DE4116416A1 - PUSH-IN RELAY FOR THE STARTER OF AN INTERNAL COMBUSTION ENGINE - Google Patents

Abstract

A solenoid switch for a starter for an internal combustion engine comprises an armature (3) axially movable in an armature guide sleeve (5) which is surrounded by a relay coil (4) axially supported by a resilient member (31). The armature guide sleeve (5) and the resilient member (31) are formed as a single component such that a radially extending region (30) defining the resilient member (31) is connected to a cylindrical section (11) of the armature guide sleeve (5), the radially extending region (30) being arranged between a magnetic core (2) and a front surface (32) of a winding support (12) of the relay coil (4). <IMAGE>

Description

State of the art

The invention relates to an engagement relay for a Starting device (starter, especially thrust Screw drive starter) of an internal combustion engine, with a magnetic core with a cylindrical Ab cut to accommodate an axially acting anchor having associated anchor guide sleeve, which is surrounded by a relay coil and with a the relay coil axially supporting spring direction.

Such an engagement relay serves the purpose of a high current with a relatively low Switch control current. The starter current of an An Rotating device for an internal combustion engine for example in passenger cars up to approx. 1000 A, for commercial vehicles up to approx. 2500 A.  Switching on the low control current is sufficient against a mechanical switch (ignition starter ter). The engagement relay built into the starter bil the combination of an engagement magnet with a Relay. It therefore fulfills a double function namely, advancing a pinion of the starter to Tracking in a ring gear of the internal combustion engine and closing a contact bridge to switch on of the starter main flow.

An engagement relay is known (DE-OS 28 22 164), whose magnetic core is provided with a ring step, on which an anchor guide sleeve is pushed. Part of the outer surface of the anchor guide The sleeve is surrounded by a relay coil is arranged on a winding support. Within the anchor guide sleeve is an axially movable Anchor arranged, when the relay coil is not energized is laterally offset to this. Will the relay coil excited, the armature is in the winding drawn in. This anchor movement becomes one hand for the axial displacement of the said pinion used and on the other hand to press the mentioned contact bridge for the main current contacts drawn. The relay coil is made of a sleeve surrounded by a housing that is on the magnetic core distant part of the anchor guide sleeve with is pushed onto an end region. Inside the A spring is supported at the end of the housing, which surrounds the anchor guide sleeve and corresponds to one accordingly assigned end face of the winding support axially applied to the relay coil. This will the winding carrier and thus the relay coil in Position held.

Advantages of the invention

The engagement relay according to the invention with the In contrast, the main claim features the advantage that the assembly simplifies the construction form is shortened and a particularly safe fi xation of the relay coil against vibrations and Shocks is achieved.

For this purpose, the anchor guide sleeve is in one piece with the spring device designed such that to the cylindrical section of the anchor guide a radially extending sleeve, the spring device exhibiting area connecting between the Magnetic core and an end face of the relay coil is arranged. With the cylindrical section is the anchor guide sleeve on a ring step of the Ma gnetkerns plugged, the end, radial extending area between an end wall of the Magnetic core and an end face of the relay coil or an end face of the winding support of Ma the magnetic coil comes to rest. When mounting the An Ker guide sleeve is due to the one-piece with the spring device the same with the latter installed so that no additional operations necessary for the introduction of the spring device are. Through the joint training of Ankerfü tion sleeve and spring device simplified and the design of the relay is also shortened, as a result the space and weight are reduced.

After further training, it is provided that Spring device from or part of the radially extending region is formed. Provided  the entire radial area for example curved convex towards the relay coil trained, it forms the Federein overall direction. However, it is also conceivable that the well-trimmed area cut spring tongues, which then the spring device bil the.

According to a preferred embodiment, the Spring device of bent or corrugated Spring plate sections of the radially extending Be empire formed.

Furthermore, the relay coil is preferably off covering housing provided, which in particular hül is formed like a sen. The housing is on one part of the armature located away from the magnetic core guide sleeve with an end portion so opened pushed that end area against the associated one other end face of the relay coil is present. These End face can - when using a winding carrier - the other end face of said wick be responsible. This will make the relay coil or their winding support against the spring device crowded, so that the relay coil shakes particularly is firmly held.

According to a further embodiment is pre see that opposite the radial area lying end zone of the anchor guide sleeve in such a way is designed that the end zone an abutment for the end of the housing bil det. This will position the housing additionally fixed relative to the magnetic core, so that which receives the ring coil and the spring device  free space within the housing niert size, which ensures that the Relay coil firmly against the spring force of the spring direction is pressed and thus safely and safely is held firmly. The outward facing End zone of the anchor guide sleeve also has the front partly that no sharp-edged compared to the anchor Anchor guide sleeve opening is formed which the Anchor surface can damage an intake wi which would evoke what in turn the power would increase for the anchor actuation and so that the life of the engagement relay ver diminishes. Moreover, due to the radial course the end zone is a labyrinthine annular gap created between anchor guide sleeve and anchor, causing the intrusion of unwanted fluidi media into the interior of the housing and the Avoid coil. Corrosion and short circuit driven are reduced. In the state of the tech nik, in which no end zone running outwards the anchor guide sleeve is provided, supported the axial annular gap on the coil body through its Capillary action the penetration of fluidic Me serve so that the functional reliability of the engagement lais' can be affected. It also does that sharp-edged end of the anchor guide sleeve of the be knew relay 'that on the anchor surface damage caused by vibrations.

It is preferably provided that the end zone from cylindrical section of the anchor guide sleeve is crimped on the outside.  

Likewise, it is also functional, which is radial fenden area of the cylindrical portion of the Bend the anchor guide sleeve outwards. Prefers the radially extending area can be used as a spring direction by a drawing, punching and molding preferably created in one operation will.

drawing

The invention is described below with reference to the figures explained in more detail. Show it:

Fig. 1 a longitudinal section through a relay Einrückre,

Fig. 2 is a plan view of an armature guide sleeve of the engaging relay of FIG. 1,

Fig. 3 shows a longitudinal section through part of the anchor guide sleeve of Fig. 2 and

Fig. 4 is a plan view of the armature guide sleeve according to FIG. 2, but with presen- tation of an end face of a winding support of a relay coil of the Einrückre relay '.

Description of the embodiment

In Fig. 1, a longitudinal section through a back relay 1 is shown. The engagement relay 1 has a magnetic core 2 , an armature 3 , a relay coil 4 , an armature guide sleeve 5 and a housing 6 .

The magnetic core 2 is seen with a ring step 7 ver, which is composed of an axial wall 8 and an end wall 9 . A part 10 of a cylin drical section 11 of the armature guide sleeve 5 is pushed onto the axial wall 8 of the ring step 7 . Adjacent to the magnetic core 2, there is a winding support 12 on the outer lateral surface of the armature guide sleeve 5 , on which the relay coil 4 is arranged.

The housing 6 is designed like a sleeve; it covers the relay coil 4 and has a knife-smaller end region 13 which is pushed onto a part 14 of the core guide sleeve 5 which is remote from the magnetic core 2 in such a way that it bears against an end face 15 of the winding support 12 and thereby the winding support 12 together with the relay coil 4 in the direction of the end wall 9 of the ring stage 7 . The other end region 16 of the housing 6 is supported on a housing cover 17 of a contact chamber 18 . The housing cover 17 is penetrated by two main current contacts 19 , the electrodes 20 of which can interact with a contact bridge 21 .

The armature 3 has an actuation extension 22 for the pinion of a starter motor, not shown, of a starting device for an internal combustion engine. A return spring 23 is supported at one end on the magnetic core 2 and at the other end on the armature 3 and holds the latter - when the relay coil 4 is not energized - in the position shown in FIG. 1 Darge.

The magnetic core 2 is penetrated by an opening 24 in which a bearing bush 25 is arranged. The bearing bush 25 is penetrated by part of a split switching axis 26 , the other part being located on the armature 3 . On the first ge part of the switching axis 26 - the contact bridge 21 is fixed - within the contact chamber 18 . A spring 27 is supported at one end on the housing sedeckel 17 and at the other end on the end face 28 of an abutment 29 from the switching axis 26 and thereby holds the contact bridge 21 - with the relay coil 4 not energized - in the in FIG. 1 as given position.

It is essential that from the cylindrical section 11 of the armature guide sleeve 5 a radially extending region 30 connects, which forms a Federein direction 31 . The area 30 lies between the end wall 9 of the ring step 7 and an end face 32 of the relay coil 4 or the winding support 12 of the relay coil 4 .

The spring action of the spring device 31 is achieved by the fact that the preferably bent area 30 of the armature guide sleeve 5 is bent, in particular is corrugated. The material of the anchor guide sleeve 5 therefore preferably has resilient properties.

At the other end of the anchor guide sleeve 5 , an end zone 33 is formed which - starting from the cylindrical section 11 - extends outwards in such a way that it forms an abutment 34 for the end region 13 of the housing 6 .

Fig. 2 shows that the radially extending loading area 30 of the armature guide sleeve 5 is provided with spring tongues 35 which the spring device 31 bil. For the purpose of simpler illustration, the end zone 33 of the anchor guide sleeve 5 is not shown in FIG. 2. The individual spring tongues 35 are - in the direction of the end wall 9 - bent convexly; this can be seen in particular in FIG. 3 . The end portion 36 of each spring tongue 35 is seen with a concave curvature 37 ver.

FIG. 4 shows a representation corresponding to FIG. 2, but the end face 32 of the winding support 12 is also shown.

When installing the engagement relay 'is first on the ring stage 7 of the magnetic core 2, the provided with Wick development carrier 12 and relay coil 4 armature guide sleeve 5 pushed. Then the housing 6 is then mounted and secured by forming the end zone 33 . By abutment of the Endbe rich 13 on the associated end face 15 of the winding support 12 , the winding support 12 ge gene against the spring device 13 with the corresponding end face 32 is pushed, the Federein device 31 is supported on the end wall 9 of the ring stage 7 . As a result, the relay coil 4 is firmly held shake.

The spring device 31 can be produced in one operation by pulling, punching and compression molding. The number and arrangement of the spring tongues 35 is dependent on the design of the winding support 12 . The end zone 33 is preferably produced by a flanging process. By flanging an input lock for fluidic media is created in the interior of the housing 6 , so that the relay coil 4 is protected from corrosion and the like.

The design according to the invention results in a weight reduction because the engagement relay has a relatively small length dimension. moreover, who reduces the part costs by the one-piece of anchor guide sleeve 5 and spring device 31 , so that less inventory is required. In addition, the assembly effort of the engagement relay 'is reduced.

Claims (11)

1. engagement relay for a starting device (star ter) of an internal combustion engine, with a magnetic core, which is assigned an armature guide sleeve having a cylindrical section for receiving an axially acting armature, which is surrounded by a relay coil and with a relay coil supporting spring device, characterized in that the armature guide sleeve ( 5 ) is formed in one piece with the spring device ( 31 ) in such a way that on the cylindrical portion ( 11 ) of the armature guide sleeve ( 5 ) a radially continuous fender, the spring device ( 31 ) having Be rich ( 30 ), which is arranged between the magnetic core ( 2 ) and an end face (end face 32 of a winding support 12 ) of the relay coil ( 4 ). 2. Engagement relay according to claim 1, characterized in that the magnetic core ( 2 ) has an annular step ( 7 ) which is formed by an axial wall ( 8 ) and an end wall ( 9 ) that on the axial wall ( 8 ), the armature guide sleeve ( 5 ) is pushed on and that the spring device ( 31 ) bears against the end wall ( 9 ). 3. engagement relay according to one of the preceding claims, characterized in that the radially extending region ( 30 ) has cut-free spring tongues ( 35 ). 4. engagement relay according to one of the preceding claims, characterized in that the Federein direction ( 31 ) of bent or corrugated Fe derblechabschnitte (spring tongues 35 ) of the radially extending region ( 30 ) is formed. 5. engagement relay according to one of the preceding claims, characterized in that the Fe dereinrichtung ( 31 ) on the end face ( 32 ) of a winding support ( 12 ) of the relay coil ( 4 ) is supported. 6. engaging relay according to one of the preceding claims, characterized in that a re laiss coil ( 4 ) covering housing ( 6 ) on a part of the magnetic core ( 2 ) located part ( 14 ) of the ker guide sleeve ( 5 ) with an end region ( 13 ) is pushed on. 7. engagement relay according to claim 6, characterized in that the end region ( 13 ) bears against the other end face ( 15 ) of the winding support ( 12 ). 8. engagement relay according to one of claims 6 or 7, characterized in that the radial loading area ( 30 ) opposite end zone ( 33 ) of the ker guide sleeve ( 5 ) is formed such that the end zone ( 33 ) an abutment ger ( 34 ) for the end region ( 13 ) of the housing ( 6 ). 9. engagement relay according to claim 8, characterized in that the end zone ( 33 ) from the cylindrical portion ( 11 ) of the armature guide sleeve ( 5 ) is bent outwards, in particular crimped. 10. Engagement relay according to one of the preceding claims, characterized in that the radially extending region ( 30 ) from the cylindrical section ( 11 ) of the armature guide sleeve ( 5 ) is bent. 11. Engagement relay according to one of the preceding claims, characterized in that the radially extending region ( 30 ) and / or the Federeinrich device ( 31 ) by a drawing and punching and molding press operation, preferably in one operation, he provides.