DE2241136C3 - Circuit arrangement for generating a constant DC voltage from a sampled DC voltage - Google Patents

Description

The invention relates to a circuit arrangement according to the preamble of patent claim.

A connection technology for teletype and data subscribers is already known in which the line current is independent of the length of the connection lines is kept constant by regulating the voltage of the power supply. In such systems variable voltage, the voltage must be floating. For low-loss generation of the changeable Voltage, a keyed control known per se can be used.

Often a constant opening is now required, for example to operate an amplifier. If the entire system works ungrounded, so must the Auxiliary voltage must be ungrounded. This auxiliary voltage could for example, can be generated via a converter. However, this possibility leads to an additional benefit Effort and should therefore be avoided. It would also be possible to use the constant auxiliary voltage from the changeable Discharge voltage. A typical stabilization circuit would, however, at a relatively high Control ratio (ratio of the adjustable minimum voltage to the adjustable maximum voltage) to lead to high losses.

The invention is based on the object of converting the voltage, which can be changed with the aid of a keyed control system to generate a constant DC voltage with little additional effort and good efficiency. This object is achieved by the measures characterized in the patent claim.

Details of the invention are explained with reference to the drawings,

F i g. I a timing diagram of various voltages occurring in the circuit arrangement and
F i g. 2 shows an embodiment of the invention.

ίο case considered here, the usual process is performed at a substantially constant amplitude and frequency of the conduction angle or the pulse duty factor changes, the control device St in Figure 2 attaches to an energized in the controllable voltage converter RW measuring resistor a current supplied to the current at the output of the rectifier G 1 The control device St sets the pulse duty factor of the controllable voltage converter RW as a function of this current. In this way, the output voltage of the rectifier G 1 is controlled such that the output current is constant irrespective of the load via a second secondary winding of the voltage transformer RW, the output voltage of the voltage converter R VVeinem second rectifier G 2 is fed in the auxiliary circuit for the constant DC voltage at the output of this In rectifier G 2 , the sampled direct voltage UE, which is shown in FIG. 1, appears. Different pulse duty factors are indicated by dashed lines. The sampled direct voltage UE

ίο is fed to the differentiating element D at the output of which the voltage UD arises. After the rectification in the rectifier (73, the voltage L / is fed to your integrating element / at the output of which the voltage UA appears. When the amplitude

H and the frequency of the sampled direct voltage UE are constant, the output voltage UA, i.e. the average direct voltage value, is constant .

Fluctuations in the amplitude and / or the frequency of the sampled direct voltage UE are each included linearly in the constancy of the auxiliary voltage generated and must, if necessary, be regulated normally, ie with losses.

1 sheet of drawings

Claims (1)

Claim; Circuit arrangement for generating a constant DC voltage from a DC voltage sampled with a constant repetition frequency and variable duty cycle in telecommunication systems, in particular in telex switching systems, characterized in that a differentiating element (D) converts the sampled direct voltage (UE) into pulses (UD) of both polarities, the duration of which at most is equal to the shortest pulse duration of the sampled direct voltage and that a downstream rectifier and integrating arrangement (G3,1) forms a mean value representing the constant direct voltage ft / A ^ from the number of pulses of both polarities