DE102014224581A1 - Electromagnetic relay, in particular starter relay for a starting device - Google Patents

Abstract

An electromagnetic relay has two radially superimposed windings whose winding wires have the same non-round cross-sectional shape but a different cross-sectional area.

Description

The invention relates to an electromagnetic relay, in particular a starter relay for a starting device, according to the preamble of claim 1.

State of the art

From the DE 10 2010 001 895 A1 An electromagnetic starter relay is known, which is used in a starting device for an internal combustion engine. By means of the starter relay, a starter pinion is adjusted between a retracted disengagement position and an advanced in-line position in which the starter pinion meshes with a ring gear of the engine to be started. About an electric starter motor, the starter pinion for starting the internal combustion engine is rotated.

The starter relay has in a housing on a first relay winding, which has the function of a pull-in winding and the field adjusts a lifting armature, which is coupled via a fork lever with the starter pinion. When energizing the relay winding of the lifting armature is pulled axially into the encompassing winding.

On the first relay winding, a second relay winding is wound, which has the function of a switching device for switching on the electric starter motor. When the second relay winding is energized, the lifting armature is adjusted by an additional amount and actuates a switching armature, whereby the electric circuit of the starter motor is closed. The first and the second relay winding have different cross sections, between the two relay windings is an intermediate layer which forms a smooth surface for the radially outer, second relay winding, so that the second relay winding can be wound in an orthocyclic manner, in which the turns at least approximately orthogonal to the longitudinal axis of the winding support.

Further known are starter relays for starting devices, which have on a winding support a first winding, which has the function of a pull-in winding, and axially spaced a second winding, which acts as a holding winding. To move the starter pinion, both windings are energized, whereby the lifting armature is adjusted and the starter pinion is meshed into the ring gear of the internal combustion engine. Subsequently, only the holding winding is energized to hold the lifting armature. Such a starter relay is used for example in the DE 10 2006 033 174 A1 or in the WO 2012/040109 A1 described.

Disclosure of the invention

The invention is based on the object to provide a cost-effective and compact design electromagnetic relay with two radially superimposed windings.

This object is achieved with the features of claim 1. The dependent claims indicate expedient developments.

By means of the electromagnetic relay according to the invention, an electromagnetic field for adjusting a lifting armature can be generated. The electromagnetic relay is used, for example, as a starter relay for a starting device for an internal combustion engine to adjust a starter pinion between a non-functional position and an advanced engagement position with the ring gear of the internal combustion engine. In the engaged position, the starter pinion is driven by an electric starter motor, whereby the internal combustion engine is started. The lifting armature of the starter relay is kinematically coupled to the starter pinion, for example via a fork lever.

There are also applications of the electromagnetic relay in other applications, regardless of starting devices.

The relay has two windings which are arranged radially one above the other on a winding support. The windings can advantageously be energized independently of each other and each generate an electromagnetic field which acts on the same lifting armature and this adjusted against the force of a return spring. The first winding, for example, has the function of a pull-in winding in order to adjust the lifting armature against the force of a positioning spring from the rest position into a deflected position. The second winding has an additional function, for example, as a retaining spring or winding to hold the lifting armature in the deflected position, in which the pull-in winding is advantageously no longer energized. However, it is also possible, for example, a function of the second winding for amplifying the magnetic field of the first winding, to e.g. to deflect the lifting armature even further axially and to adjust it into a contact position with a switching-on device and to close an electric circuit, for example for the starter motor of a starting device.

The radially inner winding has, for example, the function of the pull-in winding and the radially outer winding the function of the holding winding. But it is also a reverse embodiment possible in which the radially inner winding has the function of the holding winding and the radially outer winding the function of the pull-in winding.

In the electromagnetic relay according to the invention, the radially outer, second winding is located directly on the radially inner, first winding. An intermediate layer separating the windings is eliminated, the inner winding layer of the second winding is in contact with the outer winding layer of the first winding. By eliminating the intermediate layer between the windings, a compact design is achieved in the radial direction.

The winding wires of the two windings have the same non-round cross-sectional shape, but they differ in cross-sectional area.

By choosing a non-round cross-sectional shape for both winding wires, gaps between axially adjacent turns and radially superposed layers within a winding can be minimized. Furthermore, with the non-circular cross-section, a smooth-surface lateral surface can be achieved on the outer circumference of the radially inner winding on the winding carrier, wherein the lateral surface forms the underlay for the second, radially outer winding. An intermediate layer between the first, radially inner winding and the second, radially outer winding can be dispensed with, whereby the structure of the relay considerably simplified and the process step of applying the intermediate layer can be completely eliminated. In addition, the space requirement is reduced in the radial direction, it is achieved a compact design.

Another advantage is that due to the minimization of gaps between adjacent turns or layers, the fill factor is increased.

In addition, there are thermal benefits through the direct contact between inside and outside lying winding. The direct contact improves the heat transfer between the two windings.

According to an advantageous embodiment, the winding wires each have a rectangular cross-sectional shape, in which the length of the side edges differ from each other. For rectangular cross-sectional shape, preferably with right angles, possibly also in skewed design, gaps between adjacent turns arise only through the rounded corners.

According to a further expedient embodiment, the shorter side edge of the winding wire, which has a larger cross-sectional area, is the same length as the longer side edge of the winding wire with a smaller cross-sectional area. This makes it possible to wind the two windings in such a way that the longer side of the smaller winding wire lies on the narrow side of the larger winding wire. In this way, identical numbers of turns are possible for each winding. The number of turns per winding is advantageously adapted to the axial length of the receiving space on the winding support, which is an integer multiple of the narrow side of the larger winding wire and the longer side edge of the smaller winding wire.

According to yet another advantageous embodiment, both winding wires have the same ratio of shorter to longer side edge. Accordingly, these are similar cross sections of the winding wires. For example, it may be appropriate for the longer side edge to be 50% longer than the shorter side edge.

According to yet another expedient embodiment, the two windings each have the same number of winding layers. Since the longitudinal side of the smaller winding wire is adapted to the narrow side of the larger winding wire, the winding of the smaller winding wire has a smaller radial extent than the winding of the larger winding wire.

According to yet another expedient embodiment, the winding wires are produced by profiling from a round wire. Each winding wire is advantageously profiled in a forming tool from two different sides and in this case acted upon by a deforming force, then the profiled winding wire is wound onto the winding support. The profiling of the winding wire from two sides to adjust the height and width of the winding wire has the advantage that wire diameter fluctuations due to manufacturing tolerances affect only the corner radius of the profiled wire, but not on the height and width. This ensures a stable manufacturing process.

Further advantages and expedient embodiments can be taken from the further claims, the description of the figures and the drawings. Show it:

1 a starting device for an internal combustion engine with a starter relay for adjusting a starter pinion,

2 a section through the starter relay with two radially superimposed windings on a winding support,

3 a section through the winding wire of one of the windings. In the figures, the same components are provided with the same reference numerals.

In the 1 illustrated starting device 1 for an internal combustion engine has a starter pinion 2 on, that for starting the internal combustion engine 4 in engagement with a sprocket 3 the internal combustion engine is brought. The starter pinion 2 is on a wave 5 As shown by the double arrow mounted axially displaceable, wherein the starter pinion 2 rotatably with the shaft 5 is coupled. The starter pinion 2 is between a retracted non-functional position and an advanced engagement position with the sprocket 3 the internal combustion engine 4 via a starter relay 6 adjusted, which is formed electromagnetically and energizable windings 7 as well as a lifting anchor 8th comprises, which is drawn in energized upon energization of a first and a second winding against the force of a return spring in this and held in sole position current of the second winding in this position. The lifting anchor 8th is via an engaging lever 9 kinematically with the starter pinion 2 coupled, so that the axial adjustment movement of the lifting armature 8th between a rest position and an adjustment position in a corresponding axial adjusting movement of the starter pinion 2 between the non-functional position and the engaged position is implemented.

The rotating drive movement on the shaft 5 or the starter pinion 2 is using an electric starter motor 11 generated by a planetary gear 12 with the wave 5 is coupled. Upon actuation of the electric starter motor 11 becomes the wave 5 and with it the starter pinion 2 set in rotation.

The starting device 1 is a control unit 10 assigned via which the functions of the starter relay 6 as well as the starter motor 11 to be controlled. When energizing another winding in the starter relay is an actuating armature 13 of the starter relay 6 adjusted over which the electric starter motor 11 is turned on.

In 2 is a winding carrier 14 with wound windings on it 7a and 7b of the starter relay shown in section. The longitudinal axis 15 of the winding carrier 14 is at the same time the adjustment direction of the lifting armature.

In a winding receptacle of the winding carrier 14 are the two windings 7a and 7b taken, wherein the radially inner winding 7a directly on the lateral surface of the winding carrier 14 rests and the radially outer winding 7b on the outer turns of the inner winding 7a is wound up. The two windings 7a and 7b have the same axial length and the same number of turns, also have both windings the same number of winding layers.

The winding wire 16 . 17 every winding 7a . 7b has the same non-round cross-sectional shape, but the winding wires are different in cross-sectional area. Both winding wires 16 . 17 are rectangular in shape and have the same ratio a: b of the longer side edge a to the shorter side edge b ( 3 ). The radially inner winding 7a has, for example, the function of a pull-in winding, in the energization of the lifting armature is pulled against the force of a return spring in the winding. The radially outer winding 7b Advantageously, it has the function of a holding winding, in whose energization the retracted already in the winding lifting armature is held in the retracted position, even if the first, radially inner winding 7a is no longer energized.

The side edges of the winding wires 16 and 17 are matched in the manner that the shorter side edge b of the winding wire 16 with larger cross-sectional area is identical to the longer side edge a of the winding wire 17 with a smaller cross-sectional area. This allows the in 2 shown winding in which the two windings 7a . 7b are each wound so that centroids of wire cross sections of the inside and outside lying winding are radially aligned. The radially outer circumferential surface of the inner, first winding 7a is here smooth surface formed, the second, radially outer winding 7b is directly on the first winding 7b wound.

Due to said size and side edge ratio, both windings have the same number of turns within the receptacle of the winding carrier 14 , Furthermore, the number of winding layers stacked together in the radial direction in both windings can also be 7a . 7b be the same size.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 102010001895 A1 [0002]
• DE 102006033174 A1 [0005]
• WO 2012/040109 A1 [0005]

Claims (10)

Electromagnetic relay, in particular starter relay for a starting device ( 1 ) for an internal combustion engine ( 4 ), with an adjustable lifting anchor ( 8th ) and with two windings ( 7a . 7b ), which lie radially one above the other on a winding carrier ( 14 ) are wound, characterized in that the radially outer winding ( 7b ) directly on the radially inner winding ( 7a ) and that the winding wires ( 16 . 17 ) of the windings ( 7a . 7b ) have the same non-round cross-sectional shape but a different cross-sectional area. Relay according to Claim 1, characterized in that the winding wires ( 16 . 17 ) have a rectangular cross-sectional shape with different lengths side edges. Relay according to Claim 2, characterized in that the shorter side edge of the winding wire ( 16 ) of greater cross-sectional area the same length as the longer side edge of the winding wire ( 17 ) having a smaller cross-sectional area. Relay according to Claim 2 or 3, characterized in that the winding wires ( 16 . 17 ) have the same ratio of shorter to longer side edge. Relay according to one of claims 1 to 4, characterized in that centroids of the wire cross-sections of the two windings ( 7a . 7b ) radially in alignment with the winding carrier ( 14 ) are wound. Relay according to one of claims 1 to 5, characterized in that the two windings ( 7a . 7b ) each have the same number of winding layers. Relay according to one of claims 1 to 6, characterized in that the two windings ( 7a . 7b ) each have the same number of turns. Relay according to one of Claims 1 to 7, characterized in that the winding wires ( 16 . 17 ) are made by profiling from a round wire. Relay according to one of claims 1 to 8, characterized in that the winding ( 7a ) whose winding wire ( 16 ) has the larger cross-sectional area, directly on the winding support ( 14 ) is wound up. Starting device for an internal combustion engine with a starter relay according to one of claims 1 to 9 and with a starter relay ( 6 ) between a disengaged position and an engaged position adjustable starter pinion ( 2 ).

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