FI12042U1 - DEVICE FOR OPTICAL EMISSION SPECTROSCOPY OF THE FLUID - Google Patents

Description

FIELD OF THE INVENTION Field of the Invention

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

Atomic / optical emission spectroscopy is a method of measuring the presence or amount of element in a sample. With the help of an electromagnetic energy source, such as a laser, plasma is induced in the sample and the electrons of the element excite to a higher level, and when the electrons discharge back to a lower energy level, they emit photons at a characteristic wavelength. The light, i.e. the photons emitted by the plasma, is received and analyzed in a spectroscopy system. The wavelength is proportional to the difference in energy between the excited and the excited plane. The measured intensity is proportional to the plasma concentration of the measured element, the atomic parameters of the measured transition, including the probability of the transition and the energy of the excited state, and the parameters of the plasma, including electron density and temperature.

Atomic / optical emission spectroscopy can be used, for example, to measure the presence or amount of element (s) in a fluid flow sample.

The problem with optical emission spectrometry of fluids is that plasma causes a particle to detach from the surface of the sample stream in a hemispherical formation, i.e., toward the source of electromagnetic energy and toward the spectroscopy system. The more electromagnetic energy is used, the more particles will separate from the surface of the sample stream. One solution to this problem is to blow the gas against the surface of the sample stream, at least in part, to prevent the particles from separating from the surface of the sample stream. However, the problem with blowing gas against the surface of the sample stream is that the blown gas forms waves on the surface of the sample stream and that the blown gas causes the surface of the sample stream to oscillate.

Purpose of the Invention

It is an object of the invention to provide a device for optical emission spectroscopy of fluids which solves the above problem.

Brief Description of the Invention

The device of the invention for optical emission spectroscopy of fluids is known from the definitions of independent protection claim 1, respectively.

Preferred embodiments of the device are defined in the dependent claims.

The purpose of the shielding wall is to protect the spectroscopy system from the fluid in the fluid sample stream.

The purpose of the shielding wall may be to protect the electromagnetic energy source and the spectroscopy system from the fluid in the fluid sample stream.

List of figures

The invention will now be described in more detail with reference to the figures, in which: Fig. 1 shows a part of a first embodiment of a fluid optical emission spectroscopy device, Fig. 2 shows a part of another embodiment of a fluid optical emission spectroscopy device, Fig. 3 is a sectional view of a third embodiment; Fig. 5 is a sectional side view of a detail of an embodiment of a fluid optical emission spectroscopy apparatus, Fig. 6 is a sectional side view detail of an embodiment of a fluid optical emission spectroscopy apparatus, and Fig. 7 is a schematic view of a fluid optical emission spectroscope.

DETAILED DESCRIPTION OF THE INVENTION

The invention relates to an apparatus for optical emission spectroscopy of fluids.

The device may be an inductively coupled plasma optical emission spectrophotometer (ICP-OES or arc-spark OES).

The device for optical emission spectroscopy of fluids and some embodiments and variations of the device will be described in more detail below.

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

The apparatus comprises a source of electromagnetic energy 4 for directing electromagnetic energy 3 to a surface 5 of a fluid sample stream 1 flowing through a flow cell 2 to cause plasma 6 in a fluid sample stream 1 flowing through a flow cell 2.

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

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

The shield wall 10 comprises an opening 11 to allow light 7 emitted by the plasma 6 to pass through the shield wall 10.

The shielding wall 10 may have a first side 12 facing the fluid sample stream 1 flowing through the flow cell 2. The diameter of the opening 11 at the first side 12 of the shielding wall 10 may be between 4 and 9 mm, preferably between 5 and 7 mm, e.g.

The shield wall 10 may have a second side 13 facing away from the fluid sample stream 1 flowing through the flow cell 2.

The first page 12 may be planar and the second page 13 may be planar, and the first page 12 and second page 13 may be parallel.

The flow cell 2 may comprise a vertical stabilizing surface 14 directed towards the protective wall 10, and the horizontal distance between the first side 12 of the protective wall 10 and the vertical stabilizing surface 14 may be between 20 and 40 mm, preferably between 25 and 35 mm, e.g. 28 mm.

The vertical stabilizing surface 14 and the first side 12 of the shielding wall 10 facing the fluid sample stream 1 flowing through the flow cell 2 may be parallel. For example, the distance between the first side 12 and the second side 13 may be between 0.5 and 20 mm.

The device may comprise a gas blowing means 16 configured to blow gas 15 against one side 13 of the shielding wall 10. The gas blowing means 16 may be configured to blow gas 15 against one side 13 of the shield wall 10 such that the gas 15 passes through an opening 11 in the shield wall 10.

The opening 11 of the shielding wall 10 may have a conical or tapered configuration that tapers towards the first side 12 of the shielding wall 10 as shown in Figure 6. The diameter of the opening 11 at the first side 12 of the shielding wall 10 may be 4-9mm, preferably 5-7mm, e.g. about 6 mm. The inner surface 24 of the aperture 11 may be inclined 5 to 15 ° with respect to the central axis A of the aperture 11.

The opening 11 of the shielding wall 10 may be circular in cross-section and cylindrical in configuration, as shown in Figure 5.

The opening 11 of the shielding wall 10 may be circular in cross-section and may have a diameter of between 4 and 9 mm, preferably between 5 and 7 mm, e.g. 6 mm.

The opening 11 of the shielding wall 10 may be at least partially parabolic in shape.

The aperture 11 of the shielding wall 10 may be at least partially hyperbolic in shape.

The protective wall 10 may comprise a polymer, e.g. polytetrafluoroethylene (PFTE). The source of electromagnetic energy 4 and the spectrometer 8 of the spectroscopy system 9 may be separated from the flow cell 2 by a window 21 and a 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 a window 21 and a protective wall 10 may be provided between the fluid sample and the window 21, as shown in Figure 1.

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

The device may be configured to conduct light 7 emitted by plasma 6 to a spectrometer 8 of a spectroscopy system 9 under vacuum.

The apparatus may be configured to conduct light emitted by plasma 6 onto a spectrometer of a spectroscopy system 9 without the use of optical fibers. The source of electromagnetic energy 4 is one of the following: a laser, e.g. an Nd: YAG laser, as in Figure 1, and an arc spark generator, as in Figure 2.

The device may comprise, as shown in Figures 1 and 2, a conduit 17 configured to conduct a fluid flow 22, the conduit 17 having an inclined conduit 18, the conduit 17 defining a flow passage for fluid flow 22, and the apparatus may comprise an inclined conduit 17 A separating element 20 arranged at an outlet 19 to separate a portion of the fluid flow 22 22 of the inclined conduit portion 18 of the conduit 17 to generate a fluid sample flow 1, wherein the flow cell 2 is in fluid communication with the separating element 20.

The apparatus may comprise, as shown in Fig. 3, a conduit 17 configured to conduct a fluid flow 22, the conduit 17 having an inclined conduit 18, the conduit 17 defining a flow passage for fluid flow 22, an outlet opening 19 in the inclined conduit portion 18 of the conduit 17; at the outlet 19 of the inclined guide section 18 of the pipe 17 of the vertical wall member 23. In such a case, the fluid flow 22 is configured to be guided from the outlet 19 of the inclined conduit portion 18 of the conduit 17 against the vertical wall member 23 to generate a 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.

The opening 11 of the shielding wall 10 may be configured to allow the electromagnetic energy 3 generated by the electromagnetic energy source 4 to pass through the shielding wall 10.

It will be obvious to a person skilled in the art that as technology advances, the basic idea of the invention can be implemented in many ways. Accordingly, the invention and its embodiments are not limited to the above examples, but may vary within the scope of the claims.

Claims (22)

protection Requirements 1. Anordning for spectroscopy of a fluid for optical radiation, with the aid of an omnidirectional fluid (2), and the configuration of the fluid (1), the fluid of the fluid (1), the genomic fluid (2), the electromagnetic energy. 4) for detecting (5) av genomic fluid (2) fluorescent fluids (1) for electromagnetic energy (3) fluorescent plasma (6) for det genomic fluids (2) fluorescence spectroscopy (1) for spectra (9), som omfattar en spectrometer (8) för att emote plasma (6) emitter flux (7) och för att analyzer av (6) emitter flux (7), och en sky dds vägg (10) belägen mellan det genomic fluid (2) fluorescent fluids (1) och spectroscopic systems (9) spectrometer (8) fluorescent fluorescents (1), fluorescent fluids (1), fluorescent fluids (1) öppning (11) för att låta av plasmas (6) emitterat ljus (7) passera genom skyddsväggen (10), kangnetecknad av, att skyddsväggen (10) har en första sida (12), som är vänd mot det genom flödescellen (2) strömmande fluidumprovsflödet (1), av, att flödescellen (2) omfattar en lodrät stabiliseringsyta (14), som vänd mot skyddsväggen (10), av, att det vågräta avståndet mellan skyddsväggens (10) första sida (12) och den. (14) 20 and 40 mm, och av, att ö apning (11) diameter vid skyd ds ds ä ä (10) första sida (12) 4 and 9 mm. Apparatus for optical emission spectroscopy of fluids comprising a flow cell (2) configured to receive and deliver a fluid sample flow (1) so that the fluid sample flow (1) flows through the flow cell (2) to direct the electromagnetic energy source (4) to the flow cell. (2) a fluid sample flow (1) flowing through a fluid sample flow (1) to a surface (5), a spectroscopy system (9) comprising a spectometer (8) for receiving light (7) emitted by the plasma (6) and a plasma (6) for analyzing the light emitted (7), and a protective wall (10) between the fluid sample flow (1) flowing through the flow cell (2) and the spectrometer (8) of the spectroscopy system (9) such that the fluid sample flow ( 1) an intermediate space is formed, wherein the protective wall (10) comprises an aperture (11) to allow the light (7) emitted by the sman (6) to pass through the shielding wall (10), characterized in that the shielding wall (10) has a first side (12) directed towards the fluid sample flow (1) flowing through the flow cell (2). the flow cell (2) comprising a vertical stabilizing surface (14) facing the protective wall (10), wherein the horizontal distance between the first side (12) of the protective wall (10) and the vertical stabilizing surface (14) is between 20 and 40 mm , that the opening (11) has a diameter between 4 and 9 mm at the first side (12) of the protective wall (10). 2. anordning enligt skyddskrav 1, anchors (10) har en andra sida (13), som e vänd bort från det genom flödescellen (2) strömmande fluidumprovsflödet (1), Device according to Claim 1, characterized in that the screen (10) has a second side (13) facing away from the fluid sample flow (1) flowing through the flow cell (2). 3. Anordning enligt skyddskrav 2, Attaching threads, att den första sidan (12) and plan, att den andra sidan (13) om plan, och av, att den första sidan (12) och den andra sidan (13) parallel. Device according to claim 2, characterized in that the first side (12) is planar and in that the second side (13) is planar and in that the first side (12) and the second side (13) are parallel. 4. Anordning enligt något av skyddskrav en 2 till 3, kännetecknad av, att det vågräta avståndet mellan skyddsväggens (10) första sida (12) och den lodräta stabiliseringsytan (14) up to 25 and 35 mm, t.ex. 28 mm. Device according to one of Claims 2 to 3, characterized in that the horizontal distance between the first side (12) of the protective wall (10) and the vertical stabilizing surface (14) is between 25 and 35 mm, e.g. 28 mm. 5. Anordning enligt något av skyddskraven 2 till 4, kännetecknad av et gasblåsningsmedel (16) som configurat att blåsa gas (15) mot sky dds väggens (10) andra sida (13). Device according to one of Claims 2 to 4, characterized in that it comprises a gas blowing means (16) configured to blow gas (15) against one side (13) of the protective wall (10). 6. Anordning enligt skyddskrav 5, kännetecknad av, att gasblåsningsmedlet (16) and configuring att blåsa gas (15) mot skydds väggens (10) andra sida (13) så, att det strömmar gas (15) genome öppningen (11) i skyddsväggen (10). Device according to Claim 5, characterized in that the gas blowing means (16) is configured to blow gas (15) against one side (13) of the shielding wall (10) so that the gas (15) passes through the opening (11) of the shielding wall (10). 7. Anordning enligt något av skyddskraven 1 till 6, kännetecknad av, att öppningen (11) i skyddsväggen (10) har conformig config, som avsmalnar mot skyddsväggens (10) första sida (12), och av, att öppningens (11) diameter vid skyddsväggens (10) första sida (12) up to 4 and 9 mm, fördelaktigt mellan 5 and 7 mm, e.g. circus 6 mm. Device according to one of Claims 1 to 6, characterized in that the opening (11) of the protective wall (10) has a conical configuration which narrows towards the first side (12) of the protective wall (10) and the diameter (10) of the opening (11). ) at the first side (12) is between 4 and 9 mm, preferably between 5 and 7 mm, e.g. about 6 mm. 8. Anordning enligt skyddskrav 7, kännetecknad av, att en inneryta (24) i öppningen (11) lutar med en vincel B om mellan 5 and 15 ° i förhållande till öppningens (11) centralaxel A. Device according to Claim 7, characterized in that the inner surface (24) of the aperture (11) is inclined by 5 to 15 ° with respect to the central axis A of the aperture (11). 9. Anordning enligt något av skyddskraven 1 till 8, kännetecknad av, att öppningens (11) diameter vid skyddsväggens (10) första sida (12) after 5 and 7 mm, t.ex. circus 6 mm. Device according to one of Claims 1 to 8, characterized in that the opening (11) has a diameter between the first side (12) of the protective wall (10) of between 5 and 7 mm, e.g. about 6 mm. 10. Anordning enligt något av skyddskraven 1 till 9, kännetecknad av, att öppningen (11) i skyddsväggen (10) har cirkelformigt tvärsnitt. Device according to one of Claims 1 to 9, characterized in that the opening (11) of the protective wall (10) has a circular cross-section. 11. Anordning enligt något av skyddskraven 1 till 10, kännetecknad av, att öppningen (11) i skyddsväggen (10) åtminstone delvis har formen av en parabolic con. Device according to one of Claims 1 to 10, characterized in that the opening (11) of the protective wall (10) is at least partially parabolic in shape. 12. Anordning enligt något av skyddskraven 1 till 10, kännetecknad av, att öppningen (11) i skyddsväggen (10) åtminstone delvis har formen av en hyperbolisk kon. Device according to one of Claims 1 to 10, characterized in that the opening (11) of the protective wall (10) is at least partially shaped as a hyperbolic cone. 13. Anordning enligt något av skyddskraven 1 till 10, kännetecknad av, att öppningen (11) i skyddsväggen (10) har cirkelformigt tvärsnitt och en diameter om 4 mm and 9 mm, fördelaktigt mellan 5 and 7 mm, t.ex. circus 6 mm. Device according to one of Claims 1 to 10, characterized in that the opening (11) of the protective wall (10) has a circular cross-section and a diameter of between 4 and 9 mm, preferably between 5 and 7 mm, e.g. about 6 mm. 14. Anordning enligt något av skyddskraven 1 till 13, kännetecknad av, att skyddsväggen (10) omfattar en polymer, t.ex. PTFE. Device according to one of Claims 1 to 13, characterized in that the protective wall (10) comprises a polymer, e.g. PFTE. 15. Anordning enligt något av shielddskraven 1 till 14, kännetecknad av, att den electromagnetic energy (4) och spectroscopic systems (9) spectrometer (8) åtskilda från flödescellen (2) med hjälp av ett fönster (21) och av, att man åstadkommit skyddsväggen (10) mellan fluidumprovet och fönstret (21). Device according to one of Claims 1 to 14, characterized in that the source of electromagnetic energy (4) and the spectrometer (8) of the spectroscopy system (9) are separated from the cell (2) by a window (21) and a protective wall (10) is provided. ) between the fluid sample and the window (21). 16. Plasma (6) emitterat (7) till spectroscopy systems (9) spectrometer (8) or gas. Device according to one of Claims 1 to 15, characterized in that the device is configured to conduct light (7) emitted by plasma (6) into the spectrometer (8) of the spectroscopy system (9). 17. Plasma (6) emitterat (7) till spectroscopy (9) spectrometer (8) in vacuo. Device according to one of Claims 1 to 15, characterized in that the device is configured to conduct light (7) emitted by plasma (6) to the spectrometer (8) of the spectroscopy system (9) under vacuum. 18. Anordning enligt något av shielddskraven 1 till 15, kangnetecknad av, att anordningen and configurerad atteda av plasma (6) emitterat (7) till spectroscopy systems (9) spectrometer (8) after annealing the optical fiber. Device according to one of Claims 1 to 15, characterized in that the device is configured to conduct light (7) emitted by plasma (6) to the spectrometer (8) of the spectroscopy system (9) without the use of optical fibers. 19. Anordning enligt något av skyddskraven 1 till 18, kännetecknad av, att den electromagnetic energy (4) någon av feljande: en laser, t.ex. en Nd: YAG laser, och en ljusbågsgnistgenerator. Device according to one of Claims 1 to 18, characterized in that the source (4) of electromagnetic energy is a laser, e.g. an Nd: YAG laser, and a spark generator. 20. Anordning enligt något av skyddskraven 1 till 19, tiltnings av en rörledning (17), som configuratorad attildeda fluidumflöde (22), dör rörledningen (17) har ett sluttande rörledningsavsnitt (18), colors rörledningen (17) avgränsar en fluid channel for fluid fluid flow (22), av for separating ring (20), som arrangerats vid en utloppsöppning (19) for sluttande rörledningsavsnitt (18) for att separera en del av det i rörledningens (17) for sluttande rörledningsavsnitt (18) the fluid fluid (22) for the fluid generator fluid (1) and the fluid fluid (2) for the fluid fluid separator (20). Device according to one of the claims 1 to 19, characterized in that it has a conduit (17) configured to conduct a fluid flow (22), the conduit (17) having an inclined conduit (18), the conduit (17) defining a flow channel for fluid flow (22), characterized by a separating element (20) disposed at an outlet opening (19) of the inclined conduit (17) for separating a portion of the inclined fluid flow (18) in the conduit (17) 22) to generate a fluid sample flow (1), and in that the flow cell (2) is in fluid communication with the separation element (20). 21. Anordning enligt något av skyddskraven 1 till 20, tiltnings av en rörledning (17), som configuratorad attededa fluidumflöde (22), dör rörledningen (17) har ett sluttande rörledningsavsnitt (18), colors rörledningen (17) avgränsar en fluid channel for fluid fluid flow (22), av, att rörledningens (17) sluttande rörledningsavsnitt (18) har en utlopp söppning (19), av ett lodrätt väggorgan (23) vid utloppsöppningen (19) i rörledningens (17) sluttande rörledningsavsnitt (18) av, att fluid (22) and configurator att ur utloppsöppningen (19) i rörledningens (17) sluttande rörledningsavsnitt (18) ice emitter detergent (1), att det attodor 23 (23) ) and the configurator att leda fluidumprovsflödet (1) längs det lodräta väggorganet (23) till flödescellen (2). Device according to one of the claims 1 to 20, characterized in that it has a conduit (17) configured to conduct a fluid flow (22), the conduit (17) having an inclined conduit (18), the conduit (17) defining for fluid flow (22) of the flow duct, characterized in that the inclined conduit (18) of the conduit (17) has an outlet (19), in that it has a vertical wall member (23) with an outlet (18) of the inclined conduit (17) 19), the fluid flow (22) is configured to be conducted from the outlet (19) of the sloping conduit (18) of the pipeline (17) against the vertical wall member (23) to form a fluid sample flow (1), and ) is configured to conduct a fluid sample flow (1) along a vertical wall member (23) to a flow cell (2). Device according to one of Claims 1 to 21, characterized in that the opening (11) of the shielding wall (10) is configured to allow the electromagnetic energy (3) generated by the electromagnetic energy source (4) to pass through the shielding wall (10). Skyddskrav 22. Anordning enligt något av skyddskraven 1 till 21, kännetecknad av, att öppningen (11) i skyddsväggen (10) and configurator att låta electromagnetic energy (3) generator av den electromagnetic energy (4) passera genome skyddsväggen (10).