An optical mount is used for mounting an optical element, such as a beam splitter or a mirror, to a housing. The optical mount includes a pair of optical element retainer clamps that secure a first side of the optical element at respective first securement points on one of the major surfaces of the optical element, and also engage a first edge. A whiffletree retainer clamp secures a second side of the optical element at a second securement point on the one of its major surfaces. The whiffletree retainer clamp couples a whiffletree retainer to the housing, with the whiffletree retainer engaging a second edge along the second side of the device. The whiffletree retainer is positionally adjustable, for example able to pivot. Pivot pads may be used in at least some of the engagements to secure the optical element. The pivot pads may be segments of ball bearings.
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19. A method of securing an optical element, the method comprising:
placing the optical element in a whiffletree retainer of an optical mount; and
securing the optical element in three places at three securement points, by use of coaxial pairs of pads of the mount pressing on opposite major surfaces of the optical element.
1. An optical mount comprising:
a housing;
a pair of optical element retainer clamps mechanically coupled to the housing, wherein the optical element retainer clamps are configured to receive and secure a first side of an optical element at respective first securement points on a major surface of the optical element, adjacent to a first edge of the optical element that is along the first side;
a whiffletree retainer clamp mechanically coupled to the housing, wherein the optical element whiffletree retainer clamps are clamp is configured to receive and secure a second side of an the optical element at a pair of second securement points point on the major surface; and
a whiffletree retainer that is configured to press against at least two points along a second edge of the optical element that is along the second side;
wherein the whiffletree retainer clamp mechanically couples the whiffletree retainer to the housing; and
wherein the whiffletree retainer is positionally adjustable relative to the optical element retainer clamps and the whiffletree retainer clamp.
2. The optical mount of
wherein the major surface is a first major surface; and
further comprising pivot pads that are mechanically coupled to the housing that press against a second major surface of the optical element;
wherein the pivot pads allow the optical element and the whiffletree retainer to pivot relative to the housing, the retainer clamps, and the whiffletree retainer clamp.
3. The optical mount of
7. The optical mount of
8. The optical mount of
9. The optical mount of
10. The optical mount of
11. The optical mount of
12. The optical mount of
13. The optical mount of
14. The optical mount of
wherein the whiffletree retainer locking mechanism includes lock screw and a lock ball; and
wherein the lock ball is threaded into a hole in the whiffletree retainer clamp to press the lock ball against a surface of the whiffletree retainer.
15. The optical mount of
wherein the optical element retainer clamps and the whiffletree retainer clamp each have flat pads that are configured to engage and press against the edges of the optical element; and
wherein each of the flat pads includes a plunger and a spring, with the spring used to provide a spring force to push the plunger against one of the edges of the optical element.
16. The optical mount of
20. The method of
wherein the pads include pivot pads; and
further comprising pivoting the optical element and the whiffletree retainer relative to other parts of the optical mount.
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1. Field of the Invention
The invention is in the field of mounts for optical elements, and methods for securing and/or adjusting optical elements.
2. Description of the Related Art
Precision optical devices or elements, such as beam splitters or mirrors, may need substantially strain-free optical mounts to provide diffraction-limited optical performance. One typical type of mount capable of achieving these requirements is referred to as kinematic. The theory of kinematic design assumes that the bodies are perfectly rigid, and that contact only occurs at points. Every rigid body possesses six degrees of freedom. These degrees of freedom are translations along three (3) mutually orthogonal axes, and three (3) rotations around these axes. The theory of kinematic design states that a rigid body has (6-n) degrees of freedom, where (n) is the number of contact points. Any mount or support that constrains a rigid object with more than six (6) contact points, is said to “over-constrain” the object, which likely results in distortion and uncertain position of the object. In kinematic design, three (3) points determine a plane, so that contact of a plane surface to more than three (3) points, distorts the plane surface to the co-planarity of all points contacting the plane surface. This co-planarity requirement for the mating surface must then be equal to the optical tolerance for flatness of the plane surface, which typically is a fraction of the wavelength of light. Such a requirement for mechanical surfaces, designed to mate with optically flat surfaces, imposes significant design and fabrication challenges.
Current mounts use angularly adjustable frames that house rectangular optic devices which are potted with room temperature vulcanization (RTV) silicone, or some other suitable adhesive. These adhesives are liquid when applied and thus conform to the optic's surface, but typically induce some strain into the optic when cured to their final state as a more rigid compound. The coefficient of thermal expansion of these RTV compounds does not equal those of the optic or the metals, such as aluminum, typically used to fabricate optical mounts. To ensure strain-free mounting of potted optics, over temperature changes, the gap used for the potting must be athermalized, i.e., made to function as though it is unchanging, independent of temperature. This means that the gap is sized such that ideally, no stress results from expansion differences between the mount, the RTV or other potting compound, and the optic being mounted. Since materials expand in all three dimensions simultaneously, designing perfectly athermal potting gaps can be challenging. For non-circular optics, such as in rectangular shapes, this more complex geometry results in athermalized gap designs that are typically impractical to fabricate, due to the requirement for continually varying cross-sections. RTV and other optics bonding adhesives generally used, typically possess a low bulk modulus of elasticity to minimize forces on the optic resulting from non-athermalized gaps. The more non-circular the optic, the greater the temperature changes relative to the bonding temperature, the more sensitive the optic to strain, etc., all underscore the importance of a perfectly athermalized potting gap. Strain induced by temperature changes on non-athermalized gaps can both deform the optic, and tilt it relative to surfaces of the frame to which it is potted. As an option, some frames may use flexures for mounting the optic within the frame. The flexure, or any surfaces or materials contacting the optic, which over-constrain it, can create localized stresses at the points of contact-with the optic. This can result in degraded optical characteristics, such as degraded surface figure, with its resulting degradation on optical wavefronts interacting with strained optical surfaces. Minimizing strain in optics can also be challenging, particularly in extreme environmental conditions, such as involving temperature extremes, vibrations, and/or shocks. It would be desirable to have improved optical mounts that would avoid or alleviate these shortcomings.
According to an aspect of the invention, an optical element mount includes pivot pads that allow an optical element, held by the mount, to be adjusted in one or two axes. The pivot pads facilitate tilting the optical element without inducing over-constraints, i.e., bending moments. The pivot pads may be portions of commercially available ball bearings, which are inexpensive, made to tight tolerances, and can be fabricated by processes, like electrical discharge machining (EDM), to be substantially burr free.
According to another aspect of the invention, an optical mount includes two retainer clamps that engage a first side of a major surface of an optical element held by the mount, and one retainer clamp that engages a second side of the major surface. The retainer clamp that engages the second side of the major surface also is mechanically connected to a whiffletree retainer that engages one or more edges of the optical element. The whiffletree retainer is able to pivot, along with the optical element, relative to the retainer clamps and a housing of the optical mount.
According to yet another aspect of the invention, an optical mount includes: a housing; a pair of optical element retainer clamps mechanically coupled to the housing, wherein the optical element retainer clamps are configured to receive and secure a first side of an optical element at respective first securement points on a major surface of the optical element, adjacent to a first edge of the optical element that is along the first side; a whiffletree retainer clamp mechanically coupled to the housing, wherein the optical element retainer clamps are configured to receive and secure a second side of an optical element at a pair of second securement points on the major surface; and a whiffletree retainer that is configured to press against at least two points along a second edge of the optical element that is along the second side. The whiffletree retainer clamp mechanically couples the whiffletree retainer to the housing. The whiffletree retainer is positionally adjustable relative to the optical element retainer clamps and the whiffletree retainer clamp.
In accordance with a further aspect of the invention, a method of securing an optical element includes: placing the optical element in a whiffletree retainer of an optical mount; and securing the optical element in three places, by use of pads of the mount pressing on opposite major surfaces of the optical element.
To the accomplishment of the foregoing and related ends, the invention comprises the features hereinafter fully described and particularly pointed out in the claims. The following description and the annexed drawings set forth in detail certain illustrative embodiments of the invention. These embodiments are indicative, however, of but a few of the various ways in which the principles of the invention may be employed. Other objects, advantages and novel features of the invention will become apparent from the following detailed description of the invention when considered in conjunction with the drawings.
The annexed drawings, which are not necessarily to scale, show various aspects of the invention.
An optical mount is used for mounting an optical element, such as a beam splitter or a mirror, to a housing. The optical element may have a rectangular shape, with opposed major surfaces, such as top and bottom major surfaces, and with side edges running from one major surface to the other. The optical mount includes a pair of optical element retainer clamps that secure a first side of the optical element at respective first securement points on one of the major surfaces of the optical element, and that also engage a first edge of the optical element. A whiffletree retainer clamp secures a second side of the optical element at a second securement point on the one of the major surfaces. The whiffletree retainer clamp couples a whiffletree retainer to the housing, with the whiffletree retainer engaging a second edge of the optical element that is along the second side of the device. The whiffletree retainer is positionally adjustable relative to the optical element retainer clamps and/or the whiffletree retainer clamp, for example being able to pivot relative to either or both. Pivot pads may be used in at least some of the engagements to secure the optical element. The pivot pads may have a flat engagement surface that engages one of the optical element major surfaces, and a curved surface that enables pivoting. The pivot pads may be segments of ball bearings, for example cut using an electro-discharge machining process. The optical mount allows for firm securing of the optical element, but without placement of bending moments on the optical element that could result in stresses that could distort or damage the optical element. By using the whiffletree in securing the optical element, overconstraint of the optical element may be avoided. Suitable adjustment mechanisms and locking mechanisms may be used as part of the optical mount.
Referring to
The optical element retainer clamps 18 and 20 secure a first side (side portion or side part) 52 of the optical element 12. The retainer clamps 18 and 20 have respective flat pads 58 and 60 that engage and press against first securement points on the first surface 32 of the optical element 12. The flat pad 58 includes a plunger 62, a compression spring 64, and a snap ring 66. The flat pad 60, as well as other flat pads of the optical element mount 10, include similar parts. The springs of the pads 58 and 60 provide a preloading force against the first surface 32. The optical element first side 52 is clamped between the flat pads 58 and 60, which engage the first surface 32, and pivot pads 70 and 72, which press against securement points on the second major surface 34 of the optical element 12. Pads 58 and 60 are coaxial with pivot pads 70 and 72, respectively, to prevent the generation of bending moments in this plane of support of the optical element 12. The pivot pads 70 and 72 have flat front surfaces that engage the second major surface 34, and curved back surfaces, such as spherical back surfaces.
The optical element retainer clamps 18 and 20 also have respective flat pads 82 and 84 for engaging the first edge 36 of the optical element 12. The pads 82 and 84 have a configuration similar to that of the flat pads 58 and 60, having respective spring-loaded plungers that provide a spring force for pushing against the first edge 36, and snap rings for keeping the plungers and the springs coupled to the retainer clamps during assembly.
A second side (side portion or side part) 90 of the optical element 12 is gripped between the whiffletree retainer clamp 22 and the housing 16. The whiffletree retainer clamp 22 includes a flat pad 92, similar to pads 58, 60, 82 and 84, that presses against a second securement point on the first optical element major surface 32. From the other side, the major surface 34, an adjustable pivot pad 94 holds the optical element 12 in place. The adjustable pivot pad 94 may be similar to the pivot pads 70 and 72 described above, having a flat front surface that is against the second major surface 34, and a curved back surface that rests in a cup-shape pivot pad support 96. The position of the pivot pad support 96 may be adjusted by use of an adjustment screw 102. Turning the adjustment screw 102 adjusts the height of the pivot pad support 96 above (from) the housing 16, and thus also the heights above the housing 16 of the pivot pad 94 and the second side 92 of the optical element 12 (which change height together). A lock 104 may be used to lock the position of the pivot pad support 96 in place. The lock 104 includes a locking screw 106 and a locking pin 108, with a spring 110 between the two. Threading the locking screw 106 into the corresponding threaded hole 112 in the housing 16 presses the locking pin 108 inward against the pivot pad support 96, locking the pivot pad support 96 in place to prevent movement of the pivot pad support relative to the housing 16.
The whiffletree retainer 24 also aids in kinematically supporting the second side portion 90 of the optical element 12. Instead of engaging the major surfaces 32 and 34 of the optical element 12, the whiffletree retainer 24 engages the edges 38, 42, and 44 of the optical element 12. The whiffletree retainer 24 has four pads 122, 124, 126, and 128. The pads 122 and 124 are pivot pads, having the same general configuration as is described above with regard to the pivot pads 70 and 72. The pads 122 and 124 are coaxial with pads 82 and 84 to prevent bending moments in this second support plane across the optical element 12. The pad 126 is a flat pad that may have the same general configuration as is described above with regard to other flat pads of the optical mount 10, such as the flat pads 58 and 60. Similarly, pad 128 is coaxial with pad 126 to prevent bending moments in this third support plane across the optical element 12. Since there is only a single point of contact with pad 128 on edge 44 of the optical element 12, the criticality of the contour of this pad is diminished as compared to the other pads. For this reason, pad 128 may be a pivot pad like pads 70 and 72, or it may be a spherical or cylindrical surface machined integral into the whiffletree retainer 24. Thus, the flat pads 122 and 124 engage (press against) the second edge 38, the flat pad 126 engages the third edge 42, and pad 128 engages the fourth edge 44. The pads 122 and 124 work in combination with the pads 82 and 84 on the optical element retainer clamps 18 and 20 to hold the optical element 12 in a first direction 132 that is substantially parallel to the major surfaces 32 and 34 (and substantially perpendicular to a height or distance from the housing 16). The pads 126 and 128 hold the optical element 12 in a second direction 136 that is substantially parallel to the major surfaces 32 and 34, and is perpendicular to the first direction 132.
The whiffletree retainer 24 has a pivot radius on an end surface 142 that butts up against an inner surface 144 of the whiffletree retainer clamp 22. The pivot radius is configured to allow the whiffletree retainer 24 and the optical element 12 to pivot as the position of the adjustable pivot pad 94 is adjusted by use of the adjustment screw 102. The pivot radius thus may be selected for pivoting of the whiffletree retainer 24 and the optical element 12 about the pivot pads 70 and 72.
Referring to
The optical mount 10 advantageously allows the securing of the optical element 12 with a minimum of strain on the device 12. Precision optical elements may require low levels of stress and strain in order to provide good, diffraction-limited optical performance. Flat optical elements such as the optical element 12 may need to be supported in a planar fashion to a high degree of accuracy, for example requiring support-point coplanarity on the order of a fraction of an optical wavelength, such as approximately 0.0762-0.3048 micrometers (3-12 microinches). The optical mount 10 provides virtually strain-free planar support of the optical element 12, while facilitating controllable tilt of the optical element 12, for angular alignment of the optical element 12.
The optical mount 10 advantageously has only three pairs of coaxial contact points with each of the major surfaces 32 and 34 of the optical element 12. Utilizing only three pairs of points on these major surfaces provides minimum, but adequate, planar support and registration while preventing overconstraint of the optical element 12, which would-introduce stress (and strain) into the optical element 12. The pivoting whiffletree retainer 24, both avoids overconstraint of the optical element 12, and prevents undesired movement of the optical element 12 in all remaining directions, while facilitating adjustment of the angle of the optical element 12 relative to the housing 16. Another key advantage of the whiffletree retainer 24 is that it provides the critical support technique to allow aligning the contact points at pads 122 and 124 to be coaxial to contact pads 60 and 58, respectively. Distributed pairs of coaxial support points provide robust inertial support to the optical element, while preventing bending stresses across the optical element 12.
The use of the whiffletree retainer 24, to provide dual points of support, also minimizes the optical element's contact stresses during high inertial load conditions. The optical mount 10 provides stable support and alignment retention over a large range of environmental conditions, including shock and vibration. In particular, changes in temperature do not introduce significant stresses into the optical element 12. The various spring-loaded pads provide a means by which the optical mount 10 has some “give” that allows for changes in dimensions during thermal changes.
The various parts of the optical mount 10 may be made of any of a variety of suitable materials. Aluminum is a suitable material for the larger parts of the optical mount 10, such as the housing 16, the retainer clamps 18-22, and the whiffletree retainer 24. Parts of the mount 10 may be made of aluminum, steel, or other metallic material suitable for the environment and the opto-mechanical requirements. For example the whiffletree retainer clamp 22 may be made of steel or aluminum. Unlike potted optical assemblies, which require athermalized gaps at all bonding locations to ensure that the adhesives provide strain-free mounting over temperature extremes, the springs loading pads 58, 60, 82, 84, and 126 inherently compensate for the thermal expansion differences between the mount materials and the optic. Unlike certain optical bond joints, the compression-only forces, generated by these six coaxial spring-loaded pairs of pads, do not induce any bending moments in spite of housing and optic dimensional changes with temperature.
Many variations are possible in the configuration of the optical mount 10. For example the flat pads 58, 60, and 92, and the pivot pads 70, 72, and 94, may be reversed. That is, the housing 16 may include the flat pads, and the retainer clamps 18-22 may include pivot pads. Other variations will be appreciated.
As noted earlier, the pivot pads 70, 72, and 94 may be parts of one or more ball bearings. Ball bearings have the advantage of being inexpensive parts having a very accurate (tight toleranced) radius and a burr-free surface. The pivot pads 70, 72, and 94 may be sections or parts of ball bearings, with the ball bearings for example cut using an electro-discharge machining process, or another suitable process. The ball bearings may be made of suitable steel, such as 440C stainless steel. Such stainless steel has the advantage of a high microyield strength (the allowable stress that will cause 1 ppm of permanent strain in a short time, also known as precision elastic limit or PEL), which improves alignment stability in high shock environments.
Another difference from the optical mount 10 (
In addition to the adjustment mechanism for adjustment of elevation, described earlier with regard to the mounts 10 and 210, the mount 410 has a pseudo-azimuth adjustment mechanism 600. The adjustment mechanism 600 includes a spring-loaded plunger 604 that has a threaded shaft 606 that engages a threaded hole 608 in a housing 610. The plunger 604 can be turned to adjust the vertical position of a cup 612 and a pad 614 above the housing 610. A retainer clamp 418 is secured to the housing 610 by the cup 612 and the pad 614, with the height of the retainer clamp 418 adjustable as described above. Another retainer clamp 420 is coupled to the housing 610 by an additional cup 632 and pad 634, allowing the retainer clamp 420 to pivot relative to the housing 610 as the height of the retainer clamp 418 is adjusted.
The elevation adjustment is performed about an elevation axis 642, and the pseudo-azimuth adjustment is performed about an axis 644. Several alignment iterations may need to be performed to align the optical device 412, alternatively between elevation adjustment and pseudo-azimuth adjustment.
The optical mounts described herein may be used in any of a variety of devices, for example as part of sensor systems in air vehicles, such as unmanned aerial vehicles. The mounts may be used to secure a variety of other sorts of precise devices in highly dynamic thermal and inertial environments that may need to be securely held and precisely positioned, without placing undue stress on the device being held.
Although the invention has been shown and described with respect to a certain preferred embodiment or embodiments, it is obvious that equivalent alterations and modifications will occur to others skilled in the art upon the reading and understanding of this specification and the annexed drawings. In particular regard to the various functions performed by the above described elements (components, assemblies, devices, compositions, etc.), the terms (including a reference to a “means”) used to describe such elements are intended to correspond, unless otherwise indicated, to any element which performs the specified function of the described element (i.e., that is functionally equivalent), even though not structurally equivalent to the disclosed structure which performs the function in the herein illustrated exemplary embodiment or embodiments of the invention. In addition, while a particular feature of the invention may have been described above with respect to only one or more of several illustrated embodiments, such feature may be combined with one or more other features of the other embodiments, as may be desired and advantageous for any given or particular application.
Fierro, Emmanuel, Bratton, Robert K., Marr, Lyale F., Keels, Kelvin L.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
4635887, | Jul 05 1984 | Martock Design Limited | Adjustable mountings |
5505422, | Jun 02 1994 | Varian Australia PTY LTD | Top adjustable kinematic mount |
6836968, | Jun 25 2003 | Exelis Inc | Precision frictionless flexure based linear translation mechanism insensitive to thermal and vibrational environments |
6986211, | Mar 14 2003 | ONTO INNOVATION INC | System and method of planar positioning |
7164546, | Apr 24 2002 | Sanyo Electric Co., Ltd. | Lens shift mechanism and projection type video display |
7800852, | Feb 29 2008 | Corning Incorporated | Kinematic optical mount |
7992835, | May 21 2009 | IMAX Corporation | Kinematic mirror mount adjustable from two directions |
8085482, | May 27 2010 | Corning Incorporated | X-Y adjustable optical mount with Z rotation |
8100377, | Sep 02 2010 | The Boeing Company | Pin mount assemblies and methods |
8205853, | Jul 17 2008 | PLX, INC | Flexure mount for an optical assembly |
8542450, | Feb 08 2011 | Utah State University Research Foundation | Kinematic optic mount |
8591048, | Oct 30 2009 | Teledyne FLIR, LLC | Spatially efficient kinematic mirror mount |
9046651, | Feb 18 2011 | Gigaphoton Inc | Mirror device |
20040065793, | |||
20060016061, | |||
20060232837, | |||
20070195441, | |||
20080219756, | |||
JP4296708, |
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