CONNECTOR FOR A CIRCUIT BREAKER AND A DOWNSTREAM CONTACTOR, FEEDER WITH SUCH A CONNECTOR AND ARRANGEMENT WITH SUCH A FEEDER

Abstract

A connector for a circuit breaker and a downstream contactor has a one-piece configuration and facilitates an electrical connection between the circuit breaker and the downstream contactor. The connector includes at least one sensor, the connector includes an evaluation unit for measured values of the sensor, and the connector includes first contacts for the circuit breaker and second contacts for the downstream contactor, both acting in the same mating direction. A feeder for connecting a load and an arrangement having a distribution system, a load and a feeder, are also provided.

Claims

1. A connector for a circuit breaker and a downstream contactor, which comprises: the connector having a one-piece configuration; the connector facilitating an electrical connection between the circuit breaker and the downstream contactor; the connector including at least one sensor; the connector including an evaluation unit for measured values of said sensor; and the connector including first contacts for connecting the circuit breaker and second contacts for connecting the downstream contactor, said first and second contacts configured to be connected in the same mating direction.

2. The connector for a circuit breaker and a downstream contactor according to claim 1, wherein said at least one sensor is a sensor for current measurement.

3. The connector for a circuit breaker and a downstream contactor according to claim 2, wherein said sensor is at least one of a current transformer or a sensor for voltage measurement.

4. The connector for a circuit breaker and a downstream contactor according to claim 1, wherein said at least one sensor is disposed electrically between said first contacts and said second contacts in or on a main circuit.

5. The connector for a circuit breaker and a downstream contactor according to claim 1, wherein the connector includes an actuator for actuating the downstream contactor.

6. The connector for a circuit breaker and a downstream contactor according to claim 1, wherein the connector includes a communication interface.

7. The connector for a circuit breaker and a downstream contactor according to claim 1, wherein the connector includes a read plunger for a contactor position indicator.

8. The connector for a circuit breaker and a downstream contactor according to claim 1, wherein the connector includes an actuator for actuating a reversing contactor.

9. A feeder for connecting a load, the feeder comprising: a circuit breaker; a downstream contactor; and a connector according to claim 1; the connector forming at least one of a mechanical or electrical connection between the circuit breaker and the downstream contactor.

10. The feeder for connecting a load according to claim 9, wherein the connector, the circuit breaker and the downstream contactor are connected to one another in a tool-based manner.

11. The feeder for connecting a load according to claim 9, wherein the feeder is configured to supply power to an electric motor acting as the load.

12. An arrangement, comprising: a distribution system; a load; and a feeder for switching a load according to claim 9; the feeder being disposed between the distribution system and the load.

Description

BRIEF DESCRIPTION OF THE FIGURES

[0018] FIGS. 1A and 1B are respective diagrammatic perspective and elevational views of a connector according to the invention with a circuit breaker and a downstream contactor;

[0019] FIG. 2 is an elevational view of a connector according to the invention;

[0020] FIG. 3 includes elevational views of a circuit breaker and a downstream contactor and also a connector according to the invention prior to mounting; and

[0021] FIG. 4 is a block diagram of an arrangement including a distribution system, a load and a feeder according to the invention.

DETAILED DESCRIPTION OF THE INVENTION

[0022] Referring now to the figures of the drawings in detail and first, particularly, to FIGS. 1A and 1B thereof, there is seen an electrical connector 100 for a circuit breaker 150 and a downstream contactor 180. The connector 100 is of one-piece configuration, wherein the connector 100 facilitates the electrical connection between the circuit breaker 150 and the downstream contactor 180 and includes at least one sensor 200. In addition, the connector 100 includes an evaluation unit 210 for the measured values of the sensor 200, and first contacts 101 for the circuit breaker 150 and second contacts 102 for the downstream contactor 180 in the same mating direction.

[0023] In addition to the connector 100 and the circuit breaker 150 and the downstream contactor 180, there can be provision for a mechanical connector 160 that spaces the circuit breaker 150 from the downstream contactor 180 and can additionally serve as a contact surface for the connector 100.

[0024] In the illustrations in FIGS. 1A and 1B, the connector 100 according to the invention is mounted on the circuit breaker 150 and the downstream contactor 180.

[0025] FIG. 2 shows the connector 100 according to the invention and the mechanical connector 160. The connector 100 includes the first contacts 101, which electrically connect the connector 100 to the circuit breaker 150, and the second contacts 102, which electrically connect the connector 100 to the downstream contactor 180. The first contacts 101 and the second contacts 102 are in the same mating direction, which means that the connector 100 according to the invention can be connected to the circuit breaker 150 and the downstream contactor 180 simultaneously by using a single mounting movement.

[0026] The sensor 200 of the connector 100 according to the invention can be in the form of a sensor for current measurement, for example in the form of a current transformer, and/or in the form of a sensor for voltage measurement. The sensor 200 can be disposed electrically between the first contacts 101 and the second contacts 102 in or on the main circuit.

[0027] The connector 100 according to the invention can moreover include an actuator 110 for actuating the downstream contactor 180, and also a communication interface 119. By way of example, the communication interface 119 can be in the form of a plug or socket for a wired connection; the communication interface 119 can also set up a wireless radio connection by using typical protocols such as Zigbee, WiFi or others.

[0028] Further elements on the connector 100 according to the invention can be a read plunger 111 for a contactor position indicator and an actuator 115 for actuating a reversing contactor.

[0029] FIG. 3 shows the mounting of the connector 100 according to the invention on the circuit breaker 150 and the downstream contactor 180. As a result of the first contacts 101 and the second contacts 102 of the connector 100 being formed in the same mating direction, the connector 100 according to the invention can be mounted on the circuit breaker 150 and the downstream contactor 180 by using a single mating movement. In line with the illustration in FIG. 3, this means that the connector 100 according to the invention can be pushed onto or plugged into the circuit breaker 150 and the downstream contactor 180 in one movement to the left.

[0030] FIG. 4 shows an arrangement 2000 including a distribution system 2100, a load 1000 and a feeder 2001 for switching a load 1000. The feeder 2001 in turn includes a circuit breaker 150, a downstream contactor 180 and a connector 100 according to the invention, wherein the connector 100 forms the mechanical and/or electrical connection between the circuit breaker 150 and the downstream contactor 180.

[0031] The load 1000, for example a motor, is electrically disposed on the downstream contactor 180.

[0032] The connector 100 according to the invention includes a sensor 200 and an evaluation unit 210.

[0033] The feeder 2001 can be configured in such a way that the connector 100, the circuit breaker 150 and the downstream contactor 180 are connected to one another in a tool-based manner.

[0034] In the arrangement 2000, the feeder 2001 is disposed electrically between the distribution system 2100 and the load 1000 by virtue of the distribution system 2100 being electrically connected to the circuit breaker 150 and the load 1000 being electrically connected to the downstream contactor 180.

[0035] The electronics of the connector 100 according to the invention, in particular the evaluation unit 210, can be disposed within the connector 100 in such a way that a relatively low and controllable temperature profile acts on them. This is the only meaningful way of using electronics in the connector 100 or in the feeder 2001.

[0036] The mating direction of the main current terminals, such as the first contacts 101 and the second contacts 102, is the same, specifically 90 to the device arrangement. All other electrical connections are also disposed in this same mating direction, such as the actuator 110 for actuating the downstream contactor 180. This is the only way to create a system that can be easily integrated into existing systems. Additionally, the contactor switching direction is the same as the mating direction, which allows simple but important reading of the contactor position by way of the read plunger 111.

[0037] The mating direction from the front to the circuit breaker 150 and the downstream contactor 180 allows compensation for tolerances in the feeder 2001. This compensation for tolerances can be easily and reliably ensured by bending up the first contacts 101 and the second contacts 102 for the main current path. Another advantage of this arrangement is that the footprint of the feeder 2001 according to the invention remains the same and almost all existing accessories, such as all attachment modules, feed systems, etc., can continue to be used. It is also possible to upgrade all spring-loaded feeders sold to date.