WO2024115184A1 - Connection assembly and gas spectrometer for analysing a gas or a gas mixture by means of raman scattering - Google Patents

Abstract

The invention relates to a connection assembly (10) for analysing a gas or a gas mixture by means of Raman scattering (11), the connection assembly (10) being designed to conduct a gas or a gas mixture through the connection assembly (10), said connection assembly comprising: a first connecting element (12) which is tubular and has a first end (14), a second end (16), and at least one opening (18, 60, 68, 72) located between the first end (14) and the second end (16); a second connecting element (20) which is tubular and has a first end (22), a second end (24), and at least one opening (26, 62, 66, 72) located between the first end (22) and the second end (24); and an intermediate element (28) which is tubular and has a first end (30) and a second end (32), wherein at least parts of the intermediate element (28) are made of transparent material, wherein, when the connection assembly (10) is in an assembled state (34), the intermediate element (28) is located between the first connecting element (12) and the second connecting element (20) and between the opening (18, 60, 68, 72) of the first connecting element (12) and the opening (26, 62, 66, 72) of the second connecting element (20) along a radial direction (13), wherein the opening (18, 60, 68, 72) of the first connecting element (12) and the opening (26, 62, 66, 72) of the second connecting element (20) are positioned so as to be at least partially in alignment with one another when the connection assembly (10) is in an assembled state (34).

Description

Description

Title

Connection arrangement and gas spectrometer for the analysis of a gas or a gas mixture by Raman scattering

State of the art

The invention relates to a connection arrangement for analyzing a gas or a gas mixture with features of claim 1, as well as a gas spectrometer for analyzing a gas or a gas mixture with features of the independent claim.

Raman spectroscopy can be used to identify and quantify gases in a gas mixture. Each gas has a characteristic Raman spectrum. By evaluating the respective Raman spectrum, the gas can be identified and its concentration determined. EP 3 961 195 A1 describes a measuring device for gases based on Raman spectroscopy.

Disclosure of the invention

According to the invention, a connection arrangement for analyzing a gas or a gas mixture by means of Raman scattering is proposed. The connection arrangement is designed to pass a gas or a gas mixture through the connection arrangement. In other words, the connection arrangement is suitable for passing a gas or a gas mixture through. The gas or the gas mixture can be under pressure or pressureless.

The connection arrangement comprises a first connection element. The first connection element is tubular, has a first end, a second end and at least one opening arranged between the first end and the second end. The opening is formed in a wall of the first connecting element. The connecting arrangement further comprises a second connecting element. The second connecting element is tubular, has a first end, a second end and at least one opening arranged between the first end and the second end. Here too, the opening is formed in a wall of the second connecting element. The first connecting element and/or the second connecting element can have several, in particular at least two, in particular at least four, such openings. The openings can be designed differently in their (geometric) shape and size. It is also conceivable that the openings can be designed identically in their shape and size.

In the present case, "tubular" means an elongated (but by no means necessarily straight) body whose longitudinal extension is significantly greater than its transverse extension. The connection arrangement also comprises an intermediate element. The intermediate element is tubular and has a first end and a second end. The intermediate element is formed at least in regions from a material that is transparent, in particular for Raman scattering, in particular in the visual frequency range. The intermediate element can also be tinted. The intermediate element can have a tint that, for example, reduces the transparency by 25%.

In an assembled state of the connection arrangement, the intermediate element is arranged along a radial direction between the first connection element and the second connection element. In the present case, an axial direction means a direction oriented parallel to the longitudinal extension of the intermediate element. Accordingly, in the present case, a radial direction means a direction oriented perpendicular to the axial direction. The intermediate element is also arranged between the opening of the first connection element and the opening of the second connection element. The opening of the first connecting element and the opening of the second connecting element in the assembled state of the connecting arrangement are arranged at least partially in alignment with one another (or corresponding to one another). For example, a laser beam can be used to irradiate the interior of the connecting arrangement through two mutually corresponding or at least partially aligned openings in the first and second connecting elements and the intermediate element. The Raman scattering emitted by the gas or gas mixture can be radiated outwards from the interior of the connecting arrangement through two (further) mutually corresponding or at least partially aligned openings in the first and second connecting elements and the intermediate element.

The first connecting element, the second connecting element and/or the intermediate element can be arranged coaxially to one another in the assembled state of the connecting arrangement. The first connecting element, the second connecting element and/or the intermediate element can each be formed in one piece or in one piece.

In the assembled state of the connection arrangement, the first connection element, the second connection element and/or the intermediate element can be arranged at least partially nested in one another. In other words, in the assembled state of the connection arrangement, the first connection element, the second connection element and/or the intermediate element can be arranged one after the other along a radial direction (in a sandwich-like manner, with the intermediate element being arranged between the first and the second connection element). In the assembled state of the connection arrangement, the second connection element can protrude at least partially, in particular with its first end, into the first connection element.

The connection arrangement can be used at least partially as a measuring chamber for Raman spectroscopy or can represent a Raman measuring cell. The connection arrangement can thus connect a gas inlet and a gas outlet to one another. In particular, the first end of the first connection element can be provided with a gas inlet for introducing a gas or a gas mixture into the connection arrangement. In particular, the second end of the second connection element can be connected to a gas outlet for discharging a gas or a gas mixture from the connection arrangement.

This means that a structurally simple connection arrangement can be created with just a few components, which can be used as a measuring chamber for Raman spectroscopy, for example in a gas spectrometer. Direct inline measurement is possible, i.e. during actual process operation, without the medium to be tested (e.g. gas or gas mixture) being changed or influenced. As a result, no sampling is necessary or the sample (e.g. gas or gas mixture) remains in the process. The complexity of the media-carrying parts (e.g. gas or gas mixture-carrying parts) is also reduced. The actual media path (e.g. gas or gas mixture path) can consist primarily of metal, and the rest of the measuring cell (or Raman measuring cell) can be manufactured as a plastic injection-molded part, for example.

According to a further development, the intermediate element can be made of glass, industrial glass or sapphire glass. This ensures a high compressive strength or pressure resistance of the intermediate element, while retaining the transparent properties.

According to a further development, the intermediate element can be at least partially polished. The intermediate element can be polished at its first end and/or at its second end. The intermediate element can be polished on one or both of its end faces. In this case, the end faces mean the surfaces of the intermediate element that are aligned orthogonally to the axial direction (arranged at the two ends of the intermediate element). The intermediate element can be polished on an inner side and/or an outer side of a wall of the intermediate element. Alternatively or additionally, the intermediate element can have an anti-reflective coating, in particular for the visual frequency range, at least in some areas. Alternatively or additionally, the intermediate element can have a tint, in particular for the visual frequency range, at least in some areas, to reduce transparency. This allows fluorescence and/or interference radiation or their reflections to be avoided or at least reduced. This allows a clearer or better measurement signal to be achieved and thus the measurement result to be optimized. Weak signals can also be detected better.

According to a further development, the intermediate element can have an opaque coating in sections, in particular for the visual frequency range. The opaque coating, in particular for the visual frequency range, can be arranged in the area of the first end of the intermediate element and/or in the area of the second end of the intermediate element. This allows the interference radiation or its reflections to be avoided or at least reduced. This allows a clearer or better measurement signal to be achieved and thus the measurement result to be optimized. Weak signals can also be detected better.

According to a further development, the first connecting element, the second connecting element and/or the intermediate element can have a round, oval or square cross-section. It is also conceivable that the cross-section of the first connecting element, the second connecting element and/or the intermediate element has a cross-section that has a different geometric shape. The intermediate element can have at least one integrated lens. The geometric shape of the cross-section of the intermediate element can be determined or influenced by the integrated lens. This allows the connection arrangement to be used flexibly and adapted to different requirements depending on the application.

According to a further development, the connection arrangement can have at least one seal. In the case of non-critical gases or gas mixtures and low pressure ranges, a seal can also be dispensed with. The seal can be designed as an O-ring or a shaped sealing element, in particular a thermo-chemical connection. In the assembled state of the connection arrangement, at least one seal can be arranged at the first end or the second end of the intermediate element. In the assembled state of the connection arrangement, the seal can be arranged at a Front side of the intermediate element. The connection arrangement can have two or more seals. The seals can be designed as O-rings. When the connection arrangement is assembled, at least one seal can be arranged at the first end and the second end of the intermediate element. When the connection arrangement is assembled, at least one seal can be arranged at both front sides of the intermediate element. This makes it possible to achieve the tightness of the connection arrangement using simple means. Complex seals and/or sealing systems can be dispensed with.

According to a further development, the first connecting element can have an internal thread. The internal thread can be arranged at the second end of the connecting element. The second connecting element can have an external thread corresponding to the internal thread. In the assembled state of the connecting arrangement, the first connecting element and the second connecting element can be screwed together, in particular in a block, by means of the internal thread and the external thread. By means of this screw connection, the assembled state of the connecting arrangement can be realized with simple means. The connecting arrangement can be quickly and safely transferred to the assembled state or the assembled state can be released.

According to a further development, the second connecting element can have a receiving area for receiving the intermediate element. The receiving area of the second connecting element can extend from the first end of the second connecting element to a projection of the second connecting element. In other words: the second connecting element can have a projection, wherein the receiving area of the second connecting element is arranged between the projection and the first end of the second connecting element. The opening or openings of the second connecting element can be arranged in its receiving area. If the intermediate element is received in the receiving area of the second connecting element, the intermediate element is between the first end of the second connecting element and the projection of the second connecting element. This allows the intermediate element to be picked up quickly and safely and positioned in the connection arrangement.

According to a further development, the first connecting element can have a receiving area for receiving the intermediate element and/or the second connecting element and in particular its receiving area. The receiving area of the first connecting element can extend from a projection of the first connecting element to the second end of the first connecting element. In other words: the first connecting element can have a projection, wherein the receiving area of the first connecting element is arranged between the projection and the second end of the first connecting element. The opening or openings of the first connecting element can be arranged in its receiving area. This allows the second connecting element together with the intermediate element to be received quickly and securely and positioned in the connection arrangement.

According to a further development, the opening or openings of the first connecting element and/or the opening or openings of the second connecting element can be round and/or oval. It is also conceivable that the openings of the first and/or the second connecting element have a different geometric shape. This allows the openings and thus the connection arrangement as a whole to be adapted to different focus geometries (e.g. oval, round) of a laser. This allows the connection arrangement to be used more flexibly.

According to a further development, the first connecting element and/or the second connecting element can have a coating. The coating of the first and/or the second connecting element can be multi-layered. In other words: the coating can comprise several layers or plies. The coating can be anti-reflective, hydrophobic and/or designed as corrosion protection. This can prevent moisture from adhering to the interior of the connection arrangement, so that, for example, moisture in a gas or gas mixture can be measured. In addition, corrosion formation can be prevented or at least reduced. According to a further development, the first connecting element and/or the second connecting element can be made of metal, in particular of stainless steel 316 or stainless steel 316L. The first connecting element and/or the second connecting element can be made of a nickel-iron-chromium alloy with molybdenum, copper and titanium additives, for example as 2.485810 NiCr21MoF55 or 1.4401 X5CrNiMo17-12-2. This makes it possible to achieve a high gas resistance and surface quality of the first connecting element and/or the second connecting element. This prevents the gas molecules from sticking and provides an effective coating. For non-critical gases, e.g. N2 in low pressure ranges, plastic or a general steel can also be used as the material.

According to the invention, a gas spectrometer for analyzing a gas or a gas mixture by means of Raman scattering is also proposed, comprising at least one connection arrangement according to the above statements. The gas or the gas mixture can be under pressure or without pressure.

With regard to the advantages that can be achieved, reference is made to the relevant explanations regarding the connection arrangement. The measures described in connection with the connection arrangement and/or those explained below can be used to further configure the gas spectrometer.

The gas spectrometer can comprise a laser for generating a laser beam. The gas spectrometer, in particular the laser and/or the connection arrangement, can be set up in such a way that the laser beam of the laser is irradiated into the interior of the connection arrangement through two mutually corresponding or aligned openings of the first and second connection elements and the intermediate element and strikes the gas or the gas mixture in the interior of the connection arrangement.

The gas spectrometer may comprise at least one detector for detecting Raman scattering. The gas spectrometer, in particular the detector and/or the connection arrangement, may be designed such that the gas or gas mixture emitted from the interior of the connection arrangement emitted Raman scattering is radiated through two corresponding or aligned openings of the first and second connecting elements and the intermediate element and strikes the detector.

The openings through which the laser beam is radiated into the interior of the connection arrangement can be the same as those through which the Raman scattering is emitted and detected. It is also conceivable that the openings through which the laser beam is radiated into the interior of the connection arrangement are different from the openings through which the Raman scattering is emitted and detected.

An embodiment of the invention is explained below with reference to the accompanying drawings.

Figure 1 shows a longitudinal section of a connection arrangement for the analysis of a gas or a gas mixture by means of Raman scattering in a composite state,

Figure 2 shows a longitudinal section of a first connecting element of the connecting arrangement according to Figure 1,

Figure 3 shows a longitudinal section of a second connecting element of the connecting arrangement according to Figure 1,

Figure 4 schematically shows a side view of an intermediate element of the connecting arrangement according to Figure 1 and

Figure 5 shows schematically a gas spectrometer with the connection arrangement according to Figure 1.

The connection arrangement bears the reference number 10 in Figure 1. The connection arrangement 10 is designed to analyze a gas or a gas mixture by means of Raman scattering 11. The connection arrangement 10 can be designed as part of a gas spectrometer 54 (see Figure 5). The connection arrangement 10 can at least partially represent a Raman measuring cell or a measuring chamber for Raman spectroscopy. Figure 1 shows an assembled state 34 of the connection arrangement 10. The connection arrangement 10 is set up to conduct a gas or a gas mixture through the connection arrangement 10. This is indicated in Figure 1 by two thick arrows. The connection arrangement 10 can be connected with its left end in Figure 1 to a gas inlet for introducing a gas or a gas mixture into the connection arrangement 10 and with its right end in Figure 2 to a gas outlet for discharging a gas or a gas mixture from the connection arrangement 10.

The connection arrangement 10 in the present case comprises a first connection element 12, a second connection element 20 and an intermediate element 28. The connection arrangement 10 in the present case comprises, for example, two seals 40, which in the present case are designed as O-rings, for example.

The intermediate element 28 is arranged here along a radial direction 13 between the first connecting element 12 and the second connecting element 20. The intermediate element 28 is arranged here, for example, along an axial direction 15 between the two seals 40.

In the assembled state 34 of the connection arrangement 10, the first connection element 12, the second connection element 20, the intermediate element 28 and the two seals 40 are arranged coaxially to one another, as an example.

Figure 2 shows a longitudinal section of the first connecting element 12 of the connecting arrangement 10 according to Figure 1. The first connecting element 12 is tubular, has a first end 14, a second end 16 and, in the present case, four openings 18. The openings 18 are arranged between the first end 14 and the second end 16 of the first connecting element 12.

The first connecting element 12 has, for example, an internal thread 42 at its second end 16. The second connecting element 20 has a with the internal thread 42 corresponding external thread 44 (see Figure 1 or 3). The internal thread 42 and the external thread 44 form a screw connection by means of which the connection arrangement 10 can be transferred into the assembled state 34 and held in the assembled state 34. The assembled state 34 of the connection arrangement 10 can be released again by screwing on or loosening this screw connection.

The first connecting element 12 has, for example, a receiving area 50 for receiving the intermediate element 28 and at least partially the second connecting element 20. The first connecting element 12 has a projection 52. The receiving area 50 of the first connecting element 12 extends from the projection 52 to the second end 16 of the first connecting element 12.

The openings 18 of the first connecting element 12 are arranged in the present example within the receiving area 50 of the first connecting element 12. An angle of 90° is arranged between the individual openings 18 of the first connecting element 12. In other words, two adjacent openings 18 are arranged or oriented orthogonally to one another.

Figure 3 shows a longitudinal section of the second connecting element 20 of the connecting arrangement 10 according to Figure 1. The second connecting element 20 is tubular, has a first end 22, a second end 24 and, in the present example, four openings 26 arranged between the first end 22 and the second end 24 of the second connecting element 20.

The second connecting element 20 in the present example has a receiving area 46 for receiving the intermediate element 28. The second connecting element 20 has a projection 48. The receiving area 46 of the second connecting element 20 extends from the projection 48 to the first end 22 of the second connecting element 20.

The openings 26 of the second connecting element 20 are in the present example within the receiving area 46 of the second connecting element 20. An angle of 90° is arranged between the individual openings 26 of the second connecting element 20. In other words, two adjacent openings 26 are arranged or oriented orthogonally to one another.

In the assembled state 34 of the connection arrangement 10 (see Figure 1), the intermediate element 28 is arranged in the two receiving areas 46, 50 and along the radial direction 13 between the openings 18, 26 of the first connection element 12 and the second connection element 20. In the assembled state 34 of the connection arrangement 10, the second connection element 20, in particular with its receiving area 46 and the intermediate element 28 received there, projects into the receiving area 50 of the first connection element 12. In the present case, the receiving area 50 of the first connection element 12 surrounds, for example, the receiving area 46 of the second connection element 20 together with the intermediate element 28 radially outward.

The openings 18, 26 of the first connecting element 12 and/or the second connecting element 20 can have a round and/or oval shape.

The first connecting element 12 and/or the second connecting element 20 can have a coating, in particular a multi-layer coating. This coating can be anti-reflective, hydrophobic and/or designed as corrosion protection.

The first connecting element 12 and/or the second connecting element 20 can be made of metal, in particular of stainless steel 316 or stainless steel 316L. The first connecting element 12 and/or the second connecting element 20 can be made of a nickel-iron-chromium alloy with molybdenum, copper and titanium additives.

Figure 4 shows a schematic side view of the intermediate element 28 of the connection arrangement 10 according to Figure 1. The intermediate element 28 is tubular and has a first end 30 and a second end 32. The intermediate element 28 is made of a transparent material. The intermediate element 28 is particularly suitable for Raman scattering 11, in particular in visual frequency range, transparent. The intermediate element 28 can be made of glass, industrial glass or sapphire glass.

The intermediate element 28 can be polished at its first end 30 and/or at its second end 32. The intermediate element 28 can be polished in particular on one or both of its end faces 36. The intermediate element 28 can also be polished on an inner side 17 and/or an outer side 19 of a wall 21 of the intermediate element 28. The intermediate element 28 can have an anti-reflective coating, in particular for the visual frequency range.

In the assembled state of the connection arrangement 10 (see Figure 1), a seal 40 is arranged on each of the two end faces 36 of the intermediate element 28, for example.

In the present case, the intermediate element 28 has, for example, an opaque coating 38, in particular for the visual frequency range, in the region of its first end 30 and in the region of its second end 32. The two sections of the intermediate element 28 provided with the opaque coating 38 are arranged at a distance from one another, so that a transparent region remains between the regions provided with the opaque coating 38, through which, for example, laser light and/or Raman scattering 11 can be transmitted.

In the present example, the first connecting element 12, the second connecting element 20 and the intermediate element 28 each have a round cross-section. It is also conceivable that the cross-section of at least one of these elements can have a square or another geometric shape. The intermediate element 28 can have at least one integrated lens. The geometric shape of the cross-section of the intermediate element 28 can be influenced or changed due to the lens.

Figure 5 shows a schematic view of a gas spectrometer 54 with the connection arrangement 10 according to Figure 1. The gas spectrometer 54 is designed such that the gas or gas mixture can be passed through the connection arrangement 10. For this purpose, the gas or the gas mixture is introduced through the first end 14 of the first connecting element 12 of the connecting arrangement 10 into the interior 64 of the connecting arrangement 10. The first end 14 of the first connecting element 12 can be connected to a gas inlet for this purpose. This is indicated in Figure 5 by a thick arrow on the left in Figure 5. The gas or the gas mixture can be passed through the connecting arrangement 10 and discharged from the interior 64 of the connecting arrangement 10 at the second end 24 of the second connecting element 20. For this purpose, the second end 24 of the second connecting element 20 can be connected to a gas outlet. This is indicated in Figure 5 by a thick arrow on the right in Figure 5.

In the present case, the gas spectrometer 54 has, for example, a laser 56 for generating a laser beam 58. In the present case, the gas spectrometer 54 is set up in such a way that the laser beam 58 of the laser 56 passes through a first opening 60 of the second connecting element 20, through the intermediate element 28 and through a first opening 62 of the first connecting element 12 into the interior 64 of the connecting arrangement 10 and thus onto the gas or gas mixture located in the interior 64 of the connecting arrangement 10.

In the interior 64 of the connection arrangement 10, the gas or gas mixture struck by the laser beam 58 can emit Raman scattering 11. The Raman scattering 11 can leave the interior 64 of the connection arrangement 10 through a second opening 66 of the second connection element 20, through the intermediate element 28 and through a second opening 68 of the first connection element. The Raman scattering 11 then strikes a detector 70 of the gas spectrometer 54, which is set up to detect the Raman scattering 11.

The first openings 60, 62 of the first connecting element 12 and the second connecting element 20 are arranged in alignment with one another in the present example. Likewise, the second openings 66, 68 of the first connecting element 12 and the second connecting element 20 are arranged in alignment with one another in the present example. The first openings 60, 62 and the second openings 66, 68 are oriented or arranged at an angle of 180° to one another in the present example. It would also be conceivable for the Raman scattering 11 to be carried out through further openings 72 of the first Connecting element 12 and the second connecting element 20, which are also arranged in alignment with one another and at an angle of 90° to the first openings 60, 62 and to the second openings 66, 68, respectively, are emitted from the interior 64 of the connecting arrangement 10 and are then detected (in each case) by a further detector (not shown) of the gas spectrometer 54.

Claims

Expectations 1 . Connection arrangement (10) for analyzing a gas or a gas mixture by means of Raman scattering (11), wherein the connection arrangement (10) is designed to guide a gas or a gas mixture through the connection arrangement (10), comprising: a first connection element (12) which is tubular and has a first end (14), a second end (16) and at least one opening (18, 60, 68, 72) arranged between the first end (14) and the second end (16), a second connection element (20) which is tubular and has a first end (22), a second end (24) and at least one opening (26, 62, 66, 72) arranged between the first end (22) and the second end (24), and an intermediate element (28) which is tubular and has a first end (30) and a second end (32), wherein the intermediate element (28) is made at least in regions from a, in particular for Raman scattering (11), in particular in the visual frequency range, transparent material, wherein in an assembled state (34) of the connecting arrangement (10) the intermediate element (28) is arranged along a radial direction (13) between the first connecting element (12) and the second connecting element (20) and between the opening (18, 60, 68, 72) of the first connecting element (12) and the opening (26, 62, 66, 72) of the second connecting element (20), wherein the opening (18, 60, 68, 72) of the first connecting element (12) and the opening (26, 62, 66, 72) of the second connecting element (20) in the assembled state (34) of the connecting arrangement (10) are arranged at least partially flush with one another. 2. Connection arrangement (10) according to claim 1, characterized in that the intermediate element (28) is made of glass, industrial glass or sapphire glass is trained. 3. Connecting arrangement (10) according to claim 1 or 2, characterized in that the intermediate element (28) is at least partially polished, in particular at its first end (30) and/or at its second end (32), in particular on one or both of its end faces (36), in particular on an inner side (17) and/or an outer side (19) of a wall (21) of the intermediate element (28), and/or that the intermediate element (28) has at least in some regions an anti-reflective coating, in particular for the visual frequency range. 4. Connecting arrangement (10) according to at least one of the preceding claims, characterized in that the intermediate element (28) has in sections, in particular in the region of its first end (30) and/or its second end (32), a coating (38) which is opaque, in particular for the visual frequency range. 5. Connecting arrangement (10) according to at least one of the preceding claims, characterized in that the first connecting element (12), the second connecting element (20) and/or the intermediate element (28) has a round, oval or square cross-section, in particular wherein the intermediate element (28) has at least one integrated lens. 6. Connection arrangement (10) according to at least one of the preceding claims, characterized in that the connection arrangement (10) has at least one seal (40), in particular designed as an O-ring or a shaped sealing element, wherein in the assembled state (34) of the connection arrangement (10) at least one seal (40) is arranged on the first end (30) or the second end (32) of the intermediate element (28), in particular on one of its two end faces (36), in particular wherein the connection arrangement (10) has at least two seals (40), in particular designed as an O-ring and/or as a shaped sealing element, wherein in the assembled state (34) of the connection arrangement (10) at the first end (30) and the second end (32) of the intermediate element (28), in particular on its at least one seal (40) is arranged on each of the two end faces (36). 7. Connecting arrangement (10) according to at least one of the preceding claims, characterized in that the first connecting element (12), in particular at its second end (16), has an internal thread (42), wherein the second connecting element (20) has an external thread (44) corresponding to the internal thread (42), wherein in the assembled state (34) of the connecting arrangement (10) the first connecting element (12) and the second connecting element (20) are screwed together, in particular in a block, by means of the internal thread (42) and the external thread (44). 8. Connecting arrangement (10) according to at least one of the preceding claims, characterized in that the second connecting element (20) has a receiving area (46) for receiving the intermediate element (28), wherein the receiving area (46) of the second connecting element (20) extends from the first end (22) of the second connecting element (20) to a projection (48) of the second connecting element (20), in particular wherein the opening (26, 62, 66, 72) of the second connecting element (20) are arranged in its receiving area (46). 9. Connecting arrangement (10) according to at least one of the preceding claims, characterized in that the first connecting element (12) has a receiving area (50) for receiving the intermediate element (28) and/or the second connecting element (20), in particular its receiving area (46), wherein the receiving area (50) of the first connecting element (12) extends from a projection (52) of the first connecting element (12) to the second end (16) of the first connecting element (12), in particular wherein the opening (18, 60, 68, 72) of the first connecting element (12) are arranged in its receiving area (50). 10. Connecting arrangement (10) according to at least one of the preceding claims, characterized in that the opening (18, 60, 68, 72) of the first connecting element (12) and/or the opening (26, 62, 66, 72) of the second connecting element (20) are round and/or oval. Connecting arrangement (10) according to at least one of the preceding claims, characterized in that the first connecting element (12) and/or the second connecting element (20) have a coating, in particular a multi-layer coating, wherein the coating is anti-reflective, hydrophobic and/or corrosion-protective. Connecting arrangement (10) according to at least one of the preceding claims, characterized in that the first connecting element (12) and/or the second connecting element (20) are made of metal, in particular of stainless steel 316 or stainless steel 316L, in particular as a nickel-iron-chromium alloy with molybdenum, copper and titanium additives. Gas spectrometer (54) for analyzing a gas or a gas mixture by means of Raman scattering (11) comprising at least one connection arrangement (10) according to at least one of the preceding claims.