconductor switching element T1 no Vibrations occur. about the size of the resistor R can Any flanks can be set so that on the one hand a high-frequency operation of the cascode circuit is possible and on the other hand noise be avoided.

The Switching off the first semiconductor switching element T1 is performed by the application of a negative voltage by the control means SM1 to the first control terminal G1. The pinch-off voltage is thus determined by the Voltage VDS, i. the drain-source voltage across the load path of the second Semiconductor switching element, reduced by the forward voltage of the at least one diode D of the decoupling means EM. The diode D must be designed such that this at least the drain-source voltage of the second semiconductor switching element T2 can lock. During the Turning off and the blocking of the first semiconductor switching element T1, the second semiconductor switching element T2 remains conductive, i.e. the cathode terminal of the diode D is connected to the reference potential GND connected.

The Provision of the decoupling means thus allows the gate control of the junction field effect transistor. At the same time, a lock of the first semiconductor switching element in case of failure of the control means SM1 allows, since in this case the second semiconductor switching element T2 from its conducting into one locking state passes, whereby the voltage at the source terminal ST1 of the first semiconductor switching element T1 rises and finally reached the pinch-off voltage. The presence of the decoupling agent continues to lead in that the gate terminal GT1 of the first semiconductor switching element T1 against too big protected positive voltages is.

The Entkopplungsmittel EM can outside the actual cascode circuit K be arranged.

Of the Advantage of the circuit arrangement according to the invention is that operation of the cascode circuit with very high Frequencies by a direct drive of the junction field effect transistor allows is. The switching speed can in this case by the by the Control means SM1 generated current or resistor R is set become. A self-locking state is achieved even if a malfunction should be present in one of the control means.

Claims (12)

An electronic switching device comprising - a first semiconductor switching element (T1) having a first load terminal (DT1), a second load a second semiconductor switching element (T2) having a third load terminal (DT2), a fourth load terminal (ST2) and a second control terminal (GT2), the second and the third Load connection are electrically interconnected, and - a control means, with which the switching device (K) is conductively or blocking switchable, characterized in that - the control means to the first control terminal (GT1) of the first semiconductor switching element (T1) is coupled to which a first control signal which can be generated by the control means for switching on or off the first semiconductor switching element (T1) can be applied, a decoupling means (EM) is provided which is connected between the first control terminal (GT1) of the first semiconductor switching element (T1) and the fourth load terminal (ST2) is connected and a decoupling of the second semiconductor switching element (T2) of the first Halbleiterschaltelem ent (T1) causes when the first semiconductor switching element is or is brought into a blocking state by the first control signal. Switching device according to claim 1, characterized in that in that on the second control connection (GT2) of the second semiconductor switching element (T2) in a normal operation the switching device is applied a second control signal, which is the second semiconductor switching element (T2) conductively switches. Switching device according to claim 1 or 2, characterized characterized in that the decoupling means (EM) by a semiconductor switching element or switching network is formed, which is adapted to the first Control terminal (GT1) of the first semiconductor switching element (T1) with to connect to the fourth load terminal (ST2) if an error occurs is present and an electrical connection between the first control terminal (GT1) of the first semiconductor switching element (T1) and the fourth load terminal (ST2), if the switching device operated regularly becomes. Switching device according to one of the preceding claims, characterized characterized in that the decoupling means (EM) by at least a diode (D) is formed. Switching device according to claim 4, characterized in that in that an anode connection of the at least one diode (D) to the first Control terminal (GT1) of the first semiconductor switching element (T1) coupled and a cathode terminal of the at least one diode (D) with the fourth load terminal (ST2) is coupled. Switching device according to one of claims 3 to 5, characterized in that the decoupling means (EM) a Has blocking voltage, the greater or equal to the reverse voltage of the second semiconductor switching element (T2) is. Switching device according to one of the preceding claims, characterized in that the control means is designed as a driver circuit is connected to the first control terminal (GT1) of the first semiconductor switching element (T1) over a resistor (R) is connected, with which the edge steepness the voltage level of the control signal is adjustable. Switching device according to one of the preceding claims, thereby marked that with the second control connection (GT2) the second semiconductor switching element (T2), a further control means (SM2) is coupled, which - The second semiconductor switching element (T2) in a normal operation the switching device (K) switches substantially permanently conductive, - the second Switching semiconductor switching element (T2) in an error case, - the second Semiconductor switching element (T2) at a switch-on of the switching device (K) with a predetermined delay from a blocking to a conducting state. Switching device according to one of the preceding claims, characterized characterized in that the first semiconductor switching element (T1) as self-conducting field effect transistor, in particular as a junction field effect transistor (Junction Field Effect Transistor JFET) is formed. Switching device according to one of the preceding claims, characterized in that the first semiconductor switching element (T1) is made of the semiconductor material silicon carbide (SiC) consists. Switching device according to one of the preceding claims, characterized characterized in that the second semiconductor switching element (T2) as self-blocking MOS field effect transistor (Metal Oxide Semiconductor Field Effect Transistor) is formed. Switching device according to one of the preceding claims, characterized in that the second semiconductor switching element (T2) is made of the semiconductor material consists of silicon.