JP2007077810A - Starter - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To seal between a motor side and a reduction gear side with a simple construction and inhibit abnormal abrasion of an internal gear 20 due to vibration. <P>SOLUTION: A reduction gear 3 is disposed in a reduction gear chamber enclosed by a center case 19 and a plate 22. The plate 22 is installed between the reduction gear 3 and a motor so that foreign matter such as a brush powder does not enter the reduction gear chamber. The internal gear 20 is made of resin and a collar part 20a provided on an outer periphery on an axial plate side is pressed against the plate 22 with resilience to seal between the plate 22 and the internal gear 20. The internal gear 20 is caught between a front wall part 19c of the center case 19 and the plate 22 and when the pressing force of the collar part 20a acts on the plate 22, by the reaction, an end face 20c of the internal gear 20 on an opposite side to the plate is pressed against the front wall part 19c of the center case 19. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a starter including a planetary gear type reduction gear.

For example, the starter with a reduction gear described in Non-Patent Document 1 includes a plate 110 that partitions between a motor (not shown) and the planetary gear reduction gear 100 as shown in FIG. An elastic body 120 such as rubber is baked on the outer periphery of the plate 110, and the elastic body 120 is applied to the inner peripheral surface of the center case 130 that covers the outside of the speed reducer 100 and the end surface of the motor yoke 140. By being assembled in contact, brush powder generated inside the motor is prevented from entering the reduction gear 100 side.
NIPPON ELECTRONICS ENGINEERING REPORT Publication date: March 15, 1987 Reference number 52-132

However, in the above known technique (Non-Patent Document 1), the elastic body 120 manufactured in a separate process from the plate 110 is baked on the outer periphery of the plate 110, so that not only the number of parts increases but also the manufacturing cost increases. There is a problem of getting higher.
Further, there are two seal surfaces with which the elastic body 120 abuts, the inner peripheral surface of the center case 130 and the end surface of the motor yoke 140, and it is necessary to ensure the accuracy of the two seal surfaces, so the structure is complicated. Become.

  Furthermore, since a part of the elastic body 120 is sandwiched between the plate 110 and the motor yoke 140, the position of the plate 110 may be shifted in the axial direction due to the bending state of the sandwiched elastic body 120. When the plate 110 is displaced, the internal gear 150 sandwiched between the plate 110 and the front wall surface 131 of the center case 130 moves in the axial direction, so that excessive external vibration (for example, engine vibration, When the vehicle travels vibration, etc., is transmitted to the internal gear 150, the internal gear 150 may vibrate in the axial direction and wear abnormally.

  The present invention has been made based on the above circumstances, and its purpose is to seal between the motor side and the speed reducer side with a simple structure with respect to the plate disposed between the motor and the speed reducer. Another object of the present invention is to provide a starter that can suppress abnormal wear due to internal gear vibration.

(Invention of Claim 1)
The present invention relates to a motor that generates a rotational force in an armature by the action of electromagnetic force, a planetary gear type reduction device that reduces the rotation of the armature, and a plate that is disposed between the motor and the planetary gear type reduction device. In the starter for transmitting the rotation decelerated by the planetary gear type reduction gear to the gear on the engine side and starting the engine, the plate is a yoke of which the end surface on the counter reduction gear side forms the magnetic circuit of the motor. The internal gear that is arranged in contact with the axial direction and is used for the planetary gear type reduction gear is made of resin, and a flange portion having elasticity is provided integrally on the outer periphery of the internal gear. The portion is elastically pressed against the plate.

According to the present invention, the flange portion is provided on the resin internal gear itself, and the flange portion is elastically pressed against the plate. Can seal between internal gear. As a result, brush powder generated inside the motor can be prevented from entering the inside of the reduction gear, and the grease (particularly oil vaporized by temperature) applied to the gear portion of the reduction gear can be prevented from flowing out to the motor side. Can be prevented.
Further, in the above-described configuration, only one seal surface with which the collar portion abuts, that is, the surface of the plate, and it is only necessary to ensure the surface accuracy of the plate. In comparison, the seal structure can be made easily and inexpensively.

(Invention of Claim 2)
The starter according to claim 1, further comprising a center case disposed on the opposite side of the plate in the axial direction with the internal gear interposed therebetween, wherein the internal gear is sandwiched between the plate and the center case, The axial end surface on the side opposite to the plate is pressed against the center case by the reaction of the force with which the collar portion presses the plate.

According to the above configuration, the plate is pressed against the axial end surface of the yoke by the pressing force received from the collar portion, and the end surface on the side opposite to the plate of the internal gear held between the plate and the center case is pressed against the center case. Since it is applied, the internal gear and the plate can be prevented from moving in the axial direction. As a result, even when excessive external vibration is transmitted to the internal gear, the internal gear does not vibrate in the axial direction, and abnormal wear of the internal gear can be prevented.
Further, since the internal gear can be fixed in the axial direction, stable operation and durability of the reduction gear can be ensured.

(Invention of Claim 3)
The starter described in claim 1 or 2 is characterized in that the collar portion is pressed against the plate in a state of being opened radially outward of the internal gear.
In this case, since the collar portion is pressed against the plate while being bent outward, the elasticity of the collar portion can be effectively transmitted to the plate, and the gap between the plate and the internal gear can be reliably sealed.

  The best mode for carrying out the present invention will be described in detail with reference to the following examples.

  FIG. 1 is a cross-sectional view showing the configuration of the planetary gear speed reducer 3, and FIG. 3 is a half cross-sectional view of the starter 1. The starter 1 shown in the first embodiment includes a motor 2 that generates a rotational force, a speed reducer 3 that decelerates the rotation of the motor 2, and an output shaft 4 to which driving torque of the motor 2 is transmitted via the speed reducer 3. And a pinion gear 6 disposed integrally with the clutch 5 on the outer periphery of the output shaft 4 and a function of pushing the clutch 5 and the pinion gear 6 in the counter-motor direction (left direction in FIG. 1) via the shift lever 7. And an electromagnetic switch 8 for opening and closing a main contact (not shown) provided in the motor circuit.

The motor 2 has a field configured by arranging a plurality of field coils 10 on the inner periphery of the yoke 9, and an armature 11 disposed on the inner periphery of the field, and the armature is generated by electromagnetic force. 11 is a known DC motor that generates a rotational force. The field coil 10 is wound around a field pole 12 fixed to the inside of the yoke 9, and forms a magnetic field when a starting current flows. A permanent magnet can be used instead of the field coil 10.
The armature 11 includes an armature shaft 13 that is rotatably supported, an armature core 14 that is serrated and fitted to the outer periphery of the armature shaft 13, and an armature that is wound around the armature core 14. The coil 15 is composed of a commutator 16 provided on one end side (the right side in FIG. 3) of the armature shaft 13, and a plurality of carbon brushes 17 are arranged on the outer periphery of the commutator 16.

As shown in FIG. 1, the speed reducer 3 includes a sun gear 18 formed on the side opposite to the commutator of the armature shaft 13, an annular internal gear 20 whose rotation is restricted by a center case 19, and both gears 18, 20. Is a well-known planetary gear type reduction gear constituted by a planetary gear 21 and the like meshing with each other, and is arranged in a reduction gear chamber surrounded by a center case 19 and a plate 22.
The center case 19 includes an outer cylindrical portion 19a that is fitted in the front end portion of the yoke 9, an bearing portion 19b that rotatably supports the output shaft 4 via a bearing 23, an outer cylindrical portion 19a, and a bearing portion 19b. And a front wall portion 19c that is connected and closes the non-motor side of the speed reducer 3.

The plate 22 is disposed between the speed reducer 3 and the motor 2 so that foreign matter such as brush powder generated by the wear of the brush 17 does not enter the speed reduction gear chamber, and a collar portion provided on the internal gear 20. It is pressed against the axial end surface of the yoke 9 under the elasticity of 20a (described below).
The internal gear 20 is made of resin, and a collar portion 20a is integrally provided on the outer peripheral portion on the axial plate side. As shown in FIG. 2, the collar portion 20a is open to the outside of the internal gear 20 in a trumpet shape as shown in FIG. Projecting from the end face 20b in the axial direction of the internal gear 20 that contacts the plate 22.

When the internal gear 20 is assembled to the plate 22 from the axial direction, the tip of the collar portion 20a first contacts the plate 22 before the axial end surface 20b of the internal gear 20 contacts the plate 22. Thereafter, when the internal gear 20 is moved to the plate 22 side until the axial end face 20b comes into contact with the plate 22, the collar portion 20a bends outwards, thereby generating elasticity in the collar portion 20a and pressing the plate 22. .
Further, the internal gear 20 is sandwiched between the front wall portion 19c of the center case 19 and the plate 22, and when the pressing force of the flange portion 20a acts on the plate 22, the reaction causes the anti-plate of the internal gear 20 to counteract. The side end surface 20c (see FIG. 1) is pressed against the front wall portion 19c of the center case 19.

The output shaft 4 is disposed on the same axis as the armature shaft 13, and one end side is provided integrally with the carrier plate 24 of the speed reducer 3, and the other end side end portion is freely rotatable to the housing 26 via the bearing 25. It is supported by. A support pin 27 that rotatably supports the planetary gear 21 is fixed to the carrier plate 24.
The clutch 5 is fitted to a helical spline 4a formed on the output shaft 4 so as to be movable on the output shaft 4. The clutch 5 transmits the rotation of the output shaft 4 to the pinion gear 6 when the engine is started, and the pinion gear 6 is connected to the engine. As a one-way clutch that cuts off the power transmission between the two so that the rotation of the pinion gear 6 is not transmitted to the output shaft 4 when the rotation speed of the pinion gear 6 exceeds the rotation speed of the output shaft 4. It is configured.

The pinion gear 6 is disposed on the non-motor side of the clutch 5, moves on the output shaft 4 in the anti-motor direction integrally with the clutch 5, meshes with an engine ring gear (not shown), and then passes through the clutch 5. The transmitted rotational force is transmitted to the ring gear.
The electromagnetic switch 8 includes an excitation coil (not shown) that is energized from the battery to form an electromagnet when a start switch (not shown) is closed, and a plunger (not shown) inserted inside the excitation coil. When the electromagnet is formed by energizing the exciting coil, the plunger is attracted to the electromagnet to close the main contact of the motor circuit. When the energization of the exciting coil is stopped and the attraction force of the electromagnet disappears, the plunger is pushed back by the reaction force of a return spring (not shown) to open the main contact.

  The shift lever 7 has a lever fulcrum portion 7a that is rotatably supported by the lever holder 28. A lever end portion 7b on one end side of the lever fulcrum portion 7a is connected to the plunger of the electromagnetic switch 8, and the lever fulcrum portion The lever end 7 c on the other end side from 7 a is engaged with the clutch 5, and the movement of the plunger is transmitted to the clutch 5. That is, when the plunger is attracted by the electromagnet and moved, the lever end portion 7b connected to the plunger is pulled and moved by the plunger, so that the lever end portion 7c engaged with the clutch 5 is centered on the lever fulcrum portion 7a. It swings and pushes the clutch 5 in the direction opposite to the motor.

Next, the operation of the starter 1 will be described.
When the electromagnet is formed by energizing the exciting coil of the electromagnetic switch 8 by closing the start switch, the plunger is attracted to the electromagnet and moves rightward in FIG. When this movement of the plunger is transmitted to the clutch 5 through the shift lever 7, the clutch 5 moves together with the pinion gear 6 on the output shaft 4 in the counter-motor direction, so that the end surface of the pinion gear 6 contacts the end surface of the ring gear. Stop in contact.

  On the other hand, when the main contact of the motor circuit is closed by the movement of the plunger, the motor 2 is energized from the battery, and a rotational force is generated in the armature 11 by the action of the electromagnetic force generated in the field. When the rotation of the armature 11 is decelerated by the speed reducer 3 and transmitted to the output shaft 4 and further transmitted from the output shaft 4 to the pinion gear 6 via the clutch 5, the pinion gear 6 reaches a position where it can mesh with the ring gear. By rotating and meshing with the ring gear, the rotational force is transmitted from the pinion gear 6 to the ring gear, and the engine is cranked.

When the engine is started from the cranking and the start switch is opened, the attraction force disappears by stopping the energization of the exciting coil, so that the plunger is pushed back by the reaction force of the return spring (not shown). As a result, when the main contact of the motor circuit is opened, energization from the battery to the motor 2 is stopped, and the rotation of the armature 11 is stopped.
When the plunger is pushed back, the shift lever 7 swings in the direction opposite to that at the time of engine start, so that the clutch 5 and the pinion gear 6 move backward on the output shaft 4 and move to the stop position shown in FIG. .

(Effect of Example 1)
The starter 1 is provided with a flange portion 20a on the resin internal gear 20, and the flange portion 20a is elastically pressed against the plate 22, so that another part such as a seal member is used. In addition, the space between the plate 22 and the internal gear 20 can be sealed. Further, since the outer peripheral portion of the plate 22 is pressed against the axial end surface of the yoke 9 by the pressing force (elasticity) of the collar portion 20a, the gap between the plate 22 and the yoke 9 can be eliminated. Thus, foreign matter such as brush powder generated by the wear of the brush 17 can be prevented from entering the reduction gear chamber, and the grease (particularly oil content evaporated by temperature) applied to the gear portion of the reduction gear 3 can be prevented. Further, it can be prevented from flowing out to the motor 2 side.

Further, in the above configuration, only one sealing surface with which the collar portion 20a abuts, that is, the surface of the plate 22, and only the surface accuracy of the plate 22 needs to be ensured. Compared with 1), the seal structure can be made easily and inexpensively.
Further, the plate 22 is pressed against the axial end surface of the yoke 9 by the pressing force received from the collar portion 20a, and is held between the plate 22 and the front wall portion 19c of the center case 19 on the opposite plate side of the internal gear 20. Since the end surface 20c is pressed against the front wall portion 19c of the center case 19, the internal gear 20 and the plate 22 can be prevented from moving in the axial direction. As a result, even when excessive vibration such as engine vibration is transmitted to the internal gear 20, the internal gear 20 does not vibrate in the axial direction, so that abnormal wear of the internal gear 20 can be prevented and the speed reducer 3 stable operation and durability can be secured.

(Modification)
In the first embodiment, an example in which the plate 22 is pressed against the axial end surface of the yoke 9 by receiving the elasticity of the flange portion 20a provided on the internal gear 20, is described. The plate 22 can also be positioned. For example, as shown in FIG. 4, a plurality of projecting portions 9 a may be provided inside the yoke 9, and the outer peripheral portion of the plate 22 may be pressed against the projecting portions 9 a for positioning.

It is sectional drawing which shows the structure of a reduction gear. It is sectional drawing which shows the shape of the collar part provided in the internal gear. It is a half sectional view of a starter. It is sectional drawing which shows the positioning means of the plate with respect to a yoke (modified example). It is sectional drawing which shows the structure of the speed reducer which concerns on a well-known technique.

Explanation of symbols

1 Starter 2 Motor 3 Planetary Gear Reducer 9 Yoke 11 Armature 19 Center Case 19c Front Wall (Center Case)
20 Internal gear 20a Collar 22 Plate

Claims (3)

A motor that generates a rotational force on the armature by the action of electromagnetic force;
A planetary gear reducer that decelerates the rotation of the armature;
A plate disposed between the motor and the planetary gear reducer;
In the starter for starting the engine by transmitting the rotation decelerated by the planetary gear type reduction gear to the gear on the engine side,
The plate is disposed such that the end surface on the side of the anti-reduction gear contacts the axial direction of the yoke that forms the magnetic circuit of the motor,
The internal gear used for the planetary gear type reduction gear is made of resin, and a flange portion having elasticity is provided integrally on the outer periphery of the internal gear, and this flange portion has elasticity on the plate. The starter is characterized by being pressed. The starter according to claim 1,
A center case disposed on the opposite side of the plate in the axial direction across the internal gear;
The internal gear is sandwiched between the plate and the center case, and the axial end surface on the side opposite to the plate is pressed against the center case by the reaction of the force with which the flange portion presses the plate. A starter characterized by The starter according to claim 1 or 2,
The starter characterized in that the collar portion is pressed against the plate in a state of being opened radially outward of the internal gear.

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