DE887059C - Circuit arrangement for fast charging of a capacitor using a voltage divider - Google Patents

Description

In circuit engineering it is sometimes necessary to use a capacitor to be charged via a voltage divider, especially when it comes to devices that are to be connected to several voltages as required.

So far one has to: for this purpose voltage dividers made of ohmic resistors used, but have a relatively large power consumption and a generate appropriate heat. This is especially true in encapsulated telecommunications equipment very undesirable.

According to the invention, the capacitor is charged for a short time parallel to one of several (preferably two) as a voltage divider in series switched glow lamps and then discharged via the useful circuit. A circuit, in which capacitors are parallel to glow lamps connected as voltage dividers, is known, but are used in the known arrangement in which it is Voltage equalizer acts, the capacitors only to the drainage of the To enable charge and discharge alternating currents.

Glow lamp voltage dividers are known per se, but bring them their use for capacitor charging has particular advantages, as shown by the the following embodiment is set out.

In the drawing, two glow lamps G1 and G2 are connected to voltage. In parallel with the glow lamp G1, a capacitor C is switched through a contact k2, by a contact hl at a different point in time, for example via a relay or a magnet R, is discharged. In one application this circuit acts they are electric teletypewriters with contacts k1 and k2 through Cam are controlled and the discharge of the capacitor C to operate the Printing magnet is used.

The charging process is as follows: The contact k2 causes the Capacitor C connected in parallel to glow lamp G1, while connected in series full voltage of G1 and G2 is present. This increases the voltage on the glow lamp G1 zero. The glow lamp goes out and will only ignite again when. The capacitor is charged to ignition voltage.

First of all, the capacitor C is present behind the glow lamp G2 the full voltage, and the glow lamp G2 reaches an overcurrent that is slow subsides. It is beneficial that .the inherent resistance of the lamp in the event of overload decreases very sharply. The charging takes place via a resistor that is lower is than the continuous resistance of the glow lamp, i.e. correspondingly faster. As soon the ignition voltage of the glow lamp G1 is reached, it ignites again. The condenser can discharge through R when the contact k1 closes. The process repeats themselves.

It is useful to choose the ignition voltage of the glow lamps so that that it corresponds approximately to the full charge voltage of the capacitor. While z. B. for a voltage divider with ohmic resistance, a self-consumption of the voltage divider with 12, watts to charge a capacitor of 8, u was required, one could get by with the glow lamp voltage divider with an internal consumption of 3 watts.

Claims (2)

PATENT CLAIMS: i. Circuit arrangement for quickly charging a Capacitor via voltage divider, characterized in that the capacitor to its charging briefly parallel to one of several (preferably two) than Voltage divider in series connected glow lamps: placed and then across the useful circuit is discharged. 2. Circuit arrangement .according to claim i, characterized in that that: the ignition voltage of the glow lamp (GI) connected in parallel to the capacitor (C) is chosen to be approximately equal to the charging voltage of the capacitor. Referred publications: German patent specifications No. 573 633, 574 924-