FR2796991A1 - Starter for car comprises engagement spring placed inside mobile magnetic core, and having non-linear elastic stiffness - Google Patents

Abstract

Engagement spring (70) is placed inside mobile magnetic core (30). Spring has its front axial end resting on shoulder surface (56), and its rear axial end resting on bearing surface (68). Spring has non-linear elastic stiffness (R). Stiffness increases with travel of magnetic core towards fixed magnetic core (28). When mobile core is traveling towards mobile contact rod (32), stiffness has first value (R1) lower than standard stiffness (R). When mobile core gets in contact with mobile contact rod, stiffness has second value (R2) larger than standard stiffness.

Description

The invention relates to a motor vehicle starter. The invention relates to a motor vehicle starter with a nonlinear elastic stiffness meshing element. The invention more particularly relates to a motor vehicle starter, of the type comprising a contactor provided with a magnetic coil capable of exerting a magnetic attraction force on a movable magnetic core to slide it inside the coil, of the type comprising a launcher provided with a pinion capable of meshing with a driving ring of a heat engine when the launcher is moved axially, of the type in which the displacements of the movable magnetic core control the movements of the launcher with interposition of an elastic meshing element to allow the movable magnetic core to continue to slide when a tooth of the pinion abuts axially against a tooth of the drive ring.

During its axial sliding inside the coil, the mobile magnetic core must fight against the restoring forces of elastic elements arranged in the starter.

<B> It </ B> is known to arrange in a starter elastic elements which exert opposing forces to the displacement of the mobile magnetic core. In general springs are used.

In this type of starter, the movable magnetic core struggles, during its displacement, successively against the restoring forces of several springs called movable core spring, meshing spring, contact spring and pallet spring.

FIG. 2 shows the curve CP of the available load-bearing forces of the contactor and the curve C1 of the forces to be provided to fight against the restoring forces of the different springs.

The x-axis represents the stroke of the movable magnetic core towards its stop point in millimeters.

The y-axis represents the value of the Newtons forces. The figure is read from the right to the left according to the race of the mobile magnetic core which is close to its stop.

The curve CP has substantially the form of an asymptote at the y-axis and the abscissa axis. The curve C1 is a succession of segments which form bearings representing the compression of the springs. The points that bound the segments have been numbered.

From point PO to point P1, the movable core compresses in its displacement the movable core spring.

The P1-P2 segment represents the additional effort that the mobile magnetic core must provide to compress the meshing spring. From point P2 to point P3 the movable magnetic core compresses both the movable core spring and the meshing spring.

The P3-P4 segment represents the extra effort that the moving magnetic core must provide to compress the contact spring. From point P3 to point P5 the movable magnetic core compresses both the movable core spring, the meshing spring and the contact spring.

The P5-P6 segment represents the extra effort that the moving magnetic core must provide to compress the pallet spring. From point P6 to point P7 the movable magnetic core compresses both the movable core spring, the meshing spring, the contact spring and the pallet spring.

In the vicinity of point P7 the movable magnetic core abuts the fixed magnetic core, and the pinion meshes with the drive ring.

The first constraint on the curve C1 is that it must always be under the CP curve otherwise the mobile core will remain blocked in its race.

In addition, it is necessary that the points P2 and P6 are as high as possible.

Indeed, the point P2 determines the value of the effort that must be provided to compress the meshing spring which is interposed between the mobile magnetic core and the launcher. However, the value of this effort must be important, on the one hand, to limit the phase shift between the displacement of the mobile magnetic core and the movement of the launcher and, on the other hand, so that the value of the support force axial axis of the pinion against the driving ring is important.

If there is a significant phase shift between the two displacements, the electrical contact can occur in the starter before the pinion meshes with the drive ring. The electrical contact turns on an electric motor that rotates the pinion. The pinion will then turn too fast to mesh with the drive crown.

If there is insufficient axial bearing force, when a tooth of the pinion will be opposite a hollow of the driving ring, the pinion will not have enough propulsion force for mesh completely with the crown. The range of a tooth of the pinion against a tooth of the crown will then be low which will cause premature wear of the teeth of the pinion and / or the drive ring.

Point P6 determines the amount of effort required to compress the pallet spring. The value of this force also conditions the value of the axial bearing force of the pinion against the drive ring before meshing.

Indeed, the compression of the pallet spring forces the movable core to continue to compress the meshing spring as the meshing of the pinion with the drive ring is not realized.

The higher the point P6, the greater the speed of penetration of the tooth of the pinion in a hollow of the driving ring is large. As can be seen in Figure 2, the point P4 is very close to the CP curve. This means that the margin of safety is low at this point of the moving magnetic core stroke, between the value of the available bearing forces and the value of the opposing forces.

For example, if the mobile magnetic core loses strength over time, especially due to wear, the CP curve may pass under point P4 and the mobile core will be blocked in its race.

In addition, the starter according to the state of the art does not make it possible to raise the point P2, that is to say to increase the force necessary to compress the meshing spring, since this would cause an elevation of the point P4 which would then go over the CP curve.

To overcome these drawbacks, the invention proposes a motor vehicle starter of the type described above, characterized in that the elastic stiffness of the elastic meshing element is non-linear. Thanks to the invention, it is possible in particular to economically optimize the electromagnetic characteristics of the contactor and / or increase the speed of penetration of the pinion in the drive ring.

According to other features of the invention - the elastic stiffness of the meshing elastic member increases with the stroke of the movable magnetic core when the movable magnetic core is attracted by the coil; the elastic stiffness of the elastic meshing element takes a first value up to a determined point of the stroke of the movable magnetic core from which said core pushes a movable contact rod axially, then the elastic stiffness takes a second value greater than the first value; the elastic meshing element is arranged inside the movable magnetic core; in a starter of the type in which the movable magnetic core causes in its displacement a first end of a control lever whose second end axially displaces the launcher, the elastic meshing element is arranged between the launcher and the end lower control lever; the elastic meshing element is a helical spring. Other features and advantages of the invention will appear on reading the detailed description which follows for the understanding of which reference will be made to the accompanying drawings in which - Figure 1 is an axial sectional view of a starter produced in accordance with teaching of the invention; FIG. 2 is a diagram representing the value of the available forces and the value of the antagonistic forces as a function of the stroke of the movable magnetic core of a starter according to the state of the art; FIG. 3 is a diagram representing the value of the available forces and the value of the antagonistic forces as a function of the stroke of the movable magnetic core of a starter produced in accordance with the teachings of the invention.

In the following description, like reference numerals designate like parts or having similar functions. There is shown in Figure 1 a starter 10 of a motor vehicle made according to the teachings of the invention.

The starter 10 comprises in a lower part a launcher 12 and an electric motor 14, and in an upper part, a contactor 16.

The launcher 12 and the motor 14 are mounted axially, respectively from front to back, ie from left to right in the figure, on an armature shaft 18 of the motor 14.

The launcher 12 has at the front a pinion 20 which is mounted on a driver 22 placed at the rear of the launcher 12. The rear of the driver 22 has a groove 24.

The pinion 20 is provided to mesh with a pinion tooth 21 with a drive crown tooth 23 as it moves forward.

The contactor 16 comprises a housing 25 which contains in particular a substantially cylindrical coil 26 parallel to the armature shaft 18. The rear axial opening of the housing 25 is closed by a cover 27. The cover 27 bears on its transverse face before two electrical contact terminals 29, here one above the other.

The forward axial opening of the housing 25 delimits a chimney 31 of internal diameter equal to the inside diameter of the coil 26.

A movable magnetic core 30 slides axially in the chimney 31 of the housing 25 and in the front section of the coil 26.

A fixed magnetic core 28 is fitted into a rear section of the coil 26. The fixed magnetic core 28 guides a contact rod 32 in axial sliding mode.

The contact rod 32 comprises an intermediate section 34 of diameter greater than the general diameter of the rod 32.

The intermediate section 34 is delimited at the rear by the shoulder surface 36 which it forms with the rear section of the contact rod 32, and is delimited at the front by a radial collar 38 of diameter greater than the diameter. intermediate section 34 forming a shoulder surface 40 with the intermediate section 34. The radial collar 38 also has a frustoconical rear face 41 which is inclined towards the axis of the contact rod 32. A thrust washer 42, the outer diameter is greater than the diameter of the intermediate section 34, is threaded on the rear section of the contact rod 32. The thrust washer 42 is axially supported by its front transverse face on the shoulder surface 36.

A movable contact paddle 44 which is substantially in the form of a vertically oriented rectangular plate is transversely mounted in axial sliding on the rear end of the intermediate section 36.

In the rest position, the movable contact plate 44 is axially supported by its rear transverse face on the front transverse face of the thrust washer 42, and by its front transverse face on the rear transverse face of the fixed magnetic core 28.

A pallet spring 46 is axially supported by its forward axial end on the shoulder surface 40 and by its rear axial end on the front transverse face of the movable contact pallet 44.

The moving element 48 constituted by the movable contact rod 32 provided with the pallet spring 46, by the movable contact plate 44 and by the thrust washer 42, is held in the rest position by a contact spring 50.

The contact spring 50 is supported axially by its rear axial end on the bottom of a hole 52 not opening formed in the center of the front transverse face of the cover 27, between the two electrical contact terminals 29. Its forward axial end is supported axially on the substantially transverse rear face of the thrust washer 42.

In the rest position, the contact spring 50 exerts a restoring force on the contact rod 32 directed towards the front of the starter 10 so that the contact paddle 44 is pressed against the rear transverse face of the fixed magnetic core 28.

The movable magnetic core 30 is substantially cylindrical in shape. Its rear axial opening is closed by an abutment plate 54 and its front axial opening delimits a shoulder surface 56 oriented rearwardly inside the core 30.

The outer edge of the forward axial end of the movable magnetic core 30 defines a shoulder surface 58 facing rearwardly. A spring 60 movable core is supported by its rear axial end on a front transverse edge 62 of the chimney 31, and its forward axial end on the shoulder surface 58.

The movable core spring 60 exerts a forward biasing force which opposes the axial sliding of the movable magnetic core 30 aft.

A control rod 64 is inserted in the front axial opening of the movable magnetic core 30 and abuts, in the rest position, on the front transverse face of the abutment plate 54 by its rear axial end.

The rear axial end of the control rod 64 is provided with a piece 66 in the form of a mushroom, the cap defines a bearing surface 68 facing forward.

A meshing spring 70, also referred to as a tooth-to-tooth spring, is arranged inside the movable magnetic core 30. It is supported by its forward axial end on the shoulder surface 56 and by its rear axial end on the support surface 68.

The meshing spring 70 exerts a rearward-biased restoring force which tends to hold the workpiece 66 of the control rod 64 abutting against the abutment plate 54.

A control lever 72 is arranged vertically in the starter 10 so as to transmit the movement of the movable magnetic core 30 to the launcher 12. The control lever 72 is mounted on a central pivot 74 integral with the starter 10.

The upper end of the control lever 72 is connected by a transverse axis 76 to the front axial end of the control rod 64. The lower end of the control lever 72 has a fork 78 which penetrates into the groove 24 of the 22 and cooperates with its edges, so that any movement of the fork 78 forward or backward causes a displacement of the driver 22 in the same direction.

We will now explain the conventional operation of a starter 10.

When the coil 26 is energized, the movable magnetic core 30 is attracted to the fixed magnetic core 28. In its axial displacement, the movable magnetic core 30 begins by compressing the movable core spring 60. At the same time it drives the control rod 64 backwards so it pivots the control lever 72 around the central pivot 74.

The pivoting of the control lever 72 moves the fork 78 forwards which has the effect of also moving the driver 22 and the pinion 20, that is to say the launcher 12, towards the front, towards the crown. training 19.

If a tooth 21 of the pinion 20 is vis-à-vis a tooth 23 of the drive ring 19, the launcher 12 is blocked in its forward movement. The control lever 72 is then locked as well as the control rod 64.

The movable magnetic core 30 will continue to slide axially backwards but by compressing the meshing spring 70.

Continuing its course, the movable magnetic core 30 then comes into contact with the abutment plate 54 with the forward axial end of the contact rod 32, and begins to push it backwards.

From this point of its travel the movable magnetic core 30 compresses the contact spring 50, while continuing to compress the movable core spring 60 and the meshing spring 70.

By pushing the contact rod 32, the movable magnetic core 30 moves the entire moving assembly 48 backwards until the movable contact plate 44 is in contact with the two electrical contact terminals 29 .

At this point of its travel, the movable magnetic core 30 is not yet in abutment against the front transverse face of the fixed magnetic core 28. The movable magnetic core 30 thus continues to push the contact rod 32 rearwardly in that it comes into abutment against the front transverse face of the fixed magnetic core 28.

As the movable contact plate 44 is in contact with the two electrical contact terminals 29, it can no longer move with the contact pin 32. The contact rod 32 then slides through the movable contact plate 44 by compressing, in addition to the other springs, the contact spring 46. The contact spring 46 serves to maintain a sufficient contact pressure between the movable contact plate 44 and the electrical contact terminals 29 to compensate for play due to wear of the parts. .

When the movable contact plate 44 is in contact with the two electrical contact terminals 29, the electric power circuit of the starter 10 is closed. The electric motor 14 is then started which rotates the armature shaft 18.

Under the effect of the meshing spring 70 in a state of maximum compression, the tooth 21 of the pinion 20 bears axially against the tooth 23 opposite the driving ring 19.

As soon as the armature shaft 18 begins to rotate, the pinion 20 also rotates and the tooth 21 of the pinion 20 is found opposite a hollow of the drive ring 19. The tooth 21 of the pinion 20 then enters the hollow vis-à-vis the drive ring 19 using the return force of the meshing spring 70.

The meshing of the pinion 20 with the driving ring 19 causes the launcher to move forward. The fork 78 of the control lever 72 also moves and the control lever 72 pivots by causing the control rod 64 to move rearwardly.

The control rod 64 is finally abutted by its part 66 against the abutment plate 54 of the movable magnetic core 30. According to the usual characteristics of the starters, the movable core spring 60, the contact spring 50 and the pallet spring 46 are helical springs whose elastic stiffness is substantially linear and the elastic stiffness of the movable core spring 60 is lower than on the other springs.

We will now explain the operation of the starter 10 made according to the invention.

According to the teaching of the invention, the meshing spring 70 has a nonlinear elastic stiffness R.

According to the preferred embodiment of the invention, the elastic stiffness R increases with the stroke of the movable magnetic core 30 towards the fixed magnetic core 28.

Still according to the preferred embodiment, for the stroke corresponding to the coming of the movable magnetic core 30 in contact with the movable contact rod 32, the elastic stiffness R of the meshing spring 70 takes a first value R1 less than the value of the stiffness R of a meshing spring 70 according to the state of the art.

Then, at the point of its stroke for which the movable magnetic core 30 comes into contact with the movable contact pin 32, the stiffness R takes a second value R2 greater than the value of the stiffness R of a meshing spring 70 according to the state of the art.

In an alternative embodiment of the invention, it is possible to use a meshing spring 70 whose elastic stiffness R takes more than two values during the displacement of the movable magnetic core 30. For example, the elastic stiffness can increase gradually and take a infinity of stiffness values Rn. With this type of meshing spring 70 one can adjust the shape of the curve C2 between the points P2 and P7 so that it is substantially parallel to the curve CP.

According to the preferred embodiment of the invention, the meshing spring 70 is a helical spring.

The non-linearity of the elastic stiffness R is obtained by known methods for producing the springs, for example by modifying the spacing of the turns on a section of the spring or by locally modifying the characteristics of the spring wire.

According to another embodiment of the invention, the meshing spring 70 is replaced by another elastic element which has a nonlinear elastic stiffness R, for example a suitably shaped piece of synthetic or natural elastomeric material.

It has already been explained in Figure 2 the operation of a starter equipped with a meshing spring known from the state of the art.

We will now explain, with reference to Figure 3, the operation of the starter 10 equipped with a meshing spring 70 according to the preferred embodiment of the invention.

Figure 3 uses the same mode of representation as Figure 2 described above. The curve CP is identical to that of FIG. 2, and from the point PO to the point P2, the curve C2 is identical to the curve C1.

It is noted that the slope of each inclined segment represents a cumulative elastic stiffness value of the springs in the compression state. The slope of segment P2-P3 is lower on curve C2 than on curve C1. This slope represents the elastic stiffness R1 of the meshing spring 70 superimposed on the low elastic stiffness of the movable core spring 60.

Since the same elastic stiffness has been maintained for the other springs, the length of the segment P3-P4 of the curve C2 is identical to that of the curve C1. This means that it is necessary to provide the same additional effort to compress the contact spring 50 in the starter according to the invention and in the starter according to the state of the art.

But since the slope of the segment P2-P3 is lower, the point P3 of the curve C2 is lower than that of the curve C1. The point P4 is therefore lower on the curve C2, ie further from the curve C P.

From the point P3 the movable magnetic core 30 comes into contact with the contact rod 32 and begins to compress the contact spring 50. The meshing spring 70 then takes a value of elastic stiffness R2 greater than the elastic stiffness R1 and greater than the elastic stiffness used in the state of the art, the elastic stiffness of the contact spring 50 is not changed.

This is why the slope of the segment P4-P5 of the curve C2 is higher than the slope of the same segment on the curve C1.

This makes it possible in particular to obtain a higher point P5 on the curve C2, without having modified the elastic stiffness of the pallet spring 46. Thus, the height of the point P6, which represents the force to be supplied to compress the pallet spring 46, is increased. , and which conditions the propulsion force of the pinion 20 in the drive ring 19, as has been explained before.

It can be seen in FIG. 3 that the use of the meshing spring 70 according to the invention has made it possible to reduce the height of the point P4 with respect to the curve CP, without reducing the height of the points P2 and P6.

This allows us to have a greater margin of safety between the available bearing force during the course of the movable magnetic core 30 and the antagonistic efforts encountered. We can try to exploit this margin of safety. For example we can increase the height of points P2 and P6.

By increasing the height of the point P2, the effort required between the points P1 and P2 is increased so that the mobile core 30 continues its course. This makes it possible to limit as much as possible the phase difference between the displacement of the mobile core 30 and the displacement of the launcher 12.

By increasing the height of the point P6, the effort required between the points P5 and P6 is increased so that the movable core 30 continues its course. This makes it possible to maximize the value of the bearing force of the pinion 20 against the drive ring 19 by extending the compression of the meshing spring 70 after the electrical contact. Thus the pinion 20 will benefit from a maximum propulsion force in the driving ring 19.

The margin of safety can also be used to optimize the magnetic characteristics of the contactor 16 in order to reduce manufacturing costs.

For example, copper is an expensive material in the manufacture of the switch 16. By decreasing the amount of copper used, the available load-bearing forces will be decreased by bringing the CP curve closer to the point P4.

In another type of starter, the meshing spring 70 is coaxially mounted on the armature shaft 18, between the launcher 12 and the lower end of the control lever 72. The invention also applies to this type of starter.

Claims (6)

<U> CLAIMS </ U> Motor vehicle starter (10), of the type comprising a contactor (16) provided with a magnetic coil (26) capable of exerting a magnetic attraction force on a movable magnetic core (30) to slide it inside the coil (26), of the type comprising a launcher (12) provided with a pinion (20) capable of meshing with a drive ring (19) of a heat engine when the launcher (12) is moved axially, of the type in which the displacements of the movable magnetic core (30) control the movements of the launcher (12) with the interposition of an elastic meshing element (70) to allow the movable magnetic core (30) to continue to sliding when a tooth (21) of the pinion (20) comes into axial abutment against a tooth (23) of the drive ring (19), characterized in that the elastic stiffness (R) of the elastic element of meshing (70) is nonlinear. 2. Starter (10) according to the preceding claim, characterized in that the elastic stiffness (R) of the elastic meshing member (70) increases with the stroke of the movable magnetic core (30) when the movable magnetic core (30) ) is attracted by the coil (26). 3. Starter (10) according to the preceding claim, characterized in that the elastic stiffness (R) of the elastic meshing member (70) takes a first value (R1) to a given point of the race of the core mobile magnet (30) from which said core (30) pushes a movable contact pin (32) axially, and the elastic stiffness (R) takes a second value (R2) greater than the first value (R1). 4. Starter (10) according to any one of the preceding claims, characterized in that the elastic meshing element (70) is arranged inside the movable magnetic core (30). 5. Starter (10) according to any one of claims 1 to 3, of the type in which the movable magnetic core (30) drives in its displacement a first end of a control lever (72) whose second end moves axially the launcher (12), characterized in that the meshing elastic element (70) is arranged between the launcher (12) and the lower end of the control lever (72). 6. Starter (10) according to any one of the preceding claims, characterized in that the elastic meshing member (70) is a helical spring.