DE202008008703U1 - Optical test arrangement - Google Patents

Abstract

Optical experimental arrangement,
with a holding part (2) for holding an optical element (4) on a base body (6),
characterized,
that the base body (6) consists at least partially of ferromagnetic material and
in that the holding part (2) has at least one holding magnet (16).

Description

The The invention relates to an optical test arrangement in the preamble of claim 1 for holding an optical element on a base body.

optical Experimental arrangements are in different fields of application for different Problems used. Not only within science, but also in the industrial sector, for example in the field research and development, become optical experimental setups used to by varying the type and arrangement of optical elements to solve different problems or different investigations to enable. Similar Requirements arise in commercial as well as private environment, for example, in photo-optical applications, as u. a. in the Repro photography can be found. There are often different optical Filter uses in their combination the desired recording result enable.

Further Application examples are in the field of spectroscopic investigations, where z. As a laser different lenses and converters are subordinate and by a gradual adaptation of the arrangement the optical elements the desired Results are achieved.

optical Experimental arrangements therefore have a wide range of uses for example, lighting and imaging solutions, measuring and test arrangements and interferometric To realize applications. In many cases it is necessary, flexible as well as fast on different requirements or conditions to be able to react. To is a corresponding variability of the arrangement crucial, to z. B. by a change of the optical elements and their distance or alignment with each other, the desired results iteratively to approach or the structure of the optical system with respect to various types Adapt problems.

to Realization of a modularity with regard to the use of various optical elements and to achieve a flexible arrangement of the optical elements are known optical experimental arrangements of the type in question, a holding part for holding an optical element to a body exhibit.

at the known optical experimental arrangements, the holding part a body through Held clamps. The clamping effect is generated by a positive connection, in the example, the holding part by screwing a retaining plate on the body is held.

The However, known optical test devices have the disadvantage on that a change the experimental arrangement only by releasing the clamping action, for example by loosening a screw connection is accessible. There are changes the arrangement of the optical elements time-consuming and reproducibility the results are not guaranteed.

Of the Invention is based on the object, an optical test arrangement specify the type mentioned in the preamble of claim 1, the does not have the disadvantage of the known optical test arrangements.

These The object is achieved by the teaching defined in claim 1.

The Invention solves from the thought of a holding part on a body by means of To hold clamping action. It is based on the idea the holding action substantially non-positively by at least one To realize holding magnets.

Should For example, and in particular according to the invention an optical element, the z. B. is a lens or a filter on a base body, for example horizontally oriented rods for the arrangement of the optical Element has to be attached, so the optical element is through a holding part on the body held. For this purpose according to the invention, the holding part to hold an optical element at least one holding magnet.

Under Optical elements in the sense of the invention are understood to mean elements generate, record, shape or change the light radiation; measure up. In this context, optical elements, for example Lenses, prisms, mirrors, filters, apertures, projection planes, converters, Lenses and light sources, in particular laser light sources, and Recording, testing or measuring devices. The Examples given are exemplary embodiments of optical elements, their list not conclusive at this point is.

One particular advantage of the teaching of the invention is that a change the arrangement of the optical elements in the optical test arrangement fast and easy at the same time. Because of the simple Handling can optical elements are exchanged quickly, reducing the adjustment the optical test arrangement to the respective requirements in a small period of time compared to existing solutions can. This is a great improvement especially in the experimental field.

The according to the invention optical In addition, experimental design is particularly good for a fast and at the same time precise Change of optical elements suitable. In principle, an inventive optical Experimental arrangement also used to hold samples or specimens become.

According to one advantageous development of the invention, the base body a A plurality of rods for arranging the holding part, which in the radial direction their geometric axis are spaced from each other. This results the advantage that a Arrangement direction for various holding parts that can be held, is predetermined and thus a more precise one Arranging the optical elements is achieved.

According to the invention can said rods are substantially vertically aligned, whereby it is possible especially in the Reprofotografie, also comparatively size body receive. In addition, thereby also optical experimental arrangements feasible with little horizontal space requirement.

A advantageous development of the invention is that the rods are aligned substantially horizontally. This results the advantage that a Variety of optical elements even at a greater distance can be arranged to each other. It also makes it possible that too comparatively large optical elements, as may be lenses, in the optical experimental setup can be arranged. In addition, this is achieved by the Weight support the holding of the optical element to the body.

Furthermore provides a further advantageous development of the invention, that this Holding part essentially of a non-ferromagnetic material consists. As a result, there is an advantageous weight saving, which favors the ease of use of the optical experimental arrangement. In addition, the production of the holding part can be designed inexpensively be made by, for example, the holding part substantially of plastic exists and as an injection molded part economical can be produced.

Further provides a further advantageous development of the invention, that this Holding part has recesses into which the body at least partially form-fitting engaging. This has the advantage that a change of arrangement or a replacement of the optical elements in the optical test arrangement performed faster can be.

According to one Another advantageous embodiment of the invention is the magnet of the holding part at least partially made of neodymium-iron-boron (NdFeB), whereby a strong holding effect is generated. This results in the advantage that besides a secure hold also comparatively heavy optical Elements can be arranged in the optical test arrangement.

to Increasing the holding force provides a further advantageous development the invention that the Holding part has at least two holding magnets. This results in the advantage that the Holding strength increased on the one hand and on the other hand evenly distributed can be.

A further advantageous embodiment of the invention is that this Holding part on the base body is positioned positionable. This leads to the advantage that in particular in optical experiments the reproducibility is improved. This can be supported for example by a scale on the body.

Further provides a further advantageous development of the invention, that one Plurality of holding parts for a plurality of optical elements is provided, such that the optical Experimental arrangement can be used as a modular system for performing optical experiments is. This modular system gives the advantage of being flexible and react quickly to different requirements. Furthermore is it possible a parallel interaction of different optical elements to realize.

The The invention is explained in more detail below with reference to the attached drawing, in FIG the one embodiment an optical inventive Experimental arrangement for the arrangement of different optical elements is shown. This form all claimed, described and features shown in the drawing taken alone and in any Combination with each other the subject of the invention, regardless of its summary in the claims and their remittances as well as independently from their description or representation in the drawing.

It shows:

1 a highly schematic perspective view of an embodiment of an experimental arrangement according to the invention with an arrangement of different holding parts,

2 the holding part of the embodiment of an optical experimental arrangement according to the invention in the same representation as in 1 but on a different scale, and

3 the basic body of the embodiment of an optical test arrangement according to the invention in the same representation as in 1 ,

In 1 an embodiment of an optical experimental arrangement according to the invention is shown in a perspective view, with a holding part 2 for holding an optical element 4 on a base body 6 , 1 For the sake of better understanding, details are omitted and the description is limited to the essential components of the embodiment.

The main body 6 consists of a base plate 8th which has recesses for easy modification of the optical experimental arrangement (for a better overview see 1 only a recess with the reference numeral 10 provided), in the manner of a perforated grid on the base plate 8th are arranged. In addition, the basic body exists 6 from a fortification 12 which serves the substantially horizontally arranged rods 14 of the basic body 6 at the base plate 8th to keep. This in 1 illustrated embodiment of an optical experimental arrangement according to the invention makes it possible to different optical elements 4 on the substantially horizontally arranged rods 14 to arrange. The holding part 2 consists in this embodiment, essentially made of plastic, in the two holding magnets 16 are inserted (this is in 1 for a better overview only on a holding part 2 indicated). In principle, any material can be used instead of the plastic. To save weight, for example, a light metal such as aluminum is suitable.

Furthermore, the holding part 2 recesses 18 to better handle the arrangement of the optical elements 4 on the substantially horizontally arranged rods 14 to allow (for a better overview is in 1 only a recess with the reference numeral 18 Mistake). Through the recesses 18 It is also possible to position the optical elements 4 to improve, because through the recesses 18 a better leadership is given. As a result, the optical elements can 4 also on a scale 20 , which in this embodiment on a pole 14 is applied, better arranged.

On the basis of the embodiment of an optical test arrangement according to the invention it is clear that the holding part 2 also in combination with known holding parts, the z. B. holding by clamping, is usable. This is useful, for example, in heavy optical elements, which by means of magnetic force not sufficiently secure on the body 6 can be kept.

2 shows the holding part 2 the embodiment of an optical experimental arrangement according to the invention in a perspective view, in which the arrangement of the magnets 16 in the holding part 2 is indicated by a dashed line. In this embodiment of an optical test arrangement according to the invention, the holding part 2 two holding magnets 16 at least partially made of neodymium-iron-boron (NdFeB) and in this embodiment of the holding part 2 surrounded by the plastic used on all sides. They are therefore not visible from the outside and without destroying the holding part 2 not removable. This results in the advantage that the magnets 16 in the holding part 2 are embedded and in particular with changes in the arrangement of the holding part 2 not eliminated. This gives a substantially constant holding force. The holding part 2 also has a recess 22 on, in which the optical element 4 is held. The shape of the recess 22 is in this embodiment of an optical experimental arrangement according to the invention substantially circular. However, the optical experimental arrangement according to the invention is not limited thereto.

In 3 is the main body 6 of the embodiment of an optical experimental arrangement according to the invention is shown in a highly schematic manner in a perspective view. For better positioning is on a pole 14 of the embodiment of the optical experimental arrangement according to the invention a scale 20 appropriate. It serves to ensure that an array of optical elements 4 at a later time is better reproducible and also a change of the optical elements, for example, during an experiment is faster feasible. The scale 20 is representative of all suitable means that support the positioning of the optical elements. So can the scale 20 not only glued on, but also on the pole 14 be imprinted, or a position marker can be done by means of color pencil or laser. In addition, also on several rods a scale 20 be attached to support a more precise alignment of the optical elements. The main body 6 of the embodiment of an optical test arrangement according to the invention has three substantially horizontally arranged rods 14 on. The number of rods 14 but is not limited to this number, but can be increased or decreased. However, it has a use of two to four rods 14 proved to be useful.

The cross-sectional shape of the rods 14 is in the embodiment of an optical test arrangement according to the invention for easy handling substantially circular. Other cross-sectional shapes of the rods may also be used be, so that they can be performed, for example, polygonal.

In the exemplary embodiment of an optical test arrangement according to the invention, the rods are 14 equally spaced. The arrangement of the bars 14 but is not limited to this.

Claims (9)

Optical test arrangement, with a holding part ( 2 ) for holding an optical element ( 4 ) on a base body ( 6 ), characterized in that the basic body ( 6 ) consists at least partially of ferromagnetic material and that the holding part ( 2 ) at least one holding magnet ( 16 ) having. Optical test arrangement according to claim 1, characterized in that the basic body ( 6 ) a plurality of rods ( 14 ) for arranging the holding part ( 2 ) which are spaced from each other in the radial direction of their geometric axis. Optical test arrangement according to claim 2, characterized in that the rods ( 14 ) are arranged substantially horizontally. Device according to one of the preceding claims, characterized in that the holding part ( 2 ) consists essentially of a non-ferromagnetic material. Optical test arrangement according to one of the preceding claims, characterized in that the holding part ( 2 ) Recesses ( 18 ), in which the basic body ( 6 ) engages at least partially positively. Optical test arrangement according to one of the preceding claims, characterized in that the magnet ( 16 ) consists at least partially of neodymium-iron-boron (NdFeB). Optical test arrangement according to claim 6, characterized in that the holding part ( 2 ) at least two holding magnets ( 16 ) having. Optical test arrangement according to one of the preceding claims, characterized in that the holding part ( 2 ) on the base body ( 6 ) is positioned positionable. Optical test arrangement according to one of the preceding claims, characterized in that a plurality of holding parts ( 2 ) for a plurality of optical elements ( 4 ) is provided, such that a modular system for performing optical experiments is formed.