DE1488933A1 - Circuit arrangement for generating high-voltage output pulses - Google Patents

Description

PATENT Attorney DIPL.-ING. H. E. BOHMER

70S BOBLlNCBN 8 I N DBLFI N C BR 8TRAS SB 49

PBRN8PRBCHBR (07031) «613040 I H 0 0 S? V V

Boeblingen, 2}. August 1966
bu-ha

Applicant: International Business Machines

Corporation, Armonk, N.Y. 10

Official file number: New registration
Applicant's file number: Docket 6933

Circuit arrangement for generating high-voltage output

impulses

The invention relates to a circuit arrangement for generating high-voltage output pulses with the aid of an iron-core transformer applied input pulses.

For this purpose it has hitherto been necessary to use a high voltage source to use, which then has the disadvantage that a significant power consumption takes place during the pulse pauses.

The object of the invention is to provide a high voltage pulse -To create a generator of the above type in which no high voltage source is required and no power consumption takes place during the pulse pauses. In addition, the effort for this should be as low as possible.

According to the invention the object is achieved in that in each case Generating an output pulse means to the primary winding

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of the iron core transformer are connected, which make the soft magnetic smell Bias transformer core during a first time interval in a first direction and in one second time interval, which corresponds approximately to the duration of the output pulse, in the opposite magnetization state bring, and that on the secondary side a diode is connected in series with a resistor, the polarity of which is chosen so that the diode is blocked during the second time interval and during the first time interval and after the second time interval is biased until the magnetization of the magnetically soft transformer core in the forward direction, so that then the resistance acts essentially solely as a load on the transformer.

It is advantageous if two separate secondary windings are used, one of which is used to feed a consumer and the second, in the opposite direction of the winding to the first, for supplying the series circuit formed by the diode and resistor serves.

There are several ways to do this for each output pulse required alternating magnetization of the soft iron core to bring about, e.g. by supplying bipolar input pulses to a primary winding, or in the case of a winding with a center tap, but both winding parts are wound in opposite directions by supplying pulses the first polarity on one part of the winding and the other polarity on the other part of the winding.

According to an advantageous development of the invention, the ends of the primary winding are each controlled via a driver, one of which the pulse input of the first driver via a pulse delay circuit connected to the pulse input of the second driver to provide a pulse during the second time interval

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to which the input pulse is applied during the first time interval. The primary winding is the same on the whole are wound, then drive pulses of the same polarity are applied to the ends.

A driver circuit which is advantageous according to a further concept of the invention contains a transistor connected to the input of the driver circuit, the emitter of which is connected to the emitter of a second transistor, which is normally blocked and opposite to the first transistor complementary transistor is connected, the first transistor is normally conductive. The emitter connection is here connected to the base of a third normally blocked transistor, the collector of which is at one end of the primary winding lies in such a way that when a pulse is applied, the first transistor is blocked and the second and third transistor switched to the conductive state. This provides a powerful pulse that is able to control the transformer core, so that at the output of the transformer with a a high-voltage pulse is available in accordance with the winding ratio. The power consumption is during the pulse pauses negligibly small, with the modulation of the transformer core from its first magnetization state in its second magnetization state, i.e. a maximally possible induced as a result of running through the entire hysteresis loop Tension arises. The effort for this is relatively low and, moreover, maximum possible operational safety is thereby achieved ensures that no high voltage can occur during the pulse pauses.

Further advantages of the invention emerge from the following description, which is illustrated with the aid of exemplary embodiments on the basis of FIG The drawings listed below will be explained in more detail, and from the claims.

Show it :

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-4-Fig. 1: a circuit diagram of the arrangement according to the invention,

FIG. 2: a detailed circuit diagram of a driver used in the circuit arrangement according to FIG. 1,

Fig. 3: Pulse diagrams to explain the mode of operation the circuit arrangement according to the invention.

The embodiment of the arrangement according to the invention according to FIG. 1 contains a transformer 10 which has a primary winding 11 Center tap and the two secondary windings 12 and 13 has. The center tap of the primary winding 11 is at a fixed potential, in this embodiment to minus 12 volts. That one end of the primary winding 11 is at the output of the first driver 20, while the other end is connected to the output of the second driver 30. A circuit example for the drivers 20 and 30 is shown in Fig. 2 and will be discussed further below described in detail.

The drivers 20 and 30 serve to make the currents each opposite To transmit direction to the primary winding 11. Of course, at any given point in time, there is always one of the two Driver effective.

To use the transformer 10 voltage pulses of high amplitude To be able to generate, a relatively high magnetic flux is required in each case. Such a great change in flow occurs by first transmitting a drive current in one direction through the primary winding to the magnetic core in one direction Direction to pre-magnetize, with a limiter circuit being provided in order to prevent a resulting in the secondary winding Suppress voltage pulse. Then a driver current is in the opposite direction from before via the Transfer primary winding. This results in a large change in the flux, so that, since the limiter circuit is now also in blocking

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device is operated, a voltage pulse on the secondary winding, connected to the output occurs.

In this exemplary embodiment, the secondary winding 12 represents the output winding. One end of this output winding 12 is at a fixed potential, in this case at ground, while the other end of the output winding is connected to the load 60 is then supplied with voltage pulses of large amplitude will. The direction of winding of the secondary winding 13 is opposite that of winding 12, so that the voltages in both windings are shifted in phase from one another by 180. A limiter diode 14 is located parallel to the secondary winding 13 in series with a damping resistance 1 ^>. Flows in from the first Driver 20 transmitted current through primary winding 11, then the diode 14 is forward biased so that substantially all of the current in the secondary winding 13 represented energy in the damping resistance If? is destroyed. There is only a small negative voltage from the output winding, since the largest part is caused by the transformer transmitted energy is destroyed in the damping resistor I5. In this exemplary embodiment, the first driver 20 is used to to pre-magnetize the transformer core in a first direction, in in this case to a negative value. The driver 30 then takes effect, with the diode is now biased in the reverse direction, so that almost the entire Energy from the output winding 12 in the form of a high voltage pulse occurs with a substantially rectangular shape.

The first driver 20 is effective during a time interval, which is determined by the period of a monostable multivibrator 40. The monostable multivibrator 40 is by a the control signal TO applied to the input terminal 45 is excited. That Control signal TO is supplied from a suitable source such as a computer system if it should be necessary

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to generate a high voltage pulse, as it is for a printing process, Punching process or the like is required. The output of the monostable multivibrator 40 is also on Input of a second monostable multivibrator 50, the output of which with the. Input of the second driver 30 is connected. This ensures that with the decay of the output pulse from the first monostable multivibrator 40, the first Driver 20 is no longer activated, and thus becomes ineffective with respect to the primary winding 11, while the second monostable multivibrator 50 is controlled to thereby aen second Let driver 30 take effect.

The second driver 30 then remains for one through the period of the second monostable multivibrator 50 set time interval effective, in turn, a drive current through the primary winding 11 to transfer. At this point it should be noted that after switching off the second driver 30, i.e. after the initial pulse has decayed from the second monostable multivibrator 50 as a result of the magnetic flux direction then effective in the transformer 10 the diode 14 is biased in the forward direction so that no overshoot can occur in the output winding 12 and the im Transformer core stored energy in the damping resistor is destroyed.

The circuit construction of the drivers 20 and 30 is essential the same, so that it suffices to illustrate the circuit of a driver as in FIG. Here the output of the first is monostable Multivibrator 40 is connected to the input of an inverter 21 in driver 20.

The output of the inverter 21 is each connected to the base of a transistor 22 and the transistor 23 connected, the emitter of which is connected together are. Both transistors are complementary to each other. For example, transistor 22 is an NPN transistor whose Collector is at earth potential and which is normally expanding,

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where, however, the transistor 23 is a PNP transistor, the collector of which is at a fixed negative potential (-12 V) via a resistor 62. A third transistor 24 of the PNP conductivity type has its base connected to the emitter connection of the two first transistors 22 and 23 via a resistor 100. The third transistor 24 is normally not conductive. When the positive output pulse from the first monostable multivibrator 40 is used, the base of the transistor 22 becomes negative, so that the transistor 22 becomes non-conductive. In this way, however, the base voltage of both the transistor 23 and the transistor 24 becomes sufficiently negative so that both transistors then become conductive. When the transistor is conducting 24, flows a relatively high drive current through the connected to the collector of the transistor 24 primary winding At the falling of the output pulse of the monostable multivibrator 40, the transistor 22 is again brought into the conductive state, while the second and third transistors 23 and 24 go into the off state at the same time. The flow of current through the primary winding 11 is then prevented under the control of the third transistor 24.

In order to explain the operation of the circuit according to the invention, it should first be remembered that, in order to provide a high-voltage pulse at the consumer 60, the magnetization of the transformer core of the transformer 10 is first brought to a negative value when a control pulse TO (Fig. 3) is sent to the first monostable multivibrator 40 (Fig. 1) is supplied. When the first monostable multivibrator 40 becomes effective, the first driver 20 goes into the on-state, so that a current flows through the primary winding 11 and its center tap to the negative potential source (-12 V) for a duration that through the period of the first monostable multivibrator 40, ie from time TO to time T1 (FIG. 3), is fixed.

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In this condition, a current flows through the secondary winding 15 because the diode 14 is then biased in the forward direction. Most of the energy in the damping resistor 15 is destroyed, so that only a voltage pulse with a very low amplitude can occur on the output winding 12. If the output pulse of the first monostable multivibrator 40 falls, then the second monostable multivibrator 50 becomes effective, so that the second driver J> 0 is then switched on during the time interval T1 to T2 and a current through the corresponding part of the primary winding 11 via its center tap the negative potential source (- 12 V) flows. Since the current from the second driver 30 flows through the primary winding 11 in the opposite direction than the current from the first driver 20, the diode 14 is biased in a blocking manner, so that the current resulting from the induction effect is now taken over by the output winding 12 and turned on High voltage pulse is transmitted to the engine 60. After the output pulse from the second monostable multivibrator 50 has dropped, the second driver JtO is brought back into the off state, so that the flux in the transformer core collapses. During the breakdown of the magnetic flux, the diode 14 is again biased in the forward direction, so that the resulting energy in the damping resistor I5 is destroyed.

From the foregoing it can be seen that the circuit arrangement according to the invention provide high-voltage pulses in the Is able to without the need to use a high voltage supply device. Furthermore, it follows that the inventive Circuit arrangement is relatively simple and not expensive in structure. Furthermore, there is the advantage that during the period in which no high voltage pulse is to be generated, both drivers are switched off and therefore the Power consumption practically corresponds to the idle state. That

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means that when using the circuit arrangement according to the invention Safety and economy are largely guaranteed.

Although two separate drivers are used in the exemplary embodiment shown above, it is also entirely possible to use only one to use only driver arrangement, which must then emit bipolar pulses.

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Claims (3)

U8B933 PA TENT CLAIMS Circuit arrangement for generating high-voltage output pulses with the help of an iron core transformer supplied input pulses, characterized in that each for generating an output pulse means (20,30,40,50) to the primary winding (11) of the iron core transformer (10) are connected, the soft magnetic transformer core during a first time interval (TO to T1) in a first direction v <"" and magnetize in a second time interval (T1 to T2), yes corresponds approximately to the duration of the output pulse, bring into the opposite magnetization state and that on the secondary side a diode (14) in series with a resistor (15) is connected, the polarity of which is chosen so that the diode (14) during the second time interval (T1 to T2) locked and during the first time interval (TO to T1) and after the second time interval (T1 to T2) until the magnetization of the magnetically soft transformer core has decayed is biased in the forward direction, so that then the resistor (I5) essentially alone as a load for the Transformer (10) works. 2. Circuit arrangement according to claim 1, characterized in that a first secondary winding (12) for feeding a consumer (60) and a second secondary winding (13) with the opposite direction of winding compared to the first (12) for the supply the series circuit formed from diode (14) and resistor (I5) serves. 3. Circuit arrangement at least according to claim 1, characterized in that that the primary winding (11) has a center tap which is at a fixed potential (-12 V), and that the Ends of the primary winding (11) each via a driver (20,30) 909833/0268 U88933 are controlled, of which the pulse input of the first Driver ä (30) via a pulse delay circuit (50) for Provision of a pulse during the second time interval (T1 to T2) with the pulse input of the second driver (20) to which the input pulse is applied during the first time interval (TO to T1). Circuit arrangement at least according to claim 5, characterized in that the pulse input of the first driver (30) is connected via a first monostable multivibrator (50) to the pulse input of the second driver (20), which is connected to the pulse input of the second driver through the trailing edge of a (20) connected second monostable multivibrator (40) is triggered, on the other hand, the input pulse at the time (TO) is fed. Circuit arrangement according to Claims 1 to 4, characterized in that the driver (20 or 30) normally has a first conductive transistor (22) connected to its input, the emitter of which is connected to the emitter of a second, normally locked, opposite to the first complementary transistor (23) is connected and that the emitter connection with the Base of a third, normally blocked transistor (24) is connected, the collector of which is at one end of the primary winding (11) is such. That when a pulse is applied, the first transistor (22) is blocked and the second (23) and the third transistor (24) can be switched to the conductive state. 909833/0268 Blank page