FR2571783A1 - Meshing control device of the starter gear for an internal combustion engine starter motor - Google Patents

Abstract

An electromagnetic actuator 16 has its movable core 17 connected to a lever 19 enabling the gear 11 of the starter 9 to move axially, so as to come into engagement with the ring gear 12 of the engine. The "spring action of tooth against tooth" system, intervening in the event of abutment of the gear 11 teeth against those of the ring gear 12, comprises two springs 29, 30 of different flexibilities, which are successively compressed during the travel of the movable core 17. The two springs 29, 30 can be housed in a recess 31 in the movable core 17. Application to motor vehicle starter motors.

Description

"Launcher pinion gear control device,
for an internal combustion engine starter "
The present invention relates to a device for controlling the engagement of the starter pinion, for an internal combustion engine starter, in particular a motor vehicle engine starter. More particularly, this invention relates to starters in which the starter pinion is axially displaceable, for its engagement with a toothed ring for starting the internal combustion engine, from an electromagnetic actuator whose movable core is connected at one end of a lever, shaped like a fork, having its other ends linked to a freewheel trainer of the launcher.

 This device makes it possible, at each start-up, to temporarily engage the gear wheel of the starter which, moreover, is driven in rotation by means of the electric starter motor. When the electrical windings of the actuator are supplied, the axial displacement of the movable core, attracted by the fixed core, controls the pivoting of the lever which itself causes the axial displacement of the launcher with its pinion; the movement of the movable core also controls the closing of electrical contacts by which the electric motor of the starter is powered so as to rotate the pinion.

 In such meshing control devices, it is necessary to provide, in addition to the naturally necessary return springs, a special spring known as "tooth spring against tooth", which intervenes in the case where a tooth of the pinion of the starter is initially opposite a tooth of the toothed crown so that these teeth come into abutment against each other and that the interpenetration of the teeth is not immediately possible. The tooth against tooth spring allows in this case the complete stroke of the movable core of the actuator, so that the closing of the power supply contacts of the electric motor can take place, and this tooth against tooth spring stores mechanical energy necessary for penetration of the toothing of the starter pinion into that of the crown, after rotation of the pinion.

 In a known embodiment, the tooth against tooth spring is a single helicoidal spring placed between the movable core of the actuator and the first end of the engagement control lever.

 In all cases, the actuator should exert an electromagnetic attraction greater than the antagonistic force of compression or tensioning of the tooth-against-tooth spring, in order to compress this spring if necessary, or else the tension, depending on whether it is a spring working in compression or in tension. In order to have a sufficiently high attraction force, taking into account the travel of the mobile core and its distance from the fixed core in the rest position, the facing faces of the fixed core and of the movable core usually have complementary frustoconical shapes, of which obtaining it involves complicated and costly machining, and therefore increases the cost of the cores.

 The present invention aims to avoid these drawbacks, therefore to achieve more economically the fixed and movable cores of the electromagnetic actuator, while having a tooth-against-tooth spring system which can be suitably put in compression or in tension.

 To this end, the subject of the invention is a device for controlling the engagement of the starter pinion, for a starter of the type mentioned above, in which the tooth-to-tooth spring system comprises at least two springs of different flexibilities, mounted so as to come into action successively during the stroke of the movable core of the electromagnetic actuator.

 This double tooth-to-tooth spring system can be put in compression or in tension by an actuator exerting a weaker attraction force, all other things remaining equal, and without the efficiency of this system being reduced when its intervention is necessary. The fixed and mobile cores of the actuator can thus be produced with cylindrical external shapes and flat ends, and no longer with frustoconical shapes, therefore in a simpler and more economical manner while exerting one on the other a sufficient attraction.

These advantages are illustrated by the diagram in FIG. 1 of the appended drawing, in which the strokes (C) of the movable core are indicated on the abscissa, and the forces (F) are plotted on the ordinate. Curve (D) is representative of the attraction force exerted by an electromagnetic actuator whose cores have the usual frustoconical shapes, while curve (E) is representative of the attraction force exerted by the same actuator in which the cores have flat ends. The other plots in the diagram represent the opposing efforts that the actuator must overcome
The line (abdefgh) indicates the efforts to be overcome in the absence of abutment of the sprocket teeth against those of the crown, therefore without the intervention of the tooth-to-tooth spring system. After a race (C2), the jump ( de) corresponds to the preload of the return spring of the movable contact of the actuator, spring which compresses on the stroke (C2- C3), corresponding to the section (ef). At the end of the race (C3
C4), to which corresponds the section (gh), the pressure contact spring is compressed simultaneously with the return contact spring.

 The "tooth against tooth" operating domain, which will now be considered, corresponds to the portion (C1 - C2) of the stroke.

In the classic case of a tooth against single tooth spring, the forces to be overcome are represented by the line (a b c d 'e' f 'g h). After the stroke (C1), the toothing of the pinion abuts against that of the crown, and on the rest of the stroke (C1 - C2), compression of the tooth-against-tooth spring takes place, corresponding to the part of trace (c d '), the position of which requires that the force developed by the actuator follow the curve (D).

 On the stroke (C2 - C3), the portion of the trace (ex f ') corresponds to that (d e f) of the trace in operation without "tooth against tooth".

After the stroke (C3), the engagement of the pinion, driven in rotation by the starter motor, occurs in the crown; the effort to be overcome then drops suddenly (f 'g) and we return to the previous layout (g h) for the end of the race (C3 - C4).

By adopting the solution according to the invention, with double tooth-to-tooth spring, the forces to be overcome are represented by the line (abc 'c "d' e 'f' gh), which differs from the previous one in the operating field" tooth against tooth "(C1 - C2). On a first part (C1
C'1) of this domain, only the first spring, of greater flexibility, is compressed which corresponds to the portion of the trace (c 'c ") of relatively slight slope. On a second part (C'1 - C2) of the "tooth against tooth" operating range, the second spring of greater flexibility is also compressed, which gives the portion of the trace (c "d ') with a steeper slope than the previous one. All of these two portions of trace (c 'c "d') remains below the curve (E) of the neural action with cores having flat ends, which shows that thanks to the double tooth-against-tooth spring according to the invention it is possible to s '' accommodate slightly lower performance of such an actuator.

 According to an advantageous embodiment of the invention, the two tooth springs against tooth of different flexibility, are helical springs arranged coaxially and both housed inside a central recess of the movable core of the electromagnetic actuator. Thus, the double tooth-to-tooth spring system according to the invention occupies a minimum space requirement.

 In a particular construction, the spring of greater flexibility is a helical spring working in compression, mounted between a member for closing the recess of the movable core and a support element linked to a rod coupled to the first end of the lever. meshing control; the spring of smaller flexibility, mounted around the previous one, is also a helical spring working in compression, which is mounted between the closing member of the recess of the movable core and another support element slidably mounted inside this recess and capable of being either stopped against an interior shoulder of the recess, or driven by the displacement of the support element of the first spring. This first spring, of greater flexibility, acts either alone or by adding its effect to that of the second spring of smaller flexibility, the main function of which is to ensure rapid penetration of the teeth of the starter pinion into that of the crown, over a predetermined minimum distance.

In any case, the invention will be better understood with the aid of the description which follows, with reference to the appended schematic drawing representing, by way of nonlimiting example, an embodiment of this gear control device.
Figure 2 is an overall view, in longitudinal section, of an internal combustion engine starter equipped with the gear control device according to the invention;
Figure 3 is a sectional view, on an enlarged scale, showing the movable core of the actuator of this starter, with the double tooth spring against tooth system in the rest position;
Figure 4 is a sectional view similar to Figure 3, but showing the double tooth spring against tooth system in the compressed state.

 FIG. 2 represents a motor vehicle starter, comprising a direct current electric motor (1) with a stator (2) and a rotor (3) carried by a shaft (4) mounted rotating in two bearings (5,6). Near one of the bearings (5), the shaft (4) carries a blade collector (7) on which brushes (8) are applied. On the side close to the other bearing (6), the shaft (4) carries a launcher (9), mounted around this shaft (4) by means of helical grooves (10) allowing axial movement of the launcher ( 9). In a usual manner, the launcher (9) is composed of a pinion (11), capable of engaging with a ring gear (12) located on the flywheel, and of a driver with freewheel (13) .

 Along an axis (14) parallel to the axis (15) of the electric motor (1), an electromagnetic actuator (16) is disposed, the movable core (17) of which is connected, by means of a rod (18) terminated in a hook, at one end of a lever (19) mounted pivoting about an axis (20) disposed between the two parallel axes (14,15). The other end of the lever (19), shaped like a fork, is linked to the driver (13) of the launcher (9).

 The electromagnetic actuator (16) comprises an external armature (21) inside which are mounted electrical windings (22,23), surrounding a fixed core (24) traversed by a movable rod (25), slidably mounted along the axis (14). The rod (25) carries a movable electrical contact (26) which cooperates with two fixed electrical contacts (27,28), by -I'intermediate which the electric motor (1) is supplied.

 According to the invention, a system of double tooth-to-tooth spring (29,30) is arranged in the kinematic chain of meshing control, between the movable core (17) and the rod (18) coupled to the lever (19) . This system, more particularly shown in Figures 3 and 4, is housed inside a central recess (31) of the movable core (17), closed by a washer (32) crossed by the rod (18) and surrounded by 'a cup (33) on which bears a return spring (34) of the movable core (17).

 The first tooth against tooth spring (29), of greater flexibility, is a helical spring mounted around the rod (18) and compressed between the washer (32) and another washer (35) carried by the end of the rod (18) located inside the core (17). The second tooth against tooth spring (30), of smaller flexibility, is a helical spring mounted coaxially around the previous spring (29), and compressed between the washer (32) and a sleeve (36) with flange (37) able to slide in the direction of the axis (14), inside the recess (31). In the rest position, that is to say when the two springs (29,30) are relaxed, the washer (35) is supported towards the bottom of the recess (31), and the sleeve (36) is stopped , by its flange (37), against an inner shoulder (38) of the recess (31) - see Figure 3.

 During a start-up, and in the event of abutment of the teeth of the pinion (11) against those of the crown (12), the lever (19) is stopped in its pivoting around the axis (20) and the rod (18 ) cannot immediately follow the displacement of the movable core (17) along the axis (14). Thus, the washer (35) moves away from the bottom of the recess (31) and the spring (29) of greater flexibility is compressed, while the spring (30) of smaller flexibility remains first in its state initial. After a certain displacement of the movable core (17), the washer (35) abuts against the bush (36) and drives the latter, so that the spring of smaller flexibility (30) is also compressed - see FIG. 4 .

 When the electric motor (1), powered by the contacts (26,27,28), rotates the pinion (11), the spring of smaller flexibility (30) relaxes and ensures rapid penetration of the teeth on a predetermined minimum stroke.

 Thanks to this double tooth-to-tooth spring system (29,30), the two cores (17,24) of the electromagnetic actuator (16) can both have a cylindrical external shape with flat end faces located opposite one another, such as the end face (39) of the movable core (17) - see Figures 3 and 4.

 It goes without saying that the invention is not limited to the sole embodiment of this gear control device which has been described above, by way of example; on the contrary, it embraces all of the variant embodiments and applications respecting the same principle.

Thus, the same operating characteristics and the same advantages can be obtained by placing the double tooth spring against tooth in another location of the engagement control device, this double spring being able to be placed not only at the level of the actuator ( 16) but also at the launcher (9) or the pivot axis (20) of the lever (19), without departing from the spirit of the invention. The two springs of different flexibilities can work either in compression, in tension or in bending, depending on their type and arrangement;
One of these two springs can even be placed in a different location from the other spring.

Claims (5)

 1. Control device for meshing the starter pinion, for an internal combustion engine starter, in particular a motor starter of a motor vehicle, in which the pinion (11) of the starter (9) is axially displaceable, for sound. engagement with a ring gear (12). starting the internal combustion engine, from an electromagnetic actuator (16) whose movable core (17) is connected to one end of a lever (19) having its other end linked to a freewheeling drive (13 ) of the launcher (9), this meshing device comprising a "tooth against tooth spring" system intervening in the case where a tooth of the pinion (11) of the launcher (9) is initially facing a tooth of the crown (12), so as to allow the complete stroke of the movable core (17) of the actuator (16) and to store the mechanical energy necessary for the penetration of the teeth after rotation of the pinion (11) by the starter motor (1), characterized in that the tooth-to-tooth spring system comprises at least two springs (29,30) of different flexibilities, mounted so as to come into action successively during the stroke of the movable core (17) of the electromagnetic actuator (16).  2. gear control device according to claim 1, characterized in that the two springs of tooth against tooth, of different flexibility, are helical springs (29,30) arranged -coaxially and both housed at inside a central recess (31) of the movable core (17) of the electromagnetic actuator (16).  3. gear control device according to claim 2, characterized in that the spring of greater flexibility is a helical spring (29) working in compression, mounted between a closure member (32) of the recess (31) of the movable core (17) and a support element (35) linked to a rod (18) coupled to the first end of the engagement control lever (19), while the spring of smaller flexibility, mounted around the previous, is also a helical spring (30) working in compression, which is mounted between the closing member (32) of the recess (31) of the movable core (17) and another support element (36) slidably mounted inside this recess (31) and capable of being either stopped against an internal shoulder (38) of the recess (3 I), or driven by the displacement of the support element (35) of the first spring (29).  4. Gear control device according to claim 3, characterized in that the support element of the first helical spring (29), of greater flexibility, is a washer (35) carried by the rod (18) coupled to the lever (19), while the support element of the second helical spring (30), of smaller flexibility, is a sleeve (36) slidably mounted in the recess (31) of the movable core (17) and having a flange (37) cooperating with the inner shoulder (38) of the recess (31).  5. Gear control device according to any one of claims 1 to 4, characterized in that the movable core (17) of the electromagnetic actuator (16), as well as its fixed core (24), have a cylindrical outer shape with flat end faces (39) located opposite one another.