DE10215727A1 - Magnetic actuator for a camshaft adjuster - Google Patents

Abstract

The invention relates to a magnetic actuator for a camshaft adjuster, with a basic housing body, with receiving sections provided on the basic housing body for receiving at least one magnetic body, the magnetic body being provided for actuating an actuating means which is arranged coaxially with the camshaft and which effects the adjustment of the camshaft. DOLLAR A The invention is characterized in that the basic housing body is made of plastic, in particular glass fiber-reinforced plastic, and that conductor tracks are arranged on the plastic or are injected into the plastic and provide a central electrical connection with the at least one magnetic body and / or with the adjustment or connect the movement of the camshaft sensor elements.

Description

The invention relates to a magnetic actuator for a Camshaft adjuster, with a basic body, with on the housing base provided for receiving sections Recording at least one magnetic body, the Magnetic body for actuating a coaxial to the camshaft arranged, causing the adjustment of the camshaft Actuating means is provided. As a means of adjustment in particular hydraulic valves are used by the Magnetic body can be actuated in the axial direction.

Known magnetic actuators have a basic housing body Cast metal, in particular cast aluminum. To the The magnetic bodies are screwed onto the basic body. to Supplying the magnetic body with electrical current is one Wiring required. Such camshaft adjusters are for example from DE 196 54 926 A1 or DE 199 55 507 A1 known. These camshaft adjusters are in the Drive connection of the camshaft arranged to the crankshaft and carried over a central clamping screw, which in turn engages coaxially with the camshaft and the connection to the camshaft. The tension screw is in her the camshaft adjoining area to the Adjustment of the phase position of the camshaft to the crankshaft mutually rotatable transmission parts of the Camshaft adjuster. The clamping screw is regarding the Centered camshaft, which in the to the camshaft subsequent area of the screw shaft the housing of a Control spool forms, which in turn on the magnetic actuator is movable. The magnetic actuator is part of the housing Internal combustion engine can be set during the Anchor interacting magnet actuator with the spool connected is. This arrangement of the magnetic actuator on the outside Housing of the internal combustion engine has the advantage that the Magnetic actuator on the armature after assembling the camshaft and the camshaft adjuster can be aligned so that itself comparatively between the magnetic body and the armature small gap cross-sections result as required by sufficiently large actuating forces with a relatively small one Realize coil and magnetic body size.

The present invention is based on the object To provide magnetic actuators that are simple and inexpensive is in the making and in particular Cabling effort saved.

This task is started with a magnetic actuator mentioned type solved according to the invention in that the Housing base made of plastic, in particular glass fiber reinforced plastic, and that at the Plastic arranged or injected into the plastic Conductor tracks are provided that have a central electrical Connection with the at least one magnetic body and / or with the adjustment or movement of the camshaft Connect sensing sensor elements. The plastic is advantageously a thermoplastic. The invention has the Advantage that starting from the one central connection all components of the electrical power required Magnetic actuator are supplied by means of the conductor tracks. A Wiring of the magnetic bodies is therefore not necessary. At in the Plastic injected conductive traces is advantageous in that these are not accessible and therefore not damaged can be. In addition to minimizing the number of electrical connectors, the number of components the device is reduced. Overall, the invention builds Magnetic actuator very compact.

An advantageous embodiment of the invention provides Basic housing body pockets for receiving the sensor elements in front. This has the advantage that the separate protective housing Sensor elements can be omitted. The sensor elements can do so be embedded in the main body that they are not or are difficult to access. For secure attachment of the Sensor elements can be inserted into the respective bags with an appropriate plastic be shed.

The pockets are advantageously in the range between two Receiving portions. This has the advantage of being pockets or the sensor elements are locally close to each other, which makes the conductor tracks relatively short and therefore unaffected by interference and can be kept easily assembled.

Another advantageous embodiment of the invention results when the sensor elements on a printed circuit board are arranged. This has the advantage that additional, required electrical components pre-assembled and can be handled.

It is particularly advantageous if several sensor elements, preferably all sensor elements, on a circuit board are arranged. This has the advantage that the sensor elements be preassembled together with the common printed circuit board can and are manageable with this. Material and Manufacturing effort is consequently reduced.

The housing base body preferably has a receptacle for the printed circuit board. The circuit board is then protective in arranged the recording. Advantageously, the PCB not the main body of the housing. The Surface design corresponds to the recording advantageously the negative of the topography of the Printed circuit board.

The recording is advantageously in the range between two Receiving portions. With one board you can several, in particular two sensor elements are supplied with current become. One sensor element each is used to detect the Rotary movement of a camshaft is provided.

In one embodiment of the invention, the Conductor tracks from the central connection for receiving and contact the circuit board. This eliminates Cabling effort between receptacle and board.

Another advantageous embodiment of the invention is characterized in that the conductor tracks with the Magnetic bodies electrically connected via the printed circuit boards are. This has the advantage that only the printed circuit board is to be supplied with electricity. Then over the printed circuit board energized the magnetic bodies. The PCB is between two receiving sections, for example, both Supply the magnetic body with electricity.

The magnetic bodies see electrical connection means before that extend to the recording and the Contact the circuit board. This eliminates Cabling effort between the circuit board and the Magnetic bodies.

An advantageous embodiment of the invention provides that all conductor tracks run parallel next to each other and preferably lie in one plane. This has the advantage that the risk of faulty contacts when the conductor tracks cross is avoided.

According to the invention, it is also conceivable that the sensor elements coaxial to the longitudinal axis of the magnetic body or the respective Camshaft run. This can be accurate and simple Attachment of the sensor elements to the basic body of the housing respectively.

Another embodiment of the invention provides that a Sensor element each with the respective adjusting means or encoder wheel non-rotatably coupled to the respective camshaft detected. The encoder wheel can be designed in such a way that signals to it over a certain angular section Emits sensor element. It is conceivable that the encoder wheel has magnetized material at least in sections, then the sensor element as a magnetic field sensor element is trained.

The encoder wheel is preferably a stamped or bent part educated. Especially when the sensor elements run coaxial to the longitudinal axis of the magnetic body, offer stamped and / or bent parts, the encoder sections perpendicular to the longitudinal axis of the sensor elements or the Magnetic body or the camshaft run.

The magnetic body is advantageously a pressure magnet educated. When the magnetic body is energized, consequently on the actuating means interacting with the magnetic body in axial pressure exerted. About for example The adjusting means can be in its initial position by compression springs be returned.

Further advantageous refinements and details of Invention can be found in the following description in which the invention with reference to that shown in the figures Exemplary embodiments are described and explained in more detail.

The drawing shows:

Figure 1 shows a magnetic actuator according to the invention in a perspective view obliquely from above.

FIG. 2 shows the magnetic actuator according to FIG. 1 in an exploded view;

Fig. 3 is a second magnetic plate according to the invention in a perspective view obliquely from above;

Fig. 4 shows the housing base body of the solenoid actuator shown in FIG. 3; and

Fig. 5, 6, 7 and 8, different items of the magnetic disk of FIG. 3.

In Figs. 1 and 2, an inventive magnet actuator 10 for a camshaft adjuster, which is not shown, is shown. The magnetic actuator 10 comprises a housing base body 12 which can be flanged to a housing via fastening sections 14 , which housing contains the camshaft and crankshaft of an internal combustion engine.

The housing base body 12 , which can be screwed onto a housing (not shown) of an internal combustion engine, has two circular-cylindrical openings 16 according to FIG. 2. Around the openings 16 there is a receiving section 18 for the arrangement of one magnetic body 20 each.

The housing base body 12 , which is made of plastic and is preferably glass-fiber reinforced, provides two pockets 22 on its upper side, into each of which a sensor element 24 can be inserted. The two sensor elements 24 which can be clearly seen in FIG. 2 are each arranged on a printed circuit board 26 . The surface design of the pockets 22 essentially corresponds to the negative of the topography of the sensor elements 24 . This ensures that the sensor elements 24 are securely seated in the pockets.

Fig. 2 shows the basic body 12 injected conductor tracks 28, the free ends terminate in a central electrical terminal 32 30. The free ends 30 of the conductor tracks 28 are bent and protrude from the basic housing body 12 . They are surrounded in a protective manner by a plug connection 34 molded onto the basic housing body 12 .

The free ends 36 of the conductor tracks 28 protrude from the basic housing body 12 in the area of the magnetic bodies 20 . In the assembled state, these free ends 36 are contacted by connection means 38 provided on the magnetic bodies 20 . The contact is advantageously made when the magnetic bodies 20 are placed in their intended position on the receiving sections 18 . For permanent contacting, the free ends 36 are advantageously soldered or welded to the connection means. Fastening screws 40 are provided for fastening the magnetic bodies 20 to the housing base body 12 . Sealing rings are advantageously inserted or molded between the housing base body 12 and the magnetic bodies 20 .

The conductor tracks 28 also provide free ends 42 which extend within the basic housing body 12 to the pockets 22 . When inserting the sensor elements 24 together with the printed circuit boards 26 contacting the printed circuit boards 26 with the free ends 42 of the conductor takes place 28th

To permanently hold the sensor elements 24 together with printed circuit boards 26 and the connecting means 38 with the free ends 42 of the conductor tracks 28 , the corresponding areas are filled with potting means 44 , as shown in FIG. 1.

FIGS. 3 to 8 show a second magnetic disc 50 of the invention. The corresponding to the magnetic plate 10 components are provided in the magnetic plate 50 with corresponding reference numerals.

The magnetic actuator 50 differs from the magnetic actuator 10 in that the sensor elements 24 are arranged on a common printed circuit board 52 . The printed circuit board 52 , which can be clearly seen in particular in FIG. 6, is arranged in a receptacle 54 in the assembled state. The receptacle 54 lies in the area between the two receptacle sections 18 .

The conductor tracks 56 shown in FIG. 5 extend from the central connection 32 to the receptacle 54 , the free ends 58 in the central connection 32 protruding from the basic housing body 12 . The free ends 60 of the conductor tracks running parallel to one another and lying in a multiple-curved plane protrude from the housing base body 12 in the region of the receptacle 54 . When the circuit board 52 is inserted into the receptacle 54 , the circuit board 52 is contacted with the free ends 60 , as shown in FIG. 6. When the magnetic bodies are placed on the receiving sections 18 , the connection means 62 of the magnetic bodies 20 are contacted with contacts of the printed circuit board 52 . The energization of the magnetic bodies 20 consequently takes place, as can be clearly seen from FIG. 7, via the printed circuit board 52 .

In the state flanged to the housing of the internal combustion engine, not shown, on the side of the housing base body 12 facing away from the magnetic body 20, a sensor wheel 64 which interacts with the respective sensor element 24 and is coupled in a rotationally fixed manner to the respective actuating means or to the respective camshaft is provided. The sensor wheel following the rotary movement of the adjusting means or the camshaft has various sensor sections 66 , which lead to a sensor signal when the sensor element 24 is passed . The encoder wheel 64 is advantageously designed as a stamped and bent part, which is inexpensive to manufacture.

In the magnetic actuator 50, the sensor elements 24 are arranged coaxially to the longitudinal axis of the magnetic body 20 . The transmitter sections 66 therefore extend largely in a plane running perpendicular to the longitudinal axis of the magnetic bodies 20 .

When the magnetic bodies 20 are energized, a magnetic field acts on an armature, not shown, which is coupled to the actuating means or to the camshaft. Depending on the embodiment of the magnetic body, either the armature is axially attracted or repelled in the direction of the magnetic body 20 via the generated magnetic field. This results in an axial adjustment of the adjusting means.

The magnetic actuator 50 has the advantage over the magnetic actuator 10 that the conductor tracks 56 are greatly simplified compared to the conductor tracks 28 by moving the sensor elements in the vicinity of the central electrical connection 32 . Furthermore, the central arrangement of the sensor elements 24 makes it possible to use only one printed circuit board 52 , as a result of which the sensor elements 24 with the printed circuit board 52 can be handled as a common preassembly group.

Both described magnetic actuators 10 and 50 have the advantage that they can only be mounted from the top. The individual components can be assembled perpendicular to the base of the basic housing body. The assembly can be done by machine.

After the printed circuit board 52 and the magnetic body 20 have been mounted, the receptacle 54 can be sealed with potting agent in the magnetic actuator 50 , corresponding to the magnetic actuator 10 .

All in the description, the following claims and the Features shown can be drawn individually as well also in any combination with each other be essential to the invention.

Claims (16)

1. Magnetic actuator ( 10 , 50 ) for a camshaft adjuster, with a basic housing body ( 12 ), with receiving sections ( 18 ) provided on the basic housing body ( 12 ) for receiving at least one magnetic body ( 20 ), the magnetic body ( 20 ) for actuating a Arranged coaxially to the camshaft, the adjusting means effecting the camshaft is provided, characterized in that the basic housing body ( 12 ) is made of plastic, in particular glass-fiber reinforced plastic, and that conductor tracks ( 28 , 56 ) are arranged on the plastic or injected into the plastic which connect a central electrical connection ( 32 ) to the at least one magnetic body ( 20 ) and / or to sensor elements ( 24 ) which detect the displacement or the movement of the camshaft. 2. Magnetic actuator ( 10 , 50 ) according to claim 1, characterized in that the basic housing body ( 12 ) has pockets ( 22 , 54 ) for receiving the sensor elements ( 24 ). 3. Magnetic actuator ( 10 , 50 ) according to claim 2, characterized in that the surface design of the pockets ( 22 , 54 ) essentially corresponds to the negative of the topography of the sensor elements ( 24 ). 4. Magnetic actuator ( 50 ) according to claim 2 or 3, characterized in that the pockets ( 54 ) lie in the area between two receiving sections ( 18 ). 5. Magnetic actuator ( 10 , 50 ) according to one of the preceding claims, characterized in that the sensor elements ( 24 ) are arranged on a printed circuit board ( 26 , 52 ). 6. Magnetic actuator ( 50 ) according to one of the preceding claims, characterized in that a plurality of sensor elements ( 24 ), preferably all sensor elements ( 24 ), are arranged on a printed circuit board ( 52 ). 7. Magnetic actuator ( 50 ) according to claim 4 or 6, characterized in that the basic housing body has a receptacle ( 54 ) for the printed circuit board ( 52 ). 8. Magnetic actuator ( 50 ) according to claim 7, characterized in that the receptacle ( 54 ) lies in the area between two receptacle sections ( 18 ). 9. Magnetic actuator ( 10 , 50 ) according to claim 7 or 8, characterized in that the conductor tracks ( 28 , 52 ) extend from the central connection ( 32 ) to the receptacle ( 22 , 54 ) and contact the printed circuit board ( 26 , 52 ) , 10. Magnetic actuator ( 50 ) according to one of claims 5 to 9, characterized in that the conductor tracks ( 56 ) are electrically connected to the magnetic bodies ( 20 ) via the printed circuit board ( 52 ). 11. Magnetic actuator ( 50 ) according to one of claims 5 to 10, characterized in that the magnetic body ( 20 ) have electrical connection means ( 62 ) which extend to the receptacle ( 54 ) and contact the circuit board ( 52 ). 12. Magnetic actuator ( 50 ) according to any one of the preceding claims, characterized in that all conductor tracks ( 56 ) run parallel next to one another and preferably lie in one plane. 13. Magnetic actuator ( 50 ) according to any one of the preceding claims, characterized in that the sensor elements ( 24 ) run coaxially to the longitudinal axis of the magnetic body ( 20 ). 14. Magnetic actuator ( 10 , 50 ) according to one of the preceding claims, characterized in that a sensor element ( 24 ) detects in each case a sensor wheel ( 64 ) coupled in a rotationally fixed manner to the respective actuating means or to the respective camshaft. 15. Magnetic actuator ( 50 ) according to claim 14, characterized in that the encoder wheel ( 64 ) is designed as a stamped and / or bent part. 16. Magnetic actuator ( 50 ) according to any one of the preceding claims, characterized in that the magnetic body ( 20 ) is designed as a pressure magnet.