EP2161460A1 - Détecteur de position sans contact avec structure de transmission de mouvement et sa structure de transmission de mouvement - Google Patents

Détecteur de position sans contact avec structure de transmission de mouvement et sa structure de transmission de mouvement Download PDF

Info

Publication number: EP2161460A1
Authority: EP; European Patent Office
Prior art keywords: slider; connection means; actuator; actuator piston; sensor
Prior art date: 2008-09-09
Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.): Withdrawn

Application number

EP08382034A

Other languages

German (de)

English (en)

Inventor

Dirk Reifel

Thorsten Munzig

Albert Carbó

Current Assignee (The listed assignees may be inaccurate. Google has not performed a legal analysis and makes no representation or warranty as to the accuracy of the list.)

TE Connectivity Germany GmbH

TE Connectivity AMP Espana SLU

Original Assignee

Tyco Electronics AMP GmbH

Tyco Electronics AMP Espana SA

Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)

2008-09-09

Filing date

2008-09-09

Publication date

2010-03-10

2008-09-09 Application filed by Tyco Electronics AMP GmbH, Tyco Electronics AMP Espana SA filed Critical Tyco Electronics AMP GmbH

2008-09-09 Priority to EP08382034A priority Critical patent/EP2161460A1/fr

2010-03-10 Publication of EP2161460A1 publication Critical patent/EP2161460A1/fr

Status Withdrawn legal-status Critical Current

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Classifications

- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B15/00—Fluid-actuated devices for displacing a member from one position to another; Gearing associated therewith
- F15B15/08—Characterised by the construction of the motor unit
- F15B15/10—Characterised by the construction of the motor unit the motor being of diaphragm type
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F15—FLUID-PRESSURE ACTUATORS; HYDRAULICS OR PNEUMATICS IN GENERAL
- F15B—SYSTEMS ACTING BY MEANS OF FLUIDS IN GENERAL; FLUID-PRESSURE ACTUATORS, e.g. SERVOMOTORS; DETAILS OF FLUID-PRESSURE SYSTEMS, NOT OTHERWISE PROVIDED FOR
- F15B15/00—Fluid-actuated devices for displacing a member from one position to another; Gearing associated therewith
- F15B15/20—Other details, e.g. assembly with regulating devices
- F15B15/28—Means for indicating the position, e.g. end of stroke

Definitions

the present invention relates to a position sensor for detecting the position of an actuator piston adjusting, for example, a variable geometric turbo charger or an exhaust gas recirculation valve, comprising a displacement transmission structure.
the invention further relates to a kit for an actuator comprising said position sensor, and a method for determining the position of an actuator piston.
Pneumatic servos also referred to as pneumatic actuators
pneumatic actuators are used, for example, in exhaust gas flow-driven pressure-charging devices for combustion engines (turbo chargers).
Pneumatic actuators can be used to rotate the vane of a variable geometric turbo charger or an exhaust gas recirculation valve.
the pneumatic servo can be provided with a position sensor determining the position of the piston.
a conventional pneumatic servo is usually conceived as a cylinder operating in a simple manner wherein a piston rod of a transmission member is connected to a diaphragm affixed to the cylinder instead of to a piston.
EP 1 852 588 discloses a pressure regulator having a box covered by a lid with a first flexible membrane spanned by its outer edge between outer edge of the box and the lid.
the flexible membrane, its support part and the connection for the underpressure source are assembled and arranged so that the control rod moves out of the regulator on connecting to the underpressure source.
the pressure regulator can be provided with a position sensor detecting the position of a magnet arranged on and displaceable with the control rod.
the problem with the actuator arm of a pneumatic actuator driving a variable geometric turbo charger or an exhaust gas recirculation valve is that said actuator arm is not displaced lineally.
the driving element for example, the turbo charger arm
the actuator piston must be displaced in a rotational movement so that the actuator piston likewise performs a circular, rotational movement at its connection with the driving element.
This rotational movement results in a tilting or tumbling displacement of the actuator piston with respect to the actuator box.
This roto-translational movement wherein the actuator piston is not only lineally displaced, but also tilts and is shifted laterally with respect to its longitudinal axis, makes it difficult to exactly monitor the position of the actuator piston. Since the sensor is usually mounted to the actuator box, whereas the marker indicating the position is arranged on the piston, accuracy of the measurement is problematic.
the target for the sensor may be guided within the sensor itself, whereby the target is pushed onto the piston by means of a return spring.
a return spring exerts a force influencing the movement of the actuator piston and a spring-mass-system is sensitive to the vibrations that commonly occur in vehicles having a combustion engine. If the target is mounted to the piston, however, the target also performs the tumbling movement of the actuator piston leading to an inaccuracy of the sensor measurement.
the object of the present invention is therefore to facilitate the detection of the position of the actuator piston of an pneumatic actuator, even in cases where the actuator piston is roto-translationally displaced, i.e. tilts with respect to the actuator box.
a slider to be lineally displaced in the position sensor, with at least one marker, of which the translational position can be detected by the sensor
a transmission element for interconnecting the actuator piston and the slider
a first connection means adapted to connect the slider and the transmission element translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other
a second connection means adapted to connect the transmission element and the actuator piston translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other.
the position sensor the above-described displacement transmission structure as well as a sensor body with a reception adapted for guiding the slider and at least one sensor element adapted to generate an output signal indicating the position of the marker in the reception.
the kit for an actuator achieves this object in accordance with the invention by comprising an actuator having a displaceable actuator piston and the above position sensor, wherein, in the assembled state, the slider is placed in the reception of the sensor body, the first connection means connects the slider and the transmission element translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other, and the second connection means connects the transmission element and the actuator piston translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other.
this object is achieved in accordance with the invention, for the method mentioned at the outset, in that the displacement of the actuator piston is transmitted via a transmission element, which is connected to the actuator piston translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other, to a substantially lineal displacement of a slider, which is connected to the transmission element translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other.
each actuation position of the actuator piston corresponds to a distinct position of the substantially lineally displaceable slider.
interconnecting the transmission element between the actuator piston and the slider as a kinematic pair having two connections that are translationally rigid it is assured that the translational movement of the actuator piston is directly transferred to the slider.
each of the connections between the actuator piston and the transmission element as well as the transmission element and the slider is pivotable on at least two rotational axes that are perpendicular to each other, which allows for a compensation of the tumbling and tilting motion of the actuator piston without the need for spring elements.
the displacement transmission structure according to the present invention compensates the tumbling and tilting motions of the actuator piston mechanically, rather than using vibration transmission, and thus permits application even in a diverse ambient and operation conditions such as vibrations, high pressures and temperatures. Therefore, the displacement transmission structure and the position sender of the present invention provides a robust and precise determination of the actuator piston's position.
the first connection means and/or the second connection means may be a swivel joint.
a swivel joint for example a universal joint or a ball and socket joint, provides a detachable connection that is translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other.
Translationally rigid means in this context that the two elements connected by the connecting means have no translational freedom so that each translational movement of one of the connected parts is directly transferred to the other connection partner.
swivel joints are of simple construction and provide pivotable connection in an easy way.
the first and/or the second connection means may be a flexible element.
the transmission element and the slider can be connected with each other translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other by means of a bendable joining element, such as a connecting web.
the transmission element, the first connection means and the slider can be formed as a single piece.
the flexibility of the first connection means can be achieved by the shape or the material of the area that constitutes the first connection means within the single piece.
the piece may be formed with an bending area having, e.g., a thinner diameter allowing for bending.
the material of the single piece may be flexible in general and the area building the slider and the transmission element may be provided with stiffeners or a stiffening profile preventing bending of the material in this regions.
the second connection means may comprise a coupling means adapted to be attached to the actuator piston.
a coupling means can, for example, be designed as an attachment disc that is pressed onto the piston by the actuator spring.
the coupling means may be provided with the ball swivel or the socket element of a swivel joint.
the mounting and the handling of the displacement transmission structure or the position sensor of the present invention can be advantageously improved if the first connection means and/or the second connection means is provided with a tilt stopper limiting the tilting of the pivotable connection to a maximum tilting angle.
the tilt stopper ensures that the displacement transmission structure, if connected to the actuator piston via the second connection means, is held in a more or less upright position because the maximum lateral tilting angle of the first and/or the second connection means is limited. This facilitates insertion of the slider into the reception of the sensor when mounting the sensor to the actuator box.
the tilt stopper may advantageously be a protrusion received in a recess. Using a protrusion received in a recess is constructionally simple and easy to manufacture.
the protrusion may be formed frustoconical with the inclination angle of the cylindrical jacket determining the tilting angle.
the corresponding recess may be formed funnel-shaped having correspondingly inclined side walls.
each of the protrusion or the recess may be arbitrarily arranged at the swivel or at the socket element.
a sensor body comprises an insertion opening for inserting the slider into the reception, which opening is surrounded by a ramp structure forming an angular guideway towards the insertion opening.
This embodiment facilitates insertion of the slider into the reception of the sensor body when mounting the position sensor, for example, to an actuator box.
the tip of the slider is led down the angular guideway towards the insertion opening.
the ramp structure may be formed by a plurality of guiding elements, wherein the maximum distance between adjacent guiding elements is smaller than the outer scale of the slider. This embodiment is material-saving and minimizes the weight of the sensor body, while at the same time ensuring safe guidance of the slider along the guiding elements towards the insertion opening.
the guiding elements may be formed as a plurality of guiding rips having inclined lead faces arranged star-like around the insertion opening.
each of the first and the second connection means is provided with a tilt stopper, and wherein the sum of the maximum tilting angle of the first and the second connection means is smaller than the inclination angle of the angular guideway with respect to the insertion opening.
the reception in the sensor body as well as the second connection means are arranged at the centre axis of the position sensor and the actuator box.
the lateral distance from the centre of the insertion opening to the lateral edge of the ramp structure is larger than the maximum lateral deflection of the slider, preferably the center of the distal tip of the slider, from the center of the second connection means.
the sum of the maximum tilting angle of the first and second connection means is smaller than the inclination angle of the angular guideway, and if the lateral distance from the centre of the insertion opening to the lateral edge of the ramp structure is larger than the maximum deflection of the slider from the centre of the second means, blind assembly of the sensor to the actuator is possible. In this case, it is ensured that the slider will always hit on the ramp structure due to the defined width of the ramp structure. Furthermore, the defined geometry of the inclination angle of the angular guideway with regard to the maximum lateral titling angle of the first and second connection means further makes sure that the tip of the slider will always be directed towards the centre of the ramp structure, where the insertion opening is located, rather than to the outside.
Fig. 1 is a schematic side view of a pneumatic actuator 1 having a displaceable piston rod 2 that is adapted to act on a driving element 3, e.g., a variable geometric turbo charger or an exhaust gas recirculation valve (not shown).
a position sensor 4 capable of determining the position of the actuator piston 5, that actuates the piston rod 2, is mounted to the pneumatic activators 1.
the pneumatic actuator 1 comprises a cylindrical body 6 and a cylindrical cover 7 which are assembled forming a cylindrical actuator box 8. lnside the actuator box 8, a diaphragm 9 is arranged between the cylindrical body 6 and the cylindrical cover 7, said diaphragm 9 dividing the actuator box into two pressure chambers 10, 11 that are substantially symmetrical about the centre axis M of the pneumatic actuator 1.
the outer edge 12 of the diaphragm 9 rests against an outer collar 13 of the cylindrical cover 7.
the edge of the cylindrical body 6 is a crimp 14, which encompasses the collar 13 at the cylindrical cover 7 and the outer edge of the diaphragm 9, thereby connecting and sealing the cylindrical body 6 and the cylindrical cover 7.
the diaphragm 9 is formed as a pot diaphragm.
the flat base 15 of the diaphragm 9 is reinforced on the side facing the cylindrical cover 7 with the bottom of the base plate 16 of the actuator piston 5.
the actuator piston 5 has the shape of a cup and is arranged such the base plate 16 is parallel to the base 17 of the cylindrical body 6 and the base 18 of the cylindrical cover 7, whereby the bottom of cup-shaped actuator piston 5 is directed towards the cylindrical body 6 and the opening faces the cylindrical cover 7.
the base 18 of the cylindrical cover 7 has an opening 19 for mounting position sensor 4 to the actuator 1.
An attachment ring 20 is connected on the outside of the base 18 forming a circular border around the opening 19.
the attachment ring 20 is provided with a plurality of lugs 21 forming a rabbet for mounting the sensor body 22 of the position sensor 4 to the actuator 1.
the sensor body 22 has an attachment collar 23 that laterally protrudes from the sensor body 22. In the assembled state, the attachment collar 23 rest on the attachment ring 20 and the lugs 21 encompass the attachment collar 23 crimping the sensor body 22 to the attachment ring 20 of the cylindrical cover 7.
the sensor body 22 of the position sensor 4 When the body 22 of the position sensor 4 is attached to the pneumatic actuator 1, the sensor body 22 closes the opening 13 in the base 11 of the cylindrical cover 7. To insure an air-tight connection between the attachment collar 23 of the sensor body 22 and the attachment ring 20 of the cylindrical cover 7, the attachment collar 14 is provided with a circumferential groove 24 in which a sealing ring 25 is placed.
the diaphragm 9 thus divides the actuator box 8 into a vacuum pressure chamber 10 and a normal pressure 11.
the vacuum pressure chamber 10 is the space surrounded by the cylindrical cover 7, the diaphragm 9, the actuator piston 5 as well as the sensor body 22 mounted in an air-tight manner to the attachment ring 20 of the cylindrical cover 7.
the jacket of the cylindrical cover 7 is provided with a vacuum connector 26 that is in communication with the vacuum pressure chamber 10 and to which a pressure generator (not shown) can be connected for evacuating the vacuum pressure chamber 10.
the normal pressure chamber 11 is surrounded by the cylindrical body 6 and the diaphragm 9.
the jacket of the cylindrical body 6 is provided with a ventilation hole 27 so that the normal pressure chamber 11 is always at ambient pressure.
a spring 28 is arranged supported at the base 16 of the actuator piston 5 with one end and on the base 18 of the cylindrical cover 7 with the other end.
the spring 28 exerts a spring force pushing the actuator piston 5 down, that is in the direction of the base 17 of the cylindrical body 6.
the actuator piston 5 is moved against the spring force towards the basis of the cylindrical cover 7 due to the different pressures in the vacuum pressure chamber 10 and the normal pressure chamber 11 acting on the diaphragm 9.
the displacement position of the actuator piston 5 can thus be adjusted, the movement of which is transferred to the piston rod 2 connected to the centre of the base 16 of the actuator piston 5.
the return spring 28 and the vacuum connector 26 may be arranged in the lower chamber that is surrounded by the cylindrical body 6.
the lower chamber constituted the vacuum chamber 10 and evacuating said lower chamber would move the piston 5 toward the base 17 of the cylindrical box 6.
a disc-shaped retainer 29 rests against the diaphragm base 15 from beneath with its flattened side.
the diaphragm base 15 is therefore sandwiched between the base 16 of the actuator piston 5 and the retainer 29.
a washer 30 is arranged on the other side of the actuator piston's base 16 facing the cylindrical cover 7.
the piston base 16, the diaphragm base 15, the retainer disc 29 and the washer 30 are provided with a central bore 31, through which one end of the piston rod 2 projects.
the head 32 of this end of the piston rod 2 is configured in such a way that it holds the piston base 16, the diaphragm base 15, the retainer disc 29 and the washer 30 by means of a type of rivet joint.
the piston rod 2 projects through an opening 33 arranged in the centre of an inversion 34 in the base 17 of the box base 6, the retainer disc 29 being supported on an inversion 34 which is raised from the base 22 of the body base 17.
the piston rod 2 is guided by an gimbal 35 which is inserted from outside the pneumatic actuator 1 into the inversion 34 in the body base 17 and which a sealing ring 36 seals against the body base 17.
the driving element 3 of a variable geometric turbo charger or an exhaust gas valve moves rotationally I on a circular path to adjust the angle of incidence of a control vane (not shown). Due to this rotational movement 1, the piston rod 2 of a pneumatic actuator actuating the driving element 3, must be moved in a roto-translational movement 11.
the actuator piston 5 that is rigidly connected with the piston rod 2 continues the roto-translational movement inside the actuator box 8 so that the actuator piston 5 is not displaced unidirectionally, but rather tilts with respect to the actuator body 6 and performs a tumbling movement inside the actuator box 8.
inventive displacement transmission structure 37 comprising a transmission element 38 and a slider 39 so that the slider 39 performs a substantially lineal movement III.
the inventive displacement transmission structure 37 comprises a transmission element 38 and a slider 39 with a marker 40, a first connection means 41, adapted to connect the slider 39 and the transmission element 38 translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other, and a second connection means 42 adapted to connect the transmission element 38 and the actuator piston 5 translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other.
the displacement transmission structure 37 ensures that one actuation position of the actuator piston 5 of the pneumatic actuator 1 corresponds to only one sensor position of the marker 40, here a permanent magnet 40' along the translational movement in which the slider 39 is lineally displaced as described in detail below.
Translationally rigid means that no translational movement of the two parts connected by the first 41 and the second connection means 42 is possible so that the translation of the actuator piston 5 is directly transferred via the first connection means 41, the transmission element 38, the second connection means 41 to the slider 39.
the translational movement of the individual components must not be in the same direction because the pivotable connection of the first 41 and second connection means 42 mechanically compensates tilting.
the displacement transmission structure 37 e.g. shown in detail in Fig. 4 , will now be described in more detail.
the displacement transmission structure 37 comprises a transmission element 38 and a slider 39.
the slider 39 comprises a magnetic marker 40, which is a permanent magnet 40' in the embodiment shown in the figures.
a cylindrical bushing 43 forms the body of the slider 39 that is arranged lineally displaceable in a reception 44 adapted for guiding the slider 39 in the sensor body 22.
the reception is formed as a guiding channel 44' whose longitudinal axis corresponds to the centre axis M, in the assembled state shown in Fig. 2 , and principally aligns with the central bores 31, 33.
the permanent magnet 40' forming the marker 40 of the displacement transmission structure 37 is arranged in the bushing 43.
a first ball swivel 46 is arranged forming part of a first ball joint 47, by means of which the transmission element 38 and the slider 39 can be pivotably connected.
a cap 49 is arranged at the insertion end 48 of the slider 39, that is opposite to the displacement end 45.
the cap 49 is provided with inclined guiding faces 50 facilitating the insertion of the slider 39 into the guiding channel 44' of the position sensor 4.
the transmission element 38 comprises a transmission rod 51 having a signal end 52 to be pivotably coupled with the slider 39 and a actuation end 53 to be pivotably coupled with the actuator piston 5.
a first socket element 54 is provided at the signal end 52, which first socket element forms the first ball joint 47 together with the first ball swivel 46 of the slider 39.
a second socket element 55 is provided wh ich forms a second ball joint 56 together with a second ball swivel 57 of the actuator piston 5.
two holding tongues 58 arranged substantially parallel to each other and forming a principally U-shaped cross section together with the respective end of the transmission rod 51, form a clamp fork providing the socket element 54, 55 of the respective ball joint 47, 56.
Each holding tongues 58 is provided with a central opening 59, in which the curvature of the corresponding ball swivel 46, 57 is placed, when the ball swivel 46, 57 is clipped between the two holding tongues 58 in a manner constituting the first and second ball joint 47, 56 to be rotated with respect to all three spacial dimensions.
the ball joint 47, 56 ensures a rigid translational connection between the transmission element 38 and the slider 39 as well as between the transmission element 38 and the actuator piston 5.
While the transmission element 38 and the slider 39 can be freely rotated relative to each other around the rotary axis running along the longitudinal axis L of the transmission element 38 and the slider 39, the rotation around the other two, the lateral direction that are perpendicular to the longitudinal axis L is limited to a maximum tilting angle ⁇ 1 between the transmission element 38 and the slider 39.
tilt stopper 60 which is formed by a recess 61 in the first ball swivel 46 and a protrusion 62 of the first socket element 54.
the recess 61 of the first ball swivel 46 is formed at the front face of the ball swivel that comes into contact with the actuation end 53 of the transmission rod 51, that is, the part of the first ball swivel 46 that is directed away from the bushing 43.
the recess 61 is formed funnel-shaped like a crater having inclined side walls 63. The slope of this side walls 63, with respect to the longitudinal axis L of the first ball swivel 46 and the slider 39, which corresponds to the centre of the recess 61, determines the maximum tilt angle ⁇ 1 of the first ball joint 47.
the protrusion 62 is formed in frustoconical shape and is arranged at the actuation end 53 of the transmission rod 51 directed substantially in the direction of the longitudinal axis L.
the slope of the cylinder barrel of the protrusion 62 with respect to the longitudinal axis L of the transmission rod 51 is also about ⁇ 1.
Fig. 2 shows a pneumatic actuator 1 with a position sensor 4 assembled thereto.
the sensor body 22 is mounted with its attachment collar 23 to the attachment ring 20 of the cylindrical cover 7.
the guiding channel 44' in the sensor body 22 runs along the centre axis M of the pneumatic actuator 1.
the slider 39 of the displacement transmission structure 37 is received in the guiding channel 44'.
the transmission element 38 interconnects the slider 39 and the actuator piston 5 such that the roto-translational movement II of the actuator piston 5 is converted to a translational movement III of the slider 39 in the guiding channel44'.
the transmission element 38 and the slider 39 of the displacement transmission structure 37 are pivotably connected with each other by the first connection means 41, which is the first ball joint 47 in the embodiment shown.
the transmission element 38 is pivotably connected to the actuator piston 5 by means of the second connection means 42, in the shown embodiment, the second ball joint 49.
the second ball joint 49 comprises the second socket element 48 at the actuation end 53 of the transmission element 38 and a second ball swivel 57.
This second ball swivel 57 is connected to a ball clip 64 which is attached to the interior of the base 16 at the bottom of the cup-shaped actuator piston 5 via an attachment member 65.
the ball clip 64 has a base plate 66, wherein the second ball swivel 57 extends at the centre of the base plate 66 in a direction perpendicular to the base plate 66 on one side thereof.
the base plate 66 is provided at two opposing sides with a clip (not shown) for connecting the ball the base plate 66 of the clip 64 to the attachment member 65.
the attachment member 65 also has the form of a disc and has a connection hole 67 in the center thereof.
the base plate 66 of the ball clip 64 is received in the connection hole 67 and fixed to the attachment member 65 via the clips.
the attachment member 65 is held at the bottom of the actuator piston 5 by the spring 29 supported on one end on the attachment member 65 pressing said pressing attachment member 65 onto the actuator piston 5.
the ball clip 64 with the second ball swivel 57 and the attachment member 65 are arranged symmetrically with respect to the centre axis M.
the displacement transmission structure 37 forms a kinematic pair of the two pivotable connections means 41, 42 between the actuator piston 5 and the transmission element 38 as well as the transmission element 38 and the slider 39. Due to this kinematic pair, the inventive displacement transmission structure 37 is capable of compensating the roto-translational movement II of the actuator piston 5, which is converted into the substantially lineal translational movement III of the slider 39 in the guiding channel 44'. Since each of the pivotable connections 41, 42 is translationally rigid, each activator position corresponds to a defined position of the marker 40 on the slider 39.
This position of the marker 40 can be detected by a sensor element 68 of the sensor 4.
the sensor element 68 is designed as magnetic field sensor adapted to detect a translational position of the permanent magnet marker 40'.
the sensor element 68 outputs a signal indicating said translational position of the marker 49 in the guiding channel 44'.
the sensor element 68 is arranged in a chamber 69 of the sensor body 22.
the chamber 69 is arranged in the part of the sensor body that is arranged outside the actuator box 8 and is closed by a hood 70 covering the opening of the chamber 69.
the output signal can be transferred to a control device (not shown) via a connector (not shown) and a data link (not shown) connecting the connector and the control device.
the control device controls the vacuum generator (not shown) generating the low pressure in the vacuum pressure chamber 10 and activating the actuator piston. Thereby, closed loop for the pneumatic actuator 1 is realized.
each of the first ball joint 47 and the second ball joint 56 is provided with a tilt stopper 60, 60a, respectively.
each of the tilt stopper 60, 60a is formed by a protrusion 62, 62a arranged on the socket element 54, 55 working together with a corresponding recess 61, 61 a in the corresponding ball swivel 46, 57.
the function of such tilt stopper 60, 60a has already been described above with respect to Fig. 4 .
the tilt stoppers 60, 60a limit the maximum deflection of the slider 39 with respect to the central axis M, which corresponds to the sum of the maximum tilting angles ⁇ 1 + ⁇ 2 of each tilt stopper 60, 60a.
the maximum tilting angles ⁇ 1 is the maximum tilting of the longitudinal axis L1 of the transmission element 38 with respect to center of the second ball swivel 57 that corresponds to the centre axis M.
the maximum tilting angles ⁇ 2 is the maximum tilting of the longitudinal axis L2 of the slider 39 with respect to the longitudinal axis L1 of the transmission element 38.
each of the first 41 and the second connection means 42 with a tilt stopper 60, 60a, the upright connection position of the displacement transmission structure 37 on the actuator piston 5, shown in Fig. 5 , before mounting the sensor body 22 to the cylindrical cover 7 is achieved.
the maximum tilting angle ⁇ 1, ⁇ 2 is that the sum ⁇ 1 + ⁇ 2 at least corresponds to the maximum tilting of the actuator piston 5 with respect to the centre axis M in order to compensate the roto-translational movement II of the actuator piston 5. Further, the maximum tilting angle ⁇ 1 + ⁇ 2 should make a blind mounting of the sensor body 22 with the cylindrical cover 7 possible.
the displacement transmission structure 37 is pivotably connected to the ball clip 64 at the second socket element 55 arranged at the actuation end of the transmission rod 51.
the slider 39 is located in the opening 19 of the cylindrical cover 7 and extends from the inside of the actuator box 8 through the opening 19 to the outside of the actuator box 8.
the cap 49 of the slider 39 slides along the substantially funnel-shaped angular ramp structure 72 towards the narrow stem thereof, which is formed by the insertion opening 74 so that the slider 39 is introduced and received with its cap 49 first into the guiding channel 44' of the sensor body 22.
the inclination angle ⁇ of the ramp structure 60 with respect to the insertion opening 74 must be smaller than the maximum tilt angle ⁇ 1 + ⁇ 2 of the displacement transmission structure 37. Only in case of ( ⁇ 1 + ⁇ 2) ⁇ ⁇ , the tip of the dome-shaped cap 49 will contact the ramp structure 72 with an acute angle directing toward the narrow stem, where the insertion opening 74 is located. Hence, the slider 39 is led on the ramp structure 72 towards the insertion opening and not towards the lateral edge 75 of the ramp structure 72.
Fig. 6 shows a preferred embodiment of the angular ramp structure 72.
This ramp structure 72 is formed by a plurality of guiding elements 76, which are designed as guide ribs 76' having inclined guiding faces 77 arranged star-like around the insertion opening 74.
the maximum distance d max between adjacent guiding element 76 is smaller than the outer scale d 1 of the slider 39, which makes sure that the slider 39 slides along the ramp structure 72 formed by the plurality of guide ribs 76' and does not enter between the spaces between the individual guiding elements 76.
the outer scale d 1 here the diameter of the slider 39 principally corresponds to, i.e. is only slightly smaller than the inner diameter d 2 of a guiding channel 44' to ensure lineal translational guidance of the slider 39 in the guiding channel 44'.
the distance D1 from the center axis M of the insertion opening 37 to the lateral end of the angular ramp structure 72 is larger than the maximum lateral deflection D2 of the slider 39, at least the center of the cap 49 of the slider 39. This geometry ensures that the cap 49 will hit the angular ramp structure 72 when assembling the sensor body 22 to the sensor body plate 12.
the aforementioned embodiments of the present invention may be modified within the scope of the invention.
the sensor body 22 and the cylindrical cover 7 may be designed as one piece which is then assembled with the cylindrical body 6.
the first and the second socket element 54, 55 are both arranged on the transmission element.
the first and the second ball swivel 46, 57 could be arranged on the transmission rod 51, in which case, the first and the second socket element 54, 55 would be arranged on the slider 39 and the actuator piston 5.
the ball clip 64 and the attachment member 65 may be omitted if the actuation end 53 of the transmission rod 51 is directly coupled to the actuator piston 5.
the assignment of the recess 61 and the protrusion 62 to the socket element 54, 55 and the ball swivel 46, 57 can be arbitrarily selected.
connection means 41 and 42 are transitionally rigid, this does not mean that the direction of translational transmission at the two connection means 41, 42 is the same since the actuator piston 5, the transmission element 38 and the slider 39 are displace in different directions when the roto-translational movement II of the piston 5 is converted to the lineal displacement III of the slider 39 placed in the reception 44 of the sensor body 22.
the translationally rigid connection means 41, 42 with at least two axis of rotation, said axis that are perpendicular to each other can be provided by any other coupling, e.g. a universal joint allowing such a connection.
the sensor body 22 can be formed with a section building the cylindrical cover 7 of the actuator box 8 rather than designing the sensor body 22 and the cylindrical cover 7 as individual components.
a single element comprising the sensor body 22 and the cylindrical cover 7 is easier to assemble since the number of components is reduced.
the air-tight connection 20, 23, 25 between the cover 7 and the body 22 can be omitted in such single-piece unit.
the embodiment with a separate cylindrical cover 7 to which the sensor body 22 is connected provides the advantage that the same cylindrical cover 7 can be connected with different sensor bodies 22 and maintenance and repair of the sensor 4 is facilitated since the sensor 4 is detachably connected with the cylindrical cover 7 of the actuator box 8.
the vacuum connector 26 can be a separate element that is connected with a component 6, 7 of the actuator box 8, or can be formed as one piece with the cylindrical body 6 or the cylindrical cover 7.
the marker 40 shown in the embodiment of the Figures is a permanent magnet 40'.
any type of marker 40 the position of which can be determined by a sensor element 68 can be alternatively use, such as for example an optical marker in combination with an optical sensor 68.
the transmission element, the first connection means and the slider can be formed as a single piece having a flexible region constituting the first connection means within the single piece.
the coupling means, the second connection means and the transmission element may be formed as a single piece, or the coupling means, the second connection means, the transmission element, the first connection means and the slider may be made as a single part having connection means areas that are translationally rigid and pivotable on at least two rotation axes that are perpendicular to each other.
the actuator shown as pneumatic activator 1 in the embodiment described must not be necessarily driven by a vacuum.
the present invention works with any actuator whose piston is moved in a rota-translational movement.

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Actuator (AREA)

EP08382034A 2008-09-09 2008-09-09 Détecteur de position sans contact avec structure de transmission de mouvement et sa structure de transmission de mouvement Withdrawn EP2161460A1 (fr)

Priority Applications (1)

Application Number	Priority Date	Filing Date	Title
EP08382034A EP2161460A1 (fr)	2008-09-09	2008-09-09	Détecteur de position sans contact avec structure de transmission de mouvement et sa structure de transmission de mouvement

Applications Claiming Priority (1)

Application Number	Priority Date	Filing Date	Title
EP08382034A EP2161460A1 (fr)	2008-09-09	2008-09-09	Détecteur de position sans contact avec structure de transmission de mouvement et sa structure de transmission de mouvement

Publications (1)

Publication Number	Publication Date
EP2161460A1 true EP2161460A1 (fr)	2010-03-10

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ID=40262708

Family Applications (1)

Application Number	Title	Priority Date	Filing Date
EP08382034A Withdrawn EP2161460A1 (fr)	2008-09-09	2008-09-09	Détecteur de position sans contact avec structure de transmission de mouvement et sa structure de transmission de mouvement

Country Status (1)

Country	Link
EP (1)	EP2161460A1 (fr)

Cited By (8)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
EP2199565A1 (fr) *	2008-12-17	2010-06-23	smk systeme metall kunststoff gmbh & co.	Actionneur pneumatique
GB2468779A (en) *	2009-03-19	2010-09-22	Tyco Electronics Amp Gmbh	Displacement transmission structure, for a position sensor of a turbocharger actuator, comprising a compensating slide mechanism
US8395374B2 (en)	2007-12-03	2013-03-12	Cts Corporation	Linear position sensor
US8400142B2 (en)	2008-11-26	2013-03-19	Cts Corporation	Linear position sensor with anti-rotation device
DE102012006564B3 (de) *	2012-03-30	2013-08-08	Festo Ag & Co. Kg	Antriebsvorrichtung
US20130232970A1 (en) *	2012-03-06	2013-09-12	Honeywell International Inc.	Linear Actuator for a Variable-Geometry Member of a Turbocharger, and a Turbocharger Incorporating Same
US8664947B2 (en)	2008-12-02	2014-03-04	Cts Corporation	Actuator and sensor assembly
US9435630B2 (en)	2010-12-08	2016-09-06	Cts Corporation	Actuator and linear position sensor assembly

Citations (5)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
DE3623677C1 (en)	1986-07-12	1987-04-16	Daimler Benz Ag	Exhaust gas recirculation device for an internal combustion engine
US6273631B1 (en)	1998-12-04	2001-08-14	Thk Co., Ltd.	Connecting rod equipped with ball joints capable of adjusting the distance between the centers
JP2004012393A (ja) *	2002-06-10	2004-01-15	Komatsu Ltd	バルブストロークセンサ
DE102005029904A1 (de)	2005-06-26	2007-01-04	Murrplastik Systemtechnik Gmbh	Unterdruckdose
EP1852588A2 (fr) *	2006-05-04	2007-11-07	smk systeme metall kunststoff gmbh & co.	Régulateur de pression de suralimentation pour turbosoufflante et turbocompresseur de moteurs à combustion interne pour automobile

2008
- 2008-09-09 EP EP08382034A patent/EP2161460A1/fr not_active Withdrawn

Patent Citations (5)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
DE3623677C1 (en)	1986-07-12	1987-04-16	Daimler Benz Ag	Exhaust gas recirculation device for an internal combustion engine
US6273631B1 (en)	1998-12-04	2001-08-14	Thk Co., Ltd.	Connecting rod equipped with ball joints capable of adjusting the distance between the centers
JP2004012393A (ja) *	2002-06-10	2004-01-15	Komatsu Ltd	バルブストロークセンサ
DE102005029904A1 (de)	2005-06-26	2007-01-04	Murrplastik Systemtechnik Gmbh	Unterdruckdose
EP1852588A2 (fr) *	2006-05-04	2007-11-07	smk systeme metall kunststoff gmbh & co.	Régulateur de pression de suralimentation pour turbosoufflante et turbocompresseur de moteurs à combustion interne pour automobile

Cited By (12)

* Cited by examiner, † Cited by third party
Publication number	Priority date	Publication date	Assignee	Title
US8395374B2 (en)	2007-12-03	2013-03-12	Cts Corporation	Linear position sensor
US8803514B2 (en)	2007-12-03	2014-08-12	Cts Corporation	Linear position sensor
US8400142B2 (en)	2008-11-26	2013-03-19	Cts Corporation	Linear position sensor with anti-rotation device
US9347795B2 (en)	2008-11-26	2016-05-24	Cts Corporation	Linear position sensor with anti-rotation device
US8664947B2 (en)	2008-12-02	2014-03-04	Cts Corporation	Actuator and sensor assembly
EP2199565A1 (fr) *	2008-12-17	2010-06-23	smk systeme metall kunststoff gmbh & co.	Actionneur pneumatique
GB2468779A (en) *	2009-03-19	2010-09-22	Tyco Electronics Amp Gmbh	Displacement transmission structure, for a position sensor of a turbocharger actuator, comprising a compensating slide mechanism
GB2468779B (en) *	2009-03-19	2013-09-11	Tyco Electronics Amp Gmbh	Displacement tranmission structure for a position sensor of a turbocharger actuator
US9435630B2 (en)	2010-12-08	2016-09-06	Cts Corporation	Actuator and linear position sensor assembly
US20130232970A1 (en) *	2012-03-06	2013-09-12	Honeywell International Inc.	Linear Actuator for a Variable-Geometry Member of a Turbocharger, and a Turbocharger Incorporating Same
US8991173B2 (en) *	2012-03-06	2015-03-31	Honeywell International Inc.	Linear actuator for a variable-geometry member of a turbocharger, and a turbocharger incorporating same
DE102012006564B3 (de) *	2012-03-30	2013-08-08	Festo Ag & Co. Kg	Antriebsvorrichtung

Legal Events

Date	Code	Title	Description
2010-02-05	PUAI	Public reference made under article 153(3) epc to a published international application that has entered the european phase	Free format text: ORIGINAL CODE: 0009012
2010-03-10	AK	Designated contracting states	Kind code of ref document: A1 Designated state(s): AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MT NL NO PL PT RO SE SI SK TR
2010-03-10	AX	Request for extension of the european patent	Extension state: AL BA MK RS
2010-04-07	RTI1	Title (correction)	Free format text: CONTACTLESS POSITION SENSOR WITH DISPLACEMENT TRANSMISSION STRUCTURE AND DISPLACEMENT TRANSMISSION STRUCTURE THEREFOR
2010-10-20	17P	Request for examination filed	Effective date: 20100906
2010-11-17	AKX	Designation fees paid	Designated state(s): AT BE BG CH CY CZ DE DK EE ES FI FR GB GR HR HU IE IS IT LI LT LU LV MC MT NL NO PL PT RO SE SI SK TR
2011-12-28	17Q	First examination report despatched	Effective date: 20111123
2014-10-10	STAA	Information on the status of an ep patent application or granted ep patent	Free format text: STATUS: THE APPLICATION IS DEEMED TO BE WITHDRAWN
2014-11-12	18D	Application deemed to be withdrawn	Effective date: 20140603

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