DE2050034C2 - Electronic regulated DC voltage converter - Google Patents

Description

The invention relates to an electronic Regulated DC voltage converter of the type specified in the preamble of claim 1.

From US-PS 34 00 319 is an electronic regulated DC-DC converter of the type specified in the preamble of claim I known, in which the Feedback link is an ohmic resistor, upper the counter-voltage pulses from the primary winding of the converter transformer during the blocking phase of the Converter block the transistor cascade. However, the oscillation frequency of the known transducer is essential on the data of the oscillating transformer used and the dimensioning of the oscillating transistor dependent, so that in this case it is not möjr'ich to have a ίο for the core material used in the oscillating transformer determine the optimal vibration frequency.

The output voltage of the known DC voltage converter is regulated by a corresponding one Changing the oscillation frequency of the converter is by using the first transistor of the transistor cascade as variable resistor is used in the base branch of the second transistor and is controlled in the ratio of the comparison voltage.

The invention is therefore based on the object of an embodiment for an electronic controlled To find DC-DC converter of a type specified in the preamble of claim 1, its Vibration frequency is almost independent of the design despite a simple design of the converter transformer of the converter transformer can be determined within wide limits.

This object is achieved according to the invention by the circuitry measures specified in the characterizing part of claim 1.
In a DC voltage converter according to the invention, essentially only the feedback element of the oscillating circuit for the charging and discharging tents, ie for the pulse times, is relevant in an advantageous manner. Since the feedback element can be dimensioned within very wide limits without endangering the operational safety of the circuit, the oscillation frequency can also be set within wide limits, so that the oscillation circuit can always be adapted to the optimal transmission frequency of the converter transformer.

Another advantage is the favorable pulse width / pulse pause ratio of about 1: 1, which the DC-DC converter according to the invention generates.

Advantageous refinements of the invention are specified in the subclaims.

The embodiment according to claim 3 has the advantage that a DC voltage converter according to the invention even with a very low supply voltage of, for example, 2 volts, a good one Has efficiency and oscillates flawlessly.

With the measures according to claim 5 is advantageous Way achieved that the oscillation frequency of the converter is not changed by the voltage regulation will.

The invention is described below with reference to an advantageous exemplary embodiment shown in the drawing explained in more detail. The DC / DC converter according to the invention shown in the drawing is for example for generating a high operating voltage as a supply voltage for a Gelger-Müller counter tube Used in a radiation warning and / or radiation measuring device.

A high voltage part 25 of the DC voltage converter comprises the low voltage winding II and the High-voltage winding III of a converter transformer 26. a charging rectifier 3 and a high-voltage Spelcher capacitor 5. A GM counter tube and its in series is connected to the storage capacitor 5 as load 6 to this lying work resistance connected.

At the low-voltage winding II of the converter transformer 26 is an electronic oscillating circuit 27 and a comparison and control circuit 28. Die Oscillating circuit, which is fed from a battery 2, consists of two transistors 29 connected in cascade and 30, resistors 31 to 33. Diodes 34 and 35 and a feedback element with a capacitor 36 and a resistor 37. The actual comparison circuit consists of a rectifier 4, a storage capacitor 7 and a voltage divider with resistors 38 and 39 formed while the control circuit consists of a Zener diode 40, a switching transistor 41 and a resistor 42.

The charging phase of the oscillating circuit 27 is introduced into the base of the first transistor 29 of the cascade with an auxiliary current that is kept small by the resistor 32. As a result of the cascade connection, the second transistor 30 also becomes somewhat conductive, as a result of which the current now flows into the base of the first transistor 29 via the second transistor 30 and the feedback branch. As a result, both transistors switch to the fully conductive state and remain in this state until the capacitor 36 in the feedback branch has been charged and the charging current is no longer sufficient to keep the first transistor open. The second transistor 30 thereby throttles the current through the low-voltage winding II of the converter transformer, which serves as a working resistor the counter voltage completely blocks the transistor cascade 29, 30 via the feedback branch and at the same time charges the storage capacitor 7 of the comparison circuit via the rectifier 4. The capacitor 36 in the feedback branch is now discharged via the diode 34 until the discharge current has the effect of the starting current via the resistor 32 is no longer suppressed and a new charging process ₀ nec the diode 34 is initiated. the same time protects the input of the first transistor 29 from the high voltage values of the reverse voltage peak.

The resistors 31 and 33 dampen the influence of the parameter spreads and the temperature response of the Transistors, in particular the diode 34, which are opposite in parallel to the input of the second transistor 30 Is switched has a high temperature stabilizing influence on the oscillating circuit.

It is very advantageous if the second transistor 30 of the transistor cascade is a silicon transistor of the NPN type which has a very low residual collector-emitter voltage even with a high collector current and as a result, only small losses occur at this transistor during power transmission. Because of the demand after a small residual current in the blocking state, the first transistor 29 should also advantageously be a silicon transistor (of the PNP type).

In the comparison circuit arises on the storage capacitor 7 from the low-voltage winding II due to the counter-voltage pulses a direct voltage proportional to the high voltage on the high voltage capacitor 5, which is subordinated by the voltage divider 38, 39 'iei. As soon as the voltage at the tap of the voltage divider 38, 39 exceeds the breakdown voltage of the Zener diode 40, a current flows through this zener diode. the base of transistor 41 and diode 34. The transistor 41 becomes conductive as a result, leads the Charging current of the feedback branch 36, 37 and sets the oscillating circuit 27 out of operation until the voltage at resistor 38 has dropped below the Zener voltage of diode 40. As a result of the small The hysteresis of the switch-on and switch-off points of the Zener diode 40 are the fluctuations in the high voltage on the high-voltage capacitor 5 very low.

At the connection points AA of the circuit, ie to the low voltage winding II of the converter transformer 26, a further rectifier circuit 43 for a direct current load 44, for example as a direct voltage supply for a booster circuit, can be connected. In the exemplary embodiment shown, the rectifier circuit 43 consists of a rectifier 45 and a storage capacitor 46.

1 sheet of drawings

Claims (5)

Patent claims: 1. Electronic regulated DC voltage converter with the primary winding of a converter transformer and a cascade circuit of two oscillating circuits containing complementary transistors, in which the base of the first transistor of the cascade over a rock coupling element with the to the Primary winding of the converter transformer connected collector of the second transistor of the Cascade connected and between the emitter of the first transistor and one of the DC-DC converter feeding DC voltage source an emitter resistor and between the base of this transistor and the other pole of the DC voltage source, a further resistor is arranged and in which also has a diode parallel to the input of the first transistor of the cascade in the direction of flow the base-emitter path of the first transistor is in the opposite direction of flow, furthermore with a with its output to the base of the first transistor of the cascade control circuit connected to the Control of the oscillating circuit from a formed in the control circuit, for at the output of the DC voltage converter located DC voltage proportional comparison voltage a control signal generated, characterized in that the feedback member from the series circuit of a There is a capacitor (36) and a resistor (37). 2. DC voltage converter according to claim 1, characterized in that? parallel to the base-emitter path of the second transistor (30) of the cascade has a diode (35) whose direction of flow is that of the Base-emitter path of the second transistor is opposite. 3. DC voltage converter according to claim 1 or 2, characterized in that the first transistor (29) of the cascade (29, 30) a silicon transistor from PNP type and the second transistor (30) is a silicon transistor of the NPN type. 4. DC voltage converter according to one of claims 1 to 3, characterized in that the The input of the control circuit (28) is connected to the primary winding (II) of the converter transformer (26) Is. 5. DC voltage converter according to one of claims I to 4, characterized in that a Comparison circuit for generating the comparison voltage in the control circuit (28) from the series circuit a rectifier (4) and a storage capacitor (7) consists that at the tap of a voltage divider arranged parallel to the Spetcher capacitor (38. 39) the series connection of a reverse-biased Zener diode (40), the base-emitter path a transistor (41) and the parallel diode (34) to the input of the first transistor (29) connected.