DE102020202970B4 - High voltage contactor - Google Patents

Abstract

High-voltage contactor (1), comprising a contact bridge (3) with two main contacts (7), two high-voltage contacts (6) and an armature (4), the high-voltage contactor (1) being designed such that in a rest position the main contacts (7) of the high-voltage contacts (6) are separated and in a switching position a main contact (7) contacts a high-voltage contact (6), so that the high-voltage contacts (6) are electrically connected via the contact bridge (3), with each main contact (7) having an auxiliary contact (8 ) is assigned, the auxiliary contacts (8) being electrically connected to the contact bridge (3), the auxiliary contacts (8) being resiliently mounted, the auxiliary contacts (8) having a greater electrical resistance than the main contacts (7), whereby the High-voltage contactor (1) is designed in such a way that when the main contacts (7) are separated from the high-voltage contacts (6), the auxiliary contacts (8) remain connected to the high-voltage contacts (6) or are separated from the high-voltage contacts (7) with a time delay to the main contacts (7). 6), the main contact (7) being arranged concentrically around its auxiliary contact (8).

Description

The invention relates to a high-voltage contactor, in particular a high-voltage contactor for a traction network of an electric or hybrid vehicle.

The functions of high-voltage contactors in the field of electromobility include conducting and switching currents up to the kiloampere range at DC voltages of 400 V and more, as well as the safe isolation of overcurrents in the event of a fault. A problem with high-voltage contactors is so-called levitation, i.e. the opening of the contact due to the current flowing through the contact. The resulting levitation force counteracts the contact closing force. The repulsion occurs because the contacts do not touch each other over the entire surface, but rather the current has to flow through a narrow point. The opposing current directions then create mutually repelling magnetic fields. A problem with levitation is that the contacts can stick due to arcing.

From the DE 10 2012 215 344 A1 a starter relay for a starter of a motor vehicle is known with contact bolts, which are connected via a movable contact bridge when the starter relay is actuated, the contact bridge comprising a main contactor, with at least one elastic preliminary contactor being additionally provided. The advance contactor is designed to cause the contact bolts to be connected before the main contactor when the starter relay is actuated. The preliminary contactor is preferably of higher resistance than the main contactor.

From the DE 18 943 72 U a contactor is known, comprising a contact bridge with two main contacts, two connection contacts and an actuator, the contactor being designed such that in a rest position the main contacts are separated from the connection contacts and in a switching position each main contact contacts a connection contact, so that the connection contacts are connected via the contact bridge. Each main contact is assigned an auxiliary contact, with the auxiliary contacts being spring-mounted. The auxiliary contacts have a greater electrical resistance than the main contacts, with the contactor being designed in such a way that when the main contacts are separated from the connection contacts, the auxiliary contacts remain connected to the connection contacts or separate from the connection contacts with a time lag to the main contacts.

From the DE 37 18 634 A1 is an electromagnetic switch with fixed connections, a movable electrically conductive armature with contact sections facing the connections and with an electromagnet that can be connected to a power supply via a switch. Holes are provided in the fixed connections, with electrically conductive pins being arranged on insulating disks within the holes, which can come into contact with the contact sections of the armature and which are further connected to the gate and the connection of a thyristor. This is activated when the switch is pressed and suppresses the formation of an arc.

From the DE 44 19 029 A1 an electromechanical interrupter device with arc switching with blowing arrangements is known.

From the DE 539 555 A an electrical multiple switch with main and auxiliary contacts is known, the distance between the main and auxiliary contact being at least one contact width of the main contact.

The invention is based on the technical problem of creating a high-voltage contactor in which the problem of levitation is reduced and has a compact structure.

The solution to the technical problem results from a high-voltage contactor with the features of claim 1. Further advantageous embodiments of the invention result from the subclaims.

For this purpose, the high-voltage contactor comprises a contact bridge with two main contacts, two high-voltage contacts and an armature, the high-voltage contactor being designed such that in a rest position the main contacts are separated from the high-voltage contacts and in a switching position one main contact contacts a high-voltage contact, so that the high-voltage contacts via the Contact bridge are electrically connected. Each main contact is assigned an auxiliary contact, the auxiliary contacts being electrically connected to the contact bridge, the auxiliary contacts being resiliently mounted. The auxiliary contacts have a greater electrical resistance than the main contacts. The high-voltage contactor is designed in such a way that when the main contacts are separated from the high-voltage contacts, the auxiliary contacts remain connected to the high-voltage contacts or separate from the high-voltage contacts with a time lag to the main contacts. This prevents levitation or reduces its effects. If the main contacts are lifted, the current flow is not abruptly interrupted, but is maintained via the auxiliary contacts, although this is reduced by the higher resistance. This causes arcing initially prevented and the levitation forces reduced so that the main contacts can return to the switching position. However, if the levitation force is so great that the auxiliary contacts also break off, then the arc is at least not that large. Another advantage is that the high-voltage contactor also reduces the overvoltages that occur with inductive loads and thus the formation of arcs when disconnecting, i.e. switching from the switching position to the rest position.

The main contact is arranged concentrically around its auxiliary contact. This allows for a very compact design.

In one embodiment, the high-voltage contactor is designed such that when changing from the rest position to the switching position, the auxiliary contacts contact the high-voltage contacts in front of the main contact, so that the inrush currents, in particular when switching on capacitive loads, are effectively limited.

In a further embodiment, the auxiliary contacts protrude above the main contacts in the rest position and/or the high-voltage contacts have a projection in the area of the auxiliary contacts, so that the desired behavior can be implemented very easily in terms of design.

In a further embodiment, the auxiliary contacts are made of a different material than the main contacts. This means that the higher-resistance resistance can be implemented very easily. Furthermore, the auxiliary contact can then be made of a particularly robust material with regard to arcing.

• 1 ein Hochvoltschütz in einer schematischen Seitenansicht in einer Ruhelage,
• 2 eine perspektivische Darstellung eines Hauptkontaktes mit Hilfskontakt,
• 3 das Hochvoltschütz in einer Schaltstellung,
• 4 das Hochvoltschütz mit abgehobenen Haupt- und Hilfskontakten und
• 5 ein Hochvoltschütz in einer alternativen nicht-anspruchgsgemäßen Ausführungsform in einer Ruhelage.

The invention is explained in more detail below using preferred exemplary embodiments. The figures show:

• 1 a high-voltage contactor in a schematic side view in a rest position,
• 2 a perspective view of a main contact with auxiliary contact,
• 3 the high-voltage contactor in a switching position,
• 4 the high-voltage contactor with lifted main and auxiliary contacts and
• 5 a high-voltage contactor in an alternative embodiment not claimed in a rest position.

The high-voltage contactor 1 comprises a housing 2, a contact bridge 3, an armature 4, a coil 5, two high-voltage contacts 6, two main contacts 7 and two auxiliary contacts 8, which are mounted on springs 9. The coil 5 has electrical connections 10 which are led out of the housing 2. The anchor 4 is resiliently mounted. When the spring 9 is relaxed, the auxiliary contacts 8 protrude beyond the main contacts 7. Furthermore, the high-voltage contacts 6 each have a projection 11 on the contact areas of the auxiliary contacts 8. The auxiliary contact 8 is concentrically enclosed by its main contact 7, with the main contact 7 being cylindrical (see 2 ). If the high-voltage contactor 1 is now switched from the rest position to the switching position by energizing the connections 10, the armature 4 with the contact bridge 3 is moved upwards. Due to the fact that the auxiliary contacts 8 protrude above the main contacts 7, the two auxiliary contacts 8 contact the high-voltage contacts 6 in front of the main contacts 7 via the projection 11. The auxiliary contacts 8 have a greater resistance than the main contacts 7. The auxiliary contacts are 8 preferably made of a different material than the main contacts. The material of the auxiliary contacts is preferably particularly heat-resistant in order to prevent burning caused by arcs. If the auxiliary contacts 8 now contact the high-voltage contacts 6, a reduced inrush current flows via the high-voltage contacts 6 and the contact bridge 3 to a load (not shown) due to the higher resistance of the auxiliary contacts 8. If the armature 4 then moves further upwards during the switching process, the springs 9 are compressed and the main contacts 7 contact the high-voltage contacts 6. This is in 3 shown. In terms of circuitry, the main contacts 7 are then parallel to the auxiliary contacts 8, so that almost all of the current flows through the main contacts 7 due to the lower resistance (geometry and material). If levitation now occurs, the main contacts 7 are lifted off the high-voltage contacts 6 by the levitation forces, but the auxiliary contacts 8 remain in contact with the high-voltage contacts 6, so that the current flow commutates to the auxiliary contacts 8. Due to the resistance, this leads to a reduction in the current flow and thus a reduction in the levitation forces, so that the armature 4 can press the main contacts 7 against the high-voltage contacts 6 again. However, if the levitation forces are too great, the connection to the auxiliary contacts 8 will also be broken. This can lead to an arc, which can occur 4 is shown. However, this is locally limited to the auxiliary contacts 8 and is less critical since the auxiliary contacts 8 are made of a heat-resistant material.

A similar behavior occurs when regularly switching from the switching position to the rest position with an inductive load. Due to the fact that the auxiliary contacts 8 still temporarily take over the current, the induced overvoltage is reduced and the possible arc is largely limited to the auxiliary contacts 8. The lead 11 exists preferably made of the same material as the auxiliary contact 8.

The advantage of the embodiment according to 1 until 4 is that the design is very compact. The disadvantage is that due to the spatial proximity of the main contacts 7, they could also be stressed. Furthermore, the compact design makes it difficult to provide further countermeasures against arcing.

In the 5 An alternative embodiment is shown in which the main contact 7 and auxiliary contact 8 are spatially spaced apart, the distance A having several contact widths B of the main contact. In addition, the high-voltage contactor 1 has 8 quenching plates 12 and blowing magnets 13 in the area of the auxiliary contacts, which are only shown for the left auxiliary contact 8 for reasons of clarity. This allows the effects of arcs on the main contacts 7 to be excluded.

Reference symbol list

1

High voltage contactor

2

Housing

3

Contact bridge

4

anchor

5

Kitchen sink

6

High voltage contact

7

Main contact

8th

Auxiliary contact

9

Feather

10

electrical connections

11

head Start

12

blotter

13

Blow magnet

A

Distance

b

Contact width

Claims (4)

High-voltage contactor (1), comprising a contact bridge (3) with two main contacts (7), two high-voltage contacts (6) and an armature (4), the high-voltage contactor (1) being designed such that in a rest position the main contacts (7) of the high-voltage contacts (6) are separated and in a switching position a main contact (7) contacts a high-voltage contact (6), so that the high-voltage contacts (6) are electrically connected via the contact bridge (3), with each main contact (7) having an auxiliary contact (8 ) is assigned, the auxiliary contacts (8) being electrically connected to the contact bridge (3), the auxiliary contacts (8) being resiliently mounted, the auxiliary contacts (8) having a greater electrical resistance than the main contacts (7), whereby the High-voltage contactor (1) is designed in such a way that when the main contacts (7) are separated from the high-voltage contacts (6), the auxiliary contacts (8) remain connected to the high-voltage contacts (6) or are separated from the high-voltage contacts (7) with a time delay to the main contacts (7). 6), the main contact (7) being arranged concentrically around its auxiliary contact (8). High voltage contactor Claim 1 , characterized in that the high-voltage contactor (1) is designed such that when changing from the rest position to the switching position, the auxiliary contacts (8) contact the high-voltage contacts (6) before the main contacts (7). High-voltage contactor according to one of the preceding claims, characterized in that the auxiliary contacts (8) protrude beyond the main contacts (7) in the rest position and/or the high-voltage contacts (6) have a projection (11) in the area of the auxiliary contacts (8). High-voltage contactor according to one of the preceding claims, characterized in that the auxiliary contacts (8) are made of a different material than the main contacts (7).

Images