Switch, in particular power switch, for low voltages

Abstract

A switch is disclosed, in particular a power switch, for low voltages. The switch includes mechanically separable contact elements, in abutment when the switch is closed and via which a current to be monitored flows through the switch, an electronic trigger unit, which triggers a respective contact mechanics unit if a current condition is satisfied. In the event of triggering, the contacts are separated and the switch is switched on via the contact mechanics unit. A supply unit is included to extract a first electric energy from the current flowing through the switch to supply the trigger unit with energy. To guarantee energy supply even when switching to a short-circuit, the contact mechanics unit is coupled to a conversion unit, which converts a portion of the mechanical energy to be provided during switching-on into a second electric energy that supplies the trigger unit with electric energy during switching-on.

Claims

1. A breaker, comprising: a fixed contact and a displaceable contact, the fixed contact and the displaceable contact being mechanically separable contact elements, in abutment when the breaker is closed and via which a current to be monitored can flow through the breaker; a contact mechanics unit to switch on the breaker and to separate the contact elements in the event of triggering, wherein the contact mechanics unit is in the form of a breaker latching mechanism which is tensioned using a spring energy store and wherein the breaker latching mechanism has a breaker shaft which is mounted rotatably about the longitudinal axis of the breaker latching mechanism and in order to tension the breaker latching mechanism, the breaker shaft is rotated about the longitudinal axis of the breaker shaft, against the force of the spring energy store in the rotational direction of the breaker shaft, and latched in its end position; an electronic trigger unit to trigger the contact mechanics unit upon a current condition being met, wherein, in the event of triggering, the contact elements are separated and the breaker is activated via the contact mechanics unit; a supply unit to draw a first electric power from the current flowing through the breaker via a power transformer, to supply the electronic trigger unit with power during running operation; and an electric generator, including a stationary and a displaceable part, arranged at the breaker shaft such that the displaceable part is directly fixed to the breaker shaft, the electric generator being coupled to the contact mechanics unit and configured to convert some of the mechanical energy to be applied during switching-on into a second electric power to supply the trigger unit with electric power during switching-on, and wherein a rotary movement of the breaker shaft occurring during switching-on of the breaker leads to the conversion of mechanical rotary-movement energy into the second electric power.

2. The breaker of claim 1, wherein the generator charges an energy store.

3. The breaker of claim 2, wherein the energy store is designed as a capacitor.

4. The breaker of claim 1, wherein the second electric power is sufficient to check during switching-on whether the current condition has been met and, if the current condition has been met, to trigger the breaker.

5. The breaker of claim 2, wherein the second electric power is sufficient to check during switching-on whether the current condition has been met and, if the current condition has been met, to trigger the breaker.

6. The breaker of claim 3, wherein the second electric power is sufficient to check during switching-on whether the current condition has been met and, if the current condition has been met, to trigger the breaker.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention is explained once again below with reference to the enclosed FIGURES on the basis of example embodiments. In these example embodiments the same components in different FIGURES are provided with identical reference numbers. In the FIGURES:

(2) FIG. 1 shows a schematic diagram of an example embodiment of a breaker.

DETAILED DESCRIPTION OF EXAMPLE EMBODIMENTS

(3) At least one embodiment provides that an electric generator comprising a stationary and a displaceable part is arranged at the breaker shaft such that the displaceable part is fixed to the breaker shaft, wherein the generator converts some of the mechanical energy to be applied during switching-on into electric power which supplies the trigger unit with power in each case during switching-on.

(4) In order to be able to better use the electric power generated by the generator, what is proposed is that the generator charges an energy store.

(5) In the simplest case, the energy store is designed as a capacitor.

(6) The generator is rated such that the generated electric power is in each case sufficient to check during switching-on whether the current condition has been met and, if the current condition has been met, to trigger the breaker.

(7) The invention is described in more detail below on the basis of an example embodiment. As shown in FIG. 1, the breaker 10 is designed as a power circuit breaker for low voltages and has (generally for each current phase) in each case a contact which is formed from mechanically separable contact elements in the form of contact pieces 11, 12. One of the two contact pieces is a stationary contact 11 while the other contact 12 is arranged in a displaceable manner. The contact pieces are in abutment when the breaker 10 is closed. The current flows through the breaker 10 via connection lugs and the contact pieces 11, 12 which are in abutment.

(8) An electronic trigger unit 15 acquires the electric power 26 flowing in each case through the breaker 10 via a power transformer 14 (in particular current transformer). If said electric power exceeds a predefined power threshold, that is to say a predefined power condition (or current condition) is met, the trigger unit 15 triggers and the contact pieces 11, are separated from one another, that is to say the displaceable contact element 12 is lifted off the stationary contact element 11.

(9) The contact pieces 11, 12 are separated by way of a contact mechanics unit 16 in the form of a breaker latching mechanism which is tensioned using a spring energy store (energy store) 17. The breaker latching mechanism has a breaker shaft 18 which is mounted rotatably about the longitudinal axis thereof. In order to tension the breaker latching mechanism, the breaker shaft 18 is rotated about the longitudinal axis thereof, against the force of the spring energy store 17, and latched in its end position.

(10) In order to supply power to the trigger unit 15 during running operation, a supply unit 20 is used. This draws a (relatively small) portion of the electric power which flows through the breaker 10. An electromagnetic generator 21 is arranged at the breaker shaft 18. The generator 21 comprises a stationary part 22 and a displaceable part 23, wherein the latter is fixed to the breaker shaft 18.

(11) In this way, a rotary movement 19 of the breaker shaft 18, as occurs during switching-on of the breaker 10, leads to the conversion of mechanical rotary-movement energy into electric power, that is to say that, during switching-on, in each case some of the mechanical energy to be applied is converted into electric power.

(12) The generated electric power 27 charges an energy store 24 in the form of an electric capacitor 25.

(13) Generator 21 and capacitor 25 are dimensioned such that the electric power 27 is in each case sufficient to allow the trigger unit 15 to check during switching-on whether the current condition has been met and, if the current condition has been met, to trigger the mechanically pre-tensioned breaker latching mechanism and hence to trigger the breaker 10.