DE3907133A1 - Device for adjusting a throttling element in a fluid line - Google Patents

Abstract

In the case of a device for adjusting a throttling element (12) in a fluid line (10), in particular of a motor vehicle engine, having a driving device (16) acting on the throttling element (12) and a controlling device (54) controlling said driving device, the driving device is an electromagnetic actuating drive (16) comprising a magnet arrangement (18) and a coil arrangement (34) and operating on the plunger-coil or moving-coil principle, the movable actuator (magnet arrangement (18) or coil arrangement (34)) of which is drivingly connected to the throttling element (12). <IMAGE>

Description

The invention relates to a device for adjusting a throttle element in a fluid line, esp especially in a motor vehicle engine with one on the Throttle element attacking drive device and a control device controlling this. Under Throttle element is, for example, a conventional one rotatable throttle valve or a linear adjustment Valve interacting with a valve seat to understand body.

It is known to have a throttle valve in a carburetor or ent in a turbocharger for automotive engines neither directly mechanically, for example via a Cable pull or depending on the operation Conditions of the motor vehicle engine via a tire to adjust the mechanical drive, for example exhibit one under certain operating conditions acting negative pressure on an actuating cylinder leaves. The latter system was mainly because of this preferred because you thought you were on this way the throttle in adaptation to that did Adjust the existing operating conditions can. It has now been shown that this type of ver position of a throttle valve, especially in turbo load is not accurate and fast enough to get in many countries tightened provisions on the Ab to meet gases from motor vehicle engines.

The invention has for its object a Vorrich tion of the type mentioned at the beginning, which he possible, with extremely short switching times, i.e. ge ring inertia an adjustment of the throttle element to any desired position with extreme precision enable.

This object is achieved in that the drive device is a magnet assembly 18 and a coil assembly 34 comprising, according to the plunger coil or moving coil principle working electromagnetic actuator, the movable actuator (magnet assembly or coil assembly) is in drive connection with the throttle element.

Drives of this type are in magnetic disk storage to adjust the magnetic heads relative to the magnet plates used. It has surprisingly been shows that these drives, which in themselves are in the field of data technology for a product of precision mechanics were developed, the manufacture and operation of which exact compliance with defined environmental conditions and is very sensitive to rough mechanical Influences is under the harsh mechanical environment conditions in a motor vehicle engine and the there prevailing high temperature precise and error-free work. The drive according to the invention enables Almost inertia-free adjustment of the throttle element to any desired value with extreme accuracy. The susceptibility to wear of such a drive is very low. In contrast to pneumatic actuators facilities cannot function as a position directional sealing problems  The requirements placed on the adjustment device such as a lifespan of 10 Switching cycles, a high level of accuracy in the adjustment throttle element (0.5 ° during adjustment a throttle valve) as well as security Vibration accelerations of 15G are effortless fulfill.

The actuator can be used both for a straight line Movement of the actuator, a rotary movement of the same or for a movement of the actuator along an arcuate path. A rectilinear movement of the actuator is suitable especially for the adjustment of a throttle element, for example from one in a cylindrical Valve housing axially adjustable valve body is formed. Is the throttle element against it a rotatably mounted throttle valve, so includes the drive connection between the rectilinearly movable Actuator and the throttle valve shaft more appropriate as a crank drive. With a rotation of the Stell member or a movement of the actuator an arcuate path, the actuator on a carrier which is pivotable about an axis is arranged, the wearer can either rotate directly with the Dros Selklappe be connected or via a gear arrangement with the throttle valve in the drive connection stand.

A particularly compact arrangement results for a rotatably mounted throttle element when the magnet order of the actuator at least two each Perment magnets carrying, perpendicular to the shaft axis ge directed magnetic return plates, which  non-rotatably connected to the throttle element and through spacer elements parallel to the shaft axis in are kept axial distance and a coil order between themselves, the one with the Actuator enclosing housing rigidly connected is. An alternative solution to this provides that the Magnet arrangement of the actuator at least two each Weil permanent magnets, perpendicular to the waves includes axis-directed magnetic return plates, of which at least one is connected to the housing and the distance directed parallel to the shaft axis elements or directly by attachment to the housing wall are kept at an axial distance and a Include coil assembly between them that with the Throttle element is connected. The spools can order in both cases surround a nucleus that is rigid is connected to the magnetic return plates.

Another embodiment, especially for the Adjustment of a rotatable throttle element is suitable, is described in claims 7 and 8 ben.

When switching off or if the engine fails, one should Possibility exist, the throttle element in a defi transferred position. This can be done either a spring arrangement take place on the throttle element or attacks on the actuator or by a special reset device. For example, the Reset device an auxiliary voltage source, such as may include a capacitor in the control circuit, which is in the event of failure or when the power is turned off supply of the actuator via the coil arrangement the same in the sense of opening or closing the  Throttle element discharges.

To the actuator and thus the throttle element in a certain position relative to the other hold their part, there is the possibility of to adjust member against the force of a spring, being the travel only depends on the current of the coils order through current depends. There is however there is a risk that the spring force of the spring will not is precisely determinable or changes with time and the Ambient conditions changes. A solution that's a very much more precise positioning of the actuator and so that the throttle element is also allowed to exist according to the fact that the control device a Posi tion control loop, comprising a be movable actuator or the throttle element position transmitter and a position controller for ver equal to position setpoints and those from the Posi position transducer determined actual position values and for Generation of control signals depending on the actual value-setpoint comparison. About this control loop the position of the actuator can be extraordinary can be set precisely. The position sensors can be designed in different ways. So the position transmitter can have a sensor and a support with markings, one of the parts with the actuator or the throttle element is connected and the other is stationary. About the sensor the markings when the actuator moves gen counted so that the position of the position link can be determined. Scanning the markie can be on optical, inductive or capacitive way. It would also be possible to have the buttocks determination via a resistance measurement.  

To take into account the operating conditions directly can, the control device can a second rule have a loop that is close in the fluid line the throttle element arranged sensor for measurement a flow parameter actual value, a parameter Setpoint generator and a controller that depend in Dep of an actual value / setpoint comparison Position setpoint generated. It can also be the first or position control loop and the Second rule taking flow parameters into account loop overlay each other. For stabilization the control device described above can be seen that another entrance of the position ver with the output of a circuit arrangement is bound, due to the actual position value and one of the control current in the coil arrangement of the Actuator-derived signal an estimate for the adjustment speed of the throttle element generated.

Further features and advantages of the invention result from the following description, which is in Verbin with the accompanying drawings of the invention hand explained by embodiments. Show it:

Fig. 1 is a partially cutaway perspective view of a first embodiment of the invention with an actuator in which the coil arrangement of the actuator is pivotally mounted,

Fig. 2 drive is a partially schematic side view of a second embodiment of the invention with a linearly movable coil of the actuator,

Fig. 3 is a plan view of the in Fig. 2 Darge arrangement presented in the direction of arrow A in Fig. 2,

Fig. 4 shows a third embodiment of a drive with a pivotable Stellan coil arrangement,

Fig. 5 is a partially sectioned perspective view of a drive coil of a fourth embodiment with an actuator by way of a pivot,

Fig. 6 shows a schematic section containing the axis, by the actuator of FIG. 5

FIGS. 7 and 8 in Figs. 5 and 6 corresponding depicting settings of a fifth embodiment of the invention He and

Fig. 9 is a schematic representation of a control device for controlling the actuator drive.

In Fig. 1 you can see a pipe section 10 in which a circular disc-shaped throttle valve 12 with a shaft 14 directed perpendicular to the tube axis is pivotally mounted GE. The throttle valve is shown in a half-open position in FIG. 1.

The throttle valve 12 is adjustable by means of a generally designated 16 electromagnetic actuator. This comprises a magnet arrangement 18 with a magnetic yoke, which comprises three circular arc-shaped legs 20 , 22 and 24 arranged concentrically to one another, which extend over 90 ° and are integrally connected at one end by a cross leg 26 and at the other end by a screwed-on one End piece 28 are connected to each other, so that the magnetic circuit is closed. On the inside of the curved legs 20 and 24 , a permanent magnet 30 and 32 , respectively, is arranged concentrically to these. The actuator 16 further comprises a rectangular coil 34 which surrounds the central curved leg 22 of the magnet arrangement 18 and is arranged at the free ends of two levers 36 , 38 forming a coil carrier, which are connected at their other ends in a rotationally fixed manner to a shaft 40 which is arranged coaxially to the axis of curvature of the curved legs 20 to 24 of the magnet arrangement 18 .

The shaft 40 also extends coaxially with the Drosselklap penwelle 14 and is rotatably coupled to this via a clutch 42 not shown. The shaft 40 is surrounded by a torsion spring 44 , which engages with one end on a tubular stop 46 and with its other end on a sector-shaped extension 48 of the lever 36 . The bias of the torsion spring is selected so that it opens the throttle valve 12 when the coil 34 is de-energized.

The sector disk-shaped extension 48 carries a circular arc-shaped marking strip 50 with markings that can be scanned optically, inductively, capacitively or in some other way, to which a corresponding stationary sensor 52 is assigned. The outgoing from the sensor 52 signals or pulses are supplied to a control device 54 which determines the position of the lever 36 and thus the coil 34 relative to the magnet arrangement 18 and thus also the angular position of the throttle valve 12 from the incoming signals. In a comparator (not shown) of the control device 54 , the actual position values determined in this way are compared with the control device before given actual position values. Depending on the comparison, the current intensity of the current supplied to the coil 34 via a control line 56 is changed in the sense of an adaptation of the actual position values to the desired position values. The position of the coil and thus also the angular position of the throttle valve can be adjusted extremely precisely in this way with almost no inertia. The restoring force exerted by the torsion spring 44 only serves to transfer the throttle valve in its open position when the coil 34 is de-energized. The respective position of the coil 34 with current flow, however, does not depend on the force of the spring 31 , but is only determined by the control circuit comprising the coil 34 , the control device 54 and the position transmitter 50 , 52 .

In the embodiment according to FIG. 4, the same parts are again provided with the same reference symbols. Also in the embodiment shown in Fig. 4, the actuator 16 is designed in such a way that the coil 34 is arranged on a coil support 60 pivotally mounted about an axis 58 , so that it moves on an arcuate curved path be. The magnet arrangement 18 in this embodiment, for example, does not necessarily have to extend through 90 °, since the drive connection between the coil carrier 60 and the throttle valve shaft 14 takes place via a transmission and thus enables a specific transmission ratio. The transmission comprises a toothed rack 62, which is connected to the coil carrier 60 in the form of an arc of a circle, and a gear 64 which meshes with the latter and is arranged on the throttle valve shaft 14 in a rotationally fixed manner. The coil carrier 60 is in turn biased by a gate spring 44 in its open position of the throttle valve not shown Darge corresponding position. He also carries a bar 50 with markings to which a sensor 52 is assigned. The position sensor formed by the bar 50 and the sensor 52 serves in the manner described with reference to FIG. 1 for the exact determination of the position of the coil 34 relative to the magnet arrangement 18 and thus for the exact setting of the position of the throttle valve 12 in the tube 10 .

Also in the embodiment shown in FIGS. 2 and 3, the same parts are again provided with the same reference numerals. This embodiment differs from the embodiments according to FIGS. 1 and 4 primarily in that the actuator is designed for a linear movement of the coil 34 forming the movable actuator. The legs 20 , 22 and 24 of the magnet assembly 18 are GE straight. The Spu le 34 , which is not shown in FIGS . 2 and 3 and which surrounds the central magnetic leg 22 , is held on a rectangular coil support 66 enclosing the magnet arrangement 18 . This is mounted with the help of rollers 68 on two guide rods 70 in the direction of movement of the spool. He is also firmly connected to a rod 72 , which is via a double link 74 and a cure 76 in drive connection with the shaft 14 of the throttle valve 12 . The carriage formed by the coil carrier 66 with its rollers 68 is biased by a return spring 78 in FIG. 2 to the right into an end position corresponding to the open position of the throttle valve 12 .

The embodiment is particularly suitable for one rectilinearly adjustable valve body, e.g. With an annular valve seat cooperates.

The coil carrier 66 carries a sensor 52 which , together with a marker carrier 50 which is fixedly connected to the magnet arrangement 18 , in turn forms a position sensor which enables exact positioning of the actuator and thus of the throttle valve 12 in the manner described with reference to FIG. 1.

The actuators 16 provided in the embodiments of FIGS. 1 to 4 are known per se for the position of magnetic heads in magnetic disk memories as so-called voice coil drives. In the Darge presented embodiments, the movable coil 34 surrounds one leg 22 of the magnetic yoke arrangement. However, drives can also be used in which a flat coil moves between the permanent magnets 30 and 32 , which does not enclose one leg of the magnetic yoke.

Fig. 5 shows a fourth embodiment of the inven tion, wherein the same parts are again provided with the same reference characters. In this embodiment, the actuator is formed in the manner of a moving coil drive. On the outside of the throttle valve 12 receiving tube piece is coaxial with the shaft 14 of the throttle valve 12, a cylindrical housing 80 is angeord, which can be closed by a cover 82 and takes the generally designated 84 actuator. This comprises a magnet arrangement with two circular coaxial to the throttle valve shaft 14 arranged magnetic return plates 86 , 88 , which are held by two cylindrical spacer columns 80 at an axial distance. The magnetic return plate 86 is rotatably connected to the throttle valve shaft 14 ( FIG. 6). The two magnetic return plates 86 and 88 each have on their mutually facing surfaces two semicircular permanent magnets 92 which are arranged, for example, with the polarity shown in FIG. 6, the two magnets 82 arranged on a magnetic return plate 86 and 88 by one diametrically extending gap are separated from each other. The magnetic return plates 86 and 88 enclose a coil 84 between them, which surrounds a circular disc-shaped axis-oriented coil core 86 and is fastened to the inside of the housing 80 with a coil carrier 87 . The coil 84 is thus fixed. The coil core 86 is connected by the distance columns 80 , which penetrate radial extensions 88 of the coil core 86 , with the magnetic return plates. A current flow through the coil causes a rotation of the magnet arrangement and thus the throttle valve shaft 14 connected to it due to the course of the magnetic field shown in FIG. 6, the direction of rotation depending in a known manner on the direction of the current flow in the coil 84 .

Markings 50 are in turn provided on the outside of the magnetic return plate 88 , which, together with a sensor 52 arranged in the cover 82 , form a position transmitter, as was described in the embodiments shown in FIGS. 1 and 4.

The embodiment described above with reference to FIGS. 5 and 6 is characterized by its simple and compact structure. It goes without saying that a return spring can also be provided in this embodiment, which returns the throttle valve to its open position in the event of a power failure. The embodiment shown in Figs. 7 and 8 differs from that according to FIGS. 5 and 6, characterized in that the magnet arrangement 86, 88, 82 and 86 rigidly connected via the projections 88 of the spool core 86 with the housing 80, while the the magnet arrangement penetrating throttle valve shaft 14 is rotatably connected to the coil 84 a related party. The marker carrier 50 is designed here as a disk connected to the shaft 14 in a rotationally fixed manner.

The control device 110 shown in simplified form in FIG. 8 for controlling the actuator comprises a position control loop with the position sensor 50 , 52 , the measurement signal of which is converted via a converter 112 into a signal corresponding to an actual position value and is supplied to a position controller 114 . The water also receives a signal corresponding to a setpoint value and generates an output signal as a function of a comparison between the actual position value and the setpoint position value, which is sent via a converter 116 and an amplifier 118 and possibly a filter 120 of the coil 34 or 84 of the corresponding actuator is supplied. The position control loop is superimposed on a pressure control loop, which comprises a pressure sensor 122 arranged in the fluid line 10 , the measured value of which is fed via a converter 124 as a pressure actual value to a pressure controller 126 which is simultaneously provided by a pressure setpoint generator 128 of the control device 110 with a setpoint receives. The pressure controller 126 generates the position setpoint, which is supplied to the position controller 114 , as a function of a comparison of the pressure setpoint and the actual pressure value.

In order to stabilize this position, a circuit arrangement 130 is also provided which provides an estimate of the rotational speed of the throttle valve from the measured value of the position sensor 50 , 52 and the value supplied by a current sensor on the coil 34 , 94 and which supplies the position controller 114 .

With the control device described above, it is possible to mount the throttle valve with low friction. The return spring shown schematically in FIG. 9, which acts on the throttle valve 12 , is only present as a safety measure in order to transfer the throttle valve to a defi ned position if the supply voltage fails. The controllers 114 and 126 can be designed as digital controllers. In this case, the converters 112 and 124 are analog / digital converters. The controller behavior is determined by digital algorithms. The digital output signal of the position controller can be implemented via a digital / analog converter 116 and fed to the coil arrangement 34 , 84 via a linear power amplifier 118 . The filter 120 can be omitted if necessary.

The output signal of the position controller can also be supplied to the power amplifier 118 as a pulse-width modulated signal via the converter 116 . In a low pass this converts the pulse-width modulated signal into a DC voltage, which is then amplified. The pulse-width modulated signal from the position controller can also be amplified directly. In this case, the power amplifier is not subject to linearity requirements. The power loss in the output stage is low. A filter should lie between the output stage and the coil arrangement 34 , 84 in order to keep the clock frequency away from the actuator.

The controllers can also be represented by operational amplifier circuits. In the simplest case, the converters 112 , 124 and 116 are then calibrated voltage dividers for the correct scaling of the sizes.

Claims (20)

1. Device for adjusting a throttle element ( 12 ) in a fluid line ( 10 ), in particular a motor vehicle engine with an on the throttle element ( 12 ) engaging Antriebsein direction ( 16 ) and a control device controlling this ( 54 ), characterized in that the drive device is a magnet arrangement ( 18 ) and a coil arrangement ( 34 , 84 ) comprising an electromagnetic actuator ( 16 , 84 ) operating according to the moving coil or moving coil principle, the movable actuator (magnet arrangement ( 18 ) or coil arrangement ( 34 , 84 ) is in drive connection with the throttle element ( 12 ). 2. Device according to claim 1, characterized featured, that the actuator for a straight line movement of the actuator is formed. 3. Apparatus according to claim 2, characterized in that the drive connection comprises a crank drive ( 74 , 76 ). 4. The device according to claim 1, characterized in that in a rotatably mounted throttle element ( 12 ), the magnet arrangement of the actuator ( 84 ) comprises at least two permanent magnets ( 82 ) tra lowing, perpendicular to the shaft axis magnetic return plates ( 86 , 88 ) which are rotationally fixed are connected to the throttle element ( 12 ) and are kept at an axial distance by spacer elements ( 80 ) directed parallel to the shaft axis and include between them a coil arrangement ( 84 ) which is rigidly connected to a housing ( 80 , 82 ) enclosing the actuator ( 84 ) . 5. The device according to claim 1, characterized in that in a rotatably mounted throttle element ( 12 ), the magnet arrangement of the actuator ( 84 ) comprises at least two permanent magnets ( 82 ) tra ing, perpendicular to the shaft axis magnetic return plates ( 86 , 88 ), of which at least one is connected to the housing ( 80 , 82 ), and is held axially from one another by spacer elements ( 80 ) directed parallel to the shaft axis or directly by fastening to the housing wall ( 80 ) and include a coil arrangement ( 84 ) between them, which is connected to the throttle element ( 12 ). 6. Apparatus according to claim 4 or 5, characterized in that the coil arrangement ( 84 ) surrounds a core which is rigidly connected to the magnetic return plates ( 86 , 88 ). 7. The device according to claim 1, characterized in that in a rotatably mounted throttle element ( 12 ), the magnet arrangement comprises at least two permanent magnets ( 30 , 32 ), each on a cylindrical surface ( 20 , 24 ) coaxial to the axis ( 40 ) of the throttle element ( 12 ) are arranged, and that the coil arrangement ( 34 ) is rotatably connected to the shaft ( 40 ), the coil turns being directed parallel to a plane containing the shaft axis. 8. The device according to claim 7, characterized in that the Spulenan arrangement ( 34 ) surrounds a magnetic core ( 22 ) which coaxially surrounds the axis ( 40 ) of the throttle element ( 12 ). 9. Device according to one of claims 1, 7 or 8, characterized in that the actuator ( 16 ) is designed for movement of the actuator ( 34 ) along an arcuate curved path. 10. The device according to claim 9, characterized in that the actuator ( 34 ) on an axis ( 40 ; 58 ) pivotable carrier ( 36 , 38 ; 60 ) is angeord net. 11. The device according to claim 10, characterized in that the carrier ( 36 , 38 ) is rotatably connected to the rotatably mounted throttle element ( 12 ). 12. The apparatus according to claim 10, characterized in that the carrier ( 60 ) via a gear arrangement ( 62 , 64 ) with the throttle element ( 12 ) is in drive connection. 13. The device according to one of claims 1 to 12, characterized in that a resetting device ( 44 , 78 ) is provided, which the actuator with de-energized coils arrangement ( 34 , 94 ) in a defined, preferably, its the open position of the throttle element ( 12 ) Adjusted the corresponding position. 14. The apparatus according to claim 13, characterized in that the return device comprises a spring arrangement ( 44 ; 78 ) which biases the throttle element ( 12 ) in its closed or open position. 15. The apparatus according to claim 13, characterized featured,  that the reset device is an auxiliary voltage source includes that in the event of failure or stripping power supply to the actuator over the coil arrangement in the sense of an opening or a closing of the throttle element discharges. 16. The apparatus according to claim 15, characterized featured, that the throttle element in its open position or its closed position can be locked. 17. Device according to one of claims 1 to 16, characterized in that the control device has a first control loop, comprising a position transmitter ( 50 , 52 ) assigned to the movable actuator ( 34 , 94 ) or the throttle element ( 12 ) and a position controller ( 114 ) for comparing position setpoints and the actual position values determined by the position transmitter ( 50 , 52 ) and for generating control signals as a function of the actual value setpoint comparison. 18. Device according to one of claims 1 to 17, characterized in that the control device has a second control loop, which in the fluid line ( 10 ) near the throttle element ( 12 ) arranged sensor ( 122 ) for measuring a flow parameter actual value, comprises a parameter setpoint generator ( 128 ) and a controller ( 126 ) which generates a position setpoint as a function of an actual value setpoint comparison. 19. The apparatus of claim 17 and 18, characterized characterized that the second Control loop superimposed on the first control loop is. 20. The apparatus according to claim 19, characterized in that a further input of the position controller ( 114 ) is connected to the output of a circuit arrangement ( 130 ) which due to the actual position value and one of the control current in the coil arrangement ( 34 ; 94 ) of Actuator derived signals generated an estimate of the adjustment speed of the throttle element ( 12 ).