DE2218643B2 - Static inverter with astable multivibrator - is arranged to feed pushpull transistor and transformer circuit via variable resistor - Google Patents

Abstract

The static inverter has an oscillator supplied from a stabilised dc source and feeding a transistor push-pull circuit coupled to an output transformer. The output voltage amplitude of the inverter is controlled by comparing with a reference. The oscillator is constructed as an astable multivibrator (T1, T2) and has its freq. set by a variable resistor (RV3). The two oppositely-phased outputs of the multivibrator are passed via voltage dividers--consisting of two fixed resistors (R17, R18) and a variable resistor (T3)--to the push-pull circuit where they are used as control signals. The advantage lies in giving a variable frequency output with high frequency whilst retaining a simple configuration.

Description

The invention relates to a static inverter with one of a stabilized DC voltage-fed vibration generator, one on the primary winding of an inverter output transformer working transistor push-pull arrangement controls, and with a control device for the amplitude of the inverter output voltage, which is the amplitude of the inverter output voltage with a reference voltage and forms a DC control signal that is input to the output of the vibration generator outgoing control path engages

Such an inverter in the journal »Feinwerktechnik«, 1966, No. 7, pp. 315 to 319.

In this, however, the push-pull arrangement is controlled with an efficiency factor limiting sinusoidal signal, the frequency of the output signal cannot be adjusted, and the The amplitude of the output voltage is regulated by the amplification of one of the push-pull arrangements upstream preamplifier is set by the DC control signal. Amplifier with controllable gain are relatively expensive.

In contrast, the object on which the invention is based is to create an inverter Type described at the outset, which has an output signal of adjustable frequency with improved efficiency provides and still has a simple structure. This object is achieved according to the invention through di «: features of the characterizing part of claim 1.

In the above-mentioned document it is also indicated that in a thyristor output stage of the Efficiency can be improved by controlling with a square wave signal. The regulation of the The effective value of the output voltage is then determined by pulse width modulation of the thyristor output stage driving square wave signal made. A pulse width modulator must therefore also be provided will. In the above-mentioned publication, it is also considered as a vibration generator to use an astable multivibrator operated with a stabilized voltage, but with the The output voltage is regulated again via the amplification of the preamplifier.

The provision of an adjustable resistor for specifying the frequency of the vibration generator is for a counter oscillator in the magazine "Funkschau"! 964, Issue 14, pp. 385 to 387. The resistance changes the time constant of an RC network in the oscillation-enabled feedback circuit. The push-pull oscillator generates a sirius voltage, which is then converted into a trapezoid voltage by overdriving a subsequent driver stage. The circuit complexity for driving the push-pull arrangement is therefore relatively large.
With the invention, on the other hand, an inverter which operates stably with an adjustable frequency and which provides a voltage of constant amplitude at its output terminals is obtained in a very simple manner. Using the voltage divider with the resistor controlled by the direct current control signal, fluctuations in the net / power supplying the push-pull arrangement are compensated for by simply changing the proportion of the square-wave signal generated by the astable multivibrator that is fed to the input of the push-pull arrangement.

Inverters according to the invention are suitable for. B. to power a radar transmitter or one Radar receiver on board ships. To do this will be

For example, supply voltages of 180 V and a frequency of 1100Hz are required as a voltage source In most cases, an on-board DC voltage system with a nominal voltage of 24 V is available. In such DC on-board networks, however, have to be expected with strong voltage fluctuations, with one On-board electrical system designed for a nominal 24 V voltage can usually fluctuate between 18 and 32 V.

Another possible application for an inverter according to the invention is, for. B. the operation a sound transmitter on board a ship, with the z. B. warning signals are generated in fog.

The inverter according to the invention is thus characterized in that with little circuit complexity an alternating voltage that is stable in terms of frequency and voltage is generated, with the stability im Idle and at full load remain almost equally good. The efficiency of the inverter according to the invention is very good at it. It is suitable for all applications in which from a direct voltage an alternating voltage of a given variable frequency and Amplitude must be generated, while at the same time a relatively high power are provided got to.

In an advantageous development of the invention it is provided that the multivibrator with transistors is constructed and has an adjustable resistor located in the base circuit of the transistors. Above this allows the desired pulse frequency of the multivibrator to be set precisely.

In a further advantageous embodiment of the invention it is provided that in the line from the adjustable Resistance to the base of a transistor, a further adjustable resistor is connected. This further adjustable resistor is used to balance the pulses of the multivibrator, i. H. to the Achieving the same pulse lengths.

Another advantageous development of the invention is characterized in that the controlled Resistors of the two voltage dividers are the collector-emitter paths of two transistors, whose Emitters form the base points of the voltage divider and are jointly connected to a DC voltage pole and the DC control signal is applied to their interconnected bases.

In a further advantageous embodiment of the invention it is provided that in each of the two voltage dividers between the tap of the voltage divider and the collector of the associated Trans'stors temperature compensating resistor is. These resistors ensure that a change in temperature caused control deviation not to an alternating voltage on the setpoint that deviates from the setpoint Output of the inverter leads.

In a further advantageous development of the invention, it is also proposed that the two transistors the voltage divider is provided in the form of a double transistor arranged in a common housing are. As a result, the two transistors have the same, common temperature response and the two Branches of the push-pull arrangement are influenced in a symmetrical manner.

An exemplary embodiment of the invention will be described in more detail below with reference to a drawing will.

The drawing shows a circuit diagram of a static inverter for a radar transmitter or receiver on board a ship.

Terminals 6, 7 are connected to an on-board DC voltage system (not shown) of 24 volts. The positive terminal 7 is connected to a terminal 4, which can be connected to the terminal 5 with the aid of a switch (not shown). Terminal 5 is connected to the excitation winding of a Relah ReI , the other end of which is connected to ground via a diode Di and a capacitor C3. A contact K 1 is arranged in a line L i which is connected via a winding of a choke Dr and a fuse S 1 is connected to the positive terminal 7 when the relay ReI closes its contact K 1. The end of the choke facing the contact K 1 is also connected to ground via a capacitor C1.

The line L 1 leads via a resistor R 16 to one end of a series circuit of two Zener diodes D 4 and D 5, which is also connected to the base of a transistor T4. The emitter of transistor 74 is connected to the collector of a first transistor 71 via a resistor A22 and to the collector of a second transistor T1 of a multivibrator via a resistor R2i. Capacitors assigned to the bases of the transistors Ti and Tl are denoted by ClO and C11, respectively. The emitters of the transistors TX and Tl of the multivibrator are connected to the negative terminal 6 via a line L 2 and a winding of the choke Dr. The emitter of the transistor TA is finally via an adjustable resistor RV3 and a resistor R 24 at a point between the capacitor CIO and the base of the transistor 7 * 1. A point between the resistor RV3 and the resistor R 24 is connected to a point between the capacitor CI1 and the base of the transistor 72 via a resistor R13 and an adjustable resistor RV2. A point between the collector of the transistor Ti and the capacitor CIl of the transistor Tl is connected via a resistor R 17 to the base of the first transistor 75 of a first Darlington circuit. In the same way, a point between the collector of the transistor T1 and the capacitor C10 is connected via a resistor R 18 to the base of a first transistor 7 * 6 of a second Darlington circuit. The collector of the transistor 7 "5 of the first Darlington circuit is connected to the collector of the transistor 74. The emitter of the second transistor T1 of the first Darlington circuit is connected via a resistor R 14 and resistors R 6, R 7 and R 8 corresponding bases of transistors 7 * 9, Γ10 and T 11 connected to a power amplifier stage. The emitters of the transistors T9, Γ10 and 7 "11 are connected via a common line L 3 at the other end of the series circuit of the Zener diodes D 4 and D 5, which in turn is connected via a line L 4 to the negative terminal 6 of the DC voltage network. The emitters of the transistors 9, 7 * 10 and 711 are also located via a low-resistance resistor R 9 at a point between the resistor R 14 and the common connection of the resistors R 6, R 7 and Ä8. The collector of the second transistor 77 of the first Darlington pair is connected to the line L 1.

In the same way, the emitter of the second transistor 78 of the second Darlington circuit is connected via a resistor R 15 and resistors R 10, R 11 and R 12 to the corresponding bases of transistors 712, 713 and 714, which together have a

Form push-pull power amplifier stage. The emitters of the transistors 712, 713 and 714 are jointly connected to the line L 2, which leads to the negative terminal 6, and via a resistor R 13 at a point between the resistor R 15 and the common connection of the resistors R 10, R 11 and R 12. A common connection of the collectors of the transistors Γ9, T10, 711 on the one hand and a common connection of the collectors of the transistors 712, 713 and 714 are connected to opposite ends of a primary winding 20, 21 of a transformer Tr . The primary winding 20, 21 has a center tap which is connected on the one hand to the line L 1 and on the other hand to the collectors of the transistors 76 and 78 of the second Darlington circuit.

On the secondary side, the transformer Tr has a first secondary winding 22, to which a capacitor C1 is connected in parallel and which is connected to two terminals 1 and 2, at which an operating AC voltage of 180 volts and 1150 Hz is taken. The transformer Tr has a second secondary winding 23, the terminals of which are connected to a rectifier bridge circuit GIi. On the other diagonal of the bridge circuit GIi there is a line L 4 which is connected to the line L 2. A line L 6 is also connected to this bridge diagonal and is connected to the base via a resistor R 1 and a resistor / 29 and to the collector of the transistor 715 via a resistor RA. The collector of the transistor 715 is also connected via a resistor 5 and via the line L 7 to a double transistor 73 which has a common housing 24. The transformer 77 has a third secondary winding 25. the mil one

r ^ \ * 1 '■ / * ■ * ·! '' 'U. t "1 ti

i ^ 'iagwiiaiL-fi CiHCi zV \ Ciii, ii vj' »- '» -ι υ ι * -' * n-1 lm u \ _i \ t. ilriciun lung G / 2 connected im. In the other diagonal, the rectifier bridge circuit Gl2 is connected to the line LA and to a line L 5. The line L 5 is connected to the line L 2 via a resistor R 2. an adjustable :) resistor RVi and a resistor R 3. A Zener diode D 3 is connected between the line L 2 and the base of the transistor 715. The emitter of transistor 715 is connected to a tap of resistor RVi . The collectors of the double transistor 73 are each connected via a resistor R 20 or R 19 to the base of the first transistor 75 or 76 of the Darlingion circuits. The resistors R 19 and R 20 are temperature compensating resistors. The emitters of the double transistor 73 are on the line L 4.

Between the lines L 1 and L 3 there is a Zener diode D 2 and a capacitor C12 in parallel therewith. The Zener diode D 2 is a special diode with a blocking range from -0.7 to 38 volts. An electrolytic capacitor C9 is connected in parallel to the series connection of the Zener diodes D 4 and D 5 and the base-emitter path of the transistor 74. Likewise, electrolytic capacitors C4, C5 are arranged between the one diagonal of the rectifier bridge G / 1 or G / 2 and the line L2 . The line LA also contains an electrolytic capacitor C8. A point between the resistors RVi and R 2 is connected to the line i.3 via an electrolytic capacitor C6. The line L 2 is connected to the line L 6 via an electrolytic capacitor Cl , namely between the resistors R 1 and R4.

The operation of the above static inverter is briefly described as follows. The DC voltage at terminals 6 and 7 is supplied via the choke Dr

S and the lines H and L 2 given to the multivibrator, which consists essentially of the transistors 71 and 72 and the capacitors ClO and CU. Before this, however, it is necessary that the relay ReI closes a contact K 1. This is only the case if

ίο the direct voltage. is applied with the correct sign, ie the diode Dl is applied in the forward direction. Since the DC voltage, which is 24 volts, can fluctuate widely, for example between 18 and 32 volts, a voltage stabilization is made with the help of the Zener diodes DA and D5 and the transistor 74, so that a constant voltage is always applied to the multivibrator. With the help of the resistor RV3 , however, the voltage can be changed so that the frequency of the multivibrator can also be controlled within certain limits. The length of the pulses is set to the same size with the aid of the resistor RV2.

The output pulses of the multivibrator reach the current-amplifying Darlington circuits, which consist of transistors 75, 77 and 76, 78, in push-pull mode. The current-amplified pulses reach the amplifier stages, which consist of transistors 79, 710, 711 and 712, 713, 714, respectively. The amplified pulses arrive in phase opposition from the two amplifier stages to the primary winding 20. The operating AC voltage is taken from the first secondary winding 22, namely at terminals 1 and 2. At the second secondary winding 2.3, the operating voltage for the control amplifier is:

removed and practices the GiehriehterbrücAon-.eiuiiiuiig GIi giciCfigenciHci. Oic lsi-Vv echsw '-;j's.i: ii "ii: tif.

is removed from the secondary winding 25 must be equal to the rectifier bridge circuit - r \ '! i ici. Sii. ! "decreases at the potentiometer RV ! and reaches via: -

_4C deisei tap on de. '! iimiU'jr of the transistor. / Γϊ. 'X; ■ j Li rc h die Zenerdiocie etne constant '' -ipaiuiiiiu. ' is given. besiimtiu the amount of am i: n! üier α. · \; rar.s.slurs 7ί ^ .ι!:,; ^ Ι '*' KiL ^ ι ■■ ^ii: π u 11 ^ r Gen K-jiieK'.ν ί: - -ifom. The current ν \: z flowing through the line Ll depends on the Ansieueruiij; de · -. Transistor 715 changed by a voltage proportional to the actual AC operating voltage. The level of the proportional voltage can be changed with the aid of the adjustable resistor RVi. Via the line L 7 , a voltage proportional to the deviation of the actual operating AC voltage is applied to the bases of the double transistor 73, which is used as a control amplifier. The double transistor 73, the collectors of which are each connected to an input of the Darlington circuits, thus adjusts the input voltage for the Darlingtori circuits in accordance with the control deviation. The common housing 24 and the temperature-compensating resistors /? 19 and R 20 ensure optimum temperature compensation for the control deviation.

With the aid of the static inverter shown, an AC operating voltage, for example of 180 volts and a target frequency of 1150 Hz can be achieved. The efficiency is around 70%. Fluctuations in the output voltage are kept within a range of + 1%.

1 sheet of drawings

Claims (6)

Patent claims: 1.Static inverter with an oscillation generator fed by a stabilized direct voltage, which controls a transistor push-pull arrangement working on the primary winding of an inverter output transformer, and with a control device for the amplitude of the inverter output voltage, which compares the amplitude of the inverter output voltage with a reference voltage and forms a direct current control signal, which intervenes in the control path emanating from the output of the vibration generator, characterized in that the vibration generator is an astable multivibrator (Ti, T2) with a frequency that can be adjusted by setting a resistor (RV3) , that two antiphase output signals from the multivibrator (Ti, T2) are used as control signals A voltage divider each, which consists of a fixed resistor (R 17, R 18) and a resistor (T3) controlled by the direct current control signal, is fed to the push-pull branches of the transistor push-pull arrangement and are transmitted exclusively galvanically in the push-pull branches, in such a way that the voltage with which the inverter output transformer (Tr) is applied on the primary side is square-wave. 2. Inverter according to claim 1, characterized in that the multivibrator is constructed with transistors (Ti, T2) and has an adjustable resistor (RV3) lying in the base circle of the transistors {Ti, 72). 3. Inverter according to claim 2, characterized in that a further adjustable resistor (RV2) is additionally connected in the line from the adjustable resistor (RV3) to the base of one transistor (T2). 4. Inverter according to one of claims 1 to 3, characterized in that the controlled resistors of the two voltage dividers are the collector-emitter paths of two transistors (T3) , the emitters of which form the base of the voltage divider and are jointly connected to a DC voltage pole (L 4 ) are connected and the DC control signal is applied to their interconnected bases. 5. Inverter according to claim 4, characterized in that for each of the two voltage dividers between the tap point of the voltage divider and the collector of the associated transistor (T 3) a temperature compensating W ^; the position (R 19, R 20) is located. 6. Inverter according to claim 4 or 5, characterized in that the two transistors of the voltage divider are provided in the form of a double transistor (T3) arranged in a common housing (24).