DE19954538A1 - Voltage supply circuit for switching transistor operated in high-side circuit has charging capacitor that supplies driver circuit operable at first potential or at least second higher potential - Google Patents

Abstract

The circuit has a drive circuit via which supply voltages at different potentials can be provided connected to the switching transistor gate connection. A charging capacitor that supplies the driver circuit with voltage can be operated with clock phases dependent on a clock generator at a first potential or at least a second higher potential. The potential is supplied by a circuit that pumps the first potential up to the second potential.

Description

The invention relates to a circuit arrangement for Power supply to be in a high-side circuit driven switching transistor, the gate terminal of the switching transistor with a driver circuit is connected via on different pots tial lying supply voltages available are.

State of the art

Circuit arrangements of the generic type are for example to control inductive loads in Motor vehicles used. Such control scarf tations are, for example, in engine control units of motor vehicles for controlling injection valves used in internal combustion engines. The The driver circuit is a charging capacitor ordered which of an internal control unit voltage, which is a first low voltage level forms, to a second higher voltage level can be raised. Corresponding to that on the charging capacitor applied voltage level becomes the driver circuit  supplied with a correspondingly high voltage, the then the gate of the switching transistor, for example, a power MOSFET. Around these different voltage potentials of the charging To reach the capacitor is known to use this to control a separate charging path. The integration of such a charging path in the circuit arrangement is only possible with great effort. Furthermore, the Charging capacitor hereby to control unit ground.

Advantages of the invention

Through the circuit arrangement according to the invention advantageously achieved that the control of the drawer capacitor to different voltage potentials is possible with little expenditure on components. There through that of the driver circuit with voltage supplying charging capacitor with one by one clock generator-dependent clock phase with a first span potential or a second voltage potential is operable, can be operated independently of the switch the switching transistor was constantly one of either first voltage potential or the second voltage Provide potential corresponding voltage. Ins a particular circuit arrangement becomes possible where the charging capacitor is decoupled from a ground pelt is so that the different voltage potentials on the charging capacitor in a simple manner are achievable.

In a preferred embodiment of the invention seen that the voltage supply circuit of the  Charging capacitor simultaneously for several in parallel switched charging capacitors is used. Hereby can be with a voltage supply circuit simultaneous control of several driver scarves lines of several switching transistors in simple Realize wisely.

Furthermore, in a preferred embodiment, that the voltage supply circuit of the charging connector an additional charging circuit is assigned to the generator, by means of the power supply if necessary the driver circuit to a third, higher span potential can be brought. Thus, the Control variations of the switching transistor, in particular for switching inductive loads, in simple Way further increase without additional elaborate Circuits with a variety of components not are agile.

In particular, is present in all circuit arrangements partial that the power supply to the charging connector sators can also be maintained in times can in which the inductive load to be switched is not is switched off. This was according to the from the stand known circuit arrangement in which the additional charging path for the charging capacitor is necessary dig was necessary, otherwise the risk of Flow of cross currents existed.

Further preferred configurations of the invention result from the rest, in the subclaims mentioned features.  

drawings

The invention is described in the following play closer with the accompanying drawings purifies. Show it:

Fig. 1 shows a circuit arrangement for the voltage supply of a switching transistor in a first embodiment and

Fig. 2 shows a circuit arrangement for the voltage supply of a switching transistor in a second embodiment.

Description of the embodiments

Fig. 1 shows an overall designated 10 circuit arrangement for voltage supply of a switching transistor 12 by means of which an inductive load 14 with a supply voltage, in the motor vehicle typically the vehicle battery U _Batt, is connectable. The supply voltage U _Batt is present at a connection 16 . A drain of the Schalttransi stors 12 is connected to the terminal 16 and a SourceAn circuit of the switching transistor 12 to the inductive load 14 . The switching transistor 12 is operated here in a high-side circuit. A diode 18 is connected between the source connection of the switching transistor 12 and the inductive load 14 . The diode 18 serves as a blocking diode and prevents a current from flowing back when the inductive load 14 is switched off .

The gate terminal of the switching transistor 12 is connected to a driver circuit 20 , at the switching inputs 22 and 24, a supply voltage provided by a charging capacitor C _Boot can be applied. To provide this supply voltage, the charging capacitor C _{Boot is} connected to a voltage supply circuit 26 : After the structure of this voltage supply circuit 26 is discussed in more detail below.

A clock generator 28 is connected to an output stage 30 consisting of transistors T1 and T2 and an output stage 32 consisting of transistors T4 and T5. A switching output 34 of the output stage 30 is connected to an output stage 36 consisting of the transistors T3 and T4. A switching output 38 of the final stage 36 is connected via a capacitor C1 to a node K1, which is connected on the one hand via a diode D1 to a terminal 40 to which an internal supply voltage V _{CC of} the voltage supply circuit 26 is present. The terminal 40 is also connected to the transistor T3 of the switching stage 36 . The node K1 is also connected via a diode D2 to a terminal 42 to which a higher voltage U _CP is present than the supply voltage V _CC - in a manner still to be explained. The terminal 42 is connected to ground via a capacitor C2.

The terminal 42 is also connected to the transistor T5 of the switching stage 32 and the transistor T1 of the switching stage 30 . In addition, the terminal 42 is connected via a diode D3 to the terminal 40 to which the supply voltage VCC is applied. The diode D3 is switched in the reverse direction for the voltage Ucp. A switching output 35 of the output stage 32 is connected via a capacitor C11 and a diode D11 to the charging capacitor C _Boot and the input 22 of the driver stage 20 . The switching output 34 of the final stage 30 is also connected via a capacitor C12 and a diode D13 to the other terminal of the charging capacitor C _Boot and the input terminal 24 of the driver stage 20 . The switching outputs 35 and 34 of the output stages 32 and 30 are connected via a diode D12.

The circuit arrangement 10 shown in FIG. V has the following function:

Via the clock generator 20 , the output stage 30 is driven in a clocked manner. Here, a signal changes between the low level and the high level with an adjustable frequency. In accordance with the current Pe gel status of the clock generator 28 , the output stage 30 is controlled. When the level is high, a signal proportional to the level is present at the switching output 34 of the output stage 30 , by means of which the output stage 36 is controlled. When the transistors T3 and T4 are switched on, the capacitor C2 is charged with the supply voltage V _CC minus the voltage drop UD1 via the Dicde D1. In the second clock phase (level state low), a signal proportional to this level state is present at switching output 34 . The transistors T3 and T4 are tuned to this signal so that only the transistor T3 then controls. When the transistor T3 is switched on, the capacitor C1 is raised to the supply voltage VCC since T4 blocks. The capacitor C1 is constantly discharged onto the capacitor C2 via the diode D2. Due to the constantly repeating clocked activation of the output stage 36 , the capacitor C2 is raised (pumped) to the voltage UCp, which results from the relationship: U _CP = 2 × V _CC - U _D1 - U _D2 , where U _{D1 is} the voltage drop via the diode D1 and U _{D2 is} the voltage drop across the diode D2.

The pumped-up voltage U _{CP present} at the terminal 42 is present at the transistors T5 and T1 at the same time. Due to the diode D3 switched in the reverse direction, the voltage U _CP applied to the terminal 42 can take over the supply voltage of the output stages 30 and 32 compared to the supply voltage V _CC (low voltage) applied to the terminal 40 . Both the transistor T1 and the transistor T2 of the output stage 30 and the transistor T5 and the transistor T6 of the output stage 32 are driven in phase opposition via the clock generator 28 , that is to say either the transistor T1 or the transistor T2 or the transistor T5 or the transistor T6 are controlled by.

In the first clock phase, transistors T1 and T6 are conductive. The capacitors C12 and C11 charge via diode D12 to U _CP - U _D12 (half each). In the second clock phase, transistors T2 and T5 are conductive. The charge from the capacitor C11 then leads at the node K2 to a voltage potential of U _CP + (U _CP - U _D12 ) / 2. The charge from capacitor C12 leads to a voltage potential of - (U _CP - U _D12 ) / 2 at node K3. Thus, a voltage difference of 2 × U _CP - U _D12 arises between the nodes K2 and K3. This voltage is present across the diodes D11 and D13 at the capacitor C _Boot and charges it.

Through permanent repetition of this changing control of the transistors T2 and T5 or T1 and T6 of the output stages 30 and 32 , the charging voltage of the capacitor Cgoot is pumped, resulting in a maximum voltage difference of 2 × U _CP - U _D12 - U _D11 - U _D13 . The charging capacitor Cgoot is simultaneously decoupled from the ground of the voltage supply circuit 26 via the capacitors C11 and 012 and can thus be raised to any voltage potential:

The driver circuit 20 is supplied via the instantaneous voltage level of the charging capacitor CBoot, namely that part of the driver circuit 20 which jumps to the switching transistor 12 . A basic voltage supply in relation to the control unit ground of the driver circuit 20 is provided via a connection 44 , to which, depending on the switching state of the voltage supply circuit 26, the voltage V _CC or U _CP is applied.

FIG. 2 shows the circuit arrangement 10 in an expanded version, the same parts as in FIG. 1 being provided with the same reference symbols and not being explained again. In this respect, only the existing differences are dealt with.

In addition, a further voltage increase circuit 50 is provided, by means of which a further higher voltage potential U _{CP1 can be} achieved from the already pumped-up voltage U _CP . For this purpose it is easily seen that the connection 42 , to which the voltage U _CP is present, is connected via a diode D4 and a capacitor C3 to the switching output 35 of the output stage 32 . Furthermore, the diode D4 is connected to ground via a diode D5 via a capacitor C4 and, on the other hand, to a terminal 52 to which the increased pump voltage U _CP1 is present.

The additional circuit 50 ensures that the voltage U _CP charges the capacitor C3 via the diode D4. According to the clock phases of the control clocks, the voltage U _CP charges the capacitor C3 to a voltage difference U _CP -U _D4 , U _{D4 being} the voltage drop across the diode D4. The capacitor C3 is discharged via the diode D5 onto the capacitor C4. By a repeated charging and discharging of the capacitor C3, which results in accordance with the clock phases, the capacitor C4 can be raised to the pumped voltage U _CP1 . This corresponds to 2 × U _CP - U _D4 - U _D5 , where U _{D5 is} the voltage drop across the diode D5.

Furthermore, it is indicated in the circuit arrangement 10 according to FIG. 2 that the circuit arrangement connected to the switching outputs 34 or 35 of the output stages 30 and 32 is composed of the capacitors C11 and C12 or diodes D12, D11 and D13 and the charging capacitor C _Boot same circuit components existing circuits can be connected in parallel. Thus, the simultaneous control of several charging capacitors C _Boot and thus driver stages 20 by a voltage supply circuit 26 is possible. In Fig. 2, only the condensers C21, C22 and C31, C32 are indicated.

Claims (8)

1.Circuit arrangement for the voltage supply of a switching transistor operated in a high-side circuit, the gate terminal of the switching transistor being connected to a driver circuit via which voltages at different potentials can be provided, characterized in that the driver circuit ( 20)-sufficient with voltage charging capacitor (C _boat) is operable with by a clock generator (28) dependent clock phases with a first voltage potential (V _CC) or at least a second higher than the first voltage potential (V _CC) voltage potential (U _CP). 2. Circuit arrangement according to claim 1, characterized in that the voltage potential (U _CP ) is provided by a voltage supply circuit ( 26 ) that pumps the voltage potential (V _CC ) to the voltage potential (U _CP ). 3. Circuit arrangement according to one of the preceding claims, characterized in that the clock generator ( 28 ) controls transistor output stages ( 30 , 32 ), a switching output ( 34 ) of the output stage ( 30 ) controls a transistor output stage ( 36 ) which with a Pump circuit (C1, D1, C2, D2) is connected, which pumps the voltage potential (V _CC ) to the voltage potential (U _CP ). 4. Circuit arrangement according to one of the preceding claims, characterized in that the voltage potential (U _CP ) takes over the supply voltage of the output stages ( 30 , 32 ). 5. Circuit arrangement according to one of the preceding claims, characterized in that the transistors (T1, T2) or (T5, T6) of the end stages ( 30 , 32 ) are driven in phase opposition by the clock generator ( 28 ), whereby the switch Outputs ( 34 , 35 ) of the output stages ( 30 , 32 ) via a pump circuit (C11, D11, C12, D13, D12) connected charging capacitor (C _Boot ) is pumped to a voltage above the voltage potential (U _CP ). 6. Circuit arrangement according to one of the preceding claims, characterized in that the voltage supply circuit ( 26 ) is associated with a further charging circuit ( 50 ) by means of which the voltage potential (U _CP ) can be pumped to a higher voltage potential (U _CP1 ). 7. Circuit arrangement according to one of the preceding claims, characterized in that the voltage supply circuit ( 26 ) for the voltage supply of at least two parallel-connected Schalttransisto ren ( 12 ) is designed. 8. Circuit arrangement according to one of the preceding Claims, characterized in that the charging scarf device comprises a pump circuit (C3, D4, C4, D5).