The present invention relates to a micromirror device and a projection device including a micromirror device according to the present invention.
Micromirrors are presently used in a continuously increasing number of applications. These applications include, for example, projectors, scanners, or the like. The advantage of the micromirrors is that they occupy little space and may therefore be used very flexibly.
Micromirrors are typically micro-electromechanical elements which are structured and manufactured, for example, with the aid of the conventional methods from semiconductor processing.
Different methods may be used to implement the deflection of the mirrors in such a micromirror. For example, electrostatic drive methods, magnetic drive methods, piezoelectric drive methods, or the like may be used. Some drive methods only offer the option of tilting the mirror in one direction. Other drive methods also offer the option of tilting the mirror in two directions. The mirror thus carries out a rotational movement about the tilt axis or tilt axes.
Due to the relatively large rotational mass of the drive of such a micromirror, the overall structure, or parts thereof, made up of a quasistatic mirror, a resonant mirror, mechanical fixing elements, magnets, electronic parts, including connecting surfaces, in particular adhesive surfaces, may be excited into undesirable oscillations.
Connecting parts made of plastic, in particular adhesive bonds, may have a significant plastic deformation in the event of such oscillations, which becomes noticeable in an undesirable energy dissipation. Mass movements in the z direction, i.e., perpendicular to the chip surface or mirror surface, are particularly critical with respect to the energy decoupling.
Such a mass movement in the z direction is part of the normal operation of such a micromirror, however, because of the basic drive arrangement in conventional micromirrors.
The micromirror of
The present invention provides a micromirror device and a projection device.
The following is accordingly provided:
A micromirror device including a drive unit, which includes a movable drive element, which is situated in a first plane, and a guiding device, and including a mirror, which is elastically coupled to the drive element and is situated in a second plane in an idle position, which is in parallel to the first plane, the guiding device being designed to guide the movement of the drive element on a straight line situated in the first plane.
Furthermore, the following is provided:
A projection device including at least one light source, at least one micromirror device as recited in one of the preceding claims, and a control unit, which is designed to control the at least one micromirror device.
A movement of the drive body in the z direction, as it occurs in conventional micromirrors, results in amplified oscillations and therefore also amplified deformations in a carrier structure of the micromirror.
In accordance with the present invention, this is taken into consideration and an option is provided for setting the mirror of the micromirror device into a rotational movement and/or oscillation, and to move the drive element of the micromirror device only in a plane which is parallel to the plane in which the mirror is situated in an idle position. The movement in a plane also includes slight movements in other directions, which may occur, for example, as a result of component tolerances or deformations of components.
To be able to move the drive element only in the predefined direction, the present invention provides a guiding device which restricts the movement of the drive element. The guiding device is designed in such a way that the drive element is guided along a straight line, which is situated in the first plane, in parallel to the second plane, in which the mirror is situated.
With the aid of the guiding device it is therefore possible to restrict the movement of the drive element out of the provided plane. The oscillations which are induced in the entire micromirror device or in carrier elements of the micromirror device may thus be reduced to a minimum.
Advantageous specific embodiments and refinements are described herein with reference to the figures.
In one specific embodiment, the guiding device includes at least one first spring, in particular a leaf spring, which has the lowest spring stiffness in the direction of the straight line and to which at least one drive element is coupled. Since the straight line specifies the desired movement direction, the spring may be designed in such a way that a movement in the desired direction may be excited easily, movements in other directions being made difficult. The spring may have a spring stiffness in all other movement directions, for example, which is orders of magnitude greater than the spring stiffness in the desired direction.
In one specific embodiment, the at least one first spring is coupled to a carrier structure of the micromirror device at the end of the spring which is not coupled to the drive element. This enables it to induce a relative movement of the drive element in relation to the carrier structure with the aid of the spring.
In one specific embodiment, a plurality of first springs is provided, which are coupled in a symmetrically distributed way to a post standing upright on the first plane, the post being coupled to the carrier structure of the micromirror device. The stiffness of the overall system in all directions except for the desired direction, in which the springs have the lowest spring stiffness, is thus increased or multiplied as a function of the number of the springs.
In one specific embodiment, the micromirror device includes a magnet device, the drive element including an electrical coil, and the magnet device being designed to generate a magnetic field, which exerts a force on the coil in such a way that the drive element is moved on the straight line. This enables a movement of the drive element to be caused without a direct physical contact of the drive element with the magnet.
In one specific embodiment, the magnet device is situated on the carrier structure in such a way that in an idle position of the drive unit, the coil is permeated perpendicularly by the magnetic field. The maximum possible force is thus exerted in the desired direction on the drive unit.
In one specific embodiment, the drive element has at least one second spring, which is designed to couple the mirror to the drive element in such a way that the mirror is set into a cyclic rotational movement in the event of an oscillating movement of the drive element on the straight line. It is thus possible to induce a rotational movement of the mirror based on a linear oscillating movement of the drive element.
In one specific embodiment, the at least one second spring has a meandering structure, in particular having a high aspect ratio, which is designed in such a way that the at least one second spring is tiltable at least partially out of the first plane. Due to the meandering structure of the spring, the mechanical tensions nonetheless remain low in the case of high spring stiffness and small overall size.
In one specific embodiment, the guiding device is designed to provide a rotational movement of the drive element out of the first plane in a predefined tolerance range. If a rotational movement of the drive element which is only predefined in a narrow framework is enabled, the conversion of the linear movement of the drive element into a rotational movement of the mirror is improved.
In one specific embodiment, the drive unit is designed to drive the mirror in such a way that it executes a cyclic movement at a frequency of greater than 10 kHz, in particular 18 kHz to 22 kHz.
The above embodiments and refinements may be combined with one another arbitrarily whenever reasonable. Further possible embodiments, refinements, and implementations of the present invention also include combinations, which are not mentioned explicitly, of features of the present invention described above or hereafter with respect to the exemplary embodiments. In particular, those skilled in the art will also add individual aspects as improvements or supplementations to the particular basic form of the present invention.
The present invention is explained in greater detail hereafter on the basis of the exemplary embodiments indicated in the schematic figures.
In all figures, identical or functionally identical elements and devices—if not otherwise indicated—have been provided with the same reference numerals.
Micromirror device 1 of
Drive unit 2 is situated in a first plane 4 and mirror 6 is situated in a second plane 7, which is situated in parallel to first plane 4 in the specific embodiment of
Drive unit 2 has a drive element 3, to which mirror 6 is coupled. Furthermore, drive unit 2 has a guiding device 5, which guides a movement of drive element 3 on a straight line 8 situated in first plane 4. In one specific embodiment, guiding device 5 may be designed, for example, as a rail-type element 5, which guides the movement in the direction of straight line 8.
In one specific embodiment, guiding device 5 may have, for example, a first spring or a plurality of first springs 9-1-9-n. First springs 9-1-9-n may have the lowest spring stiffness in the direction of straight line 8 and may be coupled to the at least one drive element 3. First springs 9-1-9-n thus facilitate a movement in the direction of straight line 8 and make a movement of drive element 3 difficult in all other directions. To control the movement of drive element 3, first springs 9-1-9-n may also be coupled to a carrier structure 10 of micromirror device 1, 1-1-1-n, in addition to drive element 3.
Drive element 3 may be designed in particular to execute a cyclic or oscillating movement in first plane 4. This enables it to carry out a resonant excitation of the system made up of drive element 3 and mirror 6, whereby it is possible to generate a defined movement of mirror 6 at a predefined frequency.
The movement of mirror 6 itself is dependent on the type of the elastic coupling between mirror 6 and drive element 3. In one specific embodiment, the elastic coupling may be designed, for example, in such a way that mirror 6 carries out a rotational movement about an axis, which is situated approximately in the middle between mirror 6 and drive element 3, when drive element 3 is moved back and forth on straight line 8.
Projection device 17 may be, for example, a video projector for the projection of films or images on a screen. However, projection device 17 may also be a projection device 17 which is used, for example, in an HUD display in a vehicle. Further embodiments are also possible.
Projection device 17 includes a light source 18, which may be, for example, a conventional lamp, an LED lamp, a laser light source, or the like. Light source 15 is situated in such a way that it illuminates a plurality of micromirrors 1-1-1-n (shown by dashed lines in
Projection device 17 furthermore includes a control unit 19, which controls micromirror devices 1-1-1-n. For this purpose, control unit 19, depending on the specific embodiment, may provide one or multiple control voltages, for example, which control the alignment of individual micromirror devices 1-1-1-n. Control unit 19 may also be designed in one specific embodiment to control light source 18. Furthermore, control unit 19 may also include an interface, via which control unit 19 may receive image data, for example. This interface may be, for example, an HDMI interface, a DVI interface, or the like. This interface may also be a network interface or the like, however.
Micromirror device 1 of
Finally, micromirror device 1 of
In the specific embodiment shown in
Micromirror device 1 of
Second spring 16 is designed in
Spring elements 25-1, 25-2 are designed as bars in
The micromirror device of
Micromirror device 1 of
It is apparent in
The movement is continued by a directional reversal, during which first springs 9-3-9-18 are relaxed and therefore move drive element 3 back to the left again. The mirror is thus raised again from the maximally tilted position.
Magnet device 12 includes a U-shaped housing 31 situated around a magnet 30, for example, a hard magnet 30. The lines of magnetic field 14 emerge from magnet 30 in such a way that they exit perpendicularly below magnet 30. A coil 13 is situated below magnet 30, which is situated on drive element 3 in one specific embodiment. If coil 13 is permeated perpendicularly by the magnetic field lines of magnetic field 14, a force results on coil 13 and therefore, for example, on drive element 3, in the lateral direction. Coil 13 and therefore drive element 13 may be set into an oscillation with the predefined frequency by an activation of magnet 13 using an AC voltage of a predefined frequency.
Although the present invention was described above on the basis of preferred exemplary embodiments, it is not restricted thereto, but rather is modifiable in a variety of ways. In particular, the present invention may be changed or modified in manifold ways without departing from the core of the present invention.
Number | Date | Country | Kind |
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10 2014 211 379 | Jun 2014 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2015/061959 | 5/29/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/189051 | 12/17/2015 | WO | A |
Number | Name | Date | Kind |
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20040165243 | Helmbrecht | Aug 2004 | A1 |
20120127551 | Eto | May 2012 | A1 |
20120218612 | Chang | Aug 2012 | A1 |
20140146435 | Stephanou et al. | May 2014 | A1 |
20140300942 | Van Lierop | Oct 2014 | A1 |
Number | Date | Country |
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10 2012 206 269 | Oct 2013 | DE |
10 2012 206 291 | Oct 2013 | DE |
1 180 848 | Feb 2002 | EP |
Entry |
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Milanovic, et al., “Laterally actuated torsional micromirrors for large Static Deflection,” IEEE Photonics Technology Letters, IEEE Service Center, vol. 15, No. 2 (2003), pp. 245-247. |
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Number | Date | Country | |
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20170108693 A1 | Apr 2017 | US |