KR101235536B1 - Electromagnetic switch device for starter - Google Patents

Abstract

[assignment]
It is an object of the present invention to provide an electronic switch device for a starter which can be miniaturized by arranging an electromagnetic relay and an electromagnet in a coaxial series.
[Solution]
An electromagnetic relay having a movable iron core and a fixed iron core for opening and closing a motor circuit, and an electromagnet having a movable iron core and a fixed iron core for moving the pinion gear in a ring gear direction, wherein the central axis of the movable iron core of the electromagnetic relay and the electromagnet are movable. An electronic switch device for starters, in which a central axis of an iron core is arranged in series on a coaxial axis, and a magnetic circuit of the electromagnetic relay and an outer border forming a magnetic circuit of the electromagnet and an iron border forming an outer border are integrally formed. The winding of the electromagnet is provided to protrude from the edge, the winding of the electromagnetic relay is engaged through the edge, and has a rescue portion for protecting the rescue line of the excitation coil of the electromagnet.

Description

Electronic switch device for starter {ELECTROMAGNETIC SWITCH DEVICE FOR STARTER}

The present invention relates to a starter electronic switch device for starting an engine mounted on an automobile or the like, for example.

Background Art Conventionally, many engine starters have been particularly used, but in recent years, automobiles equipped with an idle stop function have been increasing as a method for improving fuel efficiency of automobiles. When the starter is used for restarting after the idle stop as in the normal engine start-up, the use frequency of the starter is increased, so the durability of the starter is required.

On the other hand, in the engine room of a vehicle, a large number of components, such as a gearbox necessary for driving the engine and a transmission necessary for transmitting power from the engine, to the tire, are disposed in addition to the engine body and the starter. The surrounding area is densely packed with other components. In recent years, the number of component parts has increased and component parts have been enlarged to improve engine performance. Therefore, the importance of miniaturization of starters has increased.

As a conventional starter electronic switch device, for example, a starter structure for starting the engine shown in Japanese Unexamined Patent Application Publication No. 56-42437 (see Patent Document 1) is known. The structure is provided with the electromagnetic force means which engages a pinion with a ring gear, and the electronic switch provided in parallel with this electromagnetic force means.

Since the electronic switch device for starters described in the above-described conventional patent document 1 is provided with a technique for preventing a poor engagement of the pinion gear and the ring gear, it is effective for mounting on an automobile having an idle stop function. Since the means and the electronic switch protrude from the radially outer periphery of the motor, there is a problem that it is contrary to the miniaturization of the starter as a whole.

This invention is made | formed in order to solve the above subjects, and an object of this invention is to provide the starter electronic switch apparatus which can be miniaturized by arrange | positioning an electromagnetic relay and an electromagnet in coaxial series.

The electronic switch apparatus for starters which concerns on this invention is equipped with the electromagnetic relay which has a movable iron core and a fixed iron core which open and close a motor circuit, and the electromagnet which has a movable iron core and a fixed iron core which move a pinion gear to a ring gear direction, The said electromagnetic relay The central axis of the movable iron core of the electromagnet and the central axis of the movable iron core of the electromagnet are arranged in series on the same coaxial axis, and the magnetic circuit of the electromagnetic relay and the yoke that constitutes the outer edge and the magnetic circuit of the electromagnet that constitute the outer edge In this integrally configured starter electronic switch device,
The electromagnetic relay has an exciting coil wound around the winding edge, the electromagnet has an exciting coil wound around the winding edge, and a battery terminal and a motor terminal are arranged, and a terminal block having a fitting hole formed on the winding edge side of the electromagnetic relay. The winding of the electromagnet is provided to protrude from the edge, and the winding of the electromagnetic relay is engaged through the edge, and the positioning of the winding edge of the electromagnetic relay and the winding edge of the electromagnet is performed while positioning. A rescue portion for protecting the rescue line of the excitation coil of the electromagnet and the winding of the electromagnetic relay is provided to protrude from an edge, and penetrates through the fixed iron core of the electromagnetic relay and engages with the fitting hole of the terminal block; And above the rotational direction of the winding edge of the electromagnetic relay A decision with doing it one comprising a rescue for protecting the lead wire of the exciting coil of the electromagnetic relay.

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The electronic switch device for starters according to the present invention arranges an electromagnetic relay and an electromagnet in a coaxial series, protrudes from the winding edge of the electromagnet, is engaged through the winding edge of the electromagnetic relay, and is coupled to the exciting coil of the electromagnet. By providing a rescue portion that protects the rescue line, a starter electronic switch device capable of miniaturization and positioning of the winding edge of the electromagnetic relay and the winding edge of the electromagnet can be obtained.

Moreover, the electronic switch device for starters which concerns on this invention is provided by providing the excitation terminal of an electromagnet and the excitation terminal of an electromagnetic relay in one area | region of the two area | region which divided the center of the battery terminal and the motor terminal by the line which connected it, The electronic switch device for starters which can improve workability can be obtained.

BRIEF DESCRIPTION OF THE DRAWINGS The block diagram which shows the starter which mounts the electronic switch device for starters which concerns on Embodiment 1 of this invention in partial cross section.
Fig. 2 is a connection diagram of a starter equipped with the electronic switch device for starters according to Embodiment 1 of the present invention.
Fig. 3 is a view of the electronic switch device for starters according to Embodiment 1 of the present invention as viewed from the terminal block side.
Fig. 4 is a longitudinal sectional view of Fig. 3 in the electronic switch device for starters according to Embodiment 1 of the present invention.
Fig. 5 is a cross-sectional view of Fig. 3 in the electronic switch device for starters according to Embodiment 1 of the present invention.
Fig. 6 is a view of the starter electronic switch device according to Embodiment 1 of the present invention as viewed from the bottom side of yoke.
FIG. 7 is a cross-sectional view taken along the line AA of FIG. 5 showing the electronic switch device for starter according to Embodiment 1 of the present invention. FIG.
Fig. 8 is a view of the winding edge of an electromagnetic relay in the electronic switch device for starters according to Embodiment 1 of the present invention, as viewed from the terminal block side.
Fig. 9 is a cross-sectional view of the winding edge of the electromagnetic relay in line BB of Fig. 5 showing the electronic switch device for starters according to Embodiment 1 of the present invention.
FIG. 10 is a cross-sectional view taken along line CC of FIG. 5 showing an electronic switch device for starter according to Embodiment 1 of the present invention. FIG.
The figure which looked at the edge of the electromagnet wound in the electronic switch device for starters which concerns on Embodiment 1 of this invention from the terminal block side.
Fig. 12 is a view of the winding edge of an electromagnet in the electronic switch device for starters according to Embodiment 1 of the present invention, as viewed from the bottom of yoke.
Fig. 13 is a sectional view showing the electronic switch device for starter according to Embodiment 2 of the present invention.
Fig. 14 is a view of the electronic switch device for starters according to Embodiment 3 of the present invention as viewed from the terminal block side.
Fig. 15 is a sectional view of the starter electronic switch device according to Embodiment 3 of the present invention, taken along line AA of Fig. 5.
Fig. 16 is a view of the winding edge of an electromagnetic relay in the electronic switch device for starters according to Embodiment 3 of the present invention, as viewed from the terminal block side.
Fig. 17 is a sectional view of a border of an electromagnetic relay corresponding to the line BB of Fig. 5 in the electronic switch device for starter according to Embodiment 3 of the present invention.
Fig. 18 is a cross-sectional view of a winding frame of an electromagnet corresponding to CC line of Fig. 5 in the electronic switch device for starter according to Embodiment 3 of the present invention.
Fig. 19 is a view of the electromagnet winding edge of the starter electronic switch device according to Embodiment 3 of the present invention as viewed from the terminal block side.

Embodiment Mode 1.

EMBODIMENT OF THE INVENTION Hereinafter, Embodiment 1 of this invention is described based on FIG. BRIEF DESCRIPTION OF THE DRAWINGS It is a block diagram which shows the starter which mounts the electronic switch device for starters which concerns on Embodiment 1 of this invention in partial cross section. Fig. 2 is a connection diagram of a starter equipped with the electronic switch device for starters according to Embodiment 1 of the present invention. Fig. 3 is a view of the starter electronic switch device according to Embodiment 1 of the present invention as seen from the terminal block side. FIG. 4 is a longitudinal cross-sectional view of FIG. 3 in the electronic switch device for starter according to Embodiment 1 of the present invention. FIG. FIG. 5 is a cross-sectional view of FIG. 3 in the electronic switch device for starter according to Embodiment 1 of the present invention. FIG. It is a figure which looked at the electronic switch device for starters which concerns on Embodiment 1 of this invention from the bottom side of yoke. FIG. 7 is a cross-sectional view taken along the line A-A of FIG. 5 showing the starter electronic switch device according to Embodiment 1 of the present invention. FIG. Fig. 8 is a view of the winding edge of the electromagnetic relay in the electronic switch device for starters according to Embodiment 1 of the present invention, as viewed from the terminal block side. Fig. 9 is a cross-sectional view of the winding edge of the electromagnetic relay in the line B-B in Fig. 5 showing the electronic switch device for starter according to Embodiment 1 of the present invention. FIG. 10 is a cross-sectional view taken along the line C-C of FIG. 5 showing the electronic switch device for starter according to Embodiment 1 of the present invention. FIG. It is a figure which looked at the edge frame of the electromagnet in the electronic switch device for starters which concerns on Embodiment 1 of this invention from the terminal block side. It is a figure which looked at the winding edge of the electromagnet in the electronic switch device for starters which concerns on Embodiment 1 of this invention from the bottom side of yoke.

In each of these figures, the starter includes a motor 1 for generating a rotational force, an output shaft 2 for extracting the rotational force from the motor 1, and is slidably disposed on the output shaft 2 in an axial direction. The overrunning clutch 3, from which the rotational force of the motor 1 is transmitted, is a component of the overrunning clutch 3 and the rotational force of the motor 1 transmitted to the overrunning clutch 3 is transmitted to the ring gear 4 of the engine. And a pinion gear (5) to be transmitted to), a main contact point (6) constituting a motor circuit, and an electromagnetic relay (7) for opening and closing the main contact point (6), and the electromagnetic relay (7) and Electronic switch device for starter having an electromagnet 9 arranged coaxially on the axial shift lever 8 side and moving the pinion gear 5 in the ring gear 4 direction via the axial shift lever 8. (10) is provided.

Next, the structure of the electronic switch device 10 for a starter is demonstrated in FIGS. The starter electronic switch device 10 is roughly divided into a yoke 12, an electromagnetic relay 7, and an electromagnet 9. It is housed in the order of the electromagnet 9 and the electromagnetic relay 7 in the yoke 12, and is comprised and functions as the electronic switch device 10 for a starter.

First, the yoke 12 is a magnetic material for forming a magnetic circuit of the electromagnetic relay 7 and the electromagnet 9, and is a cup-shaped component which integrally forms the outer circumference of the electromagnetic relay 7 and the electromagnet 9. And a caulking portion 12b, a fitting portion 12c, a body portion 12d, a bottom portion 12a, a female screw 12e, and a through hole 12f. The caulking portion 12b is provided at the opening end and is a thin cylindrical shape that is bent to the inner circumferential side after the terminal block 11 is inserted, and the fitting portion 12c is the first fixed iron core 14 of the electromagnetic relay 7. ) Is fitted, and the electromagnet 9 and the electromagnetic relay 7 are inserted into the inner circumference of the trunk portion 12d. The bottom portion 12a abuts against the front bracket 15, and the female screw 12e is provided for fastening to the front bracket 15 with a fastening screw (not shown), and the through hole 12f is penetrated by the support member 16. The movable iron core 17 of the electromagnet 9 engaged with the axial shift lever 8 is slidably provided.

Next, the electromagnetic relay 7 will be described. The electromagnetic relay 7 includes a movable iron core 18, an excitation coil 19, a winding edge 20, a support member 21, a first fixed iron core 14, a second fixed iron core 22, and a packing ( 23, a rod 24, a return spring 25, a terminal block 11, and a nonmagnetic member 13.

The movable iron core 18 is a magnetic material, constitutes a magnetic circuit, is biased toward the second fixed iron core 22 in the axial direction by the force of the return spring 25, and axially slides on the inner circumferential surface of the support member 21. Possibly supported.

The excitation coil 19 is a conductive material, wound around the winding edge 20, and the end of the excitation coil 19 is drawn out from the relief portions 20a and 20b of the winding edge 20 as the rescue lines 19a and 19b. do. FIG. 7 is a cross-sectional view taken along the line A-A in FIG. 5 and shows the states of the rescue lines 19a and 19b drawn out from the winding border 20. As shown in FIG. The winding start side rescue line 19a, which is one end, passes through the rescue portion 20a and the fixing member 26, is drawn out of the terminal block 11, and is fixed to the excitation terminal 27 so as to be electrically conductive. The winding end side rescue line 19b, which is the other end, passes through the rescue portion 20b and is drawn out to the terminal block 11 side of the fixed iron core 14, and conducts to the end face of the fixed iron core 14 side of the terminal block 11 side. Possibly fixed.

The winding edge 20 is an insulating material, and consists of a trunk | drum, the wall of the terminal block 11 side, and the wall of the electromagnet 9 side. The trunk | drum is hollow cylindrical shape, and the exciting coil 19 is wound in the space which consists of a trunk | drum, the wall of the terminal block 11 side, and the wall of the electromagnet 9 side. The wall on the side of the terminal block 11 has a contact surface of the fixed iron core 14 and rescue portions 20a and 20b protruding toward the terminal block 11 side, and excitation coils are provided from the grooves provided in the rescue portions 20a and 20b. Rescue lines 19a and 19b of 19 are drawn out. The rescue section is provided with an excitation coil 28 of the electromagnet 9 together with a rescue section 20a for drawing the winding start side rescue line 19a of the electromagnetic relay 7 and a winding end rescue line 19b of the electromagnetic relay 7. There is a relief part 20b which draws out the winding start side rescue line 28a of (), and is provided in the position facing 180 degrees, penetrates the notch 14a of the 1st fixed iron core 14, and makes the terminal block 11 ) Is positioned in the rotational direction by fitting into the fitting hole 11a of FIG. The relief portion 20b is provided with a wall 20c therein to insulate between the rescue line 28a of the electromagnet 9 and the rescue line 19b of the electromagnetic relay 7. In addition, there is a wall on the outer circumferential side to electrically insulate between the rescue line 28a and the yoke 12. The notch 20d which penetrates the rescue part 29a of the winding edge 29 of the electromagnet 9 mentioned later is provided in the wall of the electromagnet 9 side, and the rescue part 29a of this electromagnet 9 is wound up and wound up. Positioning of the rotational direction of the winding border 20 of the electromagnetic relay 7 and the winding border 29 of the electromagnet 9 is performed by the notch 20d of the edge 20. 20e is an insertion groove, and the rescue line 19a is inserted. 20f is a fitting part, and the outer periphery shading part which the support member 21 does not show is fitted. 20g is a hollow part of the winding border 20. 20h is an insertion hole, and the rescue line 28a is inserted.

The support member 21 is made of a nonmagnetic material, is provided on the inner circumference of the trunk portion of the winding border 20, the inner circumferential surface forms a sliding surface of the movable iron core 18, and the end portion on the side of the second fixed iron core 22 is The inner periphery of the second fixed iron core 22 is fitted. The inner circumferential surface of the end portion on the side of the first fixed iron core 14 of the supporting member 21 is fitted to the outer circumference of the first fixed iron core 14. The end part of the side of the 1st fixed iron core 14 is bent outward, and it is pinched | interposed and fixed between the 1st fixed iron core 14 and the winding edge 20. As shown in FIG. The inner circumferential surface of the terminal block 11 except for the fitting portion forms the sliding surface of the movable iron core 18.

The first fixed iron core 14 is a magnetic material, constitutes a magnetic circuit, a portion having a small outer diameter is fitted to the inner circumference of the support member 21, a portion having a large outer diameter is fitted to the yoke 12, and a terminal block ( The end face on the 11) side is the contact surface of the packing 23, and the surface on which the excitation coil 19 winding end side rescue line 19b is electrically conductively fixed, and the end face on the movable iron core 18 side is the contact surface of the movable iron core 18. In the center, the rod 24 is provided with a through hole which can slide in the axial direction. Rescue of the edge 20 to the first fixed iron core 14 to wind the external force (battery terminal 30, the tightening torque when the nut 32 is fastened to the motor terminal 31) applied to the terminal block 11 Since it is necessary to take out through the parts 20a and 20b, the inner diameter of the yoke 12 and the outer diameter of the 1st fixed iron core 14 are the dimension setting of interference fit. For example, the inner diameter of the yoke 12 is a dimension setting of the outer diameter of the 1st fixed iron core 14.

The second fixed iron core 22 is a magnetic material, constitutes a magnetic circuit, the support member 21 is fitted to the inner circumferential surface, and the outer circumferential portion is fitted to the yoke 12. Unlike the first fixed iron core 14, since the external force does not need to be subjected to external force, the inner diameter of the yoke 12 and the outer diameter of the second fixed iron core 22 are dimensional settings of a loose fit, but the fitting portion ( Since 22a) constitutes a magnetic circuit, the gap is set to a small minimum. For example, the inner diameter of the yoke 12> dimension setting of the outer diameter of the 2nd fixed iron core 22 is carried out.

The packing 23 is an insulating material having elasticity, and is provided with a contact pressure applied to a gap between the first fixed iron core 14 and the terminal block 11, and the inner wall of the terminal block 11 and the first fixed iron core. The contact chamber 37b which is a space comprised between the 14 is waterproofed.

The contact member 34, the insulating materials 35a and 35b, and the movable contact 36 are slidably supported by the rod 24 in the axial direction. The contact spring 34 biases the movable contact 36 in the direction of the fixed contacts 30a and 31a, and the insulating materials 35a and 35b insulate the movable contact 36, so that the movable contact 36 is fixed to the fixed contact 30a, 31a).

The return spring 25 is provided between the terminal block 11 and the fixing member 33 to bias the rod 24 and the movable iron core 18 in the direction of the second fixed iron core 22.

In the terminal block 11, a fixing member 26 for fixing the insulating member 37, the exciting terminal 27 of the electromagnetic relay 7, the exciting terminal 38 of the electromagnet 9, and the exciting terminals 27 and 38, The battery terminal 30, the motor terminal 31, the packing 39, the fixing member 40 which fixes the battery terminal 30 and the motor terminal 31 is provided.

The insulating member 37 is an insulating material and is movable in the direction of the through-hole 37a for fixing the excitation terminals 27 and 38, the battery terminal 30, the motor terminal 31, and the fixed contacts 30a and 31b. The contact chamber 37b which is the space which 36 can move to an axial direction, and the contact surface 37c of the packing 23 are provided in the cross section by the side of the 1st fixed iron core 14 side. The excitation terminals 27 and 38 are terminals for attaching and detaching the wiring and the excitation coils 19 and 28 on the vehicle side, and the fixing member 26 has a hollow cylindrical shape through which the rescue lines 19a and 28a pass. The excitation terminals 27 and 38 are fixed by pushing the end portions together, and the battery terminals 30 are fixed to the movable contact 36 side by the fixed contact 30a constituting the main contact 6 and the vehicle side on the opposite side thereof. And a screw portion 30b to which wiring from a battery of the battery is connected, and the motor terminal 31 has the fixed contact 31a constituting the main contact point 6 on the movable contact 36 side and the motor 1 on the opposite side thereof. The screw part 31b to which the wiring from is connected is provided, and the battery terminal 30 and the motor terminal 31 are fixed to the insulating member 37 by the fixing member 40.

The nonmagnetic member 13 is a nonmagnetic material, and separates the magnetic circuits of the electromagnetic relay 7 and the electromagnet 9, and the cross section on the side of the electromagnetic relay 7 has the movable iron core 18 and the second fixed iron core ( 22), the end face on the electromagnet 9 side abuts on the fixed iron core 41, and the inner end is in the dimensional relationship of the interference fitting with the second fixed iron core 22. As shown in FIG. For example, the inner diameter of the nonmagnetic member 13 is in the dimensional relationship of the outer diameter of the second fixed iron core 22.

Next, the electromagnet 9 will be described. The electromagnet 9 includes an excitation coil 28, a winding edge 29, a support member 16, a fixed iron core 41, a return spring 42, and a movable iron core 17.

The exciting coil 28 is a conductive material, wound around a winding edge, and an end of the exciting coil 28 is drawn out from the rescue portion of the winding edge as a rescue line. FIG. 10 is a cross-sectional view taken along the line C-C of FIG. 5 and showing the relief portion of the electromagnet 9. The winding start side rescue line 28a, which is one end, passes through the rescue portion 29a of the electromagnet 9, the rescue portion 20b of the electromagnetic relay 7, and the fixing member 26 to the outside of the terminal block 11. And the conductive terminal 38 is electrically fixed. The winding end side rescue line 28b, which is the other end, passes through the rescue portion 29b, is drawn out to the electromagnetic relay 7 side of the fixed iron core 41, and is conducted to the end face of the electromagnetic relay 7 side of the fixed iron core 41. Possibly fixed.

The winding edge 29 is an insulation material, and the excitation coil 28 is wound in a space composed of a body portion, a wall on the fixed iron core 41 side, and a wall on the bottom side, and protrudes from the wall on the fixed iron core 41 side. The rescue line of the excitation coil 28 is taken out from the rescue parts 29a and 29b. Fig. 11 is a view of the winding border 29 in the direction of Fig. 3, and Fig. 12 is a view of the winding border 29 in the direction of Fig. 6, wherein the rescue portion is a rescue portion that pulls out the winding start side rescue line 28a. A rescue portion 29b for taking out 29a and the winding end side rescue line 28b is provided at a position facing 180 ° and penetrates the notch of the fixed iron core 41. Regarding the rescue portion 29a which draws out the winding start side rescue line 28a, the winding end side rescue line 28b is provided to protect the contact coil 19 of the electromagnetic relay 7 from contact with the yoke 12. Protrudes to the vicinity of the wall on the side of the terminal block 11 of the winding edge 20 of the electromagnetic relay 7 longer than the rescue portion 29b for extracting the. Since this rescue part 29a penetrates the notch 20d of the winding edge 20 of the electromagnetic relay 7, the edge 29 of the electromagnet 9 is wound around the rescue part 29a and the notch part 20d. ) And positioning of the rotational direction between the winding border 20 of the electromagnetic relay 7 is configured. Moreover, the relief part 29c of the fastening screw 12e which penetrated the female thread 12e of the yoke 12 is provided in the bottom part 12a side. In addition, 29d is a flat part connected with the relief part 29c by the bottom part 12a side. 29e is an insertion groove, and the rescue line 28b is inserted. 29f is a fitting part, and the outer peripheral shading part which the support member 16 does not show is fitted. 29g is a hollow part of the winding border 29. 29h is an insertion groove, and the rescue line 28a is inserted.

The support member 16 is made of a nonmagnetic material, and is provided on the inner circumference of the trunk portion of the winding border 29, the inner circumferential surface forms a sliding surface of the movable iron core 17, and the end portion on the bottom 12a side is yoke 12. The inner circumferential surface of the end portion on the fixed iron core 41 side is fitted to the outer circumference of the fixed iron core 41. The end portion of the fixed iron core 41 side is bent outward and is pinched and fixed between the fixed iron core 41 and the winding edge 29.

The fixed iron core 41 is a magnetic material, constitutes a magnetic circuit, a portion having a small outer diameter is fitted to the inner circumference of the support member 16, a portion having a large outer diameter is fitted to the yoke 12, and an electromagnetic relay 7. The cross section on the side is a contact surface of the nonmagnetic member 13 and the surface fixing the rescue line 28b so as to be conductive, and the cross section on the movable iron core 17 side is the contact surface of the movable iron core 17 and the return spring 42. It has a contact surface. Since the fixed iron core 41 of the electromagnet 9 does not need to receive an external force at the time of terminal engagement unlike the first fixed iron core 14 of the electromagnetic relay 7, the inner diameter of the yoke 12 and the fixed iron core 41 are fixed. Although the outer diameter of is the dimension setting of loose fitting, since the fitting part 41a comprises the magnetic circuit, the clearance is set to the smallest force. For example, the dimension setting of the inner diameter of the yoke 12> the outer diameter of the fixed iron core 41 is carried out.

The return spring 42 is provided between the fixed iron core 41 and the movable iron core 17 and adds the movable iron core 17 to the axial shift lever 8 side.

The movable iron core 17 is a magnetic material, and has an engaging portion 43, a pinion force spring 44, and a fixing member 45, which is slidably supported in the circumferential direction of the inner circumferential surface of the support member 16, and returns. The force of the spring 42 is added to the axial shift lever 8 direction. The engagement portion 43 is a member for engaging the axial shift lever 8 and the movable iron core 17. The large diameter portion at one end of the movable iron core 17 side abuts the pinion bias spring 44, and the other end is axially shifted. Engage with the lever (8). The pinion force spring 44 is provided between the engaging portion 43 and the fixing member 45, and the axial direction when the moving amount of the movable iron core 17 in the direction of the fixed iron core 41 is larger than that of the engaging portion 43. The shift lever 8 is biased in the direction of the fixed iron core 41.

Next, a method of assembling the starter electronic switch device 10 will be described. An assembly jig is used to assemble the starter electronic switch device 10. The assembling jig is provided with a flat surface at which the bottom of the yoke 12 abuts, and a positioning pin for fitting with the female screw 12e. Since the length of the positioning pin extends to the height to be fitted with the relief portion 29c of the winding edge 29, the positioning in the rotational direction between the yoke 12 and the winding edge 29 of the electromagnet 9 is It becomes possible.

First, the opening of the yoke 12 is mounted on the assembling fixture with the sky direction facing the sky. Next, the electromagnet 9 is inserted from the opening of the yoke 12 toward the bottom 12a (the return spring 42 and the movable iron core 17 of the electromagnet 9 may be assembled after completion of the other parts assembling). ). Since the yoke 12 and the fixed iron core 41 have a loose fitting dimension relationship, a large force is unnecessary at the time of insertion. For example, the inner diameter of the yoke 12> dimension of the outer diameter of the fixed iron core 41 is in relationship.

The position of the electromagnet 9 with respect to the yoke 12 is the position of the height direction, the inner diameter of the yoke 12 and the electromagnet 9 by the contact of the winding edge 29 of the electromagnet 9 and the bottom part 12a. The position of the circumferential direction (rotation direction) is determined from the outer diameter of the fixed iron core 41 of the radial direction, the positioning pin of the assembly jig | tool, and the relief part 29c of the winding edge 29. As shown in FIG.

Subsequently, the electromagnetic relay 7 is inserted. First, portions except the terminal block 11 and the return spring 25 are inserted. At this time, the position of the rotation direction is determined by the notch 20d of the relief part 29a of the electromagnet 9 and the winding edge 20 of the electromagnetic relay 7. After the insertion is completed, the fixed iron core 14 is press-fitted to the yoke 12 to determine the position in the radial direction and the position in the height direction.

Subsequently, the return spring 25 and the terminal block 11 are inserted, and the terminal block 11 is pressed in the direction of the fixed iron core 14 with a load equal to or more than the combined load of the reaction force of the return spring 25 and the reaction force of the packing 23. In one state, the caulking portion 12b of the yoke 12 is caulked to fix the terminal block 11.

Next, the operation of the electromagnetic relay 7 and the electromagnet 9 will be described. First, in operation of the electromagnetic relay 7, when a voltage is applied to the exciting terminal 27, a current flows in the exciting coil 19, and a magnetic field is generated. When this current becomes equal to or more than a predetermined current, the suction force acting between the movable iron core 18 and the fixed iron core 14 overcomes the return spring 25, the contact spring 34, and the frictional resistance, and the movable iron core 18 This fixed iron core 14 is adsorbed. Since the rod 24 is in contact with the end face on the fixed iron core 14 side of the movable iron core 18, the rod 24 also moves together when the movable iron core 18 moves in the direction of the fixed iron core 14. When the rod 24 moves, the movable contact 36 supported by the rod 24 also moves. When the movable iron core 18 moves a predetermined amount, the movable contact 36 and the fixed contacts 30a and 31a come into contact with each other.

In addition, when the movable iron core 18 moves in the direction of the fixed iron core 14, the load of the contact spring 34 is given between the movable contact 36 and the fixed contacts 30a, 31a. When the movable contact 36 and the fixed contact 30a, 31a abut, electric power is supplied from the battery to the motor 1 and the motor 1 rotates. When the application of the voltage to the exciting terminal 27 is stopped, no current flows in the exciting coil 19, the magnetic field disappears, and the load 24 and the movable iron core under the load of the return spring 25 and the contact spring 34 Since 18) returns to its original position, the movable contact 36 and the fixed contacts 30a and 31a fall, and since the power supply from the battery is lost, the motor 1 stops.

Subsequently, the operation of the electromagnet 9 will be described. When a voltage is applied to the exciting terminal 38 of the electromagnet 9, a current flows through the exciting coil 28, and a magnetic field is generated. When this current is equal to or more than a predetermined current, the suction force acting between the movable iron core 17 and the fixed iron core 41 overcomes the return spring 42 and the pinion force spring 44 and the frictional force, thereby allowing the movable iron core 17 to be moved. This fixed iron core 41 is adsorbed. When the movable iron core 17 is attracted in the direction of the fixed iron core 41, the pinion gear 5 moves in the direction of the ring gear 4 through the axial shift lever 8, which causes the pinion gear 5 and the ring gear to be moved. When the end faces of (4) abut, and the pinion gear 5 does not enter the tooth surface of the ring gear 4, only the movable iron core 17 moves further, and the pinion force spring 44 is bent. A quantity generate | occur | produces and the pinion gear 5 is urged to the ring gear 4 direction through the axial shift lever 8 by the load of the pinion force spring 44. As shown in FIG.

In the first embodiment, the central axis of the movable iron core 18 of the electromagnetic relay 7 and the central axis of the movable iron core 17 of the electromagnet 9 are arranged in series on the same axis, and the magnetic field of the electromagnetic relay 7 is maintained. The magnetic circuit of the yoke 12 constituting the outer rim and the electromagnet 9 constitutes the circuit and the yoke 12 constituting the outer rim integrally can be miniaturized and the size of the electromagnet 9 can be reduced. The relief part which protrudes from the winding edge 29, is engaged through the winding edge 20 of the electromagnetic relay 7, and protects the rescue line 28a of the excitation coil 28 of the electromagnet 9 ( By having 29a), it is possible to position the circumferential direction (rotation direction) of the winding border 20 of the electromagnetic relay 7 and the winding border 29 of the electromagnet 9.

Moreover, in this Embodiment 1, the fitting hole 11a provided in the terminal block 11 provided in the axial direction opposite side to the electromagnet 9 of the electromagnetic relay 7, and the main contact point 6 which comprises a main circuit is provided. ), By the fitting portions 20a and 20b protruding from the winding edge 20 of the electromagnetic relay 7 or the relief portions 29a and 29b protruding from the winding edge 29 of the electromagnet 9, The winding of the electromagnetic relay 7 can be positioned in the rotational direction of the border 20 and the terminal block 11.

Embodiment 2:

The electronic switch device for starters which concerns on Embodiment 2 of this invention is demonstrated based on FIG. It is sectional drawing which shows the electronic switch device for starters which concerns on Embodiment 2 of this invention. The inner diameter of the yoke 12 located on the outer circumference of the electromagnetic relay 7 according to the second embodiment is configured to be larger than the inner diameter of the yoke 12 located on the outer circumference of the electromagnet 9. The outer diameter of the first fixed iron core 14 of the electromagnetic relay 7 is configured to be larger than the outer diameter of the fixed iron core 41 of the electromagnet 9.

The inner diameter of the trunk | drum 12d of the yoke 12 in Embodiment 2 of this invention has shown the case comprised, for example divided into six steps. The size of the inner diameter of the trunk portion 12d of the yoke 12 is as follows: the first trunk portion 12d1 <the second trunk portion 12d2 <the third trunk portion 12d3 <the fourth trunk portion 12d4 ) <5th trunk | drum 12d5 <It is comprised like the 6th trunk | drum 12d6, The 1st trunk | drum 12d1 is located in the outer periphery of the excitation coil 28 of the electromagnet 9, and The fixed iron core 41 of the electromagnet 9 is fitted to the body portion 12d2 of the second body, and the third body portion 12d3 is located on the outer circumference of the nonmagnetic member 13, and the fourth body portion 12d4 is provided. The second fixed iron core 22 of the electromagnetic relay 7 is fitted, the fifth body portion 12d5 is located on the outer periphery of the excitation coil 19 of the electromagnetic relay 7, and the sixth body portion ( 12d6 is fitted with the first fixed iron core 14 of the electromagnetic relay 7. Fixing iron core 41, nonmagnetic member 13, and second fixing fitting to the inner diameters of the second body portion 12d2, the third body portion 12d3, and the sixth body portion 12d6, respectively. The outer diameter of the iron core 22 is in the dimensional relationship of the interference fitting. For example, the inner diameter of the second trunk portion 12d2 < the outer diameter of the fixed iron core 41 is in a dimensional relationship.

In this Embodiment 2, the fixed iron core 41 of the electromagnet 9 is constructed by making the inner diameter of the yoke 12 of the electromagnetic relay 7 larger than the inside diameter of the yoke 12 of the electromagnet 9. After press-fitting into 12), the electromagnetic relay 7 can be assembled on the electromagnet 9, and workability can be improved.

In addition, in the second embodiment, the fixed iron core 41 of the electromagnet 9 is made larger by increasing the outer diameter of the first fixed iron core 14 of the electromagnetic relay 7 than the fixed iron core 41 of the electromagnet 9. ), The electromagnetic relay 7 can be assembled on the electromagnet 9 after press fitting and fitting the yoke 12, and workability can be improved.

Embodiment 3.

The electronic switch device for starters which concerns on Embodiment 3 of this invention is demonstrated based on FIGS. 14-19. It is a figure which looked at the electronic switch device for starters which concerns on Embodiment 3 of this invention from the terminal block side. FIG. 15 is a cross-sectional view of the starter electronic switch device according to Embodiment 3 of the present invention, taken along line A-A in FIG. 5. It is a figure which looked at the winding edge of the electromagnetic relay in the electronic switch device for starters which concerns on Embodiment 3 of this invention from the terminal block side. FIG. 17 is a cross-sectional view of a border of an electromagnetic relay corresponding to the line B-B of FIG. 5 in the electronic switch device for starter according to Embodiment 3 of the present invention. FIG. FIG. 18 is a cross-sectional view of a winding edge of an electromagnet corresponding to the C-C line of FIG. 5 in the electronic switch device for starter according to Embodiment 3 of the present invention. FIG. It is a figure which looked at the edge of the electromagnet by the electromagnetic switch device for starters which concerns on Embodiment 3 of this invention from the terminal block side.

In FIG. 14, one region of a region divided by a straight line connecting the center between the battery terminal 30 and the motor terminal 31, for example, the region D above the center line P shown in FIG. 14. ) And the lower side than the other region, for example, the center line P shown in FIG. 14.

In Embodiment 1 mentioned above, although the excitation terminal 27 of the electromagnetic relay 7 was the area | region D and the excitation terminal 38 of the electromagnet 9 was the structure arrange | positioned at the area | region E, In the form 3, the excitation terminal 38 of the electromagnet 9 and the excitation terminal 27 of the electromagnetic relay 7 are any one area | region, and the figure is an example below the center line P shown in FIG. In the area E, the exciting terminal 27 of the electromagnetic relay 7 and the exciting terminal 38 of the electromagnet 9 were attached to the housing 46 as a two-pole connector.

In such a configuration, in the first embodiment described above, as shown in FIGS. 15 and 16, the winding start side rescue line 19a and the rescuer 20a of the electromagnetic relay 7 are divided into regions ( Move from D) to the region E, move the winding end side rescue line 19b of the electromagnetic relay 7 and the rescue portion 20b of the winding border 20 from the region E to the region D, The winding start side rescue line 28a of the electromagnet 9, which has passed through the rescue section 20b of the electromagnetic relay 7, is provided in the region E as a dedicated rescue section 20i, and the electromagnetic relay 7 On the right side of the cold start side rescue portion 20a. 20j is an insertion groove, and the rescue line 19b is inserted. 20f is a fitting part, and the outer peripheral shading part of the support member 21 which is not shown in figure fits. 20g is a hollow part of the winding border 20. 20k is an insertion groove, and the rescue line 19a is inserted. 20l is an insertion hole, and the rescue line 28a is inserted.

In addition, as shown in FIG. 17, the position of the notch 20d of the winding edge 20 of the electromagnetic relay 7 is arrange | positioned so that it may become the position of the same direction as the rescue part 20i. Moreover, the rescue part 29a of the winding edge 29 of the electromagnet 9 is also arrange | positioned so that it may be located in the same direction as the rescue part 20i as shown to FIG. 18 and FIG.

In the third embodiment, the terminal block 11 is viewed from the side of the battery terminal 30 and the motor terminal 31 so as to divide two areas in which the center between the battery terminal 30 and the motor terminal 31 is divided by a line connecting the center. Since the excitation terminal 27 of the electromagnetic relay 7 and the excitation terminal 38 of the electromagnet 9 are provided in either area | region, the workability of the operation | work which connects the wiring of a vehicle side can be aimed at. .

By the way, the operation | movement of the starter using the electronic switch device 10 for starters which concerns on each embodiment mentioned above is basically the same as that of patent document 1 mentioned above, but it is not limited to this, The electromagnet 9 and an electromagnetic relay It is also possible to use the control for operating (7) individually at different timings.

[Industrial Availability]

The present invention is suitable for realizing a starter electronic switch device which can be miniaturized by arranging an electromagnetic relay and an electromagnet in a coaxial series.

1: motor
4: ring gear
5: Pinion gear
7: electronic relay
9: electromagnet
10: electronic switch device for starter
11: terminal block
11a: fitting hole
12: yoke
14: first fixed iron core
17: movable iron core
18: movable iron core
20: winding border
22: second fixed iron core
27: excitation terminal
28: excitation coil
28a: rescue ship
28b: rescue ship
29: winding border
29a: rescue
29b: rescue
30: battery terminal
31: motor terminal
38: excitation terminal
41: fixed iron core

Claims (10)

An electromagnetic relay having a movable iron core and a fixed iron core for opening and closing a motor circuit, and an electromagnet having a movable iron core and a fixed iron core for moving the pinion gear in a ring gear direction, wherein the central axis of the movable iron core of the electromagnetic relay and the electromagnet are movable. In the starter electronic switch device wherein the central axis of the iron core is arranged in series on the same coaxial axis, and the magnetic circuit of the electromagnetic relay and the iron constituting the outer border and the magnetic circuit of the electromagnet and the iron constituting the outer border are integrated. ,
The electromagnetic relay has an excitation coil wound around the winding edge,
The electromagnet has an exciting coil wound on the winding edge,
The battery terminal and the motor terminal are disposed, and the winding of the electromagnetic relay has a terminal block in which a fitting hole is formed,
The winding of the electromagnet is provided to protrude from the edge, the winding of the electromagnetic relay is engaged through the edge, and the positioning of the winding edge of the electromagnetic relay and the winding edge of the electromagnet is carried out while A rescue portion that protects the rescue line of the excitation coil;
The winding of the electromagnetic relay protrudes from an edge and is engaged with the fitting hole of the terminal block while penetrating the fixed iron core of the electromagnetic relay, and positioning the terminal block and the winding edge of the electromagnetic relay in the rotational direction. And a rescue portion that protects a rescue line of the excitation coil of the electromagnetic relay. The method of claim 1,
And said rescue portion of said electromagnet communicates with said rescue portion of said electromagnetic relay. 3. The method according to claim 1 or 2,
And said fixed iron core of said electromagnetic relay is constituted by a first fixed iron core and a second fixed iron core arranged to sandwich said winding edge. 3. The method according to claim 1 or 2,
An electronic switch device for starter, wherein the yoke inner diameter of the electromagnetic relay outer periphery is larger than the yoke inner diameter of the electromagnet outer periphery. The method of claim 3,
An electronic switch device for starter, wherein the yoke inner diameter of the electromagnetic relay outer periphery is larger than the yoke inner diameter of the electromagnet outer periphery. 3. The method according to claim 1 or 2,
The outer diameter of the fixed iron core of the electromagnetic relay is larger than the outer diameter of the fixed iron core of the electromagnet. The method of claim 3,
The outer diameter of the fixed iron core of the electromagnetic relay is larger than the outer diameter of the fixed iron core of the electromagnet. 5. The method of claim 4,
The outer diameter of the fixed iron core of the electromagnetic relay is larger than the outer diameter of the fixed iron core of the electromagnet. 6. The method of claim 5,
The outer diameter of the fixed iron core of the electromagnetic relay is larger than the outer diameter of the fixed iron core of the electromagnet. delete

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