AU2016102373A4

AU2016102373A4 - Method and apparatus for optical emission spectroscopy of fluids

Info

Publication number: AU2016102373A4
Application number: AU2016102373A
Authority: AU
Inventors: Pasi HIETARINTA; Lauri KÖRESAAR; Arto OLLIKAINEN; Kari Saloheimo; Mika Salonen
Original assignee: Outotec Finland Oy
Current assignee: Outotec Finland Oy
Priority date: 2015-07-10
Filing date: 2016-07-08
Publication date: 2019-05-09
Anticipated expiration: 2024-07-08
Also published as: BR202018000575Y1; AU2016294458A1; BR112018000575A2; RU183436U1; WO2017009530A1; FI20155549L; CN208060392U; FI12042U1; CL2018000072U1

Abstract

A method and to an apparatus for optical emission spectroscopy of fluids comprises conducting a fluid sample flow through a flow cell, applying electromagnetic energy onto a surface of the fluid sample flow to induce plasma in the fluid sample flow, and receiving light emitted by the plasma and analysing light emitted by the plasma in a spectrometer of a spectroscopy system. The method comprises providing a protective wall between the fluid sample flow and the spectrometer of the spectroscopy system so that an interspace is formed between the protective wall and the fluid sample flow, and providing the protective wall with an aperture for allowing light emitted by the plasma to pass through the protective wall. WO 2017/009530 PCT/F12016/050506 (5 coE - -22\.4 .. .. . .. .. .. . .. . . . .

Description

METHOD AND APPARATUS FOR OPTICAL EMISSION SPECTROSCOPY OF FLUIDS

Field of the invention

The invention relates to a method for optical emission spectroscopy of fluids as defined in the preamble of independent claim 1.

The invention also relates to an apparatus for optical emission spectroscopy of fluids as defined in the preamble of independent claim 24.

Atomic/optical emission spectroscopy is a method to measure the presence or quantity of an element in a sample. By means of a source for electromagnetic energy such as a laser, plasma is induced in the sample and electrons in an element are excited to a higher level, and as the electrons decay back to a lower energy level they emit photons at a characteristic wavelength. Light i.e. photons emitted by the plasma are received and analyzed in a spectroscopy system. The wavelength is proportional to the energy difference between the exited state and the state it decays to. The measured intensity is proportional to the concentration of the measured element in the plasma, the atomic parameters of the measured transition including the transition probability and the energy of the excited state, and parameter of the plasma including electron density and temperature.

Atomic/optical emission spectroscopy can for example be used for to measure the !0 presence or quantity of an element / elements in a fluid sample flow.

A problem with optical emission spectroscopy of fluids is that the plasma causes particle to detach from the surface of the sample flow in a hemispherical formation i.e. towards the source for electromagnetic energy and towards the spectroscopy system. The more electromagnetic energy that is used, the more particles detach from the surface of the sample flow. A solution to this problem is to blow gas against the surface of the sample flow to at least partly prevent detaching of particles from the surface of the sample flow. A problem with blowing gas against the surface of the sample flow is however that the blown gas form waves is formed on the surface of the sample flow and that the blown gas causes the surface of the sample flow to vibrate.

Objective of the invention

The object of the invention is to provide a method and an apparatus for optical emission spectroscopy of fluids which solves the above-identified problem.

Short description of the invention

The method for optical emission spectroscopy of fluids of the invention is characterized by the definitions of independent claim 1.

Preferred embodiments of the method are defined in the dependent claims 2 to 23.

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The apparatus for optical emission spectroscopy of fluids of the invention is correspondingly characterized by the definitions of independent claim 24.

Preferred embodiments of the apparatus are defined in the dependent claims 25 to 46.

The purpose of the protective wall is to protect the spectroscopy system from fluid of the fluid sample flow.

The purpose of the protective wall may be to protect the source of electromagnetic energy and the spectroscopy system from fluid of the fluid sample flow.

List of figures

In the following the invention will described in more detail by referring to the figures, of which

Figure 1 shows a part of a first embodiment of an apparatus for optical emission spectroscopy of fluids,

Figure 2 shows a part of a second embodiment of an apparatus for optical emission spectroscopy of fluids,

Figure 3 shows a part of a third embodiment of an apparatus for optical emission spectroscopy of fluids,

Figure 4 shows in cut side view a detail of an embodiment of an apparatus optical !0 emission spectroscopy of fluids,

Figure 5 shows in cut side view a detail of an embodiment of an apparatus optical emission spectroscopy of fluids,

Figure 6 shows in cut side view a detail of an embodiment of an apparatus optical emission spectroscopy of fluids, and

Figure 7 shows an embodiment of an apparatus for optical emission spectroscopy of fluids

Detailed description of the invention

The invention relates to a method for optical emission spectroscopy of fluids and to an 30 apparatus for optical emission spectroscopy of fluids.

The method can for example be implemented in Inductively Coupled Plasma optical emission spectrophotometer (ICP-OES) apparatuses and in Arc spark OES apparatuses.

Correspondingly, the apparatus can be a Inductively Coupled Plasma optical emission spectrophotometer (ICP-OES) apparatus or an Arc spark OES apparatus.

First the method for optical emission spectroscopy of fluids and some embodiments and variants of the method will be described in greater detail.

The method comprises conducting a fluid sample flow 1 through a flow cell 2.

The method comprises applying electromagnetic energy 3 from a source 4 for

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The method comprises receiving light 7 emitted by the plasma 6 and analyzing light 7 emitted by the plasma 6 in a spectrometer 8 of a spectroscopy system 9.

The method comprises providing a protective wall 10 between the fluid sample flow 1 that flows through the flow cell 2 and the spectrometer 8 of the spectroscopy system 9 so that an interspace is formed between the protective wall 10 and the fluid sample flow 1 that flows through the flow cell 2, and

The method comprises providing the protective wall 10 with an aperture 11 for allowing light 7 emitted by the plasma 6 to pass through the protective wall 10.

The method may include providing the protective wall 10 so that the protective wall 10 has a first side 12 that faces the fluid sample flow 1 that flows through the flow cell 2. The diameter of the aperture 11 at the first side 12 of the protective wall 10 can be between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.

The method may include providing the protective wall 10 so that the protective wall 10 has a second side 13 that turned away from the fluid sample flow 1 that flows through the flow cell 2.

The method may include providing the protective wall 10 so that the first side 12 is planar and so that the second side 13 is planar and so that the first side 12 and the second side 13 !0 are parallel. The distance between the first side 12 and the second side 13 may for example be between 0.5 and 20 mm.

The flow cell 2 that is used in the method may comprise a vertical stabilizer surface 14 that faces the protective wall 10, and the protective wall 10 may be provided so that the horizontal distance between the first side 12 of the protective wall 10 and the vertical stabilizer surface 14 is between 20 and 40mm, preferably between 25 and 35 mm, for example 28 mm.

The method may include blowing gas 15 against the second side 13 of the protective wall

10.

The method may include blowing gas 15 against the second side 13 of the protective wall 10 so that gas 15 passes through the aperture 11 in the protective wall 10.

The aperture 11 that is formed in the protective wall 10 having a conical or tapering configuration that tapers towards the first side 12 of the protective wall 10 so that the diameter of the aperture 11 at the first side 12 of the protective wall 10 can be between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm. The aperture 11 that is formed in the protective wall 10 may have inner surface 24 inclined by an angle B between 5 and 15° with respect to a central axis A of the aperture 11.

The aperture 11 that is formed in the protective wall 10 may have a circular cross section. The aperture 11 that is formed in the protective wall 10 may have at least partly the shape of a parabolic cone.

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The aperture 11 that is formed in the protective wall 10 may have at least partly the shape of a hyperbolic cone.

The aperture 11 that is formed in the protective wall 10 may have a circular cross section 5 and a diameter between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.

The method may include providing a protective wall 10 comprising polymer, such as polytetrafluoroethylene (PFTE).

In the method, the source 4 for electromagnetic energy 3 and the spectrometer 8 of the spectroscopy system 9 may be separated from the flow cell 2 by means of a window 21 and the protective wall 10 may be provided between the fluid sample and the window 21, as is shown in figures 1 and 3.

In the method, the spectrometer 8 of the spectroscopy system 9 may be separated from the flow cell 2 by means of a window 21 and the protective wall 10 may be provided between the fluid sample and the window 21, as is shown in figure 1.

The method may include conducting light 7 from the plasma 6 to the spectrometer 8 of the spectroscopy system 9 in gas.

The method may include conducting light 7 from the plasma 6 to the spectrometer 8 of the spectroscopy system 9 in vacuum.

The method may include conducting light 7 emitted from the plasma 6 to the !0 spectrometer 8 of the spectroscopy system 9 without using optical fibers.

The method may include using as the source 4 for electromagnetic energy 4 any one of the following: a laser such as a Nd:YAG laser, as in figure 1, and an arc spark generator, as in figure 2.

The method may include, as shown in figures 1 and 2, conducting a fluid flow 22 in a 25 conduit 17 having an inclined conduit section 18, separating by means of separation element 20 arranged at an outlet 19 in the inclined conduit section 18 of the conduit 17 a portion of the fluid flow 22 flowing in the inclined conduit section 18 of the conduit 17 to generate the fluid sample flow 1, and conducting the fluid sample flow 1 from the separation element 20 to the flow cell 2.

The method may include, as shown in figure 3, conducting a fluid flow 22 in a conduit 17 30 having an inclined conduit section 18, conducting the fluid flow 22 from an outlet 19 of the inclined conduit section 18 of the conduit 17 against a vertical wall member 23 to from the fluid sample flow 1, and conducting the fluid sample flow 1 along the vertical wall member 23 to the flow cell 2.

The method may include, as shown in figure 1, providing the aperture 11 in the protective 35 wall 10 to additionally allowing electromagnetic energy 3 generated by the source 4 for electromagnetic energy to pass through the protective wall 10.

Next the apparatus for optical emission spectroscopy of fluids and some embodiments and variants of the apparatus will be described in greater detail.

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The apparatus comprises a flow cell 2 configured to receive and release a fluid sample flow 1 so that the fluid sample flow 1 flows through the flow cell 2.

The apparatus comprises a source 4 for electromagnetic energy for applying electromagnetic energy 3 onto a surface 5 of the fluid sample flow 1 that flows through the flow cell 2 to induce plasma 6 in the fluid sample flow 1 that flows through the flow cell 2.

The apparatus comprises a spectroscopy system 9 comprising a spectrometer 8 for receiving light 7 emitted by the plasma 6 and for analyzing light 7 emitted by the plasma 6.

The apparatus comprises by a protective wall 10 between the fluid sample flow 1 that flows through the flow cell 2 and the spectrometer 8 of the spectroscopy system 9 so that an interspace is formed between the protective wall 10 and the fluid sample flow 1 that flows through the flow cell 2.

The protective wall 10 comprises an aperture 11 for allowing light 7 emitted by the plasma 6 to pass through the protective wall 10.

The protective wall 10 may have a first side 12 that faces the fluid sample flow 1 that 5 flows through the flow cell 2. The diameter of the aperture 11 at the first side 12 of the protective wall 10 can be between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.

The protective wall 10 may have a second side 13 that turned away from the fluid sample flow 1 that flows through the flow cell 2.

The first side 12 may be planar and by the second side 13 may be planar, and the first !0 side 12 and the second side 13 may be parallel.

The flow cell 2 may comprising a vertical stabilizer surface f4 that faces the protective wall 10, and the horizontal distance between the first side 12 of the protective wall 10 and the vertical stabilizer surface f 4 being between 20 and 40mm, preferably between 25 and 35 mm, for example 28 mm.

The vertical stabilizer surface 14 and the first side 12 of the protective wall 10 that faces the fluid sample flow 1 that flows through the flow cell 2 may be parallel. The distance between the first side 12 and the second side 13 may for example be between 0.5 and 20 mm.

The apparatus may comprise gas blowing means 16 configured to blow gas 15 against the second side 13 of the protective wall 10. The gas blowing means 16 may be configured to blow gas 15 against the second side 13 of the protective wall 10 so that gas 15 passes thorough the aperture 11 in the protective wall 10.

The aperture 11 in the protective wall 10 may have a conical or tapering configuration that tapers towards the first side 12 of the protective wall 10, as shown in figure 5. The diameter of the aperture 11 at the first side 12 of the protective wall 10 can be between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm. An inner surface 24 of the aperture 11 may be inclined by an angle B between 5 and 15° with respect to a central axis A of the aperture 11.

The aperture 11 in the protective wall 10 may have a circular cross section and a cylindrical configuration, as shown in figure 4.

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The aperture 11 in the protective wall 10 may have a circular cross section and a diameter between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.

The aperture 11 in the protective wall 10 can have at least partly the shape of a parabolic cone.

The aperture 11 in the protective wall 10 can have at least partly the shape of a hyperbolic cone.

The protective wall 10 may comprise polymer, such as polytetrafluoroethylene (PFTE). The source 4 for electromagnetic energy and the spectrometer 8 of the spectroscopy system 9 may be separated from the flow cell 2 by means of a window 21 and the protective wall

10 may be provided between the fluid sample and the window 21, as shown in figures 1 and 3.

The spectrometer 8 of the spectroscopy system 9 may be separated from the flow cell 2 by means of a window 21 and the protective wall 10 may be provided between the fluid sample and the window 21, as shown in figure 2.

The apparatus may be configured to conduct light 7 emitted the plasma 6 to the spectrometer 8 of the spectroscopy system 9 in gas.

The apparatus may be configured to conduct light 7 emitted the plasma 6 to the spectrometer 8 of the spectroscopy system 9 in vacuum.

The apparatus may be configured to conduct light 7 emitted the plasma 6 to the spectrometer 8 of the spectroscopy system 9 without using optical fibers.

!0 The source 4 for electromagnetic energy being any one of the following: a laser such as a

Nd:YAG laser, as in figure 1, and an arc spark generator, as in figure 2.

The apparatus may comprise, as shown in figures 1 and 2, a conduit 17 configured to conduct a fluid flow 22, wherein the conduit 17 having an inclined conduit section 18, wherein the conduit 17 limits a flow channel for the fluid flow 22, and the apparatus may comprise a separation element 20 arranged at an outlet 19 in the inclined conduit section 18 of the conduit 17 for separating a portion of the fluid flow 22 flowing in the inclined conduit section 18 of the conduit 17 to generate the fluid sample flow 1, wherein the flow cell 2 being fluid connection with the separation element 20.

The apparatus may comprise, as shown in figure 3, a conduit 17 configured to conduct a fluid flow 22, wherein the conduit 17 having an inclined conduit section 18, wherein the conduit 17 limits a flow channel for the fluid flow 22, an outlet 19 in the inclined conduit section 18 of the conduit 17, and a vertical wall member 23 at the outlet 19 of the inclined conduit section 18 of the conduit 17. In such case, the fluid flow 22 is configured to be conducted against the vertical wall member 23 from the outlet 19 of the inclined conduit section 18 of the conduit 17 to generate the fluid sample flow 1, and the vertical wall member 23 is configured to conduct the fluid sample flow 1 along the vertical wall member 23 to the flow cell 2.

The aperture 11 in the protective wall 10 may be configured to allow electromagnetic energy 3 generated by the source 4 for electromagnetic energy to pass through the protective

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It is apparent to a person skilled in the art that as technology advances, the basic idea of the invention can be implemented in various ways. The invention and its embodiments are therefore not restricted to the above examples, but they may vary within the scope of the claims.

Claims

Claims

1. A method for optical emission spectroscopy of fluids, comprising conducting a fluid sample flow (1) through a flow cell (2), applying electromagnetic energy (3) from a source (4) for electromagnetic energy onto a 5 surface (5) of the fluid sample flow (1) that flows through the flow cell (2) to induce plasma (6) in the fluid sample flow (1) that flows through the flow cell (2), and receiving light (7) emitted by the plasma (6) and analyzing light (7) emitted by the plasma (6) in a spectrometer (8) of a spectroscopy system (9), characterized

0 by providing a protective wall (10) between the fluid sample flow (1) that flows through the flow cell (2) and the spectrometer (8) of the spectroscopy system (9) so that an interspace is formed between the protective wall (10) and the fluid sample flow (1) that flows through the flow cell (2), and by providing the protective wall (10) with an aperture (11) for allowing light (7) emitted

5 by the plasma (6) to pass through the protective wall (10).
2. The method according to claim 1, characterized by providing the protective wall (10) so that the protective wall (10) has a first side (12) that faces the fluid sample flow (1) that flows through the flow cell (2).

:o
3. The method according to claim 2, characterized by providing the protective wall (10) so that the protective wall (10) has a second side (13) that turned away from the fluid sample flow (1) that flows through the flow cell (2).

25
4. The method according to claim 3, characterized by providing the protective wall (10) so that the first side (12) is planar and so that the second side (13) is planar and so that the first side (12) and the second side (13) are parallel.
5. The method according to any of the claims 2 to 4, characterized

30 by the flow cell (2) that is used in the method comprising a vertical stabilizer surface (14) that faces the protective wall (10), and by providing the protective wall (10) so that the horizontal distance between the first side (12) of the protective wall (10) and the vertical stabilizer surface (14) is between 20 and 40mm, preferably between 25 and 35 mm, for example 28 mm.
6. The method according to any of the claims 2 to 5, characterized by blowing gas (15) against the second side (13) of the protective wall (10).

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7. The method according to claim 6, characterized by blowing gas (15) against the second side (13) of the protective wall (10) so that gas (15) passes through the aperture (11) in the protective wall (10).

5
8. The method according to any of the claims 2 to 7, characterized by the aperture (11) that is formed in the protective wall (10) having a conical configuration that tapers towards the first side (12) of the protective wall (10), and by the diameter of the aperture (11) at the first side (12) of the protective wall (10) being between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.
9. The method according to claim 8, characterized by the aperture (11) that is formed in the protective wall (
10) having inner surface (24) inclined by an angle B between 5 and 15° with respect to a central axis A of the aperture (11).

5 10. The method according to any of the claims 1 to 9, characterized by the diameter of the aperture (11) at the first side (12) of the protective wall (10) being between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.
11. The method according to any of the claims 1 to 10, characterized by the aperture (11) that is formed in the protective wall (10) having a circular cross !0 section.
12. The method according to any of the claims 1 to 11, characterized by the aperture (11) that is formed in the protective wall (10) having at least partly the shape of a parabolic cone.
13. The method according to any of the claims 1 to 12, characterized by the aperture (11) that is formed in the protective wall (10) having at least partly the shape of a hyperbolic cone.
14. The method according to any of the claims 1 to 13, characterized

30 by the aperture (11) that is formed in the protective wall (10) having a circular cross section and a diameter between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.
15. The method according to any of the claims 1 to 14, characterized by providing a protective wall (10) comprising polymer, such as Polytetrafluoroethylene

35 PFTE
16. The method according to any of the claims 1 to 15, characterized by the source (4) for electromagnetic energy and the spectrometer (8) of the spectroscopy

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17. The method according to any of the claims 1 to 16, characterized

5 by conducting light (7) from the plasma (6) to the spectrometer (8) of the spectroscopy system (9) in gas.
18. The method according to any of the claims 1 to 16, characterized by conducting light (7) from the plasma (6) to the spectrometer (8) of the spectroscopy

0 system (9) in vacuum.
19. The method according to any of the claims 1 to 16, characterized by conducting light (7) emitted from the plasma (6) to the spectrometer (8) of the spectroscopy system (9) without using optical fibers.
20. The method according to any of the claims 1 to 19, characterized by using as the source (4) for electromagnetic energy any one of the following: a laser such as a Nd:YAG laser, and an arc spark generator.

!0
21. The method according to any of the claims 1 to 20, characterized by conducting a fluid flow (22) in a conduit (17) having an inclined conduit section (18), by separating by means of separation element (20) arranged at an outlet (19) in the inclined conduit section (18) of the conduit (17) a portion of the fluid flow (22) flowing in the inclined conduit section (18) of the conduit (17) to generate the fluid sample flow (1), and

25 conducting the fluid sample flow (1) from the separation element (20) to the flow cell (2).
22. The method according to any of the claims 1 to 20, characterized by conducting a fluid flow (22) in a conduit (17) having an inclined conduit section (18), by conducting the fluid flow (22) from an outlet (19) of the inclined conduit section (18)

30 of the conduit (17) against a vertical wall member (23) to from the fluid sample flow (1), by conducting the fluid sample flow (1) along the vertical wall member (23) to the flow cell (2).
23. The method according to any of the claims 1 to 22, characterized

35 by providing the aperture (11) in the protective wall (10) to additionally allowing electromagnetic energy (3) generated by the source (4) for electromagnetic energy to pass through the protective wall (10).

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24. An apparatus for optical emission spectroscopy of fluids, comprising a flow cell (2) configured to receive and release a fluid sample flow (1) so that the fluid sample flow (1) flows through the flow cell (2), a source (4) for electromagnetic energy for applying electromagnetic energy (3) onto a 5 surface (5) of the fluid sample flow (1) that flows through the flow cell (2) to induce plasma (6) in the fluid sample flow (1) that flows through the flow cell (2), and a spectroscopy system (9) comprising a spectrometer (8) for receiving light (7) emitted by the plasma (6) and for analyzing light (7) emitted by the plasma (6), characterized

0 by a protective wall (10) between the fluid sample flow (1) that flows through the flow cell (2) and the spectrometer (8) of the spectroscopy system (9) so that an interspace is formed between the protective wall (10) and the fluid sample flow (1) that flows through the flow cell (2), and by the protective wall (10) comprising an aperture (11) for allowing light (7) emitted by

5 the plasma (6) to pass through the protective wall (10).
25. The apparatus according to claim 24, characterized by the protective wall (10) having a first side (12) that faces the fluid sample flow (1) that flows through the flow cell (2).

:o
26. The apparatus according to claim 25, characterized by the protective wall (10) having a second side (13) that turned away from the fluid sample flow (1) that flows through the flow cell (2).

25
27. The apparatus according to claim 26, characterized by the first side (12) being planar and by the second side (13) being planar, and by the first side (12) and the second side (13) being parallel.
28. The apparatus according to any of the claims 25 to 27, characterized

30 by the flow cell (2) comprising a vertical stabilizer surface (14) that faces the protective wall (10), and by the horizontal distance between the first side (12) of the protective wall (10) and the vertical stabilizer surface (14) being between 20 and 40mm, preferably between 25 and 35 mm, for example 28 mm.
29. The apparatus according to any of the claims 25 to 28, characterized by gas blowing means (16) configured to blow gas (15) against the second side (13) of the protective wall (10).

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30. The apparatus according to claim 29, characterized by the gas blowing means (16) being configured to blow gas (15) against the second side (13) of the protective wall (10) so that gas (15) passes thorough the aperture (11) in the

5 protective wall (10).
31. The apparatus according to any of the claims 25 to 30, characterized by the aperture (11) in the protective wall (10) having a conical configuration that tapers towards the first side (12) of the protective wall (10), and

0 by the diameter of the aperture (11) at the first side (12) of the protective wall (10) being between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.
32. The apparatus according to claim 31, characterized by an inner surface (24) of the aperture (11) being inclined by an angle B between 5 and 5 15° with respect to a central axis A of the aperture (11).
33. The apparatus according to any of the claims 25 to 32, characterized by the diameter of the aperture (11) at the first side (12) of the protective wall (10) being between 5 to 7 mm, such as about 6 mm.

!0
34. The apparatus according to any of the claims 24 to 33, characterized by the aperture (11) in the protective wall (10) having a circular cross section.
35. The apparatus according to any of the claims 24 to 34, characterized by the aperture (11) in the protective wall (10) having at least partly the shape of a 25 parabolic cone.
36. The apparatus according to any of the claims 24 to 35, characterized by the aperture (11 in the protective wall (10) having at least partly the shape of a hyperbolic cone.
37. The apparatus according to any of the claims 24 to 36, characterized by the aperture (11) in the protective wall (10) having a circular cross section and a diameter between 4 and 9 mm, preferably between 5 to 7 mm, such as about 6 mm.
38. The apparatus according to any of the claims 24 to 37, characterized by the protective wall (10) comprising polymer, such as PFTE

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39. The apparatus according to any of the claims 24 to 38, characterized by the source (4) for electromagnetic energy and the spectrometer (8) of the spectroscopy system (9) being separated from the flow cell (2) by means of a window (21) and by providing the protective wall (10) between the fluid sample and the window (21).
40. The apparatus according to any of the claims 24 to 39, characterized by the apparatus being configured to conduct light (7) emitted the plasma (6) to the spectrometer (8) of the spectroscopy system (9) in gas.

0
41. The apparatus according to any of the claims 24 to 39, characterized by the apparatus being configured to conduct light (7) emitted the plasma (6) to the spectrometer (8) of the spectroscopy system (9) in vacuum.
42. The apparatus according to any of the claims 24 to 39, characterized

5 by the apparatus being configured to conduct light (7) emitted the plasma (6) to the spectrometer (8) of the spectroscopy system (9) without using optical fibers.
43. The apparatus according to any of the claims 24 to 42, characterized by the source (4) for electromagnetic energy being any one of the following: a laser such !0 as a Nd:YAG laser, and an arc spark generator.
44. The apparatus according to any of the claims 24 to 43, characterized by a conduit (17) configured to conduct a fluid flow (22), wherein the conduit (27) having an inclined conduit section (18), wherein the conduit (17) limits a flow channel for the

25 fluid flow (22), by a separation element (20) arranged at an outlet (19) in the inclined conduit section (18) of the conduit (17) for separating a portion of the fluid flow (22) flowing in the inclined conduit section (18) of the conduit (17) to generate the fluid sample flow (1), and by the flow cell (2) being fluid connection with the separation element (20).
45. The apparatus according to any of the claims 24 to 43, characterized by a conduit (17) configured to conduct a fluid flow (22), wherein the conduit (17) having an inclined conduit section (18), wherein the conduit (17) limits a flow channel for the fluid flow (22),

35 by the inclined conduit section (18) of the conduit (17) having an outlet (19), by a vertical wall member (23) at the outlet (19) of the inclined conduit section (18) of the conduit (17), by the fluid flow (22) being configured to be conducted against the vertical wall member

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2016102373 08 Jul 2016 (23) from the outlet (19) of the inclined conduit section (18) of the conduit (17) to generate the fluid sample flow (1), and by the vertical wall member (23) being configured to conduct the fluid sample flow (1) along the vertical wall member (23) to the flow cell (2).
46. The apparatus according to any of the claims 24 to 45, characterized by the aperture (11) in the protective wall (10) being configured to allow electromagnetic energy (3) generated by the source (4) for electromagnetic energy to pass through the protective wall (10).