EP2411993A1

EP2411993A1 - Starter relay of a starter device for internal combustion engines

Info

Publication number: EP2411993A1
Application number: EP10709730A
Authority: EP
Inventors: Houman Ramezanian; Josef Weigt; Raphael Schymura
Original assignee: Robert Bosch GmbH
Current assignee: Robert Bosch GmbH
Priority date: 2009-03-23
Filing date: 2010-03-22
Publication date: 2012-02-01
Anticipated expiration: 2030-03-22
Also published as: DE102009001725A1; JP5301028B2; CN102369586A; HUE031443T2; WO2010108878A1; US20120098629A1; EP2411993B1; CN102369586B; US8514038B2; JP2012521512A; ES2614160T3

Abstract

The invention relates to a starter relay (19) for internal combustion engines, comprising a relay coil (27) and an armature (20), which interacts with a fork lever (21) by way of a driver (24) so as to toe-in a starter pinion, and comprising a contact bridge (34) which is to be actuated by the armature by way of a switch axis (32) and interacts with switch contacts (23a), wherein a coupling (33b) connects the switch axis and the armature such that they can be displaced with respect to each other to a limited extent. In order to ensure that welded contacts tear open and the neutral position of the fork lever is achieved when the relay is shut off, a pretensioned compression spring (26) is inserted between the armature (20) and the end of the fork lever (21).

Description

description

title

Starting relay of a starting device for internal combustion engines

State of the art

The invention relates to a starting relay of a starting device for internal combustion engines according to the preamble of claim 1.

From the published patent application DE 199 51 116 Al is a relay for a

Starting device of internal combustion engines is known in which a coupling element, the shift rod of the relay and the armature connected to each other limited slidably. About this coupling element welds of the contact bridge with the switch contacts of the relay when the relay is turned off by the accelerated by an armature return spring magnet armature again. However, this function of the coupling element is limited by manufacturing and setting tolerances of the starting relay and the Einspurmechanismuses for the starter pinion of the starting device. Depending on the design of the coupling element, two critical cases can occur. On the one hand, when the quiescent air gap between the magnet armature and the magnet core of the relay is too small, the contacts welded together are not torn open, because the magnet armature presses the engagement device against a rest stop by means of a fork lever before the armature of the magnet armature can actuate the coupling element. On the other hand, the magnet armature reaches its by a rest stop the

Switching axis via the coupling element predetermined rest position before the Einspureinrichtung the starting device can be pressed via the fork lever in its rest position, so that, if necessary, the starter pinion is not spilled out safely. With the present solution is sought to ensure with the shutdown of the starting relay in any case tearing each other welded switch contacts of the relay and a return of the Einspureinrichtung against a rest stop.

Disclosure of the invention

The starter relay according to the invention with the features mentioned in the characterizing part of claim 1 has the advantage over the prior art that for the entire range of manufacturing and adjustment tolerances

Clutch element can be dimensioned so that on the one hand tear welded contacts when switching off the relay and on the other hand in the rest position of the armature Einspureinrichtung the starter is pressed over the fork lever against its rest stop. While the rest position of the armature as before by a rest stop the

Shifting axis is specified via the coupling element, the fork lever is now additionally pivoted back so far with the help of the compression spring according to the invention, until thereby the Einspureinrichtung the starting device rests in a simple and reliable manner to their rest stop. Another advantage of the solution according to the invention is that due to the now lacking free travel between the head of the fork lever and the punching window in the driver dynamics in the meshing of the starter pinion is increased and further that the temperature-dependent function limit of the starting relay is increased by the magnetic initial force by the Working air gap of the armature reduced by the lack of free travel in the punching window of the driver and thus the magnetic force at the beginning of the anchor travel can be increased.

Although a starting device for internal combustion engines with a starting relay is already known from the patent application publication US 2002/000 5771 Al, in which at the free end of a driver attached to the armature, a compression spring is arranged, which acts on the fork lever for the Einspurmechanismus. However, this spring is supported with its rear end on the housing of the starting relay and thus has the function of an armature return spring. The measures listed in the dependent claims, advantageous refinements and improvements of the main claim features. To achieve optimal Einspurdynamik the starting device, it is expedient if in the rest position of the starting relay, the pressure force of the compression spring is greater than the restoring force of the

Anchor return spring, because it is a game between the fork lever and the driver of the armature is avoided. Furthermore, it is advantageous for the shutdown of the starting device in a hang-lasting, einpurtem starter pinion when the pressure force of the compression spring in the closed position of the armature is less than that then on the

Magnet armature acting restoring force of contact and armature return spring, so then at least the starter motor is switched off by the starting relay.

In the simplest case, the compression spring is a helical compression spring, which is axially mounted on the end portion of the driver. To avoid constructive

Changes to the driver is provided that the helical compression spring is supported in one advantageous manner with its one end on a disc on a protruding into a punching window in the end portion of the driver head end of the fork lever and with its other end on the front side of the magnet armature. To the helical compression spring with the dish washer without the

Fork lever on the starting relay captive preassembled, a finger is suitably punched free on both sides in the middle region of the plate disc, which engages from above through the punching window, the driver, so that in the preassembled state, the plate disc with the biasing force of the helical compression spring against the outer Front wall of the punching window on

Driver supports.

Brief description of the drawings

The invention will be explained in more detail below, for example, with reference to the figures. Show it:

1 shows a starting device for internal combustion engines with a starter relay in a schematic representation, 2 shows the starting relay in longitudinal section with an additional compression spring and the armature in the position before the tearing of welded switch contacts,

FIG. 3 shows the pre-assembly of the pressure spring and disk disk on the driver of the starting relay in a room-size enlarged representation;

Figure 4 shows the starting relay in longitudinal section with an upper part a) in the illustrated operating position and in the lower part b) in the rest position.

Embodiments of the invention

Figure 1 shows the schematic structure of a starting device 10 for internal combustion engines. The starting device 10 has a starter motor 11, the drive shaft 12 has a coarse thread 13 which cooperates with a corresponding female thread in a Mitnehmerschaft 14. Alternatively, the drive shaft 12 via an interposed, not shown

Planetary gear driven by the starter motor 11. The Mitnehmerschaft 14 is fixedly connected to the outer ring of a freewheel 15, the inner ring carries a starter gear 16 front. Starter pinion 16 and freewheel 15 are mounted on the drive shaft 12 to a stop 17 on the one hand and to the end of the helical thread 13 on the other hand axially displaceable. The starter pinion 16 is doing in a

Sprocket 18 of the internal combustion engine, not shown eingespurt. The axial displacement takes place with the aid of a starting relay 19, whose armature 20 engages via a fork lever 21 and a Einspurfeder 22 on the freewheel 15. The power supply of the starter motor 11 is also via the start relay 19 whose contact pins 23 are connected on the one hand to the positive potential of the vehicle battery, not shown, and on the other hand to the starter motor 11. About a magnet armature axially outwardly projecting driver 24 of the fork lever 21 is operated to toe in the starter pinion 16. The fork lever 21 protrudes with its head end 21a in a punching window 25 of the driver. Between the armature 20 and the

Head end 21a of the fork lever 21 is a biased formed as a helical spring compression spring 26 is used. When the starter relay 19 is switched off, it presses a picking device 50 consisting of coarse thread 13, driving shaft 14, fork lever 21 and lashing spring 22 into the rest position shown. To start the engine is with the switching of the starter relay 19th the magnet armature 20 is retracted and thus the starter pinion 16 is meshed with the ring gear 18 via the fork lever 21. In the last part of the armature travel also not shown switching contacts of the starter relay are closed, and thus the starter motor 11 is turned on to crank the engine.

In Figure 2, the starting relay 19 of Figure 1 is shown in its structural design in longitudinal section. It has a relay coil 27, which is connected via a connection in a switch cover 28 with a start switch, not shown, of the motor vehicle on the one hand and on the other hand with the housing 29 of the starting relay. The relay coil 27 is first inserted into the pot-shaped housing 29 together with a brass sleeve 30 and a magnetic core 31. At the bottom of the housing 29, the armature 20 is axially guided in an opening, which dips into the relay coil 27. In a central bore of the armature 20 of the driver 24 is fixed, the axially outwardly projecting end portion 24a is provided as a so-called paddle for receiving the fork lever 21 with the punching window 25. In a passage opening of the magnetic core 31, a switching axis 32 is guided by means of an insulating sleeve 33. At the outer end of the switching axis 32, a contact bridge 34 is received axially displaceable. The housing 29 of the

Starting relay 19 is completed by the switch cover 28. The protruding into the interior of the switch cover 28 ends of the contact pins 23 are formed as switching contacts 23 a, which cooperate with the contact bridge 34. The inner end of the switching axis 32 is in the rest position of the relay to the end of the driver 24 with a distance a opposite.

Between the magnetic core 31 and the armature 20, an armature return spring 36 is inserted, which is supported at one end on the end face of the magnetic core 31 and at the other end at the bottom of a recess 35 in the magnet armature 20. In the switch cover 28 there is a contact return spring 37, which is supported on the one hand at the bottom of the switch cover 28 and on the other hand to a support plate 38 attached to the outer end of the switching axis 32. A contact pressure spring 39 is located in an axial blind hole 40 of the magnetic core 31. This spring is supported on the one hand via an insulating cap 41 on the contact bridge 34 and on the other hand on the front side of the insulating sleeve 33 from. All three springs are preloaded, wherein the stronger biased contact return spring 37 tries to press the contact bridge 34 against the bias of the contact pressure spring 39 in the rest position.

In the starting relay 19 according to FIG. 2, the insulating sleeve 33 positively fastened to the switching axis 32 is formed in the front region as a coupling 33b, which connects the switching axis 32 and the magnet armature 20 to one another in a displaceable manner. This is achieved in that the driver 24 is formed on its inner, projecting into the recess 35 of the magnet armature 20 end as a head 24b. This head 24b is covered by several, at the end of

Clutch 33b formed claws 33a includes.

With the aid of FIG. 2, which shows the position before the tearing of welded contacts together, it will now be explained how a welding of the switching contacts 23a to the contact bridge 34 is torn open again.

During the starting phase, the magnet armature 20 is pulled against the magnetic core 31 with magnetic force by the magnetic field of the relay coil 27 through which current flows. In this case, the biased armature return spring 36 is further tensioned and the driver 24 pushes the switching axis 32 after bridging the distance a to the right, so that the contact bridge 34 is raised and finally touches the switch contacts 23a. In addition, the contact return spring 37 is further tensioned. In the last section of the anchor travel, the switching axis 32 is pressed even further against the force of the contact return spring 37 for the so-called burnup reserve, thereby additionally tensioning the likewise preloaded contact pressure spring 39 until finally the armature 20 rests against the magnet core 31 at the front. If now weld at an uneven contact surface and high current load small areas of the switching contacts 23a with the contact bridge 34, so when switching off the start relay 19, the force of the contact return spring 37 is not sufficient to tear such a weld. By trained on the insulating sleeve 33 of the switching axis 32 coupling 33b is now achieved that when switching off the starter relay 19 of the armature 20 is accelerated by the force of the armature return spring 36 on its way to the rest position by initially unhindered travels a path that the Distance a between the switching axis 32 and driver head 24b corresponds. With the included Kinetic energy is now the switching axis 32 via the jaws 33a of the insulating sleeve 33 taken from the head 24b of the driver 24, as shown in Figure 2. With the help of this kinetic energy and the additional force of the contact restoring spring 37, the welding of the switching contacts 23a with the contact bridge 34 is now torn open. The contact bridge 34 is then pressed by the force of the contact return spring 37 in the rest position, in which the insulating cap 41 of the contact bridge 34 is supported at the bottom of the blind bore 40 in the magnetic core 31. Further, the armature 20 is pressed by the armature return spring 36 to its rest position, which is predetermined by the rear stop of Einspureinrichtung 50 on the starting device 10.

The helical compression spring 26, which is supported at one end via a washer 42 at the head end 21a of the fork lever 21 and with its other end on the end face of the armature 20, causes the permanent

Applying the Gabelhebel- head end 21a to the outer end wall 25a of the punching window 25 due to the biasing force of the helical compression spring 26. With the help of this measure, the clutch 33b can now be formed on the switching axis 32 and the driver 24 by means of Isolierstoffhülse 33 so that by a relative small distance a over the entire range of

Manufacturing tolerances rupturing each other welded switch contacts 23a is ensured by the armature 20. Without this helical compression spring 26, however, the head end 21a of the fork lever would be supported when switching off the starter relay 19 on the inner end wall 25b of the punched 25 with the result that when switching off the start relay

19, the contact bridge 34 is pressed into the rest position and there via the switching axis 32 and the Isolierstoffhülse 33 accelerated by the armature return spring 36 magnet armature 20 after passing through the distance a in the then reached rest position, without possibly the Einspurvorrichtung 50 of the starter 10 their Has reached rest. This could lead to unfavorable manufacturing and assembly tolerances that the starter pinion 16 can not be spitted sufficiently far from the ring gear 18. With the help of the helical compression spring 26 is thus both tearing each other welded switch contacts 23 a as well as a secure Ausspuren the starter pinion 16 to the rear stop the Einspurvorrichtung 50 achieved over the entire range of manufacturing and adjustment tolerances. In order to prevent that in the case in which the rest position of the Einspureinrichtung 50 reached earlier than the rest position of the armature 20, the armature return spring 36 presses the armature 20 against the force of the helical compression spring 26 in the rest position, and thereby between the punching window 25 of the driver 24 and the head end 21a of the fork lever 21 a game occurs, the helical compression spring 26 is designed so that in the rest position of the starting relay 19, the pressure force of the helical compression spring 26 is greater than the restoring force of the armature return spring 36th

FIG. 3 shows, in an enlarged spatial representation, the pre-assembly of the helical compression spring 26 at the rear end region 24a of the driver. This pre-assembly is required because the starting relay 19 is manufactured as a separate component of the starting device 10. In the pre-assembly, first, the helical compression spring 26 is pushed axially from the outside in the arrow direction on the end portion 24a of the driver 24 of Figure 2, so that it rests with its one end on the end face of the armature 20. Thereafter, the helical compression spring 26 is pressed axially together so that it is under bias. Subsequently, the plate disc 42 is placed from above in the arrow direction on the paddle-shaped end portion 24a by a from the middle region of the washer 42 punched on both sides to the edge of the disk fingers 42a engages from above through the punching window 25 of the driver 24. Then, the washer 42 is placed on the free end of the helical compression spring 26. With the release of the helical compression spring 26 this now presses in the preassembled state

Belleville spring 42 via the punched-out fingers 42a against the outer end wall 25a of the punching window 25th

Figure 4 shows the starting relay 19 of Figure 2, which is divided into two halves each shown in longitudinal section. In the upper part a) of Figure 4, the starting relay 19 is in the working position, the magnet armature 20 is pressed against the force of the armature return spring 36 against the armature core 31 by the magnetic field of the current-carrying relay coil 27 and there abuts the front side. The driver 24 has with its head 24b, the switching axis 32 against the force of the contact return spring 37 pressed so far to the right until the Contact bridge 34 is applied to the switch contacts 23a of the contact pin 23. In addition, the switching axis 32 is pressed by the driver 24 of the magnet armature 20 due to the so-called erosion reserve a little further to the right against the contact pressure spring 37, whereby even the contact pressure spring 39 is stretched further. The fork lever 21 of

Starting device 10 according to FIG. 1 is thus pivoted so far to the right until the starter pinion 16 is completely meshed with the ring gear 18 of the internal combustion engine. The head 21a of the fork lever 21 is pressed by the helical compression spring 26 by means of the disc plate 42 against the outer end wall 25a of the punching window 25 on the driver 24.

In the lower part b) of Figure 4, the lower half of the starting relay 19 is shown in longitudinal section, which shows the rest position of the relay when the relay coil 27 is switched off. With the force of the contact return spring 37 while the switching axis 32 is pushed back against the force of the contact pressure spring 39 until the contact bridge 34 enters its rest position. This situation is achieved as soon as the insulating cap 41 is supported as a carrier of the contact bridge 34 at the bottom of the blind hole 40 in the magnetic core 31. At the same time presses with the release of the magnetic force, the tensioned armature return spring 36, the armature 20 as far to the left until the driver 24 is held axially fixed with its head 24b of the coupling jaws 33a of Isolierstoffhülse 33.

The fork lever 21 is thereby pivoted to the left, whereby the starter pinion 16 is spoked out of the ring gear 18 of the machine. With the compression spring 26 while the head 21a of the fork lever 21 is pushed over the pan plate 42 far enough to the left until the Einspureinrichtung 50 of Figure 1 has reached its rear stop on the coarse thread 13.

The manufacturing and installation tolerances may never be so great that when reaching the rest position of the armature 20 according to Figure 4 part b) the

Starter pinion 16 of the starting device 10 of Figure 1 is not yet spit out with the required safety distance from the ring gear 17 of the machine. Ideally, therefore, the rest position of the armature 20 and the rest position of the Einspureinrichtung 50 of the starting device 10 is achieved simultaneously. But also uncritical is the case where the rest position of the Einspureinrichtung 50 is reached earlier than the rest position of the armature 20. For such cases, the helical compression spring 26 is designed so that the pressure force of the helical compression spring 26 in the rest position of the starting relay 19 is greater than the restoring force of the armature return spring 36. With the result that even then the head 21a of the fork lever 21 on the outer end wall 25a of the

Punch window 25 remains applied.

Another limiting case can occur when the relay coil 27 is indeed switched off in a failed attempt to start, but the starter pinion 16 remains in the Einspurstellung. Even in such a case the

Starter motor 11 to be able to switch off safely, the helical compression spring 26 is further designed so that their pressure force in the closed position of the starting relay 19 is smaller than acting on the armature 20 restoring force of contact return spring 37 and armature return spring 36. In this case, with the switching off the relay coil 27 of the armature 20 with the force of the anchor and

Contact return spring 36 and 37 against the force of the helical compression spring 26 moves as far to the left until the head 21a of the fork lever 21 abuts the inner end wall 25b of the punching window 25. The thereby laid back path of the driver 24 is sufficient to lift the contact bridge 24 on the so-called burn-up reserve addition of the switch contacts 23a and thus the

Circuit for the starter motor 11 to interrupt. At standstill, the starter pinion 16 from the starter relay 19 can now be completely out of the ring gear 18 of the machine effortlessly.

In the rest position shown in Figure 4b, the armature 20 has to

Magnet core 31 its maximum working air gap A occupied by the so-called burn-up reserve of the relay is greater than the marked in Figure 2 distance a between driver 24 and switching axis 31. This maximum working air gap A can now be selected smaller by 26 than by using the helical compression spring Starting relay without such a compression spring, since the helical compression spring 26 is now able to pivot the fork lever 21 in the rest position further to the left. Due to the resistance of the fork lever located in the rest position, the magnet armature dives deeper into the relay coil. This measure increases at the start relay 19, the magnetic retraction force at the beginning of the armature movement from the rest position.

The invention is not limited to the illustrated and described embodiment. Thus, it is quite possible within the scope of the invention, the designed to tear off each other welded contacts of the relay coupling provided between switching axis 32 and armature 20 constructively different, as is known inter alia from the document DE 102 60 843 Al. Essential to the invention, however, is the combination of such a coupling with a compression spring 26 between the armature end face of

Starting relay 19 and the head of the fork lever 21 of the starting device 10 in order to avoid the two critical limiting cases described above in the tolerance range of manufacturing, setting and assembly tolerances.

Claims

claims

1. start relay (19) of a starting device (10) for internal combustion engines, with a relay coil (27) and a magnet armature (20), which is energized by energizing the relay coil from the rest position to a working position against the force of an armature return spring (36) and the via an axially outwardly projecting driver (24) with one end of a fork lever (21) for touring a starter pinion (16) cooperates, and with a contact bridge (34) which is to be actuated via a switching axis (32) from the armature and with Switching contacts (23a) cooperates, wherein a coupling (33b) the shift rod and the armature to each other limited slidably connected, characterized in that between the armature (20) and the end (21a) of the fork lever (21) has a prestressed compression spring (26) is used.

2. Starting relay according to claim 1, characterized in that in the rest position of the starting relay (19), the pressure force of the compression spring (26) is greater than that

Restoring force of the armature return spring (36) and that in the working position of the magnet armature (20), the compressive force of the compression spring (26) is less than the restoring force of contact return spring (37) and armature return spring (36) acting on the armature (20).

3. Starting relay according to claim 2, characterized in that the compression spring (26) is an on the driver (24) axially patched helical compression spring.

4. starting relay according to claim 3, characterized in that the helical compression spring (26) with its one end via a plate disc (42) on a in a punching window (25) of the driver (24) projecting head (21 a) of the fork lever (21) and with its other end on the end face (20a) of the armature (20) is supported.

5. starting relay according to claim 4, characterized in that in the central region of the plate disc (42) a finger (42 a) is punched on both sides to the edge of the plate, which engages from above through the punching window (25) of the driver (24).

6. Starting relay according to claim 5, characterized in that the helical compression spring (26) on the starter relay (19) in the preassembled state, the plate disc (42) via the punched fingers (42 a) to the outer end wall (25 a) of the punching window (25) on the driver (24) presses.