DE2913576A1 - CONTROL CIRCUIT FOR INDUCTIVE CONSUMERS - Google Patents

Description

The invention relates to a control circuit for inductive loads or consumers and is used in particular for an electronic one Fuel injection system in which solenoid coils are used to control the high-speed valve work.

Most electronic fuel injection systems use solenoids to control the opening and closing of injection valves. The solenoid coils must have a sufficiently fast response time have in order to react to a switch-on or switch-off signal and thus a precise clock sequence and precise metering of the fuel injection to offer.

A control circuit is assigned to the solenoid coils in order to actuate them and control release depending on switch-on and switch-off signals. To achieve high-speed operation, the Control circuit excite the solenoid winding quickly for actuation and switch it off very quickly for release.

An earlier technique used to facilitate quick excitation of a inductive load consists in using an ignition or starting coil together with the inductive load. The ignition coil will initially excited before the load coil is switched on, and when this is switched on, the current in the ignition coil is passed to the Load coil released to accelerate its excitation. This is illustrated in more detail in U.S. Patent 3,211,963. This patent shows one Circuit for the alternating excitation of two load coils, which are formed by a single coil with a center tap. One The ignition coil is connected in series with the voltage source and the center tap of the coils. A first switching transistor is in series

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he between one terminal of the first load coil and the other Terminal of the voltage source connected, and a second transistor is in series between the terminal of the second load coil and the connected to the other terminal of the voltage source. When a switching transistor is activated, the first load coil is excited and the ignition coil carries the load current. When the first transistor turned off and If the second is activated, the energy stored in the ignition coil results in an increased voltage at the center tap, in order to achieve a fast one Bring about excitation of the second load coil. A Zener diode at the center tap is used to limit the transient voltage surges a suitable value.

Although the cited patent discloses the overall concept of using an ignition or starting coil with the load coil, it is limited in one important aspect. It requires the ignition coil to be excited on a current path that is common to one or the other load coil, ie the ignition coil cannot be excited independently of the load coils. For an electronic fuel injection with a number of parallel-connected magnet coils to open individually or closing a valve on a number of cylinders can be driven _r is this feature an inappropriate restriction.

The object of the invention is thus to provide a high-speed control circuit for inductive loads or consumers such as a solenoid to create a fast actuation and release of the inductive Consumer offers without dependence on the previous excitation of another inductive load. Invention device is a fast-working control circuit with solenoid coils is provided

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hen suitable for an electronic fuel injection system, and which can be manufactured economically thanks to the integrated switching technology is.

The control circuit according to the invention is used to control at least an inductive load by controlling the excitation of its load coil. It includes an ignition coil, one terminal of which is coupled to a supply terminal and the other connection to a circuit part, which the load coil winding and a first operating as a function of a control signal Switching device includes. According to the invention, the other connection of the ignition or storage coil is also dependent on a second one coupled by a pre-excitation or preparation signal operating switching device. The excitation of the load coil winding takes place through their interconnection with the ignition coil depending on the excitation signal and independent of the switching status of another inductive consumer.

Advantageously, the first and the second switching device a voltage limiter can be assigned, as well as current limiting resistors of the storage or ignition coil and the load coil can be switched on.

In an exemplary embodiment of the invention, a first diode is connected between the ignition coil and the circuit part, which comprises the load coil and the first switching device, and a second diode is between the supply terminal and the circuit part placed.

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In cases where the control circuit has more than one inductive Consumer controls, further circuit parts each with a load coil and the associated switching device can be parallel to the first circuit part are switched.

The invention is explained in more detail below. All in the description Features and measures contained therein can be essential to the invention. The drawings show:

1 shows a circuit diagram of a control circuit according to the invention for inductive loads.

Fig. 2 is a circuit diagram compared to the embodiment 1 modified control circuit for inductive loads.

3 shows a graph for the clock sequences of the various signals for operating the inductive load control circuit of FIG. 1.

Fig. 1 is a circuit diagram of a control circuit according to the invention 10 for inductive consumers. The control circuit 10 can be divided into two main stages: an amplifier stage as well a powershift stage. The control circuit 10 includes a load switching stage for each inductive load to be controlled. A description follows of the two main stages.

The amplifier stage comprises a starting or storage coil 12. A supply voltage V _{0 is applied} to one terminal of the starting coil 12, which supply voltage can be, for example, an unregulated battery voltage. A resistor 14 is connected in series with the storage coil 12. The resistor 14 can have both the value of the internal resistance

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Ignition coil 12 as well as its own current limiting resistor, on the other hand, it can control the internal resistance of the coil and the saturation resistor stand and represent a transistor 16 described below. In this case no own resistance is necessary, and costs are saved. The ohmic value of the resistor 14 is R. The series connection of ignition coil 12 and Resistor 14 flowing current is denoted by I and is im

called the following pilot current.

The amplifier stage also comprises an amplifier switch in the form of a two-pole junction transistor 16. A collector 18 of the bipolar junction transistor or BJT16 is on one terminal of the resistor 14, an emitter 20 led to ground, and at a base 22 is a pre-excitation or pre-control signal E via a

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Base resistor 24 on. The amplifier switch 16 can also performed by other controllable semiconductor power control switches e.g. a gated silicon rectifier, a VMOS power transistor, a Darlington power switch etc.

A Zener diode 26 is connected in parallel to the BJT16 in order to offer an upper limit to the voltage difference between the collector 18 and the emitter 20 and thus to protect the BJT 16 from voltages. The cathode of the Zener diode 26 is led to the collector 18 and its anode to the emitter 20. The Zener breakdown voltage of the Zener diode 26 is _denoted by V 17n.

Each load shift stage controls the activation and deactivation of its assigned inductive consumer. In the present case is one

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Terminal of an inductive consumer or an inductive load 30, which can be a magnetic coil, for example, to the common node of the collector of the BJT 16 and the cathode of the Zener diode 26 led. The other terminal of the inductive load 30 is, as will be explained in more detail below, connected to the load switching stage .

The load switching stage comprises a resistor 32, one terminal of which is coupled to the inductive load 30. The resistor 32 can be both represent the internal resistance of the inductive load as well as a separate current limiting resistor, which is connected to the consumer in Is connected in series, on the other hand it can reduce the internal resistance of the Load 30 and the saturation resistance of one described below Represent transistor 34. The ohmic value of the resistor 32 is R .. The series connection of inductive Current flowing through loads 30 and resistor 32 is denoted by I. and in the following as excitation or control current.

The load switching stage also includes a voltage controlled switch in the form of another two-pole junction transistor (BJT) 34. A collector 36 of BJT 34 is connected to a terminal of resistor 32, an emitter 38 is connected to ground, and a base 40 is connected through a base resistor 42 an excitation or control signal E ₁ . The BJT 34 can also be replaced by a number of equivalent devices.

f-Jine Zener diode 44 is connected in parallel to the BJT 34 to reduce the voltage difference between the collector 36 and the emitter 38 to beqrr-nzfm and thus to protect the BJT against tension. The Ka-

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method of the Zener diode 44 is with the collector 36 and its anode with connected to the emitter 38. The breakdown voltage of the zener diode is

A further load switching stage 60 is used for each additional inductive consumer 62 that can be switched on. Each such stage 60 generates a correctly keyed excitation or control signal E _n , which controls the flow of an excitation current I _n in the inductive load 62.

At a node 48, the BJT 16, the Zener diode 26 and the inductive load 30 are brought together together. The one at the junction 48 applied voltage is denoted by E. The effective stray capacitance between node 48 and ground is given by a capacitor 50 is shown.

Resistor 32, BJT 34 and Zener diode 44 are brought together at a node 52. The voltage present at node 52 is denoted _{E n.} The effective stray capacitance between node 52 and ground is represented by a capacitor 54.

The following is a description of the operation of the control circuit for inductive loads.

The pre-excitation of the amplifier or starting coil 12 takes place as a function of a pre-control signal E, which is shown as the first signal in the clock control signal image in FIG. The pre-control signal Ep is _{high in the period T -1} -T "and all

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low level at other times. In the time before T., when E If the level is low, the transistor 16 blocks.

An excitation _{signal E 1} controls the switching state of the transistor 34. The excitation or control signal E ₁ is the second signal in the graph in FIG. 3. The control signal E _{1 is located} between the times T and T-. high level and low level at all other times. Thus, both transistors 16 and 34 block in the time before T _-1 , and the precontrol _{current I p} and the control current I ₁ are zero. The voltage E ,. at node 48 is equal to the supply voltage V ".

During the period between T _-1 and T _{n , when the precontrol signal} E is high, BJT 16 is saturated and the precontrol current I flows through the storage or amplifier coil 12. The voltage E from node 48 drops to the saturation voltage V gAT of BJT 16 from. During this period, the pre-control current I increases to a maximum value of Ip (WIa _x ), for which the following equation applies:

¹ P (MAX) ^{= (V} S " ^V SAT ^{) / R} P *

The transistor 34 blocks during this period, and the control current I ₁ in the inductive consumer also remains at zero.

At the time T of the inductive load 30 is switched on, the pilot control signal E_ is low and the control signal E _{1 is} high. As a result, the transistor 16 blocks and the transistor 34 is saturated. _{The pilot current I p} directed to the transistor 16

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now flows via the stray capacitance 50 assigned to the node 48. This deflection of the current flow results in a very rapid voltage increase at the node 48 until it reaches the breakdown voltage V "p of the Zener diode 26. This relatively high voltage V "p is located on the inductive load 30 with a corresponding rapid increase of the control current I ₁ in the load coil. To the control current I ₁ equal to the pre-control current I is _p, the excess pre-control current I flows to the Zener diode 26 and _p holds the relatively high voltage drop V ₁₇ -. upright on the inductive load 30. At the point at which the control current I ₁ is equal to the pre-control current I_, the voltage at node 48 below the Zenerabbruchspannung V_ from _p. This voltage drop makes the control current I ₁ equal to the _{precontrol current I p} via a subsequent exponential decrease to a stable cuatand or holding value of s

¹ STOP = ^(V S - W < ^R P

where, in this case, V _{gAT is} the saturation voltage of transistor 34.

The graph of FIG. 3 graphically shows the changes in the signal values explained above. The voltage I ₂ . at node 48 rises very quickly from time T to the value of the Zener breakdown voltage V _p . The voltage E remains at a relatively high value until the precontrol _{current I p} and the control current I _{1 become} equal, whereupon it drops exponentially to a stable state value. _{The control current I p} flowing in the storage or starting coil 12 experiences a drop at the time T _Q up to the time

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_ 13 -

point at which it becomes equal to the control current I ₁ , whereupon it experiences an exponential decrease which is identical to the control current. The control current I ₁ rises very quickly at time T_ until it _{becomes equal to the pre-control current I p} , whereupon it undergoes an exponential decrease in the same way until it reaches a holding current value I _TT , _Tm . The target value of the holding current I ", _Tr71 is sufficient

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high to the actuation of an inductive load, for example a solenoid to maintain.

At the time T ₁ for the disconnection or release of the inductive load 30, the control signal I ₁ becomes low. Depending on the polarity reversal of the signal value of I _1, the transistor 34 blocks. The control current I ₁ flowing through the storage coil 12 and the inductive load 30 is now conducted to the stray capacitors 50 and 54 at the nodes 58 and 52. This current flow causes the voltage E_ to rise rapidly. at node 52 to the breakdown _{voltage V 21 of} the Zener diode 44. This very high voltage V ₁ - V , which is applied to the series circuit with the inductive load 30 and the storage coil 12, causes a very rapid drop in the control current I ₁ with a correspondingly rapid shutdown or release of the inductive consumer. In practice, the breakdown _{voltage V 171 of} the Zener diode 44 should be equal to or greater than the breakdown _{voltage V 1711 of} the Zener diode 26 for multiple

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Systems with inductive loads to leakage current in the other avoid inductive loads.

These changes in the signal value are shown in the graph of the figure. At the switch-off time T, the control current E ₁ becomes low. The blocking transistor 34 causes the voltage E_, at the node

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Point 52 rises very quickly until it reaches the breakdown voltage V- of the Zener diode 44. The voltage E_ then drops exponentially to the stable value of the supply voltage V ₀ . The pre-control current Ip and the control current I ₁ , which are synonymous at this point in time, drop very quickly at _{the point in time T 1.} The voltage Ε _Ά at the node 48 rises _{very quickly at the time T 1} when the capacitor 50 begins to charge and then drops exponentially to the stable value of the supply voltage V.

An essential feature of the invention of the control circuit 10 for inductive Loads (Fig. 1) is that the Zener diodes 26 and 44 of the transistor 16 of the amplifier stage and the transistor 34 of the load switching stage are connected between the collectors and emitters. In the case of mass production, the zener diodes can be based on the same Integrated circuit leaflets are produced like transistors 16 and 34, which minimizes the number of parts fitted the control circuit results. In addition, the transistors of both the amplifier stage and the load switching stage can be operated with practically the same peak current and voltage and therefore the transistors and the Zener diodes assigned to them must be of the same type. It is also essential to the invention that the required ohmic Fourth Rp and R. the current limiting resistors by corresponding Choice of wire size and length for the starter and load coil can be achieved, so in both cases no resistance of its own is required. This results in a further reduction in the parts list.

The control circuit for inductive loads 10 ¹ (Fig. 2) is a

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Modification of the basic circuit 10 in FIG. 1. The reference symbols in FIG. 1 also apply to the switching components in FIG. 2.

The changes to the control circuit 10 ′ relate to the connection of two diodes 58 and 59, which cause the consumer or load coil 30 to be switched off or released even more quickly. One diode 59 is connected between the common node of switch 16, Zener diode 26 and resistor 14 and inductive consumer 30 and is directed so that the anode is connected to switch 16 and the cathode is connected to the inductive consumer / to the current from the amplifier coil 12 to the inductive let 30 su couple. The other diode 58 is between the supply voltage source V _e and the common node

the diode Sf is connected to the inductive load 30 and possibly other inductive loads 62. The second diode 58 of the positive supply voltage V _e is directed so that its anode

is on the supply voltage V ^ to the holding current

ect from the supply voltage V _e instead of via the amplifier coil 12.

When the control signal E ₁ becomes low and the load switching transistor 34 blocks, the Zener abort voltage V _{171 is present} at the node 52. In the control circuit 10 of FIG. 1, this voltage was applied to the series circuit of the inductive load 30 and the starting coil 12. In this case, the voltage applied to the inductive load 30 was only a part of the Zener termination voltage v _z1 .

By connecting the diode 59 in the aforementioned way flows

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the largest part or the entire holding current I _TT _ _{Tm of} the inductive load 30 as a function of the relative time difference T. - T and the time constants of the amplifier coil 12 and the inductive load 30 via the diode 58 and not via the storage or starting coil 12 as In the case of the control circuit, the Zener termination voltage V ₇₁ is thus applied to the inductive load 30 and to the diode 58. Thus, there is only a loss of approximately 1 volt in the amplitude of the step voltage applied to the storage coil 12.

The pre-control voltage and the drive voltage levels and speeds are essentially the same in the control circuit 10 'as those of the basic control circuit 10. The holding current I _ der

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However, inductive load is now assigned to that of the storage coil 12 Resistor 14 independent, since the entire holding current runs through the forward biased diode 58. The holding current the control circuit 10 * is given by the following equation:

¹ HALT ^{= (V} S " ^V SAT" ^V d ^{) / R} 1 'where V, the voltage drop across diode 58 of approximately 1V.

The improvement in the shutdown or release speed will achieved with the help of two 6xtra diodes.

Another advantage of the control circuit 10 of FIG. 2 is that a higher ohmic value R _{1 of} the resistor 32 for a specific inductive load with a given inductance

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activity and a prescribed holding current includes that the Coil of the inductive load 30 could be wound in a smaller space than in the basic control circuit 10 of FIG. 1. This is a very beneficial feature for solenoid valves mounted on motors. Another advantage of the modified circuit 10 " 2 is that the holding current is not passed through the starting coil 12, and thus the power loss of this coil decreased.

Even if a lower holding current is desired and through use is achieved by only one internal resistance of the inductive load, the additional resistance can be in series with the Diode 58 can be switched. The use of such a resistor would reduce the control current level or the rate of rise of the Do not affect control circuit 10 '.

In addition to the exemplary embodiments described above, there are still others are possible without departing from the scope of the invention.

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Claims (8)

M J Control circuit for controlling the switching on and off of at least an inductive consumer by controlling the excitation of its load coil, in which a connection of a storage or Amplifier coil to one power supply terminal and the other Connection to a circuit part with the load coil and a first switching device is performed, which as a function operates from a control signal, characterized in that the other connection of the storage coil (12) is also connected to a second switching device (116), which depends on a Pilot signal (E) works. 2. Control circuit according to claim 1, characterized in that the second switching device comprises a transistor (16) on whose base, collector and emitter feed the pilot control signal (E) 909845/0699 ORIGINAL INSPECTED and which are led to the storage coil (12) and to ground. 3. Control circuit according to claim 1, characterized in that a voltage limiting device (25) of the second switching device (16) is assigned. 4. Control circuit according to claim 1, characterized in that a voltage limiting resistor (14) in series with the storage coil (12) is switched. 5. Control circuit according to claim 1, characterized in that a current limiting resistor (32) in series with the load coil (30) is switched. 6. Control circuit according to claim 1, characterized in that a voltage limiting device (54) is assigned to the first switching device (34). 7. Control circuit according to one of the preceding claims, characterized characterized in that a first diode (59) between the storage coil (12) and the circuit part with the load coil (30) and the first switching device (34) is connected and in that a second diode (58) between the supply voltage terminal (Vg) and the circuit part (30-34) is placed. 8. Control circuit according to one of the preceding claims, characterized characterized in that further circuit parts each with a load coil and the associated switching devices in parallel with the 909845/0699 first circuit part (30-34) are connected. 909845/0699