DE519744C - Maximum current time release - Google Patents

Description

GERMAN EMPIRE

ISSUED ON MARCH 4, 1931

REICH PATENT OFFICE

PATENT LETTERING

CLASS 21c GROUP

Maximum current time release Addition to patent 454857

Patented in the German Empire from January 19, 1929 The main patent started on September 4, 1925.

With patent 454857 a maximum current time release has become known, its mode of operation is characterized in that its magnet apart from that of the control current still flowed through a secondary winding that was chained to it in a transformer carries, which is loaded by a resistor with a positive temperature coefficient. The counter amp turns generated by the secondary winding and the tightening torque depend on the temperature of the resistor material. With increasing electricity heat losses, the resistance increases, resulting in a relative reduction in the counter amp turns and ultimately triggering the trip leads. Since it takes a certain amount of time for the resistor to heat up, a Delay in triggering brought about.

The greater the change in resistance, the better the release will work is in the secondary circuit. In order to achieve the limit values ο and oc for the resistance, either a complete short-circuit of the secondary circuit or its opening take place. For this purpose, institutions have already become known where instead of the Resistance in the secondary circuit is a thermal contact device that is exclusive is traversed by the secondary current and actuated. However, such devices have the major disadvantages that at Actuation of the thermally controlled contact device by the secondary current the same is de-energized for fractions of a second after responding by opening the contacts is, cools down again relatively quickly and, even before the actual release device is put into action, the contacts close again. So there is a pendulum action of the thermal contact device which causes a rattle of the release device.

The object of the invention is to overcome all of these disadvantages while achieving the above To avoid the effect. This is achieved by influencing the thermal Contact device takes place through the primary current.

An embodiment of the arrangement is shown in the figure, and the mode of operation the same will be described below: The magnet system consists of the core and the anchor.

'■' ■) The palm seeker has given as the inventor:

Ludwig Treubert in Dresden.

The core «carries the primary winding δ through which the main current flows and the secondary winding linked to it in a transformer. In the circuit of the former there is a bimetallic strip en e with the contact / which, when the bimetallic strip is cold, rests on its mating contact g and thus closes the circuit.

When the contacts are closed, a

ίο A maximum of counter amp turns is achieved, which prevents the maximum current release from responding. However, the number of turns of both windings behave in such a way that in the event of a direct short circuit in the primary circuit, supported by the increased scatter, the ampere turns generated by the primary winding _{outweigh the opposing secondary winding> in} such a way that the armature pulls immediately.

If the contacts controlled by the primary current through the thermal effect open, in this way the counter-clamp windings disappear and the trigger responds. Since the river change suddenly occurs in the magnet system, the annoying humming and fluttering of the Anchor, as can be observed with some triggers shortly before the response, is avoided. In addition, the sudden lent a large force that acts jerkily in the anchor torque a safe actuation of the release mechanism is guaranteed. This actuation is thereby regardless of the respective mechanical state of the release mechanism.

With currents up to the size of the normal current, the heating of the bimetallic strip is not sufficient to bend the strip in such a way that the contacts / and g interrupt the secondary circuit. Assuming that the setting device of the release, which has not been included in the figure for reasons of clarity, would be set to 1.6 times the normal current, and this current would be reached or exceeded in the primary circuit, the current heat losses in the bimetal strip will result in a temperature increase to have. The flexing strip causes the contacts / and g to open and the armature is tightened. Assuming the case that the overcurrent increases very gradually to 1.6 times the amount, the secondary circuit is opened after a certain time when the current rises above the normal value. However, the core can only be tightened when the 1.6-fold current is actually reached or exceeded, since currents below 1.6 amps are not sufficient to overcome the armature against the spring tension generated by the adjusting device.

This arrangement is particularly advantageous when the thermal time constant of the the item, e.g. B. a motor, is large and an equally large time constant of the 'thermal release device is required. - ν

Claims (1)

Claim: Maximum current time release according to patent 454857, characterized in that im secondary circuit with a thermally arranged in place of the resistor with a positive temperature coefficient controlled contact device that opens in the event of an overcurrent, the heating of the thermostat by the primary current directly or through a heating resistor through which it flows in whole or in part he follows. 1 sheet of drawings