DE3133828A1 - DEVICE FOR FORMING AN OPTICAL GAP - Google Patents

Description

description Device for forming an optical gap

The invention relates generally to a device for forming an optical gap, in particular for a spectrophotometer, and in particular to a device with two overlapping gap elements.
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Many modern analysis devices use light radiation as a means of determining the elementary properties of objects and substances. So that information about these properties can be obtained, the light radiation _r containing this information must be separated from the light radiation that is not of interest. These measurement methods generally work with the isolation of a relatively narrow spectral band which is contained in the relatively broad spectral band of conventional light sources. A mechanism for performing this isolation, that is, the separation of the spectral band of interest, is usually referred to as a "monochromator". Conventional monochromators contain an optical entrance slit or an entrance opening or an optical exit slit or a. Outlet opening.

The width of the entrance gap defines the area of the Radiation source that is used by the monochromator, while the exit slit defines the spectral band that is fed to a detector.

The relative width of the column are usually different Control cam mechanisms set. These conventional mechanisms are used to form optical gaps generally a stationary, rigid, central element with knife-like optical edges on each side, as well movable side elements for adjusting the width of the slots.

A major disadvantage of such a mechanism, however, is the required accuracy and freedom from errors Control mechanism. For example, the one from the control cam

sheets passed through extremely critical; in addition, the length of the associated control cam arms must be precisely defined and maintained. Because of the complexity of the components used, such mechanisms are generally very large
sensitive, ie prone to failure and also costly to ■ manufacture.

In light of the above, it is therefore a
The aim of the present invention is to propose a device for forming an optical gap which is less complex but nevertheless very precise. This is achieved by a device that has two optical slit elements
that can be moved with respect to each other.

The invention will be described in the following on the basis of exemplary embodiments with reference to the enclosed, .schematic, not to scale drawings explained in more detail. Show it.

Fig. 1 is a front view, partly in section, of a
Device for forming an optical gap according to the present invention,

Fig. 2 shows a cross section through the device according to

Fig. T along the line 2-2,
25th

Fig. 3 shows a representation of the drive device for
the adjustment of the gap width in the device for forming a gap after
present invention _r and
30th

4 shows a cross section through the drive device
for adjusting the gap according to FIG. 3
along line 4-4.

As can be seen in Figures T and 2, an all-

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Commonly indicated by the reference numeral 10 device for forming an optical gap according to the basic principle of the present invention two gap elements 12 and 14, upper and lower edging elements 16 and 18, respectively, lateral fastening elements 20 and 22, a drive mechanism 24 and a device 26 for positional prestressing of the gap elements.

The two gap elements 12 and 14 have a rectangular shape.

Each gap element 12 or 14 contains a rectangular first opening 28 or 30 and a rectangular second opening 32 or 34. For reasons to be explained, the rectangles that form the openings 28, 30, 32 and 34 according to a preferred embodiment, optical, knife-like edges. Each gap element 12 or 14 can be one Contain projection 36 or 38, which extends from a first surface 40 or 42 (see Fig. 1) j as in the To be explained in detail, these projections can be used as position indicators or to the exit to prevent stray light from an entrance slit. The gap elements 12 and 14 are according to a preferred Embodiment made of plastic and can be made by conventional molding techniques for plastics, for example Casting, being manufactured, The column members 12 and 14 are arranged close to one another back-to-back. the Gap members 12 and 14 are held in this position by the upper and lower skirt members 16 and 18, respectively. The edging elements 16 or 18 hold the gap elements 12 and 14 together, but allow a lateral Displacement with respect to one another within the limits set by the side fasteners 20 and 22 can be specified.

As can be seen in Figures 1 and 2, the lower enclosure element 18 is secured by screws, rivets or the like Fasteners attached to a base 44. Which since-

Union fasteners 20 and 22 are also rigid attached to the base 44 and protruding from the base 44. The gap elements 12 and 14 are disposed in the lower enclosure element 18 and are defined therein by the upper enclosure element 16. held in place by collar 46, which are attached over the side fasteners 20 and 22.

Each gap element 12 or 14 includes a lateral projection 48 or 50, which protrudes from its ends and as Contact surface for. the drive mechanism is used. The opposite Ends extend beyond the lateral fastening elements .22 and touch the prestressing clamps. direction 26-. ' According to a preferred embodiment, ' this pretensioning device 26 is a spring clip, which has approximately the shape of an S? one end 52 this Spring clips are between the lower bezel members 18 and the base 44 attached. The clip has such a shape that there is contact between the other end 54 and at least one of the gap elements 12 or 14 is produced.

The displacement of the gap elements 12 and 14 is through the Drive mechanism 24 controlled, which contains a contact rod 56 for the gap elements, which are rigidly attached to a movable Shaft 58 attached to an arm 60 attached and movable with shaft 58. The location of the drive arm 60 is influenced by a drive pin 62 which is driven by a motor 64.

The drive mechanism 24 is set according to a preferred embodiment so that the following basic relationship results: If the contact rod 56 for the gap elements runs perpendicular to the plane of the gap elements 12 and 14, they overlap the gap elements 12 and 14 and thus the first and second openings 28 and 30 or 32 and 34 in each case so

that half of the entire gap opening is available for the passage of the light radiation.

The contact rod 56 is in a conventional manner on the rotatable Shaft 58 attached, which in this embodiment extends through the base 44 and beyond the base 44 ■ stretches. The shaft 58 is supported by a V-shaped bush 66 surrounded at each end by an opening 68 in the base 44. the V-shaped bushing 66A at the top of shaft 58 is through the contact rod 56 held in place. The bushing 66B at the lower end of the shaft 58 is supported by a spacer washer 70 and a spring clip 72 held in place with respect to the shaft 58. ■

As can be seen in FIGS. 3 and 4, the drive arm 60 is rigidly attached to the rotatable shaft 58 and extends in this embodiment in a direction that is perpendicular to the axis of the shaft 58. The arm 60 is for example biased by a spring 74 against a fixed reference point 76 and rests on the drive pin 62,.

so that it is displaced by this one. The reference point 76 can be converted into a display for the position of the gap elements 12 and 14 will"

As can be seen in FIG. 4, runs in this embodiment the drive pin 62 is perpendicular to the drive arm 60 and faces at the end that is spaced from the drive arm 60 is located, a shoulder 78 with an external thread. The shoulder 78 of the drive pin 62 runs in an internal thread of a shaft 80 which is rigidly attached to the drive shaft 82 of the control motor 64 and with the shaft 82 moves. In a practical embodiment, the control motor 64 is a step (switch) motor of the type with ninety-six (96) equal steps or increments

per rotation. '

In a preferred embodiment, each has an opening 28, 30, 32 or 34 about 3mm wide and one Height of approximately 12.7 mm. In addition, the inside or External threads of the shaft 80 and the shoulder 38, respectively 10/32. Such threading results in approximately 0.76 mm of lateral movement of the drive pin for each complete Revolution of the drive shaft 82 of the stepping motor 6.4. Furthermore, in this example, the effective The length of the drive arm 60 is selected to be approximately 8.1 cm. Using elementary math and trigonometric relationships it can be shown that the lateral movement of each gap element 12 and 14 for each revolution of the motor 64 is approximately 76 µm. As the gap elements 12 and 14 in the same way to the rotary movement of. Contact rod 56 respond, is the effective total movement of gap elements 12 and 14 approximately 152 µm per revolution the drive shaft 82 of the motor 64. This leads to a movement on the order of about 1.8 μια per Step of stepper motor 64.

The error in correlating each step of the motor to the linear distance traveled by gap elements 12 and 14 is on the order of about 1%. This error is caused by the cosine effect between the linear movement of the drive pin and the angular rotation of the rotating shaft 58 overlapped and therefore closed would be approximately _ + 6 °, and since the cos 6 ° = 0 _r 995, the error introduced thereby becomes smaller than 1%.

It can be seen that the location of both drive arm 60 and shaft 80 can be readily positioned by conventional techniques can be continuously monitored. .

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The above-described device 10 for forming an optical gap thus provides a very precise mechanism represents, as the inlet or outlet opening of a monochromator can be used. In addition, the device 10 can be easily and thus inexpensively without the usual, complex control cam mechanism.

Claims (9)

GRUNECKER, KINKELDEY, SJ & C ^ MÄlft Ä PARTNER PATENT LAWYERS EUROPfcAN T ATTORNtVS A. GRÜNECKER. Ofwhere OR H. KINKELDEY. opling DR W. STOCKMAIR. ο η. ΐΝε., * ε DR K SCHUMANN. t> «n. ws P. H JAKOB, or. in O DR G BEZOLD. οιρι_ ο * μ W. MEISTER, on. in O H. HILGERS. D.5 - INO DR H. MEYER-PLATH. opc-ing 8000 MUNICH 22 MAXIMIUANSTRASSe 43 THE PERKHT-BUCKET COEPORilTION Main Avenue ITorwalk, Connecticut 06856 United States PH 16 54-6-40 / dg August 27, 1981 Device for forming an optical gap Claims y device for forming an optical gap 'for a spectral photometer, characterized by a first gap element (12) with several openings (28, 32) which are arranged at a distance from one another at predetermined centers are, through a second gap element (14) with a plurality of openings (30, 34) which are predetermined at a distance from one another Centers are arranged, wherein the second gap element (14) in the vicinity of the first gap element (12) and in relation to the first gap element (12) is movable, and by means for displacing the first and second gap elements (12, 14) with respect to one another. TSLKPON (ΟΒβ) β9βββ3 telex OD-aonoo ΜΟΝΑΡΛΤ 2. Apparatus according to claim 1, characterized in that the displacement means the extent of the overlap of the corresponding openings changes. 3. Device according to one of claims 1 or 2, characterized in that the number of openings (28, 32? 30, 34) in the two gap elements (12, 14) there is two » 4. Device according to at least one of claims .1 to 3, characterized in that the gap elements (12, 14) from molded, in particular molded plastic are made. ■ ".- · .- 5. Device according to at least one of claims 1 to 4, characterized in that the gap elements (12, 14) laterally are displaceable in relation to one another. 6. Device according to at least one of claims 1 to 4, characterized in that the relative movement of the gap elements (12, 14) perpendicular to the largest dimension of the Rectangles are made. ' 7. Device according to at least one of claims 1 to 6, characterized in that the displacement device. has a rotary drive and a device for converting a rotation into a linear movement. 8. The device according to at least one of claims 1 to Ί, characterized in that the drive device is a step (switching) motor. 9. Device according to at least one of claims 1 to 8, characterized in that the movement of the drive means is in relation to the frequency spectrum of interest of the light beam.