DE1021025B - Device for generating square pulses with changeable duty cycle - Google Patents

Description

GERMAN

The invention relates to a device for generating of periodic square-wave pulses with variable depending on the maximum of a DC voltage Duty cycle. The duty cycle is the ratio of the duration of a pulse period to understand the duration of the impulse. In other words, the invention relates to a device for converting a DC voltage into a proportional pulse-time-modulated square-wave voltage.

The device according to the invention is based on a pulse generator for at least approximately triangular Voltage pulses off. Its pulse voltage is switched against an adjustable DC voltage, which can be changed at least between zero and the peak value of the pulse voltage. Furthermore, a semiconductor amplifier is arranged in the circuit of the opposite voltage, the even at a very low value of its control voltage in relation to the maximum value of the triangular voltage is fully open. The square wave voltage you are looking for, its pulse duty factor is the size of the DC voltage corresponds to, is taken from the output terminals of the amplifier and a consumer fed.

A preferred field of application of the device according to the invention is in open-loop and closed-loop control circuits in heavy current engineering. The task often entails, especially in automatic control technology suggests a relatively low measured value that can represent the controlled variable, for example strengthen. This requires a so-called control amplifier that acts on the control element. The measured variables are now often in the form of direct current variables, in particular as voltages, and fine accurate reproduction of a displayed size by a transducer or transducer is often only given when a certain load the same is not exceeded. In order to avoid overloads, efforts are therefore made to use control amplifiers to be used with high input resistance. Hegen the required high input resistances however, if magnetic amplifiers or amplifying machines are to be used, not so easily before. Alan therefore endeavors to have a preamp with to use the highest possible input resistance. Known amplifiers of this type are electron tube amplifiers. However, as a result of known disadvantages, such as aging, heating power requirement, mechanical Sensitivity etc., often rejected in industrial control systems.

A device similar to electron tubes is the transistor. There are also others lately Semiconductor amplifier elements have been developed.

Facility

for generating square pulses
with variable duty cycle

Applicant:

Siemens-Schuckertwerke

Corporation,

Berlin and Erlangen,

Erlangen, Werner-von-Siemens-Str. 50

Dr.-Ing. Georg Sichling, Erlangen,
has been named as the inventor

These include, for example, semiconducting compounds of the form A ₁₁₁ B _v , such as indium antimonide

and the like. The above-mentioned disadvantages of the electron tubes now reside in transistors and others Semiconductor amplifiers are not available. However, the problem arises that they easily and generally can only be controlled up to certain, mostly relatively low output powers. Magnetic amplifiers and amplifying machines can therefore be understood from the technical-economic point of view generally not considered satisfactory Drive semiconductor amplifier arrangements. Magnetic amplifiers are known that are particularly small Input power half. However, their time constant is so large that they are used for rapid technical regulations are useless. The relationships between control power and time constant of an amplifier is defined by the concept of control energy.

In the case of magnetic amplifiers, it is not readily possible to apply a certain minimum control energy fall below. Furthermore, it is not easily possible to use transistors or other semiconductor amplifiers To take from greater tax output more tax output than its warming allows, because otherwise destruction occurs.

A contrivance has already been proposed elsewhere, by means of which it is possible to Transistors and other semiconductor amplifier elements in a relatively large control range use. These measures are based on the knowledge that the power loss of such an amplifier due to the hyperbolic power curve

709 810.Ί05

in the uncontrolled and fully controlled state is significantly smaller than with other intermediate tax values, especially in the middle of the control range. It has therefore been proposed to use the intermediate area to through control as quickly as possible, so that the amplifier element is mostly locked or open state and those occurring in the changeover time. Power losses only during occur in a vanishingly short time, so that an un-

ihin the desired triangular voltage occurs. This triangular voltage, which can also look like a sawtooth, can also be generated by other RL or RC generators or any other generators 5 per se.

Another example of a circuit for generating a triangle voltage that with a single Tip transistor 40 is operating, is shown in FIG. Between the collector and base of the transistor

permissible heating and destruction is avoided, xo there is a condensation via a resistor 41 or 42. The control takes place as a function of the variator 43. This is via a resistor 44 of constant open / closed. Thus, square-wave configurations of a current source 45 are charged as long as the transmission has a variable duty cycle for the control
needed.

The device according to the invention provides a breakdown of the resistance between the collector and the particularly simple and advantageous device, with the base suddenly collapsing, so that the condenser using the aforementioned control principle discharges via the transistor in the case of the transistor. The transistor and other semiconductor amplifiers, ζ. Β. such
with semiconductor elements with so-called magnetic

transistor resistance between collector and base is large. At a certain voltage on the capacitor

The resistance between the base and the collector then increases again. The capacitor is charging again

Barrier, can be carried out. About the fabrics and so on. This results in the capacitor 43

fen with a magnetic barrier layer, which is not only caused by a magnetic field but also by an electric field as well as being controllable by radiation, reference is made to the article by E. Weisshaar and H. Welker:

a sawtooth voltage that is taken from terminals 46, 47.

For the purposes of the invention, such generators for generating the triangular voltage are preferred- "Magnetic barriers in germanium", Zeit- 25 _ZU gt, which have the most linear pulse edges possible Proportionality between pages 681 to 686, referenced.

Accordingly, the invention consists in that

with a device for an almost lossless modulation DC voltage and the pulse duty factor of the desired Reckteckspannung achieved.

In Fig. 1, the triangular voltage to the small control of a consumer-feeding half-men 11, 12 of the pulse generator 1 is removed and conductor amplifier (transistor) converting the counter-circuit with one of the terminals 13 control variable of the amplifier in square pulses, 14 DC voltage taken from the input circuit, the duty cycle of which is proportional to the control variable. a semiconductor amplifier 15, which, for example, its known pulse generator also works at least in some cases with a flat transistor, approximately triangular voltage pulses, in front of a current source 16, the power supply is preferably provided with linear edges. Further the semiconductor amplifier 15 indicated. With 17 it is part of the invention that the pulse output denotes a series resistor. Together with its voltage of the pulse generator a between zero and the associated circuit elements as well as the given peak value of the triangular pulse voltage adjustable if a downstream auxiliary amplifier forms bare, the control variable adjacent DC voltage 40 of the semiconductor amplifier 15 is connected in opposition to the square wave genes in such a way that the differential voltage that the control circuit of the semiconductor amplifier
is fed to the semiconductor amplifier at an im
Relation to the maximum value of the triangular voltage
very low value of the control voltage fully opens.

For a more detailed explanation of the invention, reference is made to the drawing. This shows in

1 shows a possible embodiment at the same time also in connection with an application example;

rator 18. The creation of the square waves from the triangular voltage at terminals 11 and 12 and the controlling DC voltage at terminals 13, 14 is explained below. At the square 45 wave generator 18 is connected to a suitable, any power amplifier 19, z. B. a magnetic amplifier. This represents the actual rule amplifier. It feeds the armature 20 of a motor M whose speed is to be regulated and whose designated by 21

Fig. 2 shows a circuit for generating a 50 designated excitation winding from a current source 22 ge

Delta voltage and is fed. The motor M is on the shaft 23 with

Fig. 3 is a graphic representation to explain a working not shown in detail

the mode of operation of the device according to the invention machine 24,

manure. To regulate the speed of the motor M and thus

In Fig. 1, the required three- 55 of the working machine 24 is generated with the motor M via angular pulses with a pulse generator 1, which couples a shaft 25 to a tachometer dynamo 26, for example according to the multivibrator principle with the speed-proportional equal two surface transistors generated by this 2 or 3 in known voltage, one of a potentiometer 27 is working. The supply of the pulse generator can be set to the adjustable DC voltage by a switch to be connected to the terminals 4, 5 60, which represents the setpoint of the control. Can be done at any power source. With 6 and 7 are two of the terminals 28, 29, the so-called each consisting of a resistor and a capacitor. Control deviation, which is referred to as DC timing elements, through which the frequency of the generated triangular pulses is generated by the further semiconductor amplifiers 30 connected to the frequency is essentially amplified and determined at the terminals 13, 14 removed. The junction transistors 2 and 3 open 65. The amplification of the control deviation can alternately N and Close :. This may also be omitted. Then the regular resistances 1 and 5 would initially be a rectangular deviation directly from the voltage generated by the impulse pulse. By the voltage at the counter 1 counter-connected, stand 5 is a capacitor 8 via a resistor 8. The semiconductor amplifier 30, which in the present gate 9 is periodically charged and discharged, so that at 70 case to achieve a high control accuracy

is provided, for example, also works with a flat transistor 31. Its current source is with 32 and its output resistance is denoted by 33. Here as with the other parts of the circuit According to FIG. 1, the representation is limited to what is absolutely necessary for understanding. In In reality, depending on the prevailing conditions, further means and measures will be provided, to ensure the desired function of the individual parts to achieve satisfactorily. For example, to prevent overriding and thus Damage to the semiconductor amplifier 15, a voltage-dependent resistor 34 from counter-parallel switched dry rectifiers are shunted to the input terminals.

3. The curve C ₁₁ Z ₁₂ shows the voltage at the output terminals 11, 12 (FIG. 1) of the pulse generator 1 as a function of the time t. The semiconductor amplifier 15 is designed so that it would be fully controlled by a fraction of the voltage U _11112. It would therefore be open for the entire period. However, due to the direct voltage U _{13 / u} added in opposite directions in its input circuit , which represents the increased control deviation, only the difference between U ₁₁₁₁₂ and CZ ₁₃ Z _{14 is} effective in the input circuit of semiconductor amplifier 15. By changing the direct voltage U _{13 / li} , which appears as a straight line selling parallel to the time axis t (FIG. 3), different points of intersection of the curves U ₁₁₁₁₂ and U _{ls / li result} . For example, two different values of U _{ls / li are} assumed, of which the larger is labeled A and the smaller is labeled B. There are two intersection points within each triangular wave train. At Ci ₁ or b ₁ the semiconductor amplifier 15 opens (FIG. 1), and at a ₂ or b _{2 it} closes. In case A , the voltage curves shown in the lower part of the drawing result. They represent the voltages present at the output of the semiconductor amplifier 15. There is thus a periodic sudden opening and closing that takes place within the spacing of the two dashed horizontal lines indicated by AU , depending on whether the difference between the triangle voltage occurs C ₁₁ Z ₁₂ and the DC voltage U _{13lli becomes} positive or negative. In case A , the pulse duty factor is T: a, in case B, on the other hand, T: b. The time mean value of the rectangular curves (A or B) is effective for regulating the Motor.i M in FIG. 1. In the exemplary embodiment according to FIG. 1, it is assumed that the motor M operates in the regulated state with a pulse duty factor of approximately 2: 1. In the case of an upward speed deviation, it must therefore be ensured that the pulse duty factor is greater than 2: 1 and. is less than 2: 1 in the case of a downward Drek number deviation. The regulation takes care of this automatically.

The invention is not limited to the illustrated embodiment or application example, but rather can also be realized with other circuits and for regulation as well as control per se serve any consumer. In the case of a control task, according to the invention, the triangle voltage represents counter-connected DC voltage represents the so-called setting voltage, which for example can be supplied by a potentiometer. The position of the potentiometer corresponds to a certain one Duty cycle of the generated square wave voltage and the duty cycle a certain position or a certain state of the device to be controlled. The device according to the invention is except for Control purposes especially suitable for remote control purposes, since there are essentially voltages in their Control circuit are effective and thus a larger line resistance of the same does not interfere.

Claims (5)

Patent claims: 1. Device for the almost lossless control of a consumer feeding Semiconductor amplifier (transistor) converting the control variable of the amplifier into square-wave pulses, whose duty cycle is proportional to the control variable, characterized in that a Pulse generator known per se for at least approximately triangular voltage pulses, preferably is provided with linear edges, whose pulse output voltage is between Zero and the peak value of the triangular pulse voltage adjustable, representing the control variable DC voltage is connected in such a way that the differential voltage, which the control circuit of the Semiconductor amplifier is supplied to the. Semiconductor amplifier at a relative to Maximum value of the triangle voltage very low value of the control voltage fully opens. 2. Device according to claim 1, characterized in that the direct voltage is the setting voltage a control device, in particular a remote control device. 3. Device according to claim 1, characterized in that the direct voltage is the control deviation of a control loop. 4. Device according to claim 1, 2 or 3, characterized in that the in the circuit of the two voltages switched amplifier a semiconductor amplifier with a magnetic barrier layer is. 5. Device according to one of the preceding claims, characterized in that all controllable elements are controllable semiconductors. Documents considered: German Patent No. 641 176; U.S. Patent Bulletin No. 2 511093, 2 561475, 684 448. 1 sheet of drawings © 709 810/105 12.