Source: http://www.google.com/patents/US6193226?ie=ISO-8859-1&dq=ininventor:oliver+ininventor:steele
Timestamp: 2014-08-30 01:34:58
Document Index: 799095803

Matched Legal Cases: ['art.\n4', 'art.\n5', 'art.\n8', 'art.\n9', 'art.\n18', 'art.\n19', 'art.\n20']

Patent US6193226 - Positioning mechanism - Google PatentsSearch Images Maps Play YouTube News Gmail Drive More »Sign in<nobr>Advanced Patent Search</nobr>PatentsA mechanism for a multi-axis flexure positioner includes a fixed part and a movable part (7), the movable part (7) being connected to the fixed part via a plurality of transmission means, one for each axis, for transmitting actuation forces for the respective axes to the movable part (7). The transmission...http://www.google.com/patents/US6193226?utm_source=gb-gplus-sharePatent US6193226 - Positioning mechanismAdvanced Patent SearchPublication numberUS6193226 B1Publication typeGrantApplication numberUS 09/251,555Publication dateFeb 27, 2001Filing dateFeb 17, 1999Priority dateFeb 20, 1998Fee statusPaidAlso published asDE69924659D1, EP0937961A2, EP0937961A3, EP0937961B1, US6467762Publication number09251555, 251555, US 6193226 B1, US 6193226B1, US-B1-6193226, US6193226 B1, US6193226B1InventorsPhilip Andrew DaviesOriginal AssigneeMelles Griot LimitedExport CitationBiBTeX, EndNote, RefManPatent Citations (12), Referenced by (9), Classifications (8), Legal Events (6) External Links: USPTO, USPTO Assignment, EspacenetPositioning mechanismUS 6193226 B1Abstract A mechanism for a multi-axis flexure positioner includes a fixed part and a movable part (7), the movable part (7) being connected to the fixed part via a plurality of transmission means, one for each axis, for transmitting actuation forces for the respective axes to the movable part (7). The transmission means for each axis includes a flexure member (2,3,8) arranged to transmit actuation forces for that axis to the movable part (7) and to flex between the fixed part and the movable part in response to actuation forces associated with the or each other axis. There are three flexure members (2,3,8) arranged to extend along three mutually-perpendicular axes so that each flexure member (2,3,8) is flexible along the axes of extent of the other two flexure members (2,3,8). Each of the three flexure members (2,3,8) comprises a pair of flexure linkages arranged to extend parallel to each other, the three pairs of linkages thus defining three mutually-perpendicular planes.
What I claim is: 1. A mechanism for a multi-axis flexure positioner for positioning in at least three motion axes, the mechanism including a fixed part and a movable part, the movable part being connected to the fixed part via a plurality of transmissions, one for each motion axis, for transmitting actuation forces for the respective motion axes to the movable part, the transmission for each motion axis including a flexure member arranged to transmit actuation forces for that motion axis to the movable part and to flex between the fixed part and the movable part in response to actuation forces associated with each other motion axis, wherein there are three flexure members arranged to extend along three mutually-perpendicular axes of extent so that each flexure member is flexible along the axes of extent of the other two flexure members, each of the three flexure members comprising a pair of flexure linkages arranged to extend parallel to each other, the three pairs of flexure linkages thus defining three mutually-perpendicular planes.
2. A mechanism according to claim 1, wherein at least one of the transmissions comprises a hinged plate attached to the fixed part via a hinge.
3. A mechanism according to claim 2, wherein the hinge defines a hinge axis aligned parallel to, and offset from, the plane defined by the associated pair of flexure linkages, and perpendicular to the axis of extent of the associated pair of flexure linkages, to allow linear movement of the movable part relative to the fixed part.
4. A mechanism according to claim 2, wherein the hinge defines a hinge axis aligned perpendicular to the plane defined by the associated pair of flexure linkages to allow rotary movement of the movable part relative to the fixed part.
5. A mechanism according to claim 2, in combination with an actuator for the hinged plate, the actuator being arranged to actuate the hinged plate and thus control movement of the flexure linkages associated with the hinged plate.
6. A mechanism according claim 1, wherein at least one of the transmissions comprises a pivot plate attached to the fixed part via a pivot.
7. A mechanism according to claim 6, wherein the pivot allows the pivot plate to rotate about two mutually perpendicular axes of rotation, a first one of said axes of rotation being parallel to, and offset from, the plane defined by the associated pair of flexure linkages, and perpendicular to the axis of extent of the associated pair of flexure linkages, and the second of said axes of rotation being perpendicular to the first rotational axis and the axis of extent of the associated pair of flexure linkages, to allow both linear and rotary movement of the movable part relative to the fixed part.
8. A mechanism according to claim 6 or 7 in combination with a pair of actuators for the pivot plate, the pair of actuators being arranged to actuate the pivot plate and thus control movement of the flexure linkages associated with the pivot plate so that one of the actuators of the pair of actuators serves to provide linear movement, and the other of the actuators of the pair of actuators rotary movement, of the movable part relative to the fixed part.
9. A mechanism according to claim 1, wherein at least two of the transmissions provide for rotary movement of the movable part relative to the fixed part about respective axes of rotary movement, the mechanism being dimensioned and arranged so that the axes of rotary movement are mutually perpendicular.
10. A mechanism according to claim 9, the mechanism being dimensioned and arranged so that the at least two axes of rotary movement intersect at a common point.
11. A mechanism according to claim 10, wherein the flexure linkages of one of the pairs of flexure linkages are of a different length to the flexure linkages of another of the pairs of flexure linkages, the flexure linkages of each pair of flexure linkages being of equal length.
12. A mechanism according to claim 1, wherein at least two of the transmissions provide for linear movement of the movable part relative to the fixed part about respective axes of linear motion, the mechanism being dimensioned and arranged so that the axes of linear motion are mutually perpendicular.
13. A mechanism according to claim 1, wherein at least one of the transmissions provides for linear movement of the movable part relative to the fixed part about an axis of linear motion and wherein at least one of the transmissions provides for rotary movement of the movable part relative to the fixed part about an axis of rotary motion, the mechanism being dimensioned and arranged so that the axes of linear and rotary motion are one and the same axis.
14. A mechanism according to claim 1 having a positioning precision of better than one of:
1 millimeter, 100 microns, 10 microns and one micron. 15. A mechanism according to claim 1, wherein each flexure linkage is flexible to rotate about its axis of extent and bend along each of two bending axes perpendicular to said axis of extent.
16. A multi-axis flexure positioner for positioning in at least three axes, comprising:
a fixed part; a movable part; first, second and third pairs of flexure linkages connected to transmit actuation forces from the fixed part to the movable part, the flexure linkages of each pair extending parallel to each other and perpendicular to the flexure linkages of the other two pairs of flexure linkages; and a plurality of actuators, at least one for each pair of flexure linkages, the actuators being mounted on the fixed part to transmit the actuation forces from the fixed part to the movable part along the axis of extent of the associated pair of flexure linkages. 17. The multi-axis flexure positioner of claim 16, wherein at least one of the actuators is arranged to move the associated pair of flexure linkages together to cause linear displacement of the movable part.
18. The multi-axis flexure positioner of claim 16, wherein at least one of the actuators is arranged to move the associated pair of flexure linkages relative to one another to cause angular displacement of the movable part.
19. The multi-axis flexure positioner of claim 16, wherein at least one of the pairs of flexure linkages has first and second actuators associated therewith, the first actuator being arranged to move the associated pair of flexure linkages together to cause linear displacement of the movable part, and the second actuator being arranged to move the associated pair of flexure linkages relative to one another to cause angular displacement of the movable part.
20. The multi-axis flexure positioner of claim 16, wherein the plurality of actuators comprises three actuators, one associated with each pair of flexure linkages and each arranged to move the associated pair of flexure linkages together to cause linear displacement of the movable part in each of three mutually perpendicular directions.
21. The multi-axis flexure positioner of claim 16, wherein the plurality of actuators comprises six actuators classified into first and second groups of three actuators, one actuator of the first group and one actuator of the second group being associated with each pair of flexure linkages, each actuator of the first group being arranged to move the associated pair of flexure linkages together to cause linear displacement of the movable part in one of three mutually perpendicular directions, and each actuator of the second group being arranged to move the associated pair of flexure linkages relative to one another to cause angular displacement of the movable part in one of three independent rotational axes.
22. The multi-axis flexure positioner of claim 21, wherein the rotational axes intersect at a common point.
23. The multi-axis flexure positioner of claim 16, wherein each flexure linkage is flexible to rotate about its axis of extent and bend along each of two bending axes perpendicular to said axis of extent.
The linkage shown in FIG. 2 is the design chosen to provide the desired lengthways rigidity and lateral and torsional deformability in the embodiments of the invention. The linkage comprises two end portions 18 and 19 disposed on either side of a central portion 20, the central and end portions being interconnected by two flexible portions 21 and 22. The central and end portions 18 to 20 are made of sections of stainless steel rod of 3 mm diameter. The central portion is around 25 mm in length and the end portions 10 mm. The flexible portions 21 and 22 are made of sections of music wire of 1 mm diameter and are each around 15 mm in free length with around 10 mm at each end received in bores in the central and end portions and cemented in place by adhesive bonding, thus to leave a free length of the wire sections of around 10 mm.
Six linkages provide the exact desired number of constraints to hold the block 7 rigidly in a set position, six is thus the preferred number of linkages. If there are fewer than six linkages, the block will not in general be held rigidly. If there are more than six linkages, some of the linkages provide redundant constraints and as a result residual forces exist within the system.
In addition to the components shown in FIG. 1, FIG. 3 shows a plate 1 which is hingedly mounted relative to a case 13 via a hinge 15. The plate 1 need not-literally have the form of a plate, but may be a rigid body of arbitrary shape arranged to rotate about a single axis in the manner of a hinge. The hinge axis is arranged to lie along a line parallel to a line drawn between the points where the linkages 8 meet the plate 1. On the side of the plate facing towards the movable block 7, the end portions 18 of the linkages 8 are located by locating means 24. (The end portions 19 of the linkages are located by locating means 23 of the block 7). On the other side of the plate, i.e. the side facing away from the movable block 7, there is a contact region 25 at which a micrometer 14 acts via the end of its spindle 32. The micrometer is mounted on the case 13 by micrometer mounting means (not shown in FIG. 3). Although a micrometer is shown, the actuator may be of any type, for example motorised fine thread or piezoelectric.
The operation of the Z (vertical) axis differs in that the motion is effectively cranked round by 90 degrees, so that the z-micrometer 12 can be mounted horizontally and not vertically. Additional parts, namely a hinged driver plate 11, on which bears the spindle 34 of the horizontally mounted z-micrometer 12, and a horizontally extending ball-ended linkage 10, interconnecting the driver plate 11 and the z-plate 9, are used to transmit the z-motion. The z-micrometer 12 can thus be positioned conveniently in terms of the detailed design. Alternatively, the z-micrometer could act directly on the hinged z-plate 9, similar to the X-and Y-micrometers, but in general this will be less convenient if the positioner is to be table mounted.
First (Second) Embodiment
all 100+ numerals are for second embodiment
hinged (pivoted) x-plate
flexible y-linkages (y/roll linkages), 2 of
flexible z-linkages (z/pitch linkages), 2 of
hinged (pivoted) y-plate
y-actuator
roll-actuator
platform [top plate]
flexible x-linkages (x/yaw linkages), 2 of
hinged (pivoted) z-plate
ball-ended driver plate linkage for z
hinged driver plate for z
pitch-actuator
yaw-actuator
x-hinge
z-hinge
linkage actuator-end rigid locating portion
linkage carriage-end rigid locating portion
linkage central rigid portion
linkage actuator-end flexible portion
linkage carriage-end flexible portion
carriage linkage-locating means, in pairs
hinged-plate linkage-locating means, in pairs
hinged x-plate actuator-spindle contact region
hinged y-plate actuator-spindle contact region
hinged z-plate actuator-spindle contact region
driver plate hinge
x-actuator mounting means (part of case 13)
yaw-actuator mounting means (part of case 13)
y-actuator mounting means (part of case 13)
roll-actuator mounting means (part of case 13)
z-actuator mounting means (part of case 13)
pitch-actuator mounting means (part of case 13)
x-actuator drive spindle
yaw-actuator drive spindle
y-actuator drive spindle
roll-actuator drive spindle
z-actuator drive spindle
pitch-actuator drive spindle
base plate of case
side plate of case 13 accommodating
x- and z-actuator mounting means
x- pitch- and yaw-actuator mounting means
y-actuator mounting means
roll- y- and z-actuator mounting means
tapered tube mount elongations
pivot point indicator probe
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