DE1025462B - DC voltage converter using a transistor oscillator and a rectifier - Google Patents

Description

GERMAN

The invention relates to improvements in dormant DC voltage converters for power supply serve and a transistor oscillator, which is operated from a low voltage source, a Transformer and a rectifier.

Transistor oscillators of various circuit structures and in particular those according to the Blocking oscillators are for use in power supply circuits for obtaining the Anode operating voltage of electron tubes and the like are well suited. In such power supply circuits the transistor oscillator draws its energy from a source of low DC voltage and is transformer coupled with a suitable voltage ratio to a rectifier circuit, to generate a high DC voltage.

In circuits of the aforementioned type it is desirable to use a heated high vacuum rectifier tube, d. H. one with a warm cathode should be used. Although other types of rectifiers, such as z. B. gas-filled rectifier tubes, can be used in these circuits, leave factors like the constant availability in the trade and the economic efficiency of the heated high-vacuum rectifier tube appear desirable. There are, however, in known circuits that are heated with Tube rectifiers of this type work, difficulties arose in that a reliable insertion of the oscillator was not guaranteed under certain operating conditions.

These difficulties are due to the fact that a heated rectifier tube even at low Anode voltage still conducts when the cathode is sufficiently heated to be able to emit. If z. B. The oscillator and rectifier switched on a second time after a short break in operation the oscillator may not be excited. In the circumstances mentioned, the The cathode of the rectifier is heated to the point that it still emits, so that the tube for the transistor oscillator represents a low resistance across the coupling through the coupling transformer. The oscillator is therefore heavily loaded and needs an excessive feedback power in order to be Can excite vibrations. The same difficulty arises when starting an oscillator as well then on when the oscillator feeds a rectifier of some other type, which at lower Voltage conducts well.

The aim of the invention is to create an oscillator that works reliably.

The invention solves the problem set in that the rectifier circuit in addition to the smoothing capacitors an additional capacitor DC voltage converter

Using a transistor oscillator

and a rectifier

Applicant:

General Motors Corporation,
Detroit, me. (V. St. A.)

Representative: Dr. W. Müller-Bore, patent attorney,
Braunschweig, Am Bürgerpark 8

Claimed priority:
V. St. v. America January 18, 1956

Richard L. Jenkins, Kokomo, Ind. (V. St. A.),
has been named as the inventor

holds, which is connected to the rectifier with the help of the supply voltage source of the transistor or with a voltage derived therefrom when the oscillator is switched on for a short time or up to a relatively low voltage value in the sense of a power line blocking.

The invention is described in detail with reference to the drawing.

1 is a schematic circuit diagram of a push-pull transistor oscillator connected to feed a rectifier circuit having a high vacuum heated rectifier;
Fig. 2 shows a modified rectifier circuit.

In Fig. 1 the oscillator comprises a pair of transistors 10 and 10 '. It comes from a low voltage source 12 is supplied with energy and leads an output transformer 14, which in turn is a rectifier circuit 16 feeds, alternating current.

The transistors 10 and 10 'have emitter electrodes 18 and 18', collector electrodes 20 and 20 ', respectively. and base electrodes 22 and 22 ', respectively. In this exemplary embodiment, both transistors are junction transistors of the p-n-p type, in which the emitter and collector electrodes are made of ρ-conductive material with holes as majority carriers and the base electrode made of η-conductive material with electrons as majority holders.

709 908/308

3 4

Arrangements are also conceivable in which the circuit arrangement for starting the transistor contains either tip transistors or oscillator a resistor 62 which is between npn junction transistors. Base electrode 22 'and the ground point 64 is located. Here-The output circuits of the transistors 10 and 10 'through the positive pole of the battery 12 are connected to the primary windings 24 and 26 of an output 5 via switch 32, resistor 30', emitter electrode and coupling transformer 14 and the 18 ', base electrode 22 'and resistor 62 after the voltage source 12 in a push-pull arrangement to ground point 64, a circuit is closed. A summed up. The output circuit of the transistor 10 circuit also exists, starting from the positive runs from the emitter electrode 18 via the conductor tiven pole of the battery 12, via switch 32, resistor 28, the resistor 30 in the emitter circuit and the io stand 30, emitter electrode 18, base electrode 22 , Wi conductor 46 to the start or on switch 32. From the resistors 48, 50 and 62 to the same ground switch 32, the circle extends further point 64. The latter circle has larger resistance ZTi the positive pole of the voltage source 12 and stood . Consequently, the initial current supplied to the input circuit of the Trau from there to a point 34 with reference or transistor 10 'is greater than the ground potential. The output circuit of the transistor 15 is fed to the input circuit of the transistor 10, 10 closes via the primary winding 24 of the off when the switch 32 is closed,
output transformer 14 through the connection of the output of the oscillator is coupled by means of the TransMasspunktes 36 with the center tap 38 and the transformer 14 to a full-wave rectifier circuit a connection of the terminal 40 to the collector 16. The rectifier circuit contains electrode 20. In a similar way, the output 20 runs a heated high-vacuum rectifier tube 63. output circuit of the transistor 10 'from the emitter electrode 30 'im to the secondary winding 68 of the transformer at the emitter circuit, the conductor 46, the switch 32 and the terminals 70 and 72, respectively. The battery 12 to ground at 34. The circuit closes the secondary winding has a center tap at 74 at ground to the collector electrode 20 'across the primary winding 25. A charging capacitor 76 through a connection of the ground point 36 is parallel to the terminals 70 and 72 of the secondary with the center tap 38 as well as a further Verdärwindung. The cathode 78 is connected to the conductor 80 from the terminal 44 to the collector electrode of the output circuit via the resistor 82 of a trode 20 '. The input circuit of each transistor contains 30 output voltage to any desired payload 84 to apply a feedback circuit from the output which is connected at 86 to ground. The circuit of the other transistor is excited and between a filter capacitor 88 is located between conductor 80 and see emitter and base electrodes. The emitter ground connection 90 is switched.

electrodes 18 and 18 'of transistors 10 and 10' The oscillation is generated by closing are triggered via resistor 30 or resistor 30 'with 35 of the start or switch 32. Through this connected to conductor 46. A resistor 48 is connected to the above-mentioned starting circuit from the positive between the conductor 46 and the base electrode 22, pole of the battery 12 via the emitter and the base and a resistor 50 between the same conductor 46 electrode of the transistor 10 'and the resistor 62 and the base electrode 22 '. The feedback circuit to the negative pole of the battery via ground contains the feedback winding 52, which is closed with 40 connections. That way one can the primary windings 24 and 26 inductively coupled small initial current in the forward direction of and flow via terminals 54 and 56 between emitter electrode 18 'to base electrode 22', Base electrodes 22 and 22 'is connected. which in turn creates an output current from battery A capacitor 58 is located with the back 12 via emitter electrode 18 'to the collector electrode coupling winding 52 in series to the curve shape 45 20 'and from there via the primary winding 26 to to influence the fed-back current pulses. Mass point 36 is made to flow. This By means of this arrangement, current is obtained induced at the output in the output circuit of the transistor 10 ' one corresponding to a quadratic function in the feedback effect 52 by virtue of the induction wave and maximum performance. tiven coupling with the primary windings 24 and 26 The resistors 30 and 30 ', in the circles 50 a voltage. The relative polarities of the spander Emitter electrodes 18 and 18 'are generated in voltages on the primary winding 26 and the back Input circuits of the transistors a negative feedback winding 52 are in this operating eye coupling voltage, around the temperature stability of the look as indicated in the drawings. the Increase oscillator. iYuch the resistors 48 and induced feedback voltage causes an An-50 in the input circuits of the transistors create 55 grow the current in the input circuit of the Transieinen low-resistance branch from the emitter to the stors 10 ', which in turn causes a further increase in the Base electrode, which acts in such a way that it results in the current in the output circuit. The circle Operation of the transistors within the current and for the feedback current can be as follows The voltage limits of the transistors are maintained if they are followed: starting from terminal 54, operating temperatures of transistors grow. 60 it runs through the resistors 48 and 30 ', the emitter-in Increase in the collector current with the temperature electrode 18 ', the base electrode 22', the capacitor temperature with the other factors remaining constant and back to terminal 56, the feedback is heard to the unavoidable properties of development 52. The curve shape of the feedback sistors and can lead to a thermal »of it- Current is largely through the series capacitor run ”and ultimately destroys the tran- 65 58 and the resistors 48 and 30 '. Of the sistors lead when compensation does not pre- Output current reaches a maximum value, is determined is seen. The resistors 48 and 50 provide in through the circuit parameters, and the feed back Input circuits have a certain negative feedback, the pelte voltage goes back to zero. The current in the grows with the current in the output circuit and then through the output circuit via the primary winding 26 limits this to a certain value. 70 wrestles itself very quickly, creating the conductive phase

5 6

• a working period for the transistor 10 ′ terminates the transformer 14 on the primary windings 24

will. and 26 translated. The feedback loop is therefore

When the output current in winding 26 is energized enough by winding 52 to generate a normal

increases, the magnetic field of the transfer begins to start properly at low power mators collapse, thus ensuring the polar 5. However, when the oscillator is through

did the voltage between the terminal 44 and the opening of the switch 32 switched off and then again

Tap 38 reverses. This means that the switch 32 is switched on,

supply that at the electrodes of the transistor 10 'before the cathode 78 has cooled, this is

• During the non-conductive phase of a working period, the oscillator starts up by additional switching this Transistor in the reverse direction ensures a high voltage io means, which act to the effect that they

Tiung occurs. The voltage on the feedback power line in the rectifier circuit 16 is

However, winding 52 is also reversed, so hesitate. This is caused by the fact that a condensation

a polarity occurs which corresponds to that of the sator 92 in the drawings between the cathode 78 and the conductor 46

indicated polarity is opposite. Is switched to ground. In this embodiment is This new polarity begins an input current 15 also a capacitor 94 is provided. Through the-

to the transistor 10 in the forward direction between sen it is ensured that a current branch on the switch

Emitter electrode 18 and base electrode 22 to flow. low impedance towards ground

This current flow through the low-ohmic pass-through hands is. This is the power supply circuit

circuit including the capacitor 58 and separated from the load. When the power switch 32 Resistors 50 and 30 acts so that the one in which 20 is closed becomes the positive pole of battery 12

magnetic field of the transformer 14 stored via the switch 32 and the capacitor 92 currently-

Energy dissipates and thereby applied to the cathode 78 in the reverse direction. The capacitor 92

emerging voltage at the electrodes of the transistor had previously been discharged to ground potential, and

10 'limited to a safe value. since the voltage on this capacitor 92 is not

The current flow in the input circuit of the transistor 10 25 can change abruptly, appears at the constant the non-conductive phase of the transistor 10 'stood 82 and the parallel arrangement with the load 84 sets a power line in the output circuit of the Tran and the capacitor 88 the full voltage of the sistors 10 via the primary winding 24 in motion. As a battery 12. This positive voltage leaves the cathode As a result, in the feedback winding 52, 78 will become positive with respect to the anodes 65 and 66 between the terminals 54 and 56 a feedback 30 and acts as a bias voltage for suppression tion voltage induced, which in this operating the power line of the rectifier 63 until the span instant The polarity of the voltage at the anodes in the drawings is more positive than that at the cathode polarity is opposite. The senior will. The positive voltage on the cathode 78 decreases The phase for the transistor 10 ends with the combination according to a time function, since the capacitor 92 Break of the magnetic field of the transformer over the circuit with a time constant tor 14 in the same way as with respect to the with the capacitor 92, the resistor 82, the Transistor 10 'is described. The second half-cycle capacitor 88 and the payload 84 are charged of the oscillator is over. While the non-will.

The conductive phase of the transistor 10 is reversed in the delay of the current conduction in the same way Feedback winding 52 induced voltage 40 rectifier 63 acts, although the time delay is small again to be as indicated in the drawings so that the oscillator can begin to settle in polarity, causing a current in the input circuit of the gene before the load takes effect. After expiration The common electrode leads transistor 10 'in the forward direction between the emitter of the voltage and time delay 18 'and base electrode 22' to flow right current, and the load is known in is brought. This current acts to supply the high voltage power in 45 ways. If the In the reverse direction, voltage to the electric oscillator is switched off by opening switch 32 that of the transistor 10 is limited. The second period becomes, the capacitor 92 discharges to ground The oscillator becomes potential through the input current.

Transistor 10 'initiated, and the just described. A modification of the rectifier circuit is shown in FIG

The process is repeated in rapid succession, so that FIG. 2 is shown in FIG. It creates an even greater

of the primary winding of the transformer 14 delay and time delay in order to allow the onset of the

Tending vibrations arise. To improve the oscillator. In Fig. 1

The voltage induced in the secondary winding 68 and 2 are the same reference numerals used to denote the id

The two-way nature of the same parts expresses this in a well-known way. In

rectifier circuit 16 rectified. The between 55 Fig. 2 is a capacitor 93 via a switch 32 '

Cathode 78 and ground appearing DC voltage connected between cathode 78 and ground point 97,

is connected via the filter element to the conductor 80 and from The switch 32 'is suitably connected to the

The payload 84 is supplied there. On-switch 32 mechanically coupled so that it

When the oscillator is operated for the first time in time with it. When the oscillator is set after the circles have been extended for a longer period of time by closing switches 32 and 32 'to the first by being out of order, the oscillations are set in motion times, the oscillator builds up triggered in the manner described above and tension satisfactorily in the manner described above fanned. When starting up in this way, and the rectified output voltage exposure occurs, the cathode of the rectifier is of high voltage value appears on the utility 63 initially relatively cold and so long without 65 load 84. The high output voltage is also on Emission until the filament applied the cathode to the capacitor 93, which is now through the operating temperature has warmed up. Therefore the equal switch 32 'is connected to ground. The condenser judge 63 non-conductive during the start-up time, and the sator takes on a charge that the output voltage secondary winding 68 works on a circle with voltage equivalent. When the oscillator is off high impedance. This high impedance is caused by 70, the capacitor 93 remains charged because of the

Switch 32 'is open and there is no discharge path to ground. When the power switch 32 and thus also the switch 32 'are again closed, causing the charged capacitor 93 in that the cathode is located 78 at a high positive potential, whereby the power line of the' rectifier is delayed sufficiently 63, so that the oscillator unaffected by the thermal state of the cathode 78 or the load conditions. The capacitor 93 discharges via the circuit which has the time constant and which, in addition to the capacitor 93 itself, contains the resistor 82, the capacitor 88 and the load 84.

Claims (3)

PATENT CLAIMS: 1. DC voltage converter, in which the AC voltage generated by a transistor oscillator is stepped up and on the load side of the transformer a rectifier ao is provided, which conducts even at low voltage, characterized in that the Rectifier circuit in addition to the smoothing capacitors an additional capacitor (92 or 93), which is connected in such a way that it operates the rectifier with the aid of the supply voltage source (12) of the transistor or with a voltage derived therefrom when the oscillator is switched on for a short time or up to a relatively low level Voltage value in the sense of a power line blocking. 2. DC voltage converter according to claim 1, characterized in that the rectifier has a High vacuum rectifier tube with heated cathode, in particular a double diode (63), is and that the cathode (78) of the rectifier tube is connected to one side of the additional capacitor and on the other side of this capacitor a pole of the voltage source (12) or the ground can be applied via a switch. 3. DC voltage converter according to claim 2, characterized in that the additional capacitor (93 in Fig. 2) is switched by a switch (32) during operation so that it is charged to the output DC voltage of the rectifier and that the switch is opened when the oscillator is switched off. 1 sheet of drawings © 70 »9W3O8 2.58