DE102013108191B4 - Electromagnetic solenoid device for a starter - Google Patents

Abstract

Electromagnetic solenoid device (2) for use with a starter (1), which serves to apply torque, such as that generated by an electric motor (3), to a pinion (6) which meshes with a ring gear (G) of a machine to transmit to start the engine, comprising: a first solenoid (SL1) equipped with a first coil (35) having a first end and a second end opposite to the first end in an axial direction thereof, with the first end facing the pinion (6) of the starter (1) when the same is energized, the first coil (35) serving to drive the pinion (6) as it moves in the axial direction of the first coil ( 35) is positioned closer to the first end of the first coil (35) than to the second end, to move the ring gear (G); a second solenoid (SL2) equipped with a second coil (46) which is a first end and a second end which g. the first end in an axial direction thereof opposite, wherein the second solenoid (SL2) is arranged in alignment with the first solenoid (SL1) in an axial direction of the electromagnetic solenoid device (2) that the first end thereof is closer to the second end of the first coil (35 ) than to the first end of the first coil (35) when energized, the second coil (46) serving to open or close main contacts (56, 57) to the electric motor (3) of the starter (1) to supply or break an electric power; a movable contact (57) and fixed contacts (56) serving as the main contacts (56, 57), the movable contact (57) in the axial direction of the electromagnetic solenoid device (2) is arranged closer to the second end of the second coil (46) than to the first end of the second coil (46), the fixed contacts (56) each having connecting portions (56b) and between the movable K ontakt (57) and the second end of the second coil (46) are placed, wherein the movable contact (57) is moved by the second solenoid (SL2) to the pinion (6) to make contact with the fixed contacts (56) and further moved away from the pinion (6) by the second solenoid (SL2) to exit the fixed contacts (56); first and second terminal studs (54, 55) for use in making electrical connections with an exterior, wherein the first and second terminal bolts (54, 55) are respectively joined to the connecting portions (56b) of the fixed contacts (56), the fixed contacts (56) having contact surfaces (56a) with which the movable Contact (57) is moved by the second solenoid (57) to make contact, and wherein the connecting portions (56b) are positioned closer to the pinion (6) than the contact surfaces (56a), and with stationary core parts (53) which around the first and second bobbins ( 35, 46) are arranged to produce a magnetic circuit together with the first and second solenoids (SL1, SL2), the stationary core parts (53) being laid to connect in a radial direction of the electromagnetic solenoid device (2) Overlap sections (56b).

Description

BACKGROUND OF THE INVENTION

Technical field of the invention

The present invention relates generally to a compact structure of an electromagnetic solenoid device for a starter, which includes a first solenoid which is used to drive a pinion of the starter to a ring gear and a second solenoid which is used to to selectively set up or block a supply of an electric motor of the starter with an electric power.

Background technology

US 2009/0 183 595 A1 discloses a compact structure starter, according to which it is disclosed that an electromagnetic switch comprises an electromagnetic switch that opens or closes a main contact of a motor circuit, and an electromagnet that functions to push a pinion to a position away from a motor . The electromagnetic switch and the solenoid are arranged in series in a unitary structure so that the electromagnetic switch and the solenoid have a switch case and a solenoid case both of which are integrally formed with each other so as to be continuous in an axial direction. Further, a fixed core for the electromagnet and a fixed core for the electromagnet are integrally formed, and an operating direction of a piston for the electromagnet and an operating direction of a piston for the electromagnet are set in opposite directions.

Japanese Patent No. JP 4 207 854 B2 , assigned to the same assignee as this application, teaches an electromagnetic solenoid device for use with a starter equipped with a pinion shaft having a pinion and an armature shaft of an electric motor extending parallel to the pinion shaft.

The electromagnetic solenoid device serves to advance the pinion shaft through a solenoid and also to open or close main contacts. The main contacts have a moving contact and fixed contacts (also called stationary contacts). The movable contact is positioned on a side opposite to the fixed contacts on the pinion shaft. The movable contact is moved coaxially with the pinion shaft to the fixed contacts or away from them. The amount of movement of the movable contact must depend on the amount of movement of the pinion. This requires a space extending from contact portions of the fixed contacts in a direction away from the pinion and sufficiently large to allow the movable contact to move, thus resulting in an increase in the size of the electromagnetic solenoid device in that direction in which the movable contact is moved.

Japanese Patent First Publication No. JP 2009 - 191 843 A assigned to the assignee of this application discloses an electromagnetic solenoid device commonly called a tandem solenoid device equipped with two solenoids arranged in tandem.

More specifically, the electromagnetic solenoid device is provided with a first solenoid that drives a pinion to a ring gear of an internal combustion engine, and a second solenoid that is arranged coaxially with the pinion and serves to close or close the main contacts open to supply an electric motor with an exciting current or to interrupt the same. This structure is able to control the time when the pinion is to be moved independently of the time when the electric motor is to be started, and thus is suitable for use in an idle stop system (which is also a system of an automatic machine Starts / Restarts) is suitable for self-propelled vehicles.

As described above, the tandem solenoid device is provided with two separate solenoids: the first solenoid which moves the pinion and the second solenoid which closes or opens the main contacts to supply or close the electric motor with the energizing current interrupt, so that the need to consider the amount of movement of the pinion in adjusting the amount by which the movable contact must be moved is eliminated, allowing the latter amount to be reduced. In other words, it is possible to reduce the size of a portion of the tandem solenoid device that extends from the contact areas of the fixed contacts in a direction away from the pinion.

In order to reduce the size of a portion of the electromagnetic solenoid device as taught in the first-mentioned publication which extends from the contact areas of the fixed contacts in the direction away from the pinion, it can be designed to have the tandem solenoid structure as taught in the latter publication.

The electromagnetic solenoid device of the first-mentioned publication has terminal bolts that connect the fixed contacts to external terminals such as battery terminals. The terminal studs are arranged in opposite radius directions away from the axial center of the body of the electromagnetic solenoid device. The body of the electromagnetic solenoid device has a connecting portion that is on the opposite side of the fixed contacts from the pinion and through which each of the terminal bolts is joined to one of the fixed contacts. Therefore, even if the amount by which the movable contact needs to be moved is reduced using the structure of the tandem solenoid device, a space is necessary for the connecting portions on the side of the fixed contacts opposite to the pinion gear, thus resulting in a difficulty in reducing the size of the body of the electromagnetic solenoid device in the axial direction thereof.

SUMMARY OF THE INVENTION

A main object of the invention is therefore to avoid the disadvantages of the prior art.

Another object of the invention is to provide an improved structure of an electromagnetic solenoid device that is allowed to be reduced in size of a portion thereof that extends from contact surfaces of fixed contacts in a direction away from a pinion.

The main task, as well as the other task, are achieved with the features of independent claim 1. Further advantageous embodiments and further developments are the subject of the subsequent claims.

According to one aspect of the invention, there is provided an electromagnetic solenoid device for use with a starter which serves to transmit torque such as that generated by an electric motor to a pinion which meshes with a ring gear of a machine, around the machine to start. The electromagnetic solenoid device comprises (a) a first solenoid equipped with a first coil having a first end and a second end opposite to the first end in an axial direction thereof, the first end being the pinion of the starter when it is energized, the first coil serving to move the pinion, since it is positioned closer to the first end of the first coil than to the second end in the axial direction of the first coil, to the ring gear, (b ) a second solenoid having a second coil having a first end and a second end opposite to the first end in an axial direction thereof, the second solenoid thus being in alignment with the first solenoid in one axial direction of the electromagnetic solenoid device is arranged that the first end thereof is closer to the second end of the first coil than to the first end of the first coil is when the same is energized, the second coil serving to open or close main contacts to energize or interrupt the electric motor of the starter, (c) a movable contact and fixed contacts that act as the main contacts serve, the movable contact being located closer to the second end of the second coil than to the first end of the second coil in the axial direction of the electromagnetic solenoid device, the fixed contacts each having connecting portions and between the movable contact and the second Placed at the end of the second coil, the movable contact being moved by the second solenoid towards the pinion to make contact with the fixed contacts, and further moved away from the pinion by the second solenoid to leave the fixed contacts, and (d) first and second terminal studs for use with m Establishing electrical connections with an exterior, the first and the second connecting bolt being joined to the connecting portions of the fixed contacts.

The fixed contacts have contact surfaces with which the movable contact is moved by the second solenoid to make contact. The connecting sections are positioned closer to the pinion than the contact surfaces.

In other words, the connection bolts and the connections between the connection bolts and the fixed contacts are not placed at locations that are further away from the pinion than the contact surfaces are. The electromagnetic solenoid device is of a tandem solenoid type, so that the need to consider the amount of movement of the pinion in adjusting the amount by which the movable contact must move is eliminated, allowing the latter amount to be reduced. This allows the length of a portion of the electromagnetic solenoid device that is farther from the pinion in the axial direction of the electromagnetic solenoid device than the contact surfaces of the fixed contacts to be reduced.

In the preferred mode of the invention, the electromagnetic solenoid device may further include stationary core members around the first and the second coil are arranged to generate a magnetic circuit together with the first and the second solenoid. The stationary core parts are laid so as to overlap the connecting portions in a radial direction of the electromagnetic solenoid device.

The electromagnetic solenoid device may further include insulating members each of which is either between one of the first and second terminal studs and one of the stationary core parts, or between one of the connecting portions of the fixed contacts and one of the stationary core parts, or between one of the first and second terminal studs and one of the stationary core parts and between one of the connecting portions of the fixed contacts and the one of the stationary core parts lies at least within a region in which the stationary core parts overlap the first and second terminal bolts in the radial direction of the electromagnetic solenoid device. This allows an air gap between one of the first and second terminal bolts or the connecting portions and one of the stationary core parts to be reduced in size. This also enables the overall size of the electromagnetic solenoid device to be reduced.

When a foreign object has entered the air gap, the insulating member serves to prevent a short circuit between one of the terminal bolts and one of the stationary core parts.

The insulating members can be made of an elastic material. Each of the insulating members is placed while the same between one of the connecting portions or one of the first and second terminal studs and one of the stationary core parts or between one of the connecting portions and one of the stationary core parts and between one of the first and second terminal studs and one of the stationary core parts is compressed. Such a structure of each of the insulating members minimizes displacement of the location of a corresponding one of the first and second terminal studs when subjected to physical shock generated when the pinion engages the ring gear or from mechanical vibration.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be more fully understood from the detailed description given below and from the accompanying drawings of the preferred embodiments of the invention, which, however, should not be construed to limit the invention to the specific embodiments, but for purpose only serve to explain and understand.

• 1 eine Teillängsschnittansicht entlang der Linie I-I in 3, die eine elektromagnetische Solenoidvorrichtung eines ersten Ausführungsbeispiels der Erfindung darstellt;
• 2 eine Längsschnittansicht entlang der Linie II-O-II von 3;
• 3 eine Hinteransicht, die eine elektromagnetische Solenoidvorrichtung eines ersten Ausführungsbeispiels der Erfindung, die an einem Anlasser angebracht ist, darstellt;
• 4 eine Teillängsschnittansicht, die eine elektromagnetische Solenoidvorrichtung eines zweiten Ausführungsbeispiels der Erfindung darstellt; und
• 5 eine Teillängsschnittansicht, die eine elektromagnetische Solenoidvorrichtung eines dritten Ausführungsbeispiels der Erfindung darstellt.

Show it:

• 1 a partial longitudinal sectional view along the line II in 3 Fig. 11 illustrating an electromagnetic solenoid device of a first embodiment of the invention;
• 2 a longitudinal sectional view along the line II-O-II of 3 ;
• 3 Fig. 4 is a rear view illustrating an electromagnetic solenoid device of a first embodiment of the invention attached to a starter;
• 4th Fig. 4 is a partial longitudinal sectional view showing an electromagnetic solenoid device of a second embodiment of the invention; and
• 5 Fig. 3 is a partial longitudinal sectional view showing an electromagnetic solenoid device of a third embodiment of the invention.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

Referring now to the drawings, wherein like reference numbers refer to like parts throughout the several views, FIG 1 an electromagnetic solenoid device 2 shown according to the first embodiment of the invention. The electromagnetic solenoid device 2 is of a tandem solenoid type and, as it is in 1 is shown with a speed reduction starter 1 designed to start an internal combustion engine for automobiles, for example.

1 FIG. 11 is a longitudinal sectional view taken along line II in FIG 3 . 2 FIG. 11 is a longitudinal sectional view taken along line II-O-II of FIG 3 .

The speed reduction starter 1 is how it is in 2 is shown with an electric motor 3 , a pinion shaft 5 , a pinion 6th , a speed reducer as will be described in detail later, a clutch 7th and the electromagnetic solenoid device 2 fitted. The electric motor 3 serves to generate a torque and has an armature shaft 4th that are parallel to the pinion shaft 5 extends. The pinion 6th is at one end of the pinion shaft 5 fitted to together with the pinion shaft 5 to be rotatable. The speed reducer is used to reduce the rotational speed of the armature shaft 4th of the electric motor 3 reduce to the torque as it is due to the electric motor 3 is generated to amplify. The coupling 7th serves to increase the torque as output from the speed reducer, to the pinion shaft 5 transferred to. The electromagnetic solenoid device 2 is arranged so that a length thereof is coaxial with the pinion shaft 5 extends.

The motor 3 is a typical commutator motor that uses an electromagnetic field system (which will be described in detail later) that serves to generate a magnetic field, an armature 9 and brushes 10 fitted. The anchor 9 has a commutator 8th at a rear end of the armature shaft 4th is arranged. The brushes 10 lie on the outer periphery of the commutator 8th on.

The electromagnetic field system is used to create a magnetic circuit and is made up of field poles 13 made using screws 12 on an inner periphery of a yoke 11 are attached, and a field coil 14th Made from a right-angled wire that goes around the field poles 13 is wound, is made, assembled. The yoke 11 also serves as a shell or a housing of the electric motor 3 . Instead of the electromagnetic field system, a permanent magnetic field system can be used, which has a plurality of permanent magnets which are located on the inner periphery of the yoke 11 are arranged, has.

The pinion shaft 5 is within an inner periphery of a keyway tube 15th placed in a helical keyway connection therewith so that the pinion shaft 5 along the length of the keyway tube 15th (i.e. in a lateral direction in 2 ) can be moved while rotating it.

In the following discussion, on the left is a length (i.e., an axis) of an arrangement of the pinion shaft 5 and the electromagnetic solenoid device 2 in 1 and 2 referred to as a front or first side, while to the right thereof is referred to as a rear or second side. In a direction in which the pinion is 5 relative to the keyway tube 5 in a right direction in 1 and 2 along the axis of the arrangement of the pinion shaft 5 and the electromagnetic solenoid device 2 moved is still further referred to as a switch side direction or an anti-sprocket side direction, while the opposite direction thereof is further referred to as an anti-switch side direction or a pinion side direction. The pinion shaft 5 is moved in the opposite direction to the switch side to the pinion 6th with a ring gear G , which is attached to an internal combustion engine, for example, to engage.

The pinion shaft 5 has like it in 2 shown is a cylindrical chamber or hole extending from the rear end along a longitudinal centerline thereof and in which or in which a steel ball 16 is arranged.

The pinion 6th is at one end portion of the pinion shaft 5 from one end of the keyway tube 15th protrudes into direct engagement with splines formed on an outer periphery of the pinion shaft 5 are formed, joined. The pinion 6th is made by a pinion spring 17th into constant abutment with the front end of the keyway tube 15th pressed. The pinion spring 17th is between the pinion shaft 5 and the pinion 6th arranged.

The keyway tube 15th is at a front end thereof through a starter housing 19th by a ball bearing 18th and at a rear end of the same by a middle cover 21st by a ball bearing 20th held rotatable.

A return spring 22nd is between the inner periphery of the keyway tube 15th and the outer periphery of the pinion shaft 5 arranged to the pinion shaft 5 in the switch side direction away from the keyway tube 15th to press.

The speed reducer is, as in 2 is shown from a gear set, which consists of a drive gear 23 , an idle gear 24 and a clutch gear 25th is made. The drive gear 23 is at a front end of the armature shaft 4th educated. The idler gear 24 engages with the drive gear 23 one. The clutch gear 25th engages with the idle gear 24 one. The idler gear 24 is through the gear shaft 24a held to be rotatable. The gear shaft 24a is at a front end thereof in a hole made in the middle cover 21st is formed, and at a rear end thereof in a hole made in the starter housing 19th is formed, press fit. The clutch gear 25th is on an outer periphery of a cylindrical hub 26th fit. The hub 26th is through the outer periphery of the keyway tube 15th through a warehouse 27 held rotatable.

The coupling 7th is for example a one-way roller clutch or a clamping roller freewheel and has a clutch exterior 7a , a clutch interior (which will be described in detail later), rollers 7b and feathers 7c on. The clutch exterior 7a has a plurality of cam surfaces formed on an inner wall thereof. The inside of the coupling is inside the outside of the coupling 7a arranged. The roles 7b are between the cam surfaces of the clutch exterior 7a and the outer periphery of the clutch interior and arranged by the springs 7c pressed into constant abutment with the cam surfaces.

The clutch exterior 7a is with the hub 26th of the clutch gear 25th coupled so that the torque of the clutch gear 25th through the hub 26th to the outside of the coupling 7a is transmitted. The inside of the coupling is through the keyway tube 15th educated. The keyway tube 15th in other words serves as the coupling interior. The roles 7b work to rotate the clutch exterior 7a to the coupling interior (i.e., the keyway tube 15th ) to transmit and the transmission of a rotation from the clutch interior to the clutch exterior 7a to block.

The structure of the electromagnetic solenoid device 2 is below with reference to 1 described.

The electromagnetic solenoid device 2 is with a first solenoid SL1 and a second solenoid SL2 which is in alignment with the first solenoid SL1 extends, equipped. The first solenoid SL1 works as an electromagnet to create magnetic attraction around the pinion shaft 5 to move in the anti-switch side direction. The second solenoid SL2 serves to open or close the main contacts, as will be described in detail later, which are connected to a power supply circuit to supply the electric power to the electric motor 3 to interrupt or supply the same with it.

The first solenoid SL1 and the second solenoid SL2 are in order in the axial direction of the electromagnetic solenoid device 2 arranged and built in one piece within a switch shell, as described below.

The second solenoid SL2 is positioned to have a front end that is a rear end of the first solenoid SL1 is facing. The first and second solenoid SL1 and SL2 in other words, create magnetic attractions that are oriented in the same direction.

The pinion 6th is, as described above, through the pinion shaft 5 held and on the front of the first solenoid SL1 in the axial direction of the first solenoid SL1 positioned.

The switch shell is as it is in 1 is shown, from a metallic frame 28 , a resinous frame 29 and an end frame 30th composed. The metallic frame 28 covers the periphery of the first solenoid SL1 . The resinous frame 29 is at the rear end of the metallic frame 28 added to the second solenoid SL2 to cover. The end frame 30th closes an opening in the rear end of the resinous frame 29 .

The metallic frame 28 is hollow cylindrical and with the middle shell 21st formed in one piece. The metallic frame 28 extends from the middle hull 21st in the reverse direction of the electromagnetic solenoid device 2 .

FIRST SOLENOID SL1

The first solenoid SL1 is like in 1 is shown with a coil 35 , a plunger 36 , a stator core 37 , a core plate 38 , a wave 39 , a return spring 40 and a mainspring 41 fitted. When the coil 35 is excited, it functions as an electromagnet. The plunger 36 is in the coil 35 in the axial direction of the electromagnetic solenoid device 2 movable. The stator core 37 is magnetized by the electromagnet to the plunger 36 to attract. The core plate 38 is in the shape of an annular disc and is at a front end of the spool 35 arranged. The wave 39 serves to move the plunger through the steel ball 16 as it is in 2 is shown to the pinion shaft 5 transferred to. The return spring 40 serves to move the plunger 36 to return to its initial position when the magnetic attraction created by the electromagnet decreases or disappears. The mainspring 41 stores a pressure that is used to drive the pinion 6th into engagement with the ring gear G to drift.

The sink 35 of the first solenoid SL is made of an electrically insulated copper wire wrapped around a resinous bobbin 42 is wrapped. The bobbin 42 has a hollow cylindrical sleeve 43 which is fitted to an inner periphery thereof. The sleeve 43 is made of a non-magnetic material, such as stainless steel, and is used to prevent movement of the plunger 36 respectively.

The plunger 36 has a rear portion of a small diameter. The plunger 36 More specifically, it is composed of a main body of a large diameter, the rear portion of a small diameter, and an annular step or shoulder formed therebetween. In the plunger 36 is a cylindrical hole 44 formed, which extends the same through the longitudinal center. The cylindrical hole 44 has a hole 44a of a small diameter positioned at a front end thereof.

The stator core 37 is made of an annular core with a central cylindrical hole extending through the radial center thereof. The stator core 37 is partially in that Front end of the sleeve 43 in alignment with the longitudinal center of the plunger 36 fit.

The core plate 38 is on an outer periphery of the stator core 37 fitted to establish magnetic coupling therebetween. The connection of the core plate 38 with the stator core 37 is made by crimping one edge of the stator core 37 reached. The core plate 38 is how it is in 1 can be seen in one strike with the end of the middle cover 21st placed what the bottom of the metallic frame 28 forms, in other words, by the end of the middle envelope 21st kept to move in the axial direction of the electromagnetic solenoid device 2 not to move and not to rotate in the circumferential direction thereof.

The wave 39 goes through the hole 44a a small diameter of the plunger 36 so that the same through the plunger 36 is held. The plunger 39 has a rear end that comes out of the hole 44a of a small diameter protrudes outward in the rearward direction. The rear end has a flange 39a whose outer diameter is greater than the inner diameter of the hole 44a of a small diameter. Most of the plunger 39 extends out of the cylindrical hole 44 in the forward direction of the electromagnetic solenoid device 2 and has a front end that passes through the stator core 37 goes. The front end touches, as shown in 2 you can see the steel ball 16 .

A partition 45 is at the rear end of the spool 35 attached. The partition 45 serves as a stopper to have a restoring effect on the plunger 36 to stop. The partition 45 is made from a cup-shaped non-magnetic metal plate that forms the rear end of the plunger 36 covered.

When the coil 35 is de-excited so that the magnetic attraction disappears, this will cause the plunger 36 by a reactive force such as that caused by the return spring 40 is generated, to an initial position thereof, by physical contact between the plunger 36 and the partition 45 is defined, is moved.

SECOND SOLENOID SL2

The second solenoid SL2 as it is in 1 is shown is with a coil 46 , a plunger 47 , a stator core 48 , a magnetic disk 49 and a return spring 50 fitted. When the coil 46 is excited, it functions as an electromagnet. The plunger 47 is in the coil 46 in the axial direction of the electromagnetic solenoid device 2 movable. The stator core 48 is magnetized by the electromagnet to the plunger 47 to attract. The magnetic disk 49 is made from an annular disc and is at the front end of the spool 46 arranged. The return spring 50 serves to move the plunger 47 to return to its initial position when the magnetic attraction created by the electromagnet decreases or disappears.

The sink 46 of the second solenoid SL2 is made of an electrically insulated copper wire that is wrapped around a resinous bobbin 51 is wound, manufactured. The bobbin 51 has a hollow cylindrical sleeve 52 which is fitted to an inner periphery thereof. The sleeve 52 is made of a non-magnetic material, such as stainless steel, and is used to facilitate the movement of the plunger 47 respectively.

The plunger 47 has a rear portion of a small diameter. The plunger 47 is more precisely like the plunger 36 composed of a main body of a large diameter, the rear portion of a small diameter, and an annular step or shoulder formed therebetween. In the plunger 47 is a cylindrical hole 47a formed, which extends the same through the longitudinal center. The cylindrical hole 47a has a rear opening. The rear end portion (i.e., the small diameter portion) of the partition wall 45 is inside the cylindrical hole 47a of the plunger 47 arranged. When the coil 46 is de-energized, the plunger is 47 so positioned around the plunger 36 of the first solenoid SL1 partially overlap in the radius direction thereof. This design allows the electromagnetic solenoid device 2 is reduced in size in the axial direction thereof.

The stator core 48 is made of an annular core with a central cylindrical hole extending through the radial center thereof. The stator core 48 is in the front end of the sleeve 52 in alignment with the longitudinal center of the plunger 47 partially fit.

The magnetic disk 49 is made up of, for example, a stack of annular steel disks that are formed by a press and with the stator core 48 mechanically and magnetically coupled are made.

The magnetic disk 49 and the core plate 38 of the first solenoid SL1 are like it in 1 is represented by at least two stationary core parts 53 magnetically joined together, creating a magnetic circuit that is the first and second solenoids SL1 and SL2 is common, is generated.

The stationary core parts 53 are in a circumferential direction of the coils 35 and 56 positioned away from each other and are diametrically opposite each other. Each of the stationary core parts 53 has an axially extending strip 53a and a radially extending strip 53b on. The axially extending strip 53a extends along the outer periphery of the coils 35 and 46 in the axial direction of the coils 35 and 46 . The radially extending strip 53b extends from a rear end of the axially extending strip 53a inward to the rear of the spool 46 to cover.

The main contacts made by the second solenoid SL2 to open or close have two fixed contacts 56 and a moving contact 57 on. The fixed contacts 56 and the moving contact 57 in other words, function as the main contacts. The fixed contacts 56 are with the power supply circuit for the electric motor 3 by connecting bolts 54 and 55 to connect electrically. The moving contact 57 puts between the fixed contacts 56 establishes or blocks an electrical connection. If more precisely the moving contact 57 with the fixed contacts 56 makes a contact, the same becomes the electrical connection of the fixed contacts 56 generate, whereby the main contacts are closed. When the moving contact 57 alternatively from the fixed contacts 56 moved away, the same becomes the electrical connection of the fixed contacts 56 block, which opens the main contacts.

The connecting bolts 54 and 55 are usually called a B connection bolt (i.e. a battery connection bolt) or an M connection bolt (i.e. a motor connection bolt). The B and M connector bolts 54 and 55 have external threads. With the B connection bolt 54 is a terminal of a battery cable brought to a positive terminal of the battery B to be connected. With the M connection bolt 55 is a connection of a motor lead that with a plus from one of the brushes 10 of the electric motor 3 connected to connect.

The resinous frame 29 who is in 1 shown has collars 29 which are inset molded therein. Each of the B and M connector studs 54 and 55 is from within the fixed contacts 56 in one of the collars 29 introduced to have a threaded head protruding from the collar 29 protrudes. A washer 61 is on each of the collars 29 arranged. The connection of each of the collar M connector studs 54 and 55 with one of the fixed contacts 56 is made by placing a nut 62 on the washer 61 and tightening the nut firmly 62 reached.

Each of the pinned contacts 56 is separate from a corresponding one of the B and M connection bolts 54 and 55 made from a one-piece link. The fixed contacts 56 are, as described above, to the B and M connection bolts 54 and 55 electrically joined. Each of the pinned contacts 56 has a contact area 56a with which the moving contact 57 is in contact. The contact areas 56a of fixed contacts 56 are in the forward direction of the electromagnetic solenoid device 2 agile. The contact areas 56a In other words, extend substantially perpendicular to the length of the plungers 36 and 47 (that is, the axial direction of the electromagnetic solenoid device 2 ).

The moving contact 57 is how it is in 1 can be seen between a resinous insulating plate 63 and an insulating bushing 64 held and attached to the plunger 47 of the second solenoid SL2 appropriate.

The moving contact 57 extends in the radial direction of the electromagnetic solenoid device 2 (i.e. the plunger 36 and 47 ). The moving contact 57 has a contact area 57a with which the fixed contacts 56 are in contact. The contact area 57a is in the forward direction of the electromagnetic solenoid device 2 agile. The contact area 57a in other words, extends substantially perpendicular to the length of the plungers 36 and 47 (that is, the axial direction of the electromagnetic solenoid device 2 ). If necessary, the fixed contacts 56 to open, the contact surfaces 57a of the moving contact 57 from the contact surfaces 56a in the reverse direction (i.e. the right direction as in 1 and 2 seen) moved away.

The moving contact 57 is made by a contact pressure spring 65 pressed so that the same between the insulating bushing 64 and the shoulder of the plunger 47 through the insulating plate 63 is grasped. This causes the contact surfaces 57a of the moving contact 57 a given degree of pressure on the contact surfaces 56a of the pinned contact 56 exercise when the moving contact 57 with the fixed contacts 56 establishes contact.

The reset position of the plunger 47 of the second solenoid SL2 , that is, a rest position in which the plunger 47 is moved by the reactive force as it is by the return spring 50 is generated and then stopped when the coil 46 is de-excited so that the magnetic Attraction acting on the plunger 47 acts, disappears, is how it is in 1 can be seen through physical contact of the socket 64 with the end frame 30th Are defined.

The characteristics as indicated by the structure of the electromagnetic solenoid device 2 are described below. In the following discussion, the sprocket side direction, as previously described, is the forward direction (i.e., the left direction in 1 and 2 ), while the anti-sprocket side direction is the reverse direction (i.e., the right direction in Figs. 1 and 2).

Each of the pinned contacts 56 has a connecting section 56b , to which one of the connecting bolts 54 and 55 is joined. Each of the connecting sections 56b of fixed contacts 56 extends substantially in the axial direction of the plungers 36 and 47 (i.e., the axial direction of the electromagnetic solenoid device) and is closer to the pinion 6th (i.e. the front of the electromagnetic solenoid device 2 ) than the contact area 56a positioned.

Each of the pinned contacts 56 is formed by bending a plate into an L-shape and is composed of two strips with an arch between them 56e the L-shape. One of the two strips is the connecting section 56b that is attached to a corresponding one of the connecting bolts 54 and 55 is joined. The other strip is a contacting portion 56c with which the moving contact 57 establishes contact. Each of the pinned contacts 56 has a straight area that extends from an inner end 75 of the contacting section 56c to a boundary between the arch 56e and a flat body of the contacting portion 56c extends. A portion of the movable contact should be within such a straight area 57 who has an outer end 85 has each of the fixed contacts 56 to contact. The contact area 56a from each of the pinned contacts 56 and a corresponding one of the contact areas 57a of the moving contact 57 more specifically, in a wide area from the inner end 75 of the pinned contact 56 to the outer end 85 of the moving contact 57 make electrical contact with each other, thereby increasing the life of the main contacts even in the case where the electromagnetic solenoid device 2 is used with the idle stop system for self-propelled vehicles.

The contacting section 56c from each of the pinned contacts 56 extends in the radial direction of the electromagnetic solenoid device 2 and is from the pinion 6th positioned further away than the coil 46 of the second solenoid SL2 . The contact area 56a of the contacting section 56c faces in the anti-sprocket side direction.

The connecting section 56b from each of the pinned contacts 56 extends from a radially outer end (i.e. the arch 56e ) of the contacting section 56c in the pinion side direction. The connecting section 56b is outside the stationary core part 53 in the radial direction of the electromagnetic solenoid device 2 positioned. The thickness-wise direction of the connecting portion 56b is parallel to the radial direction of the electromagnetic solenoid device 2 .

Each of the connecting sections 56b has a hole 56d extending through a thickness thereof. Each of the terminal studs 54 and 55 goes through the hole 56d . The connection of the connecting section 56b with the resinous frame 29 is, as previously described, by tightening the nut 62 reached to the external thread of one of the connecting studs 54 and 55 engage and the connecting section 56b between the head of one of the connecting bolts 54 and 55 and the collar 60 to grip firmly. Each of the terminal studs 54 and 55 extends as from the 1 and 2 can be seen from one of the connecting sections 56b in the radial direction of the electromagnetic solenoid device 2 (i.e. parallel to the direction in which the contact surface is 56a extends).

Each of the connecting sections 56b is oriented around the axially extending strips 53a of the stationary core parts 53 in the radial direction of the electromagnetic solenoid device 2 to overlap. The connecting sections 56b and the connecting bolts 54 and 55 in other words, are outside the stationary core parts 53 in the radial direction of the electromagnetic solenoid device 2 positioned. An air gap C. is between the head of each of the terminal studs 54 and 55 and the outer periphery of a corresponding one of the stationary core parts 53 generated to produce electrical insulation therebetween.

The connecting sections 56b are, as described above, in direct contact with the resinous frame 29 placed and extend substantially parallel to the length of the stationary core parts 53 . Each of the connecting sections 56b is at an interval away from a corresponding one of the stationary core parts 53 arranged, which is equivalent to the sum of the thickness of the head of the connecting bolt 54 and 55 and the size of the air gap C. in the radial direction of the electromagnetic solenoid device 2 is.

OPERATION AND ADVANTAGEOUS EFFECTS IN THE FIRST EXAMPLE

The electromagnetic solenoid device 2 as previously described has the connecting sections 56b with which the connecting bolts 54 and 55 are mechanically and electrically connected. The connecting sections 56b are to the pinion 6th (i.e. the front of the electromagnetic solenoid device 2 ) positioned closer than the contact surfaces 56a of fixed contacts 56 . When the electromagnetic solenoid device 2 is in a de-excited state are the moving contact 57 , the pinned contacts 56 and the connecting bolts 54 and 55 in this order from the rear end of the electromagnetic solenoid device 2 that from the pinion 6th farthest away. The connections of the connecting bolts 54 and 55 with the fixed contacts 56 are to the pinion 6th positioned closer than the contact surfaces 56a .

The connecting bolts 54 and 55 and the connections of the connecting bolts 54 and 55 with the fixed contacts 56 In other words, they are not placed in the positions directed by the pinion 6th are further away than the contact surfaces 56a . The electromagnetic solenoid device 2 is of a tandem solenoid type, so the need to consider the amount of movement of the pinion 6th when adjusting the amount, the moving contact with me 57 must move is eliminated, which enables the latter amount to be reduced. This allows the length of a portion of the electromagnetic solenoid device 2 that is in the axial direction of the electromagnetic solenoid device 2 from the pinion 6th is further away than the contact surfaces 56a of fixed contacts 56 , is reduced.

The foregoing structure also allows the length L of the electromagnetic solenoid device 2 as it is in 2 can be seen between a starter mounting surface 19a of the starter housing 19th and the longitudinal center line of the connecting bolts 54 and 55 in the axial direction of the electromagnetic solenoid device 2 is reduced, thereby enabling electrical cables such as a wire harness to be connected to the electromagnetic solenoid device 2 connected, be shortened. The length L may be set identical to that of a starter equipped with a single solenoid, for example, as in FIG Japanese Patent No. 4207854 , which is referred to in the introductory part of this application is taught. The starter mounting surface 19a is where the electromagnetic solenoid device 2 attached to the machine.

4th represents the electromagnetic solenoid device 2 according to the second embodiment of the invention. The same reference numerals as used in the first embodiment refer to the same parts, and explanation thereof in detail is omitted here.

The electromagnetic solenoid device 2 is with isolating links 66 equipped, one for each of the stationary core parts 53 . Each of the isolating links 66 is more precisely between a corresponding one of the connecting bolts 54 and 55 and a corresponding one of the stationary core parts 53 and between a corresponding one of the connecting sections 56b of fixed contacts 56 and one of the stationary core parts 53 at least within a region in which the stationary core parts 53 in the radial direction of the electromagnetic solenoid device 2 the connecting bolts 54 and 55 overlap.

Each of the isolating links 66 is made of, for example, an insulating paper and continuously occupies or covers the whole of an outer end surface of the radially extending strip 53b of the stationary core part 53 attached to the rear of the electromagnetic solenoid device 2 facing, and an outer surface of the axially extending strip 53a , the at least one area, which is one of the connecting bolts 54 and 55 in the radial direction of the electromagnetic solenoid device 2 is facing, has.

The structure of the electromagnetic solenoid device 2 the second embodiment offers the following additional effects.

Each of the isolating links 66 is used between a corresponding one of the connecting bolts 54 and 55 and a corresponding one of the stationary core parts 53 and between a corresponding one of the connecting sections 56b and one of the stationary core parts 53 to isolate so that the air gap is allowed C. between one of the connecting bolts 54 and 55 or the connecting sections 56b and the stationary core part 53 is reduced in size compared with the structure of the first embodiment. This enables the overall size of the electromagnetic solenoid device 2 is decreased.

When a foreign object in the air gap C. has occurred, the isolating link serves 66 this to avoid a short circuit between each of the terminal studs 54 and 55 and a corresponding one of the stationary core parts 53 to avoid.

5 represents the electromagnetic solenoid device 2 according to the third embodiment of the invention. The same reference numerals as used in the second embodiment refer to the same parts, and explanation thereof in detail is omitted here.

The electromagnetic solenoid device 2 is as in the second embodiment with insulating members 6th equipped, one for each of the stationary core parts 53 . Each of the isolating links 66 is made of an elastic material such as rubber. Each of the isolating links 66 is between one of the connecting bolts 54 and 55 and one of the stationary core parts 53 squeezed and held.

Each of the isolating links 66 is how it is in 5 is shown, more precisely placed while the same between the axially extending portion 53a a corresponding one of the stationary core parts 53 and the head of a corresponding one of the connecting bolts 54 and 55 is compressed. The isolating links 66 always expand in the radial direction of the electromagnetic solenoid device 2 off so that the core sections 53 in the radial direction of the electromagnetic solenoid device 2 are pressed inwards and also the connecting bolts 54 and 55 in the radial direction of the electromagnetic solenoid device 2 be pressed outwards.

The structure of the electromagnetic solenoid device 2 the third embodiment offers the following additional effects.

Each of the isolating links 66 is used between a corresponding one of the connecting bolts 54 and 55 and a corresponding one of the stationary core parts 53 to isolate, and also to shift the location of one of the terminal studs 54 and 55 to minimize when exposure to physical shock has occurred following engagement of the pinion 6th with the ring gear G or generated when the vehicle vibrates.

Although the present invention has been disclosed in connection with the preferred embodiments in order to facilitate a better understanding thereof, it should be apparent that the invention can be embodied in various ways without departing from the principle of the invention. The invention should therefore be understood to include all possible embodiments and modifications of the illustrated embodiments that can be practiced without departing from the principle of the invention as set out in the appended claims.

The electromagnetic solenoid device 2 is as an actuator for the speed reduction starter 1 used in each of the first to third embodiments, but may be designed to match the first solenoid SL1 to have that the plunger 36 in a direction opposite to that in the second solenoid SL2 tighten, and be used with a starter in which the pinion 6th by a shift lever operated by the first solenoid SL1 is moved to the ring gear G is pushed.

Each of the isolating links 66 , as used in the second and third exemplary embodiments, can only be between a section of one of the connecting bolts 54 and 55 or a portion of one of the stationary core parts 53 that are closest to each other can be arranged. In the structure of each of the second and third embodiments, the distance between each of the terminal bolts is 54 and 55 and a corresponding one of the stationary core parts 53 between the head of the connecting bolt 54 or 55 or the connecting section 56b and the stationary core part 53 the shortest. The isolating links 66 can therefore only between the head of the connecting bolt 54 and 55 and the stationary core parts 53 be arranged.

In the case where the distance between each of the connecting portions 56b of fixed contacts 56 and a corresponding one of the stationary core parts 53 between the stationary core part 53 and the connecting section 56b or the connecting bolt 54 or 55 the shortest one can use the insulating links 66 only between the connecting gates 56b and the stationary core parts 53 be arranged.

Claims (3)

Electromagnetic solenoid device (2) for use in a starter (1), which serves to apply a torque, such as that generated by an electric motor (3), to a pinion (6) which meshes with a ring gear (G) of a machine to transmit to start the engine, comprising: a first solenoid (SL1) equipped with a first coil (35) having a first end and a second end opposite to the first end in an axial direction thereof, with the first end facing the pinion (6) of the starter (1) when the same is energized, the first coil (35) serving to drive the pinion (6) as it moves in the axial direction of the first coil ( 35) positioned closer to the first end of the first spool (35) than to the second end, to move the ring gear (G); a second solenoid (SL2) equipped with a second coil (46) having a first end and has a second end opposite to the first end in an axial direction thereof, the second solenoid (SL2) being arranged in alignment with the first solenoid (SL1) in an axial direction of the electromagnetic solenoid device (2) so that the first end thereof is closer to the second end of the first coil (35) than to the first end of the first coil (35) when the same is energized, the second coil (46) serving to open main contacts (56, 57) or to close in order to supply the electric motor (3) of the starter (1) with electrical power or to interrupt the same; a movable contact (57) and fixed contacts (56) serving as the main contacts (56, 57), the movable contact (57) closer to the second end of the second coil (2) in the axial direction of the electromagnetic solenoid device (2) 46) than to the first end of the second coil (46), the fixed contacts (56) each having connecting portions (56b) and being placed between the movable contact (57) and the second end of the second coil (46) wherein the movable contact (57) is moved to the pinion (6) by the second solenoid (SL2) to make contact with the fixed contacts (56), and further away from the pinion (56) by the second solenoid (SL2). 6) moved to leave the fixed contacts (56); first and second terminal studs (54, 55) for use in establishing electrical connections to an exterior, the first and second terminal studs (54, 55) being joined to the connecting portions (56b) of the fixed contacts (56), respectively wherein the fixed contacts (56) have contact surfaces (56a) with which the movable contact (57) is moved by the second solenoid (57) to make contact, and wherein the connecting portions (56b) closer to the pinion ( 6) are positioned as the contact surfaces (56a), and with stationary core parts (53) arranged around the first and second coils (35, 46) to form together with the first and second solenoids (SL1, SL2) a magnetic circuit with the stationary core parts (53) laid so as to overlap the connecting portions (56b) in a radial direction of the electromagnetic solenoid device (2). Electromagnetic solenoid device (2) according to Claim 1 further comprising insulating members (66) each of which is either between one of the first and second terminal studs (54, 55) and one of the stationary core parts (53) or between one of the connecting portions (56b) of the fixed contacts (56) and one of the stationary core parts (53) lies or between one of the first and second terminal studs (54, 55) and one of the stationary core parts (53) and between one of the connecting portions (56b) of the fixed contacts (56) and the one of the stationary ones Core parts (53) lies at least within a region in which the stationary core parts (53) overlap the terminal bolts (54, 55) in the radial direction of the electromagnetic solenoid device (2). Electromagnetic solenoid device (2) according to Claim 2 wherein each of the insulating members (66) is made of an elastic material, each of the insulating members (66) being placed while being sandwiched between one of the connecting portions (56b) or one of the first and second terminal bolts (54, 55) and one of the stationary core parts (53) or between one of the connecting portions (56b) and one of the stationary core parts (53) and between one of the first and second terminal bolts (54, 55) and one of the stationary core parts (53) is compressed.

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