DE699522C - Device for the automatic adjustment of the ignition advance for ignition dynamos - Google Patents

Description

Device for the automatic adjustment of the ignition advance for ignition dynamos The invention aims to improve the devices for automatic adjustment -'-. Jung of the ignition advance for ignition dynarnos of explosion engines, in particular 'for Ignition dynamos - from high-speed engines with large. Number of cylinders, especially from Aircraft engines.

There are already such devices known which with a Change in the angular position of the ignition dynamo depending on the rotational speed the motor-. crankshaft work will have two symmetrical flyweights for this purpose, the axles inserted with the ends in two parallel end shield flanges are pivotable, each flyweight with the teeth of a common gear carries engaged teeth and with end shield flanges and gear against each other are centered.

The large number of cylinders and the high rotational speed of the modern Motors cause 'Üie ignition dynamo. has to go very quickly (7,000 to 8,000 revolutions per minute), so that the device mentioned considerable centrifugal forces is subject. It is therefore necessary - they are extremely powerful and at the same time very light and to train with more space requirements than that available on the engine Space is generally extremely limited.

In the known devices, the articulation axes of the flyweights now work. , icke cantilevered, both in the radial direction and in the Umfangsrichtgiig, resulting in the necessity of d, d. H. use heavy and space-filling end shield flanges. In spite of this precaution, however, these devices often malfunction so that clotting occurs.

According to the invention, each of these end shield flanges is provided with an axial one provided hollow pegs, and these pegs rest on corresponding bearing surfaces, which form one piece with the gear and extend on both sides of it.

This arrangement avoids any radial cantilevering of these joint axes the flyweights. In an advantageous embodiment can the pin on the motor side in a part used for coupling with the motor enter and serve as a bearing surface, and there are two independent of each other axial fastenings available, namely the one for the axial definition of the the drive shaft of the dynamo attached gear and the other laying down this coupling part, the latter fastening being made up of a thread this pin screwing nut consists.

In addition, the two end shield flanges are used to reinforce the connection against rotation not only through the articulated axes of the flyweights but also through additional ones Means, e.g. B. -by screws, fastened together, which these two flanges brace and distributed on the circumference in areas not covered by the weights are, the back of these weights may be used to pass this Screws are recessed.

As a result, the cantilevered axes are the centrifugal weights avoided in the circumferential direction.

Various design modifications are shown as examples on the accompanying drawing represented by devices according to the invention. The invention is not based on that illustrated embodiments limited.

Fig. I is an axial section along the line 14 of Fig. 2 a, embodiment of an automatic controller of the ignition advance with some of the subject matter of the invention forming improvements.

Figure 2 is a top plan view of the end of the device of Figure i with the cover removed.

Fig. 3 is a view similar to Fig. 2 of a modification.

Figs. 4 and 5 are views similar to Fig. 1 of two other modifications, Fig. 5 being a section along the line VV of Fig. 6 .

Fig. 6 is a view similar to Fig. 2 of the Fig. 5 modification.

Fig. 7 is a view similar to Fig. 6 showing another modification.

Fig. 8 shows a detail of the embodiment. In the embodiment shown in Fig. I, the drive shaft i of the dynamo carries a toothing 2 which comprises only a few teeth forming two diametrically opposed groups, which are wedged on this shaft. Trunnions 3 and 4 extend on both sides of this toothing 9 and adapt to the conical end of the shaft r. The toothing 2 is held axially in place by the pivot 4, against the end of which a fastening nut 5 screwing onto a threaded extension of the shaft i lies. The hub 6 of a disc 7 provided with a rim 8 rests on the outside of the pivot 3 , while the pivot 4 carries the hub 9 of a cover which fits onto the rim 8 with a notch. -At the disc 7 , two diametrically opposed axes ii are riveted, both of which pass with their ends through corresponding holes in the cover io. Screws 1: 2, which lie against this cover and screw axially into the end of these axes ii, connect the disk 7 and the cover io to one another, thus forming a closed housing that encloses the toothing 2. Two equal centrifugal masses 23 1 3 are freely movable on these axes ii and extend forward from axes ii, the direction of rotation being indicated by arrow f . In the vicinity of its joint axis, each mass 13 has a toothing 14 consisting of a few teeth, which meshes with one of the tooth groups of the toothing: 2. Each mass can thus move around its joint axis between two stops which are unequal distances from the center point and which are formed by the smooth part of the toothing 2 or the edge 8 . Finally, the pivot pin 4 also carries a drive element 15, which is formed here by a plate engaging in a slot.

The mode of operation is now as follows: When the motor is started and it begins to drive the housing 7, 8, io by means of the clutch 15, the counter-torque of the dynamo causes the masses 13 to move towards the center and against the through the Lay the smooth part of the toothing 2 formed stop. The housing is then locked in a certain angular position on the shaft i, corresponding to the minimum value of the ignition advance, and the shaft i is driven. As soon as the centrifugal force acting on each mass 13 becomes so great that its moment in relation to the joint axis ii is greater than half the counter-moment of the dynamo on the toothing 14, the masses move away from the center and lie against the edge 8. During this movement, the teeth 14 rotate the toothing 2 and cause an angular adjustment between the housing and the shaft i, the new position of the ignition advance then being relevant for normal operation.

The embodiment of Fig. 3 is similar to the one above, but each mass 13 also works together with a leaf spring 16, which is connected between the mass and the edge 8a and drives the mass back to the center. In the embodiment shown, the spring 16 is by means of of the screws 17 is attached to the rear of the mass near the hinge axis and lies with its other end against the edge. So there is a certain position of the masses for each speed of rotation, for which the opposing effects of centrifugal force and spring force on each mass keep the equilibrium. In practice, the back of the mass 13 is shaped according to a curve which has been determined by tests so that a relationship is obtained between the centrifugal force and the spring tension such that each speed has a certain angular displacement, i.e. one of the most favorable In this example, the spring 16 is constructed in a stepped manner from several sheets placed one on top of the other, which take effect one after the other according to the centrifugal force displacement of the masses; the spring can, however, also be formed by a single sheet. The width of the Leaf or leaves be changeable.

One notices, on the other hand, that the mass of the dynamo is immediate connected parts is very small, since it only consists of that of the single piece 2, while all other parts are directly connected to the engine, so that the Inertia effects which regulate the lead during accelerations affect, be limited to a minimum value.

In the embodiment of Fig. 4, the average toothing 2b is directly on the shaft lb the dynamo keyed, and the masses 13 are b attached 7b overall an articulated on a disk which on one at one end in a bore of the end of the shaft ib and on the other hand in a ball bearing ig centered axis 18 carried by a housing 2o attached to the housing of the dynamo, the axis iS having a part 21 which drifts out of the housing and for receiving a part 22 for coupling with that of the shaft coming from the motor is used.

In the modification of the embodiment of Fig. 5 is formed, the apparatus in a manner similar to that of Fig. I, the disk 7 and the lid io'vereinigenden screws 12c are arranged but not more iic at the end of the axes, but both sides of the Articulation axis of each mass in a zone not marked by this mass during its displacements, the rear side of the mass having a cutout provided for this purpose in the vicinity of the articulation axis. So you have four fastening screws to unite the parts' 7 - and io. In addition, these screws are in pairs symmetrical to the plane passing through the axes of articulation of the two masses, which makes it possible to mount these masses in reverse without changing the various parts, if the device is to rotate against the direction of arrow f. On the other hand, the hinge axes are not riveted to the disk 7 , but only inserted into it under pressure. Finally, the coupling part 1 5 c carried by the hub 9 is held here in the axial direction by a nut 23 which is screwed onto a thread attached to the end of this hub.

It should be noted that in this embodiment, as in the one shown in Fig. 1, the overall arrangement of the automatic adjustment device forms a completely independent part, which intervenes in any existing connection between motor and dynamo without any change to the existing parts can be. - In the embodiment of Fig. 7 , two further fastening axes Ild have been arranged in the zone not covered by the masses. to strengthen the connection of the disk 7 and the cover io against rotation and to be able to turn the masses when the device is to rotate in the opposite direction of the arrow f , the axes ild. and the fastening screws i # .- i2d are arranged symmetrically to the bisector of the space delimited by the two planes passing through diametrically opposed hinge axes iid.

Fig. 8 shows another way of reinforcing the connection between the disc and the cover against rotation. In this example, the periphery of the notch joint of the cover 10 has some notches 24 in which claws 2-5 engage, which in the edge 8 of FIG Slice cut out and bent slightly towards the middle.

It is well understood that the invention is in no way restricted to the details of embodiment described or shown, which are given only as an example. In particular, the parts forming the housing, d. H. the disc and the cover, be connected to each other by some other means, in particular by means of bolts passing through the external flanges of these two parts. Also, any mass can. consist of one piece or be composed of several superimposed plates. In the latter case, these different plates can be riveted to one another or also individually freely movable on their common joint axis and not connected to one another, but then they are identical to one another and exert the same effects.

Claims (1)

PATENT CLAIMS: i. Device for the automatic adjustment of the ignition advance for ignition dynamos of explosion engines with two flyweights, which are articulated on axles, the ends of which are gripped by two parallel end shield flanges, each flyweight bearing teeth that are in mesh with the teeth of a common gear wheel and with end shield flanges and gear wheel together are centered, characterized gekennzeiclinet that each end shield flange (7, io) is provided with an axial hollow pin (6, 9) and that these pins (6, 9) rest on corresponding bearing surfaces which form one piece with the gear (2) and extend on either side of it. : 2. Device according to claim i, characterized in that the pin (9) on the motor side enters a part serving for coupling with the motor and serves as a bearing surface for it (Fig. 5, 6) and that there are two mutually independent axial fastenings, and one for the axial fixing of the gear (2) attached to the drive shaft (i) of the dynamo and the other for fixing this coupling part (159, this latter attachment consisting of a nut (23) screwing onto a thread of this pin (9) 3. Device according to claim i, characterized in that to strengthen the connection of the two end shield flanges (7, 10) against rotation, these not only through the articulation axes of the centrifugal weights, but also through additional means, e.g. through screws (12e, Fig. 6), which brace these two flanges and are distributed on the circumference in areas not covered by the weights (13), with the back of these weights possibly for detecting the passage of these screws is recessed. 4. Apparatus according to claim 3, characterized in that the screws (i2c) are arranged symmetrically to the diagonal plane passing through the joint axes of the weights. 5. Apparatus according to claim 3, characterized in that it has two other joint axes for the flyweights (Fig. 7) and that the overall arrangement of these screws (i2c) and axes (iid) has a plane of symmetry which is defined by the bisecting plane of the two diametrical planes enclosed by the axes of articulation of the weights.