EP2217912A2

EP2217912A2 - Atr probe

Info

Publication number: EP2217912A2
Application number: EP08856785A
Authority: EP
Inventors: Hakon Mikkelsen; Andreas MÜLLER; Patric Henzi
Original assignee: Endress and Hauser Conducta Gesellschaft fuer Mess und Regeltechnik mbH and Co KG
Current assignee: Endress and Hauser Conducta GmbH and Co KG
Priority date: 2007-12-04
Filing date: 2008-12-02
Publication date: 2010-08-18
Also published as: DE102007058611A1; CN101889195B; WO2009071557A2; WO2009071557A3; CN101889195A; US20100303413A1

Abstract

An ATR probe comprises a monolithic ATR body (2) comprising a surface segment (24) that can be impacted by a medium; a fiber optic transmitter arrangement (1) for irradiating non-collimated light into the ATR body (2); a fiber optic receiving arrangement for receiving the irradiated light after passing through the ATR body, wherein the light passing through the ATR body comprises at least two total reflections on a surface (24) contacting the media, characterized in that the surface area of the fiber optic receiving arrangement for receiving the light exiting the ATR body is greater than the surface area of the fiber optic transmitting arrangement for irradiating the light into the ATR body. The ATR body (2) preferably comprises at least one segment having a conical or truncated conical surface (24), and the truncated conical surface can be impacted at least partially by the medium.

Description

ATR probe

The present invention relates to an ATR probe for detecting an optical property of a medium comprising a monolithic ATR body having at least one surface portion to be acted upon by the medium, and a transmission light guide for irradiating non-collimated light into the ATR body; and a receiving optical fiber array for receiving the irradiated light after passing through the ATR body.

Such an ATR probe is disclosed, for example, in the published patent application DE 10 2006 036 409 A1. This probe relies on a single dead-fly reflection at the media-contacting interface of an ATR body and has a very simple construction. However, the sensitivity of this probe can be improved.

US2001 / 0030288 A1 discloses ATR probes with Zyiinderiinsen between transmitter and ATR body and between the ATR body and a diode line detector.

DE 198 56 591 A1 discloses an ATR probe with two separate light channels.

US 5 991 029 A discloses an ATR probe with multiple reflections on media-contacting surfaces of an ATR body, the facet having the smallest reflection angle! is mirrored to avoid a coupling of the light there.

US 5 773 825 A discloses an ATR probe with a prism for coupling in the light and, in addition, a thin optical disk. US 5,703,366 A similarly discloses a multi-part ATR body having a first crystal body and a crystal disk and an optically transmissive interface therebetween.

US 4 826 313 A discloses an ATR probe with optical lenses for the collimation of divergent beams.

EP 0 206 433 A2 discloses an ATR probe with at least two media-contacting surfaces.

The probes mentioned are visually or constructively very complex to implement and thus lead to increased production costs, especially when the probe is to be integrated into a cylindrical probe shaft with a small diameter.

It is therefore the object of the present invention to provide an ATR probe, in particular for process applications, which overcomes the disadvantages of the prior art, in particular has an improved signal to noise ratio, and is suitable for simple mass production. Preferably, the probe is chemically resistant to solvents, bases and acids as well as abrasive media.

The object is achieved by the ATR probe according to the independent patent claim 1.

The ATR probe according to the invention for detecting an optical property of a medium comprises: a monolithic ATR body which has at least one surface portion which can be acted upon by the medium; a transmission picker assembly for injecting non-collimated light into the ATR body; a receiving optical fiber arrangement for receiving the irradiated light after passage through the ATR body, wherein the passage of the light through the ATR body comprises at least two total reflections at a media-contacting surface of the ATR body; characterized in that the effective area of the receiver stirrer assembly for receiving the light emerging from the ATR body is a factor F greater than the effective area of the transmission optical fiber array for irradiating the light into the ATR body, where F is at least 1 at least 4/3 and more preferably at least 3/2 and more preferably at least 2, and wherein the transmitting light conductor arrangement comprises at least two transmitting optical fibers and the receiving optical fiber arrangement comprises at least three Empfangsüchtleiter.

According to a presently preferred embodiment of the invention, the ATR body comprises at least one section with a conical or frustoconical surface, and the frusto-conical surface is at least partially acted upon by the medium.

The section with the conical or frustoconical surface, for example, a half opening angle! of not less than 40 ° and not more than 50 °, preferably not less than 43 ° and not more than 47 °, especially 45 °. Half the opening angle denotes the angle between the axis of symmetry of the cone and the lateral surface of the cone.

In a development of this embodiment of the invention, the ATR body may comprise a cylindrical portion which adjoins the base of the conical or frustoconical portion. For example, the cylindrical portion may have a height that is not more than 1/2, preferably not more than 1/3, more preferably not more than 1/4 of the radius of the base of the conical or frusto-conical portion. In an additional development of this embodiment of the invention, the ATR body has a rounded tip, which adjoins the kegeistumpfförmigen section. For example, the rounded tip may have a radius that is not more than 1/6, preferably not more than 1/7, more preferably not more than 1/8, of the radius of the base of the frusto-conical portion.

In a further development of the invention, the ATR probe further comprises a Feruile, by means of which the SendÜtleiter and the receiving light guides are positioned, and a spacer body is clamped between the Ferulle and the ATR body, wherein the spacer body may comprise, for example, a coupling ring.

In a presently preferred embodiment of the invention, the transmitting light conductor arrangement comprises a plurality of transmitting light guides whose end face centers are arranged on a circular arc according to an embodiment of the invention, wherein the circular arc preferably has the cone axis as the center.

The end faces of the transmission optical fibers can be arranged immediately adjacent to each other according to an embodiment of the invention. By this it is meant that there are no receiving front ends between the immediately adjacent transmitting optical fiber end faces. However, this does not exclude that the transmitting and receiving light guides are taken in Ferullen and thus the optical fibers including their faces by Ferullenmaterial separated or spaced from each other. In one embodiment of the invention the Empfangslächtieiteranordnung comprises a plurality of Empfangsiichtieiter whose end faces are arranged in a region whose shortest closed boundary line encloses an image of the end faces of the transmitting light conductor, which is formed by a rotation of the end faces of the transmitting light guide about the cone axis by an angle of 180 °.

The end faces of the receiving light emitters can cover, for example, at least 20%, preferably at least 35% and particularly preferably at least 50% of the area of the area whose shortest closed bounding line encloses an image of the end faces of the transmission light conductors, which differs by rotation

End faces of the transmitting light conductor around the cone axis by an angle of 180 ° arises.

In another embodiment of the invention, the receiving optical fiber assembly, a plurality of receiving optical fibers include their end faces are arranged in a region whose shortest closed boundary line encloses a simulated image of the end faces of the Sendelichtieiter, which through the beam path of the irradiated by the transmitting light conductors in the ATR body light Assumption of a numerical aperture in air of not less than 0.1 and not more than 0.3 after two total reflections at the conical surface of the ATR body and exit from the ATR body in the plane of the end face of the receiving optical fiber is formed. The simulated image can be made, for example assuming a numerical aperture in air of not more than 0.15, wherein the end faces of the receiving light guide, for example, at least 20%, preferably at least 35% and more preferably at least 50% of the area of the area cover its shortest closed Begrenzungslinäe the said simulated image of the end faces of the transmission optical conductor encloses.

In one embodiment of the invention, the ATR probe comprises a ferrule, by means of which the transmitting optical fibers and the receiving optical fibers are positioned, wherein the optical axis of the transmitting optical fiber or the receiving optical fiber in the ferrule extends substantially parallel to the axis of the conical or kegeistumpfförmigen portion.

In another embodiment of the invention, the ATR probe comprises a ferrule, by means of which the transmitting optical fibers and the Empfangslichtieiter are positioned, wherein the optical axes of the Sendelichtieiter or the EmpfangslichtSeiter in the Ferulle each with respect to the axis of the cone or keirustumpfförmigen section to the axis of the cone are tilted so that the k vector of the light irradiated along the optical axis of a transmission optical fiber in the ATR body has a radially inwardly directed component and the k vector of light received along the optical axis of a receiving optical fiber in the ATR body having a radially outwardly directed component.

If the optical fibers comprise fibers, the end faces of the fibers are preferably perpendicular to the optical axis of the fiber.

In a further development of this embodiment of the invention, the optical axes of the transmitting light guide or the receiving light guide in the

Ferulle one to the axis of the cone or kegeistumpfförmigen

Define the parallel plane section which one with respect to a

Central plane through the axis of the cone or keirustumpfförmigen

Section and the intersection of the optical axis of the respective light guide is defined with the end face, is twisted, so that the k-

Vector of along the optical axis of the transmission optical fiber irradiated light in the ATR body has a tangential component or the k vector of the light received along the optical axis of a received light guide in the ATR body has a tangential component,

With the mentioned configuration, the area centroid or the area of maximum intensity of the light reflected twice by the ATR body, which emanates from a transmission light guide, can firstly be displaced radially inwards in the plane of the end faces of the light guides. Secondly, the area centroid or the area of maximum intensity of the light reflected twice by the ATR body, which emanates from a transmitting optical waveguide, is also twisted in the plane of the end faces of the optical waveguides with respect to a point reflection of the receiving fiber on the cone axis. Insofar as it is advantageous, at least in the area centroid mentioned or in the region of maximum intensity or at least as close to it to position a receive light guide, the discussed displacement and twisting of this point enables the position to remain free with respect to one transmit light guide for another transmit light guide. For example, even-numbered symmetries of transmission fiber arrays are possible, in particular quadrivalent or hexagonal symmetries, with hexagonal symmetries allowing the largest packing density of optical fibers.

In one development of the invention, end faces of receiving light guides may be arranged between the end faces of transmitting light conductors. This means that the connecting line between points of two adjacent transmitting optical fiber end faces intersects a receiving optical fiber end face. In a further development of the invention, the end faces of the transmitting light conductors lie on a circle, wherein the centers of the faces of at least 50% ailer Empfanglichtleiter, preferably at least 75% of all Empfangslichtieäter, in particular all received light guide within this circle.

According to another aspect of the invention, the transmission optical fiber assembly comprises at least one transmission optical fiber, wherein the light emitted by a transmission optical fiber is detected after passing through the ATR body of two or more receiving optical fibers.

In a further development of the invention, the transmitting light guides and the receiving light guides each have an end face at the distance to the ATR body at least λ _o / 2 in air, for example 5 microns preferably at least 100 microns and more preferably at least 200 microns. The value λ ₀ denotes the largest wavelength that is taken into account in the evaluation of the ATR signal. This distance prevents pressure- or temperature-dependent interference in the air gap between the optical fibers (in particular optical fibers) and the ATR body from leading to intensity modulations of the ATR signal. A Fabry-Perot effect is thus largely eliminated. On the other hand, it is advantageous if the end faces each have a distance of not more than a diameter of the respective light guide to the ATR body. In this way, the expansion of the emitted light in the air gap is limited.

In a presently preferred embodiment of the invention, the ATR probe comprises a ferrule, by means of which the transmitting optical fibers and the receiving optical fibers are positioned, and a housing having a mediate-side opening and a sealing ring, which is arranged around the medial-side opening, wherein the ATR body to the Sealing ring rests and is axially elastically clamped between the sealing ring and the ferrule. The elasticity can be given in particular by an elastic sealing ring, or by an elastic body, which is arranged in the clamping path, ie the sequence of components via which the clamping forces are transmitted to the rear side facing away from the ATR body of the Ferulle at any position.

The transmitting optical fiber array and the receiving optical fiber array are preferably positioned and aligned so that light impinging on surface portions of the ATR body against which the sealing ring abuts is less than 5%, preferably less than 2%, and more preferably less than 1%, to the signal ATR probe contributes.

The ATR body may in principle comprise any materials which are transparent in the required spectral range and have a sufficiently high refractive index in order to enable total reflection at interfaces with the media to be investigated, in particular aqueous media. Furthermore, chemical and abrasive resistance of

Advantage. In principle, in particular ZnSe, diamond, or sapphire are suitable, or Ge with a DLC coating, wherein DLC stands for a diamond-like carbon coating (according to the English

"Diamond Like Carbon").

The transmitting optical fibers or the receiving optical fibers may preferably comprise optical fibers which preferably comprise silver halide, quartz, a polymer or chalcogenide which has sufficient transmission in the wavelength range of the light used.

Between the light guides and the ATR body, according to a presently preferred embodiment of the invention, any immersion media is used like oils or glue dispensed. Thus, there remains an air gap, but over the control of the distances between the light guides and the ATR body does not lead to intensity modulation due to interference. More preferably, immersion media are dispensed with in the entire beam path of the probe, ie even when coupling a source or a receiver to the light guides.

Alternatively, the transmission fibers and the receiving optical fibers may comprise optical waveguides having an inner coating containing, for example, silver halide or Au.

The invention will now be explained with reference to an embodiment shown in FIGS.

It shows:

Fig. 1: A schematic diagram of an ATR probe according to the invention with a conical ATR body;

FIG. 2: a sectional view of a probe head of an ATR probe according to the invention with conical ATR body; FIG.

3 shows a sectional drawing through a conical ATR body for the beam calculation of an ATR probe with conical ATR body;

4 shows a plan view of an end face of a fiber reticulum for positioning under a conical ATR body according to an embodiment of the invention; Fig. 5: A projection of the end faces of paraxial

Transmittance light guide on the face of the Faserferülie with a numerical aperture of the optical fibers of 0.25 in air, which corresponds to half the opening angle of the emitted light beams of the light guide of 6 ° in the material of the ATR body.

Fig. 6: A recorded with an ATR probe according to the invention spectrum of iso-propanol; and

FIG. 7 a: a projection of the end faces of transmitting light guides inclined and twisted with respect to the cone axis according to another embodiment of the invention onto the end face of the fiber web with a half opening angle of the 1 ° light fluence emitted by the light guides in the material of the ATR body; FIG.

Fig. 7b: A projection of the end faces of tilted and twisted with respect to the cone axis transmitting optical fibers according to another embodiment of the invention on the end face of the Faserferülie with half an opening angle emitted by the light guides Eiskegeis of 6 ° in the material of the ATR body. and

Fig. 7c: A resulting from the projections positioning of

Receiving fiber optics for the arrangement of the Sendlichtlieter from Fign. 7a and 7b. Fig. 1 shows the principle of an ATR probe according to the invention. Light is irradiated via a transmitting optical fiber bundle 1, here a transmitting fiber bundle, into a conical ATR body 2 at its base and after two total refiexionen on the lateral surface of the cone at the base of the ATR body 2 by means of a receiving optical fiber bundle, here a receive fiber bundle 3 decoupled.

The irradiation of light via optical fibers, which supply the light from spatially separated sources, and decoupling of the light via optical fibers to remote receivers on the one hand allows the construction of a compact probe head and on the other hand, requirements for the explosion protection can be well met.

The construction of a probe head of an ATR probe according to the invention is shown in longitudinal section in FIG. As ATR body 2, a substantially conical ZnSe crystal with a cylindrical projection on the base 22 of the cone is provided, which is axially supported by means of an elastic O-ring 4 on a circumferential sealing surface 51 about an end opening 52 in a cylindrical probe housing 5 is. Through the frontal opening 52, a portion of the lateral surface 23 of the ATR body can be acted upon by a measuring medium. The O-ring 4 can in principle have any medium-resistant and temperature-resistant materials with a sufficient, currently Kalrez is preferred.

In the probe housing 5, a fiber bead 6 is disposed on the side of the base of the conical ATR body with which the optical fibers are positioned. For this purpose, the ferrule 6 bores 61, 63, in which the fibers are glued mitteis a suitable adhesive, for example with an epoxy resin, which is compatible with the material of the optical fibers, wherein the Lichtieiterfasern particular Have silver halide. The fibers are not shown in the drawing to preserve the clarity of the drawing. In principle, the end surface 64 of the ferrule 6 may abut directly against the base of the ATR body, however, it should be understood that the end faces of the fibers should preferably be spaced sufficiently apart from the ATR body to avoid intensity variations due to Fabry-Perot interference , For this purpose, either the end faces of the fibers with respect to the end face 64 of the ferrule 6 may be reset, or between the ferrule 6 and the ATR body is still a spacer provided when the end faces 64 of the fibers are substantially aligned with the end face of the Ferulle. The second alternative is provided here, wherein a Aufschraubring 7 is screwed from the end face 64 of the Feruile 6 ago on the Ferulle against a first axial stop 66 on the ferrule 6 by a defined distance between the end face 64 of the ferrule and the base of the ATR Adjust body, which rests with an annular peripheral edge surface of its base 22 on the screw-7.

The ferrule 6 is supported on the rear by means of a threaded ring 54 in the probe housing 5, wherein the threaded ring 54 engages in a thread in the wall of the probe housing 6 and on a second axial stop 67, which is formed as a radial projection on the lateral surface of the Feruile 6, is applied.

The ferrule also has a rear-side central bore 68, through which the light guides are guided to the respective bores 61, 63 for positioning the light guides.

The Ferulle can in principle have any sufficiently stable materials that are compatible with the material of the optical fiber or optical

Fibers are compatible, with PEEK currently being preferred since it has a enables simple and accurate production, is inexpensive and has sufficient mechanical stability even at high temperatures.

FIG. 3 shows a representation for determining the positions of the transmission fibers and the optical fibers in the optical design.

In order to optimize the ATR probe with a conical ATR body, the light distribution at the receiving fibers is calculated in each case with a predetermined position of the light source fibers or transmit density director by means of a 2-dimensional ray calculation. It is numerically estimated how the light passes through the ATR body and how the Uchtquellfasern or Sendelächtieiter and detector fibers or Empfangsiichtleiter should be organized spatially in the Faserferulie, so that a possible high light output and thus signal can be achieved at the detector. Here are some boundary conditions to consider.

First, a large radial distance d _L Q between the cone axis of the ATR body and the axis of the light source fiber, starting from the non-negligible numerical aperture NA of the beam, would cause the cone of light to enter through the long light path in the ATR body upon arrival in the plane of the base of the ATR body for decoupling into the receiving fibers would be distributed over a too large area. In this case, it would be necessary to work with many of the expensive receiving fibers. In that regard, it is preferred for cost reasons to keep d _L α minimum.

Secondly, the conical ATR body has a small radius at its cone tip during manufacture, for example not more than 0.5 mm. Preferably, no light hits the area of the rounded cone tip, because this light is otherwise lost for the ATR effect. Together with the numerical aperture NA of the optical fiber fibers used and thus the maximum, inwardly pointing beam angle of, for example, about 15 ° in air and 6 ° in ZnSe, this limits the minimum value for d _L Q. When optimizing CJLQ for a radius of 4.5 mm, the following results: For d _L Q = 1.0 mm, light strikes the area of the rounded cone tip. at mm, the light spreads on a too large area, so that too many receiving fiber would be needed.

Thirdly, it should be noted that preferably as few light rays as possible hit the area of the lateral surface against which the O-ring abuts, white! otherwise this light would experience the absorption of the O-ring material,

As a result, with axis-parallel alignment of the optical fiber axes a suitable value for d _t α between, for example, 0.210 and 0.245 base radii preferably between 0.220 and 0.235 Basisradäen, wherein the base radius by the intersection of the conical surface with the plane of the base of the entire ATR body, ie including the cylindrical part is defined. In a currently preferred embodiment, the value for dua is 0.227 base radii.

In the presently preferred embodiment, the monolithic conical ATR body has a diameter of 9 mm and has a 1 mm high cylinder portion as the base to which a conical section with 4.5 mm height and 90 ° Konuswinke! or half an opening angle of 45 °, the base radius is therefore 5.5 mm. This optical component is made of ZnSe. Fig. 2 now shows a simulation with the entrance of the light at the bottom left at the base of the ATR body. The light rays are reflected at the top left of the cone, reach the right upper edge of the cone and are reflected down to the right in the spatial area in which the receiving fibers are to be positioned to detect the light. The light beams of a light guide are drawn in Figure 3 as thin lines. To determine the position of the receiving fibers, a 2D histogram is first calculated for the light rays arriving at the base of the ATR body (bottom right in FIG. 3). The 2D histogram is represented by the solid thick line. It shows the number of rays striking the base per unit length. The envelope of this distribution corresponds approximately to a uniform rectangle distribution. The skew-shaped deviation of the curve from a rectangular distribution is due to the limited number of rays from the light source which were taken into account in the calculation.

The dotted curve represents the distribution of the beams incident on the base per unit area in a simplified 3D model. The number of beams is taken from the 2D model and divided by the ring surface elements, so that this distribution is concentrated to the center.

The receiving light guides are to be positioned so that they capture the light incident on the base as effectively as possible.

Fig. 4 shows an arrangement of transmitting and receiving light guides, which takes into account the result of the above calculations. For this purpose, six transmission optical fibers 11 are positioned with their center on a radius of 0.227 base radii about the cone axis. In contrast to the transmission optical fibers, the reception optical fibers define an area in which a sufficiently large proportion of the light incident on the base is detected.

Another simulation result of the light distribution is shown in FIG. 5. It first shows the positions of the six transmission light guides of FIG. 4.

In addition, the outer edge of the area is shown in which the light from the light cones, which are radiated by the parallax-oriented transmit optical fibers, after two occurring at the Kegeimanteifläche total reflections hits the base. In this case, a half opening angle of 6 ° was assumed for the light cone. The result essentially confirms that the positioning of the receiving light guides according to FIG. 4 makes sense and detects a sufficiently large proportion of the reflected light.

Fig. 6 finally shows an absorption spectrum of an aqueous solution of 0.5% by weight of iso-propanoi, which was taken up by means of the ATR probe. The signal-to-noise ratio is excellent, for a commercial ATR probe.

FIGS. Finally, FIGS. 7a to c show simulation data for another embodiment of an ATR probe according to the invention with a conical ATR body, in which the end faces of six transmitters in hexagonal symmetry are arranged on a circular arc. The axes of the transmission light guide are inclined radially inwardly. Further, parallel to the cone axis of the ATR body planes in which each extend the inclined axes of the transmitting light, with respect to the respective axial planes, which are defined by the cone axis of the ATR body and the intersection of the axis of a Sendelichtieiters with the end face to one twisted , As a result, the k-vector of the light irradiated along the radiator axes has a radially inward and a tangential component. For example, if the transmission optical axes are aligned in the case such that the inclination of the axis of irradiated light in the ATR body is about 6 ° and the rotation about 40 ° relative to the axial plane, then the respective center of the light from an optical fiber on the base surface of the reflected light are shifted so that the centers of the light to be coupled out with the end faces of the Send light guides in a first approximation form a hexagonal pattern, the centers fall on gaps between the end faces of the transmission light guide. In order to identify the positions of the centers of the light to be coupled out in the base of the ATR body, a half opening angle of 1 ° was set in the ATR body for the irradiated light cone. The resulting positions 24 are shown in Fig. 7a together with the end faces 14 of the transmission light guide. FIG. 7b shows the distribution of the light 26 to be coupled out assuming a half opening angle of 6 ° in the ATR body for the incident light cone.

The ensuing arrangement of the receiving light guides 26 can be seen in Fig. 7c. Accordingly, the end face of a receiving light guide is positioned on each light spot of Fig. 7a, a seventh addressee feed occupies the gap in the center of the light guide assembly. This embodiment is advantageous in that for each transmit optical fiber, a receive light guide is positioned so that the angular range of maximum intensity about the axis of the irradiated light is detected by this one receiving light guide. In addition, the receiving light guides are hexagonal, that is arranged in the densest possible package, which also the outside of the core region of a reflected light beam occurring light is optimally detected by adjacent receiving light guides.

Claims

claims:

An ATR probe for detecting an optical property of a medium, comprising:

a monolithic ATR body (2) having at least one surface portion (24) to be acted upon by the medium;

a transmission optical fiber array (1) for irradiating non-co-located light into the ATR body (2);

a receiving optical fiber assembly (3) for receiving the irradiated light after passing through the ATR body, wherein the passage of the light through the ATR body has at least two total reflections at a media contacting surface (24) of the ATR body

ATR body includes; characterized in that

the effective area of the receiving optical fiber array for receiving the light emerging from the ATR body is a factor F greater than the effective area of the

Transmitting light guide arrangement for irradiating the light in the ATR body, wherein F is at least 1, preferably at least 4/3 and more preferably at least 3/2 and more preferably at least 2, and wherein the transmitting light conductor arrangement comprises at least two transmitting optical fibers and the Empfangsüchtleiteranordnung comprises at least three receiving light guides.

2. ATR probe according to one of the preceding claims, wherein the ATR body (2) comprises at least a portion with a frusto-conical surface (24), and the frustoconical surface is at least partially acted upon by the medium.

3. ATR probe according to claim 2, wherein the ATR body (2) comprises a cylindrical portion which adjoins the base of the frusto-conical portion.

4. ATR probe according to one of claims 2 to 3, wherein the ATR body has a rounded tip, which adjoins the frusto-conical portion.

5. ATR probe according to one of claims 1 to 4, further comprising a Ferulle (6), by means of which the transmitting optical fibers and the receiving optical fibers are positioned, and a spacer body (7) arranged between the Ferulle (6) and the ATR body is, wherein the spacer body (7), for example, comprises a coupling ring.

6. ATR probe according to one of claims 1 to 5, wherein the transmission optical fiber arrangement comprises a plurality Sendelichtieiter {11; 14).

7. ATR probe according to claim 6, wherein the end faces (11; 14) of the optical waveguide have centers which are arranged on a circular arc, wherein the circular arc preferably has the cone axis as the center.

8. ATR probe according to one of claims 6 to 7, wherein the end faces (11) of the transmission optical fibers are arranged directly adjacent to each other.

9. ATR probe according to one of claims 6 to 8, wherein the receiving optical fiber array, a plurality of receiving light guide (21) whose end faces are arranged in a region whose shortest closed boundary line encloses an image of the end faces of the transmitting light guide (11), which by a

Rotation of the end faces of the transmitting light guides around the cone axis by one angle! of 180 ° arises.

10. ATR probe according to claim 9, wherein the end faces of the Empfangsüchtieiter at least 20%, preferably at least 35% and more preferably cover at least 50% of the area of the area whose shortest closed boundary line encloses an image of the end faces of the transmission light guides, which by rotation the faces of the

Transmitting light conductor around the cone axis by an angle of 180 ° arises.

11. ATR probe according to one of claims 6 to 8, wherein the receiving optical fiber array, comprises a plurality of Empfangsüchtieiter whose end faces are arranged in a region whose shortest closed boundary line encloses a simulated image of the end faces of the transmitting light conductor, which through the beam path of the transmission optical fibers in the ATR body irradiated light assuming a numerical aperture of not less than 0.1 and not more than 0.3 after two total reflections on the conical surface of the ATR body and exit from the ATR body in the plane of the front surface of the receiving view conductors.

12. ATR probe according to claim 11, wherein

the simulated image is formed assuming a numerical aperture of not more than 0.15 in air, and

the Stirnfiächen the receiving light guide at least 20%, preferably at least 35% and more preferably at least 50% of the area of the area cover whose shortest closed boundary line encloses the simulated image of the end faces of the Sendelichtieiter.

13. ATR probe according to claim 2, further comprising a FerulSe, by means of which the transmitting optical fibers and the receiving light guides are positioned, wherein the optical axis of the transmitting light conductor or the receiving light conductor in the Feruile is substantially parallel to the axis of the frusto-conical portion ,

14, ATR probe according to claim 2, further comprising a Ferulle, by means of which the transmitting light guides and the receiving light guides are positioned, wherein the optical axes of the transmitting light and the Empfangslichtieiter in the Ferulle respectively with respect to the axis of the conical or kegeistumpfförmigen section to the axis of the Kegeis are tilted so that the k vector of the along the has a radially inwardly directed component in the ATR body or the k vector of the light received along the optical axis of a received light guide in the ATR body has a radially outwardly directed component.

15. ATR probe according to claim 14, wherein the optical axes of the transmitting light conductor or the receiving light guide in the Ferulle each define a parallel to the axis of the frusto-conical or truncated portion which plane with respect to a Zentraiebene through the axis of the frustoconical or truncated Section and the intersection of the optical axis of the respective light guide is defined with the end face, is rotated, so that the k vector of the irradiated along the optical axis of the transmission optical fiber

Light in the ATR body has a tangential component or the k vector of the light received along the optical axis of a received light guide in the ATR body has a tangential component.

16. ATR probe according to one of claims 6 to 7, wherein in each case end faces of receiving light guides are arranged between the end faces of the Sendelichtieiter.

17. ATR probe according to one of claims 14 to 16, wherein the centers of the end faces of the Sendelichtieiter define a circle, and the centers of at least half of all Empfangsüchtleiter, preferably of at least three quarters of all Empfangslichtieiter, in particular all received light guide within this circle.

18. ATR probe according to one of the preceding claims, wherein the transmission stirrer arrangement comprises at least one transmission light guide, and wherein the light emitted by a transmission light guide light is detected after passing through the ATR body of two or more receiving light guides.

19. ATR probe according to one of the preceding claims, wherein the transmitting light conductor and the receiving light guide each having an end face and the end faces in each case a distance of at least λo / 2 in air, for example 5 microns preferably at least 100 microns and more preferably at least 200 microns of a spaced apart the respective surface portion, through which the Strahiengang of the light from the transmitting optical fibers or to the receiving light guides.

20. ATR probe according to one of the preceding claims, wherein the transmitting light guide and the receiving light guide each having an end face, and the end faces in each case a distance of not more than a diameter of the respective light guide to the ATR

Have body.

21. ATR probe according to one of the preceding claims, further comprising a Ferulle, by means of which the transmission optical fibers and the

Receiving light guide are positioned, and a housing with a medialseitigen opening, as well as a sealing ring, which is arranged around the medialseitige opening, whereby the ATR body rests against the sealing ring and between the sealing ring and the Ferulie axia! is elastically clamped.

The ATR probe of claim 21, wherein the transmission optical fiber array and the receiving optical fiber array are positioned and aligned such that light impinges on surface portions of the ATR body against which the sealing ring abuts, less than 5%, preferably less than 2% more preferably less than 1%, to Signa! contributes to the ATR probe.

23. ATR probe according to one of the preceding claims, wherein the ATR body comprises ZnSe, diamond, or sapphire, or Ge with a DLC coating.

24. ATR probe according to one of the preceding claims, wherein the transmission optical fibers or the receiving optical fibers comprise optical fibers, which preferably comprises silver halide, quartz, a polymer, or chalcogenide, which has a sufficient transmission in the wavelength range of the light used.

25. ATR probe according to one of claims 1 to 23, wherein the transmitting optical fibers or the receiving optical waveguides comprise optical waveguides having an inner coating, for example

Contains silver halide or Au.