DE2347935A1 - METHOD OF IGNITING AND KEEPING A CONTROLLABLE RECTIFIER AND IGNITION SIGNAL GENERATOR FOR CARRYING OUT THIS PROCEDURE - Google Patents

Description

Method for igniting and keeping a controllable rectifier conductive and an ignition signal generator for performing this method

The invention relates to a method for igniting and keeping a controllable rectifier conductive and an ignition signal generator to carry out the procedure.

In known controllable rectifiers, such as controllable silicon rectifiers, difficulties arise with inductive rectifiers Load on. With inductive loading of the rectifier circuit, the current usually rises slowly, and if so if it does not rise fast enough, the controllable rectifier can, if it does. is ignited by means of a short pulse, clear before the current has increased to the required value. Another method of ignition is to use a Ignition pulse sequence. This has the advantage that it takes the inductive load into account. In many cases, however, arise Difficulties, since a controllable rectifier must be fully conductive even at high loads in order to have a "soft" or to avoid incomplete ignition in the entire semiconductor material of the controllable rectifier. This is ^ in certain areas of application of the controllable rectifier particularly pronounced, e.g. B. for inverters or choppers for control from Z. B. asynchronous motors. Controllable rectifiers, e.g. B. in the inverter itself, but also in the chopper

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An example of such used is described in DT-PS 1 631 and DT-AS 1 631 776 of the applicant ". In these In some cases, this controllable rectifier can sometimes be ignited and extinguished under a different condition, namely the The prerequisite is that the controllable rectifier immediately causes a large current to flow when it is ignited A chopper or inverter is difficult, as mentioned above, especially with inductive loading can either by firing pulses with a fixed repetition frequency, but with a variable duty cycle, or a variable frequency can be controlled with a fixed duty cycle. In the latter case, the frequency can be relatively low, leading to even greater ones Difficulties can result than having a fixed frequency.

It is known to keep a controllable rectifier conductive by providing a circuit which is connected via the main connections of the controllable rectifier conducts a holding current. However, this leads to a loss of performance, which is the case with the above Arrangements can be quite significant, as you run the risk of this due to the fluctuating output voltage Having to maintain current at minimum voltage. Through this one obtains a loss of performance that can reach the same size can be like the power delivered at the output.

The invention is based on the object of specifying a method for igniting a controllable rectifier in which it is ensured that no "soft" ignition takes place and that the rectifier still remains conductive.

According to the invention this object is achieved in that the Control connection, the controllable rectifier is supplied with a pulse with a relatively high amplitude and edge steepness, and that the same control terminal has a second signal, however. with a lower amplitude, and that this Signal is maintained at least until a predetermined one through the main line of the controllable rectifier Electricity flows.

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This ensures that "the first impulse is a complete one Ignition causes and the "soft" ignition of the controllable rectifier avoids, while the second signal the controllable rectifier is conductive, at least as long as the required holding current is not in the main line flows. This also results in a lower power output and the avoidance of a loss of power.

It is preferably ensured that the second signal is fed in after the high pulse while the controllable rectifier is conducting, and preferably has a constant amplitude. This ensures that the second signal does not arrive before the pulse and that no misfire occurs. In contrast to before, the signal can have a constant amplitude, e.g. B _{0 be} a constant signal ,, At the same time, the delay ensures that the second signal cannot deform the previous pulse.

It is also advantageous if, as the second signal, a sequence of pulses with a preferably constant amplitude in one Period of time corresponding to the desired conduction time of the controllable rectifier, and then the controllable rectifier is deleted. This ensures that the pulses in the controllable rectifier convert as little energy as possible and at the same time this takes place in the whole time in which the controllable rectifier should be controlled, and it is still ensured that the rectifier in any Point in time within this period and is fully in charge.

Another advantage results from the fact that the second signal is fed to the control terminal before the amplitude of the pulse has dropped to the amplitude of the second signal. This ensures that at no later time -point a "soft" ignition takes place after the controllable rectifier has been made fully conductive, while at the same time as little power as possible in the controllable rectifier

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and the power consumption is kept low,

An ignition signal generator can be used to carry out the method. provided with a control signal generator and a pulse generator be, in which the invention ensures that at the output of the control signal generator both the pulse generator as also a signal generator is connected and that both the output of the pulse generator and the output of the signal generator is connected to a summing element, the output of which is connected to the control terminal of the controllable rectifier.

To achieve the desired time delay, between the signal generator and the control signal generator a delay element lie. This achieves the desired time delay, which ensures that a "soft" Avoids ignition. The signal generator can be an oscillator, and it is particularly advantageous if it is used as a blocking oscillator is trained. The blocking oscillator can emit a pulse train that is extremely easy to switch on and off. The pulse generator can have a rechargeable capacitor that can be discharged via a pulse transformer and other means, these means being controllable by the control signal generator. This gives a pulse of the desired length. It is also advantageous if a secondary winding of the pulse transformer and a secondary winding of the output transformer of the oscillator are connected in parallel. This ensures that a galvanic in the summing element Separation can take place, which enables the ignition of controllable rectifiers, which can have different potentials than those which are brought for the control signal generator.

The invention is described in more detail below with reference to the exemplary embodiments shown in the drawing. It demonstrate:

1 shows a block diagram of a pulse-controlled chopper

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with inductive load, 23 47 935

Fig. 2 is a detailed circuit diagram of the chopper, Fig. 3 is a block diagram of the ignition signal generator, FIG. 4 shows the time profile of an ignition signal and FIG. 5 shows a detailed circuit diagram of the ignition signal generator.

Fig. 1 shows in principle the structure of a chopper 2. The chopper 2 is fed from a DC or AC voltage source 1 and has an output 3, 4 at which an inductive Load 5 lies. The chopper 2 is controlled by an ignition signal generator 6.

Fig. 2 shows in detail how the chopper 2 is constructed. The voltage source 1 is a direct voltage source, the upper terminal 7 of which is connected to the load 5 via a controllable rectifier 23. In parallel with the load 5 there is a diode D ₁ which is conductive when the controllable rectifier 23 is blocked. A protective diode D «is parallel to the rectifier 23, and the extinguishing circuit contains a controllable rectifier 8. A capacitor C and a coil L are used to block (extinguish) the controllable rectifier. The ignition signal is fed to the control connection 22 of the controllable rectifier 23.

Fig. 4 shows the ignition signal resulting from a steep leading Impulse 9 and a subsequent signal 10 exist. This signal 10 can either, as shown, have a constant amplitude or, if galvanic isolation is desired, consist of a high-frequency pulse train.

An embodiment of the ignition signal generator 6 is shown in Fig. As a block diagram. It contains a control signal generator 11, which emits a control signal in the form of square-wave pulses, which via its output 12 to the input 13 of a Pulse generator 14 and the input 15 as an oscillator

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trained signal generator 16 are supplied. The output 17 of the pulse generator 14 and the output 18 of the oscillator 16 are connected to a summing element 19, the output 20 of which is connected to cathode 21 and control terminal 22 of a controllable one Rectifier 23 is connected.

A detailed circuit diagram of this ignition signal generator is shown in FIG the control signal is fed to the input 15 of the oscillator 16 designed as a blocking oscillator. A resistor 24 and a Capacitor 25 form a delay element that has a time delay of, for. B. 2-10 u see at a highest ignition frequency of the inverter of approx. IkHz. A resistance 26, the. Capacitor 25 is connected in parallel, serves to discharge the capacitor 25. The signal thus formed controls a transistor 27 and thus the oscillator 16.

The oscillator 16 contains a transistor 28, a transformer 29 with a primary winding 30, a tertiary winding 31 and a secondary winding 32, a diode 33 which is used to recover the magnetic energy from the transformer 29 and in connection with the tertiary winding causes positive feedback to to operate the oscillator 16 as a blocking oscillator, a capacitor 34 in the base circuit of the transistor 28 to supply the base with a strong current pulse with the appropriate sign once for blocking and once for switching, so that the Wecbaelverluste and times are low, and a resistor 38 for recharging of the capacitor 34. The transistors 27 and 28 are connected in series with the primary winding 30 of the transformer 29 to a 22 V DC operating voltage source. The base of transistor 27 is connected to the connection point of capacitor 25, resistor 26 and resistor 24. The base of the transistor 28 is connected to one end of the capacitor 34 and the resistor, and the other end of the resistor 38 and the capacitor 34 is connected to the junction of the diode 33 and the tertiary winding 31. Via a resistor 35

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and a diode 36 is the secondary winding 32 of the transformer 29 is connected to the control connection 21 and the cathode 22 of the controllable rectifier 23. The oscillator 16 operates in principle as previously known blocking oscillators.

The control signal is also fed from output 12 to input 13 of pulse generator 14. The pulse generator 14 includes a Capacitor 39, from the operating voltage via a resistor 40 is charged. A line leads from the connection point between the capacitor 39 and the resistor 40 one side of the primary winding 41 of a transformer 42, the secondary winding 43 of which is connected to the output 20 via a diode 44. The transistor 45, the diode 46, the transistor 47 and the diode 49 form in a known manner a substitute for a controllable one Rectifier.

The cathode of this replacement SG is on the other side cfer Primary winding 41 and its anode are connected to the positive pole of the operating voltage source via a line 37. Between the control connection 50 of this controllable rectifier and the input 13 are a capacitor 51, a resistor 52 and a resistor 53, which are a differentiator form that differentiates the square-wave pulses from output 12. The diode 54 is used to suppress pulses of one polarity. The capacitor 55 located between the line 37 and the control connection of the substitute SG has a capacitor 55 which is known per se Function.

The mode of operation of the pulse generator 14 is as follows:

The capacitor 39 is brought to full operating voltage via the resistor 40 and charged with a suitable time constant. If a square pulse from the control signal generator 11 hits one, it is differentiated in the differentiating element 51, 52, 53, the controllable rectifier, which has the transistors 45, 47, conductive, and the capacitor 39 via the primary winding 41 and the controllable rectifier, which the transistors 45,

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47 has, discharged. As a result, a steep current pulse with a high amplitude occurs on the secondary winding 43, and immediately thereafter runs with a certain time delay due to the resistor 24 and the capacitor 25 the blocking oscillator 16, which runs as long as the control signal is present, d. H. like the one half wave of the square wave signal at the entrance 15 The control signal disappears or if its polarity changes, the transistor 27 becomes non-conductive and the blocking oscillator is thereby switched off. This ignition signal generator thus initially generates a very powerful current pulse with a certain time delay with a relatively high amplitude followed by a series of high frequency pulses, e.g. B. with a frequency of approx. 100 kHz. This ensures that the first high and steep current pulse controls the controllable rectifier 23 fully, without this resulting in a "soft" or partial ignition of the semiconductor material. After that, the one lower one is sufficient Pulse sequence of the blocking oscillator 16 having amplitude to keep the rectifier 23 conductive with certainty without a renewed ignition and thus a "soft" ignition he follows.

The resistor 63 in the controllable equivalent rectifier 45, 47 determines the holding current, which is essentially through the transistor 45 flows-. The resistor 64 is intended to control the current flowing through the transistor 47 and thus the base current in the transistor 45 limit.

The diode 49 together with the resistor 63 determines the holding current, and when a voltage drop of approx. 1 V occurs across resistor 63, no more holding current flows.

The diode 46 is used to determine the amplitude and trigger signal for the base of the transistor 45.

The resistors 63 and 35 also serve to make the outputs of the two stages short-circuit proof.

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Claims (10)

Claims 1.! Procedure for igniting and keeping a controllable conductive —'Gleicher, characterized in that the control connection (22) of the controllable rectifier (23) is a pulse (9) is supplied with a relatively high amplitude and edge steepness and that the same control terminal a second signal (10), but with a lower amplitude, and that this signal is maintained at least as long as until a predetermined current flows through the main section of the controllable rectifier. 2. The method according to claim 1, characterized in that the second signal (10) is supplied after the high pulse (9), while the controllable rectifier is conductive, and preferably has a constant amplitude. 3. The method according to claim 1 or 2, characterized in that as the second signal (10) a sequence of pulses with preferably constant amplitude in a period of time that the corresponds to the desired conduction time of the controllable rectifier, and then the controllable rectifier is deleted. 4. The method according to any one of claims 1 to 3, characterized in that that the second signal is fed to the control terminal before the amplitude of the pulse to the amplitude of the second signal has dropped out. 5. ignition signal generator for performing the method according to any one of claims 1 to 4, with a control signal generator and a pulse generator, characterized in that at the output (12) of the control signal generator (11) both the pulse generator (14) and a signal generator (16) is connected and that both the output (17) of the Pulse generator and the output (18) of the signal generator (16) are connected to a summing element (19) whose 409818/0771 - ίο - Output (20) is connected to the control terminal of the controllable rectifier (23). 6. ignition signal generator according to claim 5, characterized in that between the signal generator (16) and the control signal generator (16) a delay element (24, 25) is located. 7. ignition signal generator according to claim 5 or 6, characterized in that that the signal generator (16) is an oscillator. 8. ignition signal generator according to claim 6 or 7 »characterized in that that the signal generator is a blocking oscillator » 9. ignition signal generator according to claim 5, characterized in that the pulse generator has a chargeable capacitor (39) has, which is discharged via a pulse transformer (42) and other means, these means by the Control signal generator are controllable. 10. ignition signal generator according to one of claims 7 to 9, characterized in that a secondary winding7a.es pulse transformer and a secondary winding of the output transformer (29) of the oscillator are connected in parallel. 409818/0771