DE19710668A1 - Variable lens system e.g. for endoscope zoom lens - Google Patents

Abstract

The system includes a lens chamber bounded by one or more diaphragms, which can be fully or partly transparent by changing the diaphragm thickness over the radius. Any arbitrary form of the curvature can be attained, e.g. elliptical, or hyperboloid, symmetrical, or asymmetrical. The diaphragm cross-section can also assume the shape of intermittent curves by support structures which can be exposed to tension and pressure, thus facilitating different formations. Typically both diaphragms of the lens may be different, or given different curvatures by different counterpressures.

Description

The invention relates to variable lens systems consisting of membrane lenses, their shape from concave to convex all lens shapes due to pressure or volume changes in the can assume fluid filling. Through targeted shaping of the membranes optical corrections carried out.

Variable lens systems are widely used, e.g. B. in zoom lenses. For the Zoom function they contain a mechanical moving unit with which the distance of some Lenses in the system is adjusted.

Adjustments are heavy and take up a lot of space. The mechanics are fragile and sensitive to pollution. The light intensity varies with the change in Enlargement. In addition, the adjustment range is limited, it is not easy possible to make do with one lens seamlessly from wide angle to zoom. In Conventional variable lens systems are also limited in their miniaturization. Aspherical lenses are difficult to implement and complex to manufacture.

The object of the invention is to provide an insensitive variable lens system that a very large zoom range for any size (large to very small) enables. The system must therefore be easily miniaturized in order to. B. also in the Endoscopy can be used. It should be possible to use aspherical lenses inexpensive to manufacture. All optics correction options such as surfaces Remuneration and additional aberration corrections should be realizable.

This object is achieved by the structure as shown in claim 1.

Variable membrane lenses change shape when in a closed system Pressure is varied. It is both a convex and a concave shape realizable. The exact course of the curvature is determined by a variation in thickness Membrane affected. Therefore, additional correction lenses are no longer necessary. With a System of variable membrane lenses becomes a zoom with a large adjustment range generated, the function of which is fulfilled by a mere change in pressure with a constant overall length. Alternatively, the refractive indices can also be varied, which also results in a Changing the focal length leads. All common lens sizes are with little effort producible. Membrane chambers can even be created using microtechnical processes what grants good miniaturization (e.g. endoscopic micro zooms). Complete systems made of variable membrane lenses can therefore be used in all sizes space-saving compact zooms can be an inexpensive alternative.  

Embodiments of the invention are shown in the drawings and are in following described in more detail.

In principle, membranes and frames (the center plate with a cross hole) are glued together in such a way that a pressure chamber is created ( Fig. 1). Generally the chambers will be rotationally symmetrical, but other shapes can be created if used. Because of the internal pressure, the frames must have sufficient strength. The membrane must be clear and flexible and is clamped between two frames. It is also conceivable that the membrane is glued or welded to the center piece, which means that the upper and lower frames can be omitted ( Figure 2). The permeability of the membrane or the fluid can be adapted to a narrow wavelength range, if this should be necessary.

Two cross holes in the center piece ensure that the chamber without air bubbles can be filled. The pressure can be varied via the cross holes, so that the curvature of the membrane changed. Both a concave and a Convex curvature can be achieved (negative or positive pressure). Furthermore, the Refractive index can be varied using different fluids. That too leads to a change in the focal length.

By adjusting the thickness of the membrane over the radius, any shape of the membrane curvature can be achieved, since thicker areas stretch less at the same pressure. This makes both spherical and aspherical lenses possible (e.g. ellipsoid or hyperboloid, Figure 2). The two membranes can also be designed differently, whereby they each have different curvatures when the pressure is varied ( Figure 2). This can also be achieved if the lens is inside a closed chamber, the front and back of which are of different sizes ( Figure 3). Due to the different pressure that develops on both sides when the size of the lens changes, the curvatures of the membranes differ. Membranes, the cross-section of which has the shape of non-continuous curves, can be achieved with support structures according to Figure 4 (loaded under tension or pressure). Diaphragms with corrugated symmetry can also be produced by building up a standing acoustic wave in the chamber. This function can e.g. B. can be used to quickly switch off a beam.

Another option is to use a rigid back plate (straight or curved, Figure 5 and Figure 6). Thus, one-sided variable lenses, piankoncave and plano-convex, can be created. The flexibility of this principle is expanded when the back plate is mirrored, since this enables flexible mirrors. In the case of reflecting flexible membranes or a reflecting fluid, such a mirror can also be realized without being dependent on the refractive index of the fluid. Parts of the membrane can also be mirrored, e.g. B. to reflect scattered light into the beam cone.

Using solutions with different concentrations (refractive indices) can continuously pass through a large refractive index range. Size  Opportunities are offered by a semipermeable membrane attached to an isotonic liquid borders. If the concentration in that liquid is increased or decreased, it also changes the concentration and thus the refractive index (depending on the membrane the pressure) of the Fluids in the membrane chamber.

If necessary, panels can be attached on both sides or even inside the chamber ( Figure 7, contains various possible panels). By processing the membrane, it can already contain the screen (by applying a layer or partially roughening or darkening).

A zoom system made of variable membrane lenses ( Figure 8) now consists, for example, of two variable lenses that are at a fixed distance from one another. The zoom function is only fulfilled by changing the pressure within the lenses. Since both lenses do not necessarily need the same pressure change, an easy-to-manufacture adjustment mechanism as in Figure 9 can be used: two tubes with a defined width are wound on one axis. If the hoses are attached on opposite sides, one hose is opened while the other is unrolled. The first hose is emptied, the second filled. The pressure in one lens then increases while the pressure in the other decreases. The volume change per revolution varies depending on the width of the hose. Different sizes can be obtained for both lenses with just one setting wheel and automatic focus adjustment can be guaranteed.

There is a large market for very cheap zoom systems among the more widespread "Disposable cameras" that are equipped with cheap optics and with the exposed film be returned. Here the membrane lens zoom optics can be used very well.

There are two other options for medical technology: Contact lenses that are filled with liquid are inexpensive to produce because two flat membranes can be used instead of a curved lens ( Figure 10). A small contact pad could also be used to create a variable contact lens. Furthermore, the lens of the human eye could also be simulated in this way (artificial implant). The focus could be via the visual muscles (direct pressure change on the artificial lens or via fluid pads) or externally (automatically or manually).

A mirror system can also be built with rigid but movable mirrors ( Figure 11). For this purpose, a thick mirror layer must be applied to the concavely curved membrane, which, apart from a small area in the middle of the membrane, is separated from the membrane by a sacrificial layer. If the sacrificial layer is now removed and the pressure is varied, the membrane carries out a linear displacement of the rigid mirror.

Another important possibility arises when the curved membrane is used as a tool (all membrane shapes discussed above are possible, Figure 12). First, the membrane is brought into the desired bulge and provided with a protective layer. Then z. B. liquid plastic can be poured.

Before curing, the curvature can be changed in situ in a controlled manner (e.g. with a reference image). After curing, either a fixed lens is obtained or, after applying a mirror layer ( Figure 14), a curved mirror. If the membrane is made of a non-wettable (possibly temperature-resistant) material (e.g. Teflon, good flexibility is not required here), the chamber can also be filled directly with liquid plastic ( Fig. 13). After opening the chamber you get the finished fixed lens, which can also be made into a mirror again. This molded part can be used to cast a lens (made of glass or plastic). This manufacturing process offers the possibility to manufacture aspherical lenses inexpensively.

Membranes of larger diameter in particular can react to strong accelerations (shocks...) With vibrations of the membrane. This can be compensated for with a controlled system: an acceleration sensor, the control and an actuator are required that vary the pressure according to the acceleration ( Figure 15). Such an actuator could be a piezo actuator. The vibrations are compensated for on the basis of destructive interference.

Another regulated complete system could consist of a photosensitive structure attached to the rigid back plate and a variable membrane ( Figure 16). For example, small cameras with a zoom lens could be produced inexpensively. For this purpose, the curvature of the membrane is adjusted so that the image is focused on the photosensitive structure. If the camera is made of heat-resistant materials, it enables in-situ observation of combustion chambers or the like.

Claims (25)

1. Variable lens system, characterized in that focal lengths are changed by changing the pressure, volume or concentration of the fluid in fluid-filled lens chambers. 2. Device according to claim 1, characterized in that the lens chamber by a or more membranes is limited. 3. Apparatus according to claim 1 or 2, characterized in that the lens chamber fully or can be partially transparent. 4. Device according to one of the preceding claims, characterized in that by Changing the thickness of the membrane over the radius achieves any shape of the curvature can be, e.g. B. ellipsoid or hyperboloid, symmetrical or asymmetrical. 5. Device according to one of the preceding claims, characterized in that the Cross section of the membrane through support structures also the shape of non-continuous curves can accept. These support structures can be subjected to tension or pressure and thus enable different versions. 6. Device according to one of the preceding claims, characterized in that both Membranes of the membrane lens are designed differently or by different ones Backpressures get different curvatures. 7. Device according to one of the preceding claims, characterized in that screens in If necessary, can be attached on both sides or within the chamber, or the Aperture is already built into the membrane. 8. Device according to one of the preceding claims, characterized in that by acoustically generated waves in the filling fluid suddenly change the optical properties to let. 9. Device according to one of the preceding claims, characterized in that itself have variable lenses made on one side by a rigid back plate. 10. Device according to one of the preceding claims, characterized in that a rigid Back plate is arched. 11. Device according to one of the preceding claims, characterized in that both Membranes can be replaced by rigid plates. 12. Device according to one of the preceding claims, characterized in that continuous change in the refractive index of the fluid the focal length of the lens itself also changes. 13. Device according to one of the preceding claims, characterized in that instead of Fluids use a highly viscous or solid polymer whose viscosity is above External action to vary the lens radius can be reduced by pressure can. After adjusting the lens radius, the polymer can return to the solid Original state to be reset.   14. Device according to one of the preceding claims, characterized in that the Backplate is reflective to create a variable mirror. 15. Device according to one of the preceding claims, characterized in that a partially or completely reflective membrane can also be used as a variable mirror can be used. 16. Device according to one of the preceding claims, characterized in that a reflecting fluid in a membrane lens creates a variable mirror. 17. Device according to one of the preceding claims, characterized in that at semipermeable design of one of the lens membranes or the frame (which is connected to a limit further liquid) the ion exchange with the lens liquid is made possible, which leads to a change in the refractive index. 18. Device according to one of the preceding claims, characterized in that a pure Membrane-fluid-membrane system (without frame) can be used as a contact lens. 19. Device according to one of the preceding claims, characterized in that a Contact lens can be designed as a variable contact lens, if with a Pressure pad or a similar device to increase the pressure or volume is connected. 20. Device according to one of the preceding claims, characterized in that the lens of the human eye in the same way (membrane-fluid-membrane) and with the optic muscle or an external drive whose focal length can be adjusted. 21. Device according to one of the preceding claims, characterized in that one with Mirror layer applied by sacrificial layer after removal of the sacrificial layer Pressure change within the membrane chamber can be pushed back and forth. 22. Device according to one of the preceding claims, characterized in that the Domed membrane used as a tool in all the training discussed above can be used e.g. B. manufacture aspherical mirrors or lenses. 23. Device according to one of the preceding claims, characterized in that the Cast material can be poured inside or outside the membrane chamber. 24. Device according to one of the preceding claims, characterized in that a stable Large membrane lens system can be constructed by using a vibration sensor on the Membrane is coupled to an actuator in the chamber to vibrate the membrane balance. 25. Device according to one of the preceding claims, characterized in that Attach a photosensitive structure to the rigid backplate of a membrane lens inexpensive micro camera with zoom can be produced. By using a heat-resistant membrane, the camera can also be used in very hot environments will.