EP0348909B1 - On-load electromagnetic relay - Google Patents

Abstract

In a relay, power lead elements of the load circuit are conducted between a core and a yoke in order to improve the response behavior of the relay as an auxiliary excitation. The power lead element is a stranded conductor having one end connected to the appertaining terminal element and the other end directly connected to the contact element. Therebetween, a stranded conductor is conducted from one side of the coil to the other through a transverse bore in a coil member flange. In this way, the stranded conductor and, thus, and the load circuit is well insulated from the winding and, moreover, the power lead element requires no space in the actual winding space, simplifying the assembly thereof as a result.

Description

The invention relates to an electromagnetic load relay with a coil with a winding applied to a coil former between end flanges, a core axially arranged inside the winding, a yoke arranged outside the winding, which is connected to one end of the core, and a bearing on the yoke the free core end forming an armature working gap and with at least one switch-actuable switch contact which is connected via a current supply element to a connection element, the current supply element being passed at least once through the excitation flux circuit formed from the yoke, core and armature.

When switching electromagnetic load relays, the problem arises in certain applications that the excitation voltage drops while the armature is being tightened, as a result of which the armature may no longer be fully tightened and may flutter. Accordingly, the switch contact is not closed or only closed after repeated interruptions. This problem arises in particular in applications in which the voltage source for the field winding of the relay also simultaneously supplies the current for the load circuit, as is the case especially in motor vehicles. There, when switching on certain consumers, such as lamps or starters, very high inrush current peaks occur, which can lead to a breakdown of the battery voltage. This does not ensure reliable operation of the relay.

Another, but related problem arises when relays are controlled by mechanical switches, which often have long bounce times. Corresponding these bruises the relay is then switched on and off several times until it finally closes. This leads to high stress on the relay contacts, especially when the load has very high inrush current peaks. In extreme cases, e.g. B. when switching lamp currents, come to weld the contact pieces.

In a relay of the type mentioned at the outset, as is known from EP-A-0 231 793, provision is already made to carry out the load current between the coil and the yoke in such a way that additional excitation is induced in the same direction as the excitation of the winding. In this way, a reliable response of the relay can be guaranteed with appropriate dimensioning, even if the excitation voltage drops during the switch-on process or is temporarily interrupted due to a bouncing switch.

For the guidance of the load current around the excitation flux circuit, however, problems may arise with a small relay volume if there is only a very small gap between the winding and the yoke, so that a current supply element with a larger cross section can be carried out only with difficulty. It has also already been proposed to carry out a thin sheet between the winding and the yoke, which takes up substantially the entire length of the winding, as the current supply element, in order in this way to obtain the necessary cross section for the load current with the smallest possible height. In any case, however, there are assembly problems and problems with insulation between the load circuit and the winding.

The object of the invention is therefore to develop a relay of the type mentioned in such a way that additional excitation can be generated in the same direction as the excitation circuit by the load circuit, but at the same time an intervention in the actual winding space is avoided and reliable insulation of the current supply of the load circuit is ensured.

According to the invention, this object is achieved in that the current supply element is connected on one side of the coil to a connecting element, is guided through a transverse bore in a coil flange to the other side of the coil and is connected from there to the switching contact.

Through the transverse bore in the coil body flange, which is of course located in the area between the coil core and yoke, the desired additional excitation for the relay is generated without an additional element having to be installed in the actual winding space. The guidance in the coil body flange also ensures good insulation between the load circuit and the actual excitation circuit.

The additional excitation, which is generated by the current supply element guided through the flange, keeps the relay in the tightened state after the contact current has been switched on, so that even a brief interruption of the current due to the aforementioned bouncing switching on no longer causes the relay to drop out. In addition, this additional excitation promotes a rapid pulling through of the relay armature when switched on, so that high contact forces are reached quickly and the erosion of the contact material is kept within limits. After the initial current in the load circuit has decayed, for example after the filament of a switched lamp has been heated, the holding effect due to the additional excitation is so small that there is hardly any adverse effect when the relay drops out. Appropriate dimensioning can also determine how high the additional excitation should be. If necessary, it is also possible to split the power supply and lead only a part through the cross hole in the yoke.

The additional excitation described is mainly used for relays in which the armature and the yoke are traversed by the contact current. To make the additional excitation possible To make high, you can also increase the resistance across the armature and the yoke, for example, by not using the contact spring made of a good conductive material, but of poorly conductive spring material, such as. B. steel. This has the additional advantage that materials with better spring properties and higher fatigue strength can be used, these steel materials are usually also less expensive than the otherwise required, highly conductive copper alloys. The contact current is expediently guided through a strand which is welded directly onto the rivet head of the contact and runs through the transverse bore in the coil flange.

The invention is explained in more detail using an exemplary embodiment with reference to the drawing. The show

1 and 2 a relay designed according to the invention in two different perspective views.

The relay shown in Figures 1 and 2 has a known basic structure with a coil body 1 as a supporting element, on which a winding 4 is applied between two flanges 2 and 3. A core 5 is mounted axially within the coil. This core is connected at one end to an angular yoke 6, namely to the vertical leg 6a, while the horizontal leg 6b extends above the coil. At the free end of the yoke leg 6b, a flat anchor 7 is mounted, which is fastened to the yoke via an anchor spring 8. The extension of this armature spring 8 serves as a contact spring 8a and carries at its free end a contact piece 9 which is opposite a fixed mating contact piece 10. This mating contact piece 10 is fastened to a connecting element 10a, which is designed as a flat plug. A flat plug 6c designed as an extension of the yoke leg 6a serves as the connecting element for the contact piece 9 on the contact spring 8a. As coil connection elements plug elements 11 and 12 are also anchored in the base body.

Due to the structure described, the current is supplied to the contact element 9 via the yoke 6 and the armature 7. However, in order to provide a lower resistance for high currents, a stranded wire 13 is also provided, which is connected at one end directly to the flat plug 6c and to the other end is welded directly onto the contact piece 9. This copper strand 13 can, for example, carry up to 90% of the current, in particular when the armature spring 8 is made of relatively poorly conductive metal, such as spring steel. In order to also generate additional excitation to improve the attraction behavior of the relay via the contact current, this stranded wire 13 is guided through a transverse bore 3 a of the bobbin flange 3. This transverse bore runs in the horizontal direction with the relay in the normal installation position, namely between the coil core 5 and the yoke leg 6b. In order to obtain the support of the starting behavior of the relay described above by the additional excitation, the polarity must be selected accordingly when the load circuit is connected so that there is a positive superposition of the additional excitation with the coil excitation.

Claims (4)

1. Electromagnetic relay having a coil with a winding (4) applied to a coil member (1) between end flanges (2, 3),
   a core (5) disposed axially within the winding (4),
   a yoke (6) which is disposed outside the winding and which is connected to one end of the core (5),
   an armature (7) which is mounted on the yoke (6) and which forms, together with the free end of the core, a working air gap and
   having at least one switch contact (9) which is actuatable by the armature and which is connected via a power feed element (13) to a connecting element (6c), characterized in that the power feed element (13) is connected at one side of the coil (4) to a connecting element (6c), is passed through a transverse bore (3a) in a coil flange (3) to the other side of the coil (4) and is connected from there to the switch contact (9).
2. Relay according to Claim 1, characterized in that the power feed element is a stranded conductor (13) which connects the connecting element (6c) directly to the switch contact (9) secured on an armature spring (7).
3. Relay according to Claim 1 or 2, characterized in that the transverse bore (3a) in the coil member flange (3) is situated between the core (5) and the yoke (6).
4. Relay according to one of Claims 1 to 3, characterized in that the yoke (6) exhibits a first leg (6a) perpendicular to the base plane of the relay and a second leg (6b) extending parallel to the base plane above the coil (4), and in that the transverse bore (3a) in the coil member flange (3) is situated parallel to the base plane below the second yoke leg.

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