Starters that are used for starting internal combustion engines require currents up to 3000A. Said currents are switched via an electromagnetic switch.
The magnetic armature, as claimed in the prior art, is drawn in by a magnetic field which is generated in the magnetic field windings and presses the switching axis with the contact bridge onto the contacts in the switch cover. This closes the connection between the battery and the electric motor of the starter. In the case of corresponding demands, the relay can be protected against ingress of water and other media from the surrounding area by means of a protective cap produced from an elastomer. Where a rapid increase in the temperature of the relay is caused by the motor, e.g. by traveling at high load (tow load or speed load) or by a rapid drop in atmospheric pressure caused by traveling uphill, the air in the relay expands, the protective cap swells and the relay is possibly no longer able to switch. This means that the functioning of the starter is no longer certain.
It is known from the prior art to admit a hole several millimeters large into the protective cap in order to ensure pressure compensation. However, media such as water or dirt are also able to penetrate into or emerge from the relay via said hole.
Between the core and the switch cover there is usually another cup spring. A seal is obtained in a circumferential manner in the region between the protective cap and the fixed magnetic core by the bead of the protective cap being pressed onto the relay housing by means of a retaining ring (not shown in the drawing).
By installing a gap (straight or non-straight, e.g. curved, angular, several changes in direction) at the joints of the relay (e.g. in the protective cap (13), the relay cover (in the region of B at part 12), the plain washers of the terminal screws (region C between part 6 or 7 and part 12) or between the armature (1) and the driver (21) in the region D), the excess pressure in the relay is able to escape in a targeted manner. This means that the functioning of the relay can be ensured even after a rapid rise in temperature. The solution proposed here offers sufficient protection against spray water as only gaps with a small cross section are used and/or a media flow has to change direction several times in order to penetrate into the relay.
Tests have shown that the tightness of starter relays with a protective cap varies greatly through fluctuations in the tolerances. In measurements of the draw-in potential after a rapid rise in temperature (the temperature has been increased from 20° C. to 130° C. within 15 min), values between 8.5 V and 24 V have been measured; from a value above 10 V there is a risk of failure because the moveable magnetic armature would no longer be able to be drawn in. By building-in of a slight leakage, pressure reduction can be achieved and the draw-in potential after a rapid rise in temperature is certainly less than 9.5 V. At the same time, no spray water is able to penetrate into the relay on account of the protective cap as claimed in the invention.
In the case of current protective caps, the seal to the relay armature is obtained by means of two concentric beads (functioning as sealing rings, see no. 16 in
In order to enable an exchange of air, the protective cap as claimed in the invention has in each case 4 breaks in the sealing rings which are offset symmetrically in relation to each other and thus form a labyrinth (see
The embodiment of the protective cap as claimed in the invention has, for example, per sealing ring 4 recesses/openings (170) which are distributed uniformly over the periphery and are offset in relation to the other sealing ring by alpha=45°.
It is conceivable to insert a rib structure similar to that in the rubber protective cap also into the calking disk in order to obtain a better exchange of air in this way. However, it must also be taken into account here that more water can also penetrate into the relay.
Variants:
Number of sealing rings between fixing and relay armature between 1 and 5 (
Number of breaks per sealing ring between 1 and 8. As an example, for two sealing rings in each case variants are shown with one (see
The number of breaks is independent of the number of sealing rings; combinations of two variants are possible.
The angle between the breaks per sealing ring is arbitrary and does not have to be identical for all.
In the case of more than one sealing ring, the offset angle alpha between the breaks on different sealing rings is arbitrary and does not have to be identical for all breaks.
The sealing rings and the breaks therein do not have to be between fixing (e.g. calking disc) and armature end face. It is also conceivable to obtain the seal at the neck of the relay armature (no. 18 in
In the case of this type of seal, all variants are possible, i.e. variation in the number of sealing rings and variation in the number and arrangement of breaks.
The ventilation of the relay is effected via a break in the protective cap in the region of the neck of the relay housing (no. 19 in
The break in the seal is effected in the region of the end face of the relay housing (no. 20 in
The cross-sectional form of the sealing rings is arbitrary. As an example, round, wave-like cross sections are shown in
The breaks are not situated in the protective cap, but rather in the fixing, e.g. the calking disk (fixing on armature) or the retaining disk (fixing on relay housing). The breaks can be placed in position in a manner similar to in the protective cap. All variants are possible in this case too, i.e. variation in the number of sealing rings and variation in the number and arrangement of the breaks.
Number | Date | Country | Kind |
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10 2008 043 191.5 | Oct 2008 | DE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/EP2009/064101 | 10/27/2009 | WO | 00 | 10/11/2011 |