DE2365520C3 - Device for splitting the light from a light source into at least two partial beams with a constant intensity ratio to one another - Google Patents

Description

The invention relates to a device for dividing the light from a light source into at least two partial beams with a constant intensity ratio to one another, with an element that fluoresces when irradiated by the light source, and with a focusing device that focuses the light from the light source on the element, in particular an ellipsoidal reflector, in one focal point of which the light source is arranged and in whose other focal point the element is arranged, and with devices for separating the two partial beams from the light emitted by the element

In such a known device (DT-OS 17 97 547) is the one used, with irradiation fluorescent element made of a tubular body which is filled with fluorescent material and is in the focal line of an elongated reflector with an approximately ellipsoidal cross-section, while the light source is arranged on the other focal line of the reflector that its luminous point is substantially equidistant from both ends of the element. When the Element through the light source, this emits fluorescent light at its ends in different heating directions which is used, for example, to measure the light absorption of substances.

This known device has the advantage that, under certain circumstances, light beams are generated whose intensities fluctuate relative to one another. This fluctuation in the intensity ratio The light rays also result when the light from the light source hits a spot on the side of the element falls, the intensity of which fluctuates compared to that of the light which falls on another point of the element falls, as the light transmitted along the element is weakened more when it is fed to a more distal end than when it is fed to a closer end. this has essentially its cause in the losses within the element, increasing the intensity of the out light beam exiting one end of the element

ίο can be greater than the intensity of the light beam

from the other end of the element, which is caused by the impact of light from the light source on points arises outside the middle of the long side.

The fluctuation in the intensity of the light rays emitted by the light source is inevitable given by the light source and particularly difficult to compensate when the light source is a Gas discharge tube is. In the latter, gas clouds move and the resulting density fluctuations of the gas at various points in the gas discharge tube or lamp cause the in Light emitted in one direction has a different intensity than that emitted in another direction Light.

Ej isx in contrast, the object of the invention, a To create a device with which at least two partial beams of a fluorescent light with one another constant intensity ratio can be generated.

This task is carried out with a device of the initially introduced mentioned type solved in that the element has a phosphor layer and that the expansion of the element perpendicular to the phosphor layer is so small that the light attenuation along this Direction is negligible.

Thus, the light source acts as light on an element focused, which emits fluorescent light in different directions, for example the light rays emitted on both sides perpendicular to the phosphor layer have the same intensity, while the rays of light emitted in other directions are related to each other in a certain direction Intemsity relationship. If, therefore, fluctuations in the intensity of the light source emitted When light occurs, these fluctuations are passed on to the phosphor layer and this emits fluorescent light of fluctuating intensity, but the two partial beams still have same intensity, d. H. partial beams with a constant intensity ratio are created.

The phosphor used preferably has an effective emission frequency in the range from 270 to 290 nm.

As already mentioned, an ellipsoidal reflector can serve as the focusing device, but it is It is also possible to use different types of reflectors or lens arrangements to illuminate the light from the light source focus on the element.

The invention is hereinafter based on the

5ü figures explained in more detail.

F i g. 1 shows, in a plan view, an exemplary embodiment of a device;

F i g. FIG. 2 shows a front view of the device according to FIG. 1.

F i g. 3 shows a section along the line 3-3 from FIG. 1;

F i g. 4 shows a section along the line 4-4 from FIG. 1.

FIG. 5 shows in section an exchangeable wavelength selection light filter for use in the device according to FIG. 1;

F i g. 6 shows in a diagram the light absorption of different parts of the filter.

The in Fig. 1, shown in plan view, double-beam optical system 10 has a double-beam light source 12, a first light absorption cell 14 and a second light absorption cell 16 and a first Light measuring cell 18 and a second light measuring cell 20.

The double-beam light source 12 is centered within a cuboid by means of a base part 22 Housing 24 attached and emits two light beams guided in opposite directions, wherein between a first side of the dc-ppelstrahl light source 12 and the first light measuring cell 18, a first light absorption line 14 and between the second side of the double-beam light source 12 and the second light measuring cell 20, the second light absorption cell 16 is arranged. The first side of the double beam light source 12, the first light absorption cell 14 and the first light measuring cell 18 are aligned with respect to a first light beam, and the The first light measuring cell 18 is attached to a first side of the housing 24. The second side of the double beam light source 12, the second light absorption cell 16 and the second light measuring cell 20 are related of a second light beam, and the second light measuring cell 20 is on a second side of the Case attached. To make the interior of the housing 24 accessible, the sows are at 26 and 28 hinged so that the assembly can be easily opened for repair and replacement of parts.

The double beam optical system 10 is part of a photometric device that has two mated Light rays needed. Such a photometric device can be used for localization, for example dissolved organic substances, e.g. different proteins and amino acids within one Chromatography column can be used during fractionation of the column.

In this type of device, the various organic solutes within the Column localized by their different light absorptions, which are determined by the fact that a first light beam from a double beam light source through the solute containing column and a second light beam from the double beam light source is passed through a sample of the solvent and the intensities of the two rays according to compared to the passage through the solute and through the pure solvent will.

In operation of the double-beam optical system 10, the first light beam strikes from the double-beam light source 12 after passing through the first light absorption cell 14, which enters a chromatography column to be introduced dissolved substance or a dissolved Sioff concentration to be determined ent holds, on the first light measuring cell 18, and the second light beam from the double-beam light source 12 arrives after passing through the second light absorption cell 16, in which only the solvent is is located on the second light measuring cell 20. The first and the second light measuring cell generate in dependence from the incident light a first and a second electrical signal, and these signals become for comparing the light absorption properties of the substances in the first and second light absorption cells compared to each other.

The double beam light source 12 includes a lamp 30, an element 32 and an ellipsoidal one Reflector 34, which has a first sector 36 and a second sector 38.

In order to provide light for the first and second uniform light beams, the lamp 30 is on Base part 22 attached, which serves as a receptacle for the electrical connections and is centered within the Double-beam light source 12 is arranged. The lamp 30 serves as the primary light source and can be of various kinds to deliver the light of the desired frequency.

The lamp 30 consists of a low pressure mercury vapor lamp that emits ultraviolet light, which is particularly suitable for some photometric devices, such as measuring or comparing the optical density or the light absorption of certain solutions containing organic substances, for example Contain protein, amino acid or the like.

The ellipsoidal beam is used to bundle the light from the lamp 30 into two narrowly directed beams Reflector 34, which is made up of two sectors 36 and 38 which are spaced apart in the middle and have their concave sides facing each other. As best seen in FIG. 4 to be recognized is, the brightness point of the lamp 30 is at the first focal point of the ellipsoidal Reflector 34 to focus the light on the second focal point in which the element 32 is located, wherein the two sectors 36 and 38 have two light beam openings, which with each other and align with the second focal point, so that the oppositely directed, proportional in their intensity Light rays can emerge from the ellipsoidal reflector. One of the light beam openings 40 is shown in FIG. 4 shown.

Since the light beam openings are aligned with one another and with the second focal point of the ellipsoidal reflector 34, the light is not guided directly in a straight line from one sector through the element 32 and the opening in the other sector into a light absorption cell without fluorescent light being generated because it there is no such path for the light, but rather all straight light paths from one reflector through the opening of the other reflector are at an angle to the first and second light beams. Furthermore, the light beam openings can each be closed by a lens which is aligned with the element 32 so that it intensifies the intensity of the light transmitted to the light absorption cell and reduces the intensity differences between the first and second beams, in that it preferably transmits light from the area, who is at the focal point of be ^; the lenses.

Essentially, the ellipsoidal reflector has two functions.

1. It focuses light from the lamp onto element 32.

2. It guides two oppositely directed light beams from the element 32 to the light absorption cells 14 and 15, the light rays not containing light coming through directly from a reflector the element and is guided in a straight line along the light beam. That along the straight line produced led light under certain circumstances

temporally changing irregularities in the intensity of the two opposing each other Rays of light. While ellipsoidal reflectors work well for these purposes, so can other types of reflectors and lenses can be used for the same output. So the intensities the two oppositely directed light rays have a constant ratio, even if the intensity of the light emitted by lamp 30 changes over a period of time from lamp point to lamp point and changes from direction to direction, the element 32 contains a clear Phosphor layer 42 (Fig. 3) attached to one of the focal points of the ellipsoidal reflector 34 is, while the luminous point of the lamp 30 is in the other focal point. The level, light-emitting one Area is with respect to the two light beam openings in the sections 36 and 38 of the ellipsoidal Reflector 34 aligned so that a straight line through the two light beam openings is perpendicular runs to the level, light-emitting area.

The phosphor layer 42 when irradiated gives fluorescent light proportionally into a number of rays so that the intensities of the light in the emitted light rays always have the same ratio to have. In the embodiment described, two light beams are in opposite directions radiated through light beam openings, and in this embodiment are for focusing the Light from the light emitting element to rays no lenses required because the rays are in opposite directions Directions through the light beam openings, creating possible light noise that is created by poorly focussing lenses that make the rays of light too large To areas.

Since the light is emitted in two opposite directions, the light emitting element should have its smallest dimension parallel to the rays of light and this dimension should be sufficient be small in order to cause significant weakening of the light passing through the element avoid.

Generally the element is less than 1 mm thick. The performance is usually improved if the element is translucent so that it emits the same radiation in both directions regardless of which sector of the ellipsoidal reflector the incident light is incident on

One way of building a double-beam optical system that can be easily adapted to different applications is to simply choose different frequencies for the light beams. In order to achieve this, easily exchangeable elements (not shown) can be used, each of which has different phosphors or fluorescent materials which emit light of different frequencies and which are used in the optical double-beam system for the corresponding application. Furthermore, the element can easily be adjusted in the ellipsoidal reflector and can carry a number of different phosphor layers at different points which emit light of different frequencies. The position of the element is adjusted to one of the selected phosphors so that it is in the focal point of the eUipsoidformigea ffrflrfrtnrs , at which the frequency of the light to be emitted into the rays can be selected. Of course, light filters will be used in both cases according to the desired frequencies.
Particularly suitable fluorescent materials for the element 32 are microcrystalline, cerium-activated lanthanum fluoride according to US Pat. No. 2,450,548 or calcium silicate / lead-activated phosphorus.

As most clearly in F ^r i g. 2 can be seen,

ίο have the light absorption cells 14 and 16, respectively a rectangular housing 44 or 46, the transparent, tubular, substantially Z-shaped Enclosing passages. Each of these passages contains: (1) a vertical inlet channel 48 or 50, that from a point below the double elbow light source 12 goes out and in a direction parallel to the element 32 to a point opposite the light transmission opening runs in sector 36 or 38; (2) a Lichtarbsorbicrenden channel 52 or 54, the is in alignment with the corresponding light beam aperture and the first and second light beams; (3) an outlet channel 56 or 58 which extends perpendicularly from a point opposite the corresponding light beam opening and extends parallel to element 32 to a point above the double beam light source.

So that the first and the second light beam of the double-beam light source 12 via the light beam openings can pass through the light absorbing channels 52 and 54, the channel 52 has at one Side a transparent window 60 and on the other side a transparent window 62, which with respect to the Light beam openings are aligned so that light can pass through housing 44. the Channel 54 has a transparent window 64 on one side and a transparent window on the other side 66 which are aligned with the light beam openings to allow light to pass through the housing 46. One end of each channel 52 and 54 and the transparent windows 62 and 64 are located near different ones Light beam openings.

In order to measure the light absorption or emission of the fluid in the light absorption cells 14 and 16, the first and second light measuring cells 18 and 20 are supplied with the first and the second light beam after they pass the absorption channels 52 and 54 of the first and second light absorption cell 14, respectively , Have gone through 16. Each light measuring cell 18, 20 includes a filter 68,70 known type and a photocell 72, 74 which are aligned with the first and second light beam so that they pass through the filter 68,70 before the photocell 72,74 irritate. The photocells 72 and 74 are part of a circuit for comparing the incident light and provide an indication of the relative optical density of the fluid in the light absorption cells 14 and 16, so as in a known manner a solute in the flowing through one of the light absorption cells

Locate or identify fluid.

5 shows a section through a filter 68, since: will be described in detail later and has substantially the same structure as the filter 70, see FIG that no separate description is required for this is borrowed. The filter essentially contains one grain bination of filter elements, a light filter < Liquid and a fluorescent element. A filter element and the light-filtering liquid transfer]

on the fluorescent element light of a wavelength that is used to measure the absorption of the substance in a light-absorbing cell was used, and block other wavelengths, including that of the Fluorescent element emitted wavelength. The fluorescent element reflects depending on one wavelength light of another wavelength to which the photocell responds. A third Filter element is used to suppress unwanted Wavelengths that have passed through one filter element and the light-filtering liquid, and transmits the wavelength emitted by the fluorescent element. This arrangement creates a particularly good selection of one wavelength is achieved.

The filter 68 includes a substantially cylindrical, tubular housing 76 with at one end provided disc-shaped front surface 78 in which a disc-shaped opening is centrally located, while the opposite end of the housing for receiving the filter and the fluorescent elements is open and the inner wall has a thread. To make it easy to attach the To enable tubular housing 76 on the first light measuring cell 18 is the cylindrical surface provided at one end with a shoulder near the front surface 78 and has an annular groove 80 near the other end so that the housing 76 into a cylindrical opening in the first light measuring cell 18 can be used and is held there by a projection in the annular groove 80, while the Shoulder carries the surface 78 outside the cylindrical opening.

In the tubular housing 76 there are two filter elements 82 and 84 and a fluorescent element 86, all of which have a region aligned with the opening in the front surface 78 in order to receive light from the first light beam. Furthermore, a light filtering liquid is present in the filter 68 at 88 so that the light beam passes through it before it reaches the photocell 72 (FIG. T) .

To fix the filter elements 82 and 84, the fluorescent element 86 and the light filtering Liquid at 88, the filter 68 contains a transparent quartz window 90 which defines the disk-shaped central opening closes in the front surface 78. An O-ring 92 presses against the transparent glass window 9 (i, so that a liquid-tight seal is formed. A cylindrical punch 94 presses the filter element 82 against the other side of the O-ring 92, around a liquid-tight area for the light-filtering Fluid at 88 and a retaining ring 96 is threadedly engaged with the internal threads of the tubular housing 76, thus holding the spacer on the filter element 82 and supporting the Filter element 84 and fluorescent element 86.

The filter elements 82 and 84, the fluorescent element 86 and the light filtering liquid at 88 become chosen so that a response to light frequencies of the first light beam is avoided, which do not lie in the range of a predetermined spectral line, which is important for the measurement of the light absorption or transmission property of a solute in the light absorption cell is appropriate and enables the delivery of light in a wavelength to which the photocell is particularly responsive, wherein the light has an intensity proportional to the intensity of the light of the selected spectral line.

The choice can depend on the spectral line to be used in the specific case and the type of photosensitive devices used to measure the emitted by the fluorescent element Light struck from a large number of filter elements, liquid wedges and fluorescent elements will.

With a filter 68 that is particularly useful for locating or identifying some organic matter

ίο is suitable, the filter element 84 carried over from the fluorescent element 86 generated green, visible light, the filter element 82 being made of purple-red silicon dioxide that emits light in the ultra-violet range down to a wavelength of 240 nm and absorbs green visible light. The filter element 84 absorbs ultraviolet light and leaves only gives or gives the green light. The element 86 consists of a fluorescent phosphor that produces green fluorescent light when it is used with ultra-

ao violet light with a wavelength of slightly more than 280 mn and less than 285 or 290 mn irradiated will. Together, the filter elements 82 and 84 and the fluorescent element 86 produce in dependence from light having a wavelength in the range of 240 to

»5 290 nm green visible light.

In order to generate light of a wavelength of essentially 280 nm from the light emitted by the Element 32 that activated microcrystalline, cerium-activated lanthanum fluoride or calcium-lithium-silicate / lead Contains phosphorus, a light-filtering liquid is used at 88, which Transmits light with a wavelength of more than 280 nm and absorbs light with a wavelength of 254 nm. On the other hand, to obtain light of a wavelength of 254 nm from the same light source, a light-filtering liquid is inserted at 88, which transmits light of 254 nm and fluorescent light absorbed in the wavelength range from 270 to 300 nm.

Although solids with the necessary filter properties to generate the frequency response Are rare, high filterade liquids are available without more available. 6 shows in a diagram a first curve 98 and a second curve 100, with the light absorption and on the abscissa the wavelength of the light that is absorbed by two liquids is plotted. The first curve 98 denotes a spruce filtering liquid which selectively absorbs light of a wavelength of 254 nm transmits and light with wavelengths from 270 nm to 290 nm is absorbed while the curve 100 denotes a light-filtering liquid that selectively absorbs light of wavelengths between 270 nm and 290 nm and transmits light of one wavelength

■ 55 absorbed by 254 nm. A diluted solution before Carbon disulfide has an absorption spectrum similar to curve 98, while a benzene solution in a transparent solvent has properties similar to the IOC curve, although different « other features occur in their characteristic curve which are not shown in curve 100 and are not shown in FIG are not essential either. Before the optical (double-beam system 10 is put into operation the filters 68 and 70 are prepared and inserted into the first and second light measuring cells 18, 20 (FIG. 2) set. In general, the filters are manufactured to match the type or types of dissolved organics niche substances that are in a chro

matography column located through the first light absorption cell 44 flows. Of course, the filters are used for other optical purposes System selected according to other criteria.

To display the solute, which absorbs light at a wavelength of 254 nm, the filter is used 68 according to FIG. 5, with 88 as a liquid wedge, for example, a dilute solution of Carbon disulfide is inserted. To indicate a solute, the light in the wave length range absorbed between 270 nm and 290 nm, the filter is constructed in the same way, however at 88 the liquid used was a solution of benzene in a transparent solvent

In operation of the double-beam optical system 10 becomes a solute-containing solvent through the light absorption cell 14 and pure Solvent is pumped through the light absorption cell 16. While the solute passes through the light absorbing channel 52 of the first light absorbing cell 14 flows, pure solvent flows through the light-absorbing channel 58 of the second light absorption cell 16. The first light beam passes through the light absorption channel 52 into the first light cell 18 and the second light beam through the light-absorbing Cannula 58 in the second Lichtmeßzclle 20, wherein the two light beams to each other have proportional light intensities. The first light measuring cell 18 and the second light measuring cell 20 compare the light intensity of the first and second light beams to get information about the

α ο through the most light-absorbing channel 52 to achieve flowing substance.

After the light of the first and second light beams through the first and second light absorption cells 14. 16 has passed through, it arrives at the first and second Lichtmeßzellc 18, 20, where it is Filier that select a single spectral line to pass through to the photocell, which is dependent on the wedge Generates signals from the amount of light absorbed by the solute and the solvent The filters are selected according to the specific application of the double-beam optical system as described above.

1 sheet of drawings

Claims (2)

Patent claims: 1. Device for splitting the light from a light source into at least two partial beams with constant intensity ratio to one another, with an element which, when irradiated by the Light source fluoresces, as well as with one that focuses the light from the light source on the element Focusing device, in particular an ellipsoidal reflector, in one of its focal points the light source and in whose other focal point the element is arranged, and with Means for separating the two partial beams from the beam emitted by the element Light, characterized in that the element (32) has a phosphor layer (42) and that the extent of the element (32) perpendicular to the phosphor layer (42) is so small is that the attenuation of light along this direction is negligible. 2. Apparatus according to claim 1, characterized in that the phosphorus is an effective Has emission frequency in the range of 270 to 290 nm.