RU183436U1 - Device for optical emission spectroscopy of liquids - Google Patents

Abstract

A utility model relates to a device for optical emission spectroscopy of liquids. A device for optical emission spectroscopy of liquids comprises a flow cell configured to receive and discharge a flow of a fluid sample such that the flow of a fluid sample flows through the flow cell; an electromagnetic energy source for supplying electromagnetic energy to a surface of a flow of a fluid sample that flows through the flow cell to create a plasma in the flow of a fluid sample that flows through the flow cell; a spectroscopic system comprising a spectrometer for receiving light emitted by a plasma; a protective shield between the flow of the liquid sample that flows through the flow cell and the spectrometer of the spectroscopic system, so that a gap is formed between the protective screen and the flow of the liquid sample that flows through the flow cell, the shield having an opening to allow light emitted by the plasma, pass through the protective screen. The protective screen has a first side that faces the fluid sample flowing through the flow cell, the flow cell contains a vertical stabilizer surface that faces the protective screen, the horizontal distance between the first side of the protective screen and the surface of the vertical stabilizer is from 20 to 40 mm, and the diameter of the hole on the first side of the shield is 4 to 9 mm. The technical result is the protection of the spectroscopic system from particles detaching from the surface of the sample stream. 21 cp f-ly, 7 ill.

Description

Technical field

A utility model relates to a device for optical emission spectroscopy of liquids, as defined in the preamble of independent claim 1 of the utility model formula.

Atomic / optical emission spectroscopy is a method of measuring the presence or amount of an element in a sample. Using a source of electromagnetic energy, such as a laser, a plasma is created in the sample, and the electrons in the element are excited and move to a higher level, and when the electrons descend back to a lower level, they emit photons at a characteristic wavelength. Light, i.e. Photons emitted by plasma are received and analyzed in a spectroscopic system. The wavelength is proportional to the difference in energy between the excited state and the state of a lower level. 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, as well as the plasma parameter, including electron density and temperature.

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

One embodiment of a device for atomic / optical emission spectroscopy is described in WO 2015/082752.

The problem with optical emission spectroscopy of liquids is that the plasma causes the particles to break away from the surface of the sample flow in a hemispherical formation, i.e. towards the source of electromagnetic energy and towards the spectroscopic system. The greater the electromagnetic energy used, the more particles detach from the surface of the sample stream. The solution to this problem is to blow gas onto the surface of the sample stream until the particles are at least partially torn off the surface of the sample stream. The problem with blowing gas to the surface of the stream, however, is that waves from the blown gas are generated on the surface of the sample stream, and the blown gas causes the surface of the sample stream to vibrate.

In this utility model, to solve the mentioned problems, it is proposed to place the protective shield close enough to the surface of the vertical stabilizer (i.e., at a certain distance) and make a hole in the protective shield with a sufficiently small diameter (i.e., with certain dimensions). Thus, the spectroscopic system can be protected from particles detaching from the surface of the sample stream.

Utility Model Purpose

The purpose of the utility model is to develop a device for optical emission spectroscopy of liquids that solves the above problems.

Brief Description of Utility Model

A device for optical emission spectroscopy of liquids according to a utility model is characterized by the features of the independent claim 1 of the utility model formula.

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

The purpose of the shield can be to protect the source of electromagnetic energy and the spectroscopic system from the fluid from the flow of the fluid sample.

Drawing list

Next, the utility model will be described in more detail with reference to the drawings, in which

FIG. 1 partially illustrates a first embodiment of an apparatus for optical emission spectroscopy of liquids,

FIG. 2 partially illustrates a second embodiment of an apparatus for optical emission spectroscopy of liquids,

FIG. 3 is a partially third embodiment of an apparatus for optical emission spectroscopy of liquids,

Figure 4 is a side sectional view of a detail of an embodiment of an apparatus for optical emission spectroscopy of liquids,

FIG. 5 is a side sectional view of a detail of an embodiment of an apparatus for optical emission spectroscopy of liquids,

FIG. 6 is a side cross-sectional view of a detail of an embodiment of an apparatus for optical emission spectroscopy of liquids,

FIG. 7 represents an embodiment of an apparatus for optical emission spectroscopy of liquids.

Detailed description

A utility model relates to a device for optical emission spectroscopy of liquids.

The device can be a device with an Inductively Coupled Plasma optical emission spectrometer (ICP-OES) or a device with an arc spark optical emission spectrometer (Arc spark OES).

Next will be described in more detail a device for optical emission spectroscopy of liquids and some embodiments and modifications of the device.

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

The device contains a source of electromagnetic energy 4 for supplying electromagnetic energy 3 to the surface 5 of the stream 1 of the liquid sample, which flows through the flow cell 2, to induce plasma 6 in the stream 1 of the liquid sample, which flows through the flow cell 2.

The device comprises a spectroscopic system 9 having a spectrometer 8 for receiving light 7 emitted by plasma 6, and for analyzing light 7 emitted by plasma 6.

The device comprises a protective screen 10 between the flow 1 of the liquid sample, which flows through the flow cell 2, and the spectrometer 8 of the spectroscopic system 9, so that a gap is formed between the protective screen 10 and the flow 1 of the liquid sample, which flows through the flow cell 2.

The shield 10 has an opening 11 that allows light 7 emitted by the plasma 6 to pass through the shield 10.

The shield 10 may have a first side 12 that faces the fluid sample stream 1 flowing through the flow cell 2. The diameter of the hole 11 on the first side 12 of the shield 10 can be from 4 to 9 mm, preferably from 5 to 7 mm, for example, approximately 6 mm.

The protective screen 10 may have a second side 13, which is turned away from the flow 1 of a sample of liquid flowing through the flow cell 2.

The first side 12 may be flat, and the second side 13 may be flat, and the first side 12 and the second side 13 may be parallel.

The flow cell 2 may comprise a vertical stabilizer surface 14 that faces the shield 10, and the horizontal distance between the first side 12 of the shield 10 and the vertical stabilizer surface 14 is between 20 and 40 mm, preferably between 25 and 35 mm, for example 28 mm.

The surface 14 of the vertical stabilizer and the first side 12 of the protective screen 10, which faces the flow 1 of the fluid sample flowing 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 device may comprise a gas purge means 16 configured to purge gas 15 on the second side 13 of the shield 10. The gas purge 16 may be configured to purge gas 15 on the second side 13 of shield 10 so that gas 15 passes through the hole 11 in the protective screen 10.

The hole 11 in the shield 10 may have a conical or cone-shaped configuration that tapers toward the first side 12 of the shield 10, as shown in FIG. 5. The diameter of the hole 11 on the first side 12 of the shield 10 may be from 4 to 9 mm, preferably from 5 to 7 mm, for example about 6 mm. The inner surface of the hole 11 may be inclined at an angle B from 5 to 15 ° with respect to the Central axis A of the hole 11.

The hole 11 in the shield 10 may have a circular cross section and a cylindrical configuration, as shown in FIG. four.

The hole 11 in the shield 10 may have a circular cross section and a diameter of 4 to 9 mm, preferably 5 to 7 mm, for example about 6 mm.

The hole 11 in the shield 10 may be at least partially in the shape of a parabolic cone.

The hole 11 in the shield 10 may be at least partially in the shape of a hyperbolic cone.

The shield 10 may consist of a polymer such as polytetrafluoroethylene (PFTE).

The electromagnetic energy source 4 and spectrometer 8 of the spectroscopic system 9 can be separated from the flow cell 2 by a window 21, and a protective screen 10 can be provided between the liquid sample and the window 21, as shown in FIG. 1 and 3.

The spectrometer 8 of the spectroscopic system 9 can be separated from the flow cell 2 by a window 21, and a protective screen 10 can be provided between the liquid sample and the window 21, as shown in FIG. 2.

The device can be configured to transmit light 7 emitted by plasma 6 into the spectrometer 8 of the spectroscopic system 9 in gas.

The device can be configured to transmit light 7 emitted by plasma 6 into spectrometer 8 of spectroscopic system 9 in vacuum.

The device can be configured to transmit light 7 emitted by plasma 6 into spectrometer 8 of spectroscopic system 9 without using optical fibers.

Electromagnetic energy source 4 is any of the following: a laser, such as an Nd: YAG laser, as in FIG. 2, and an arc spark generator, as in FIG. 2.

The device may comprise, as shown in FIG. 1 and 2, a tube configured to pass a fluid stream 22, the tube 17 having an inclined portion 18 of the tube, the tube 17 restricting the flow channel for the fluid stream 22, and the device may include a spacer 20 located in the outlet 19 in the inclined a portion 18 of the tube 17 for separating a portion of the fluid stream 22 flowing in the inclined portion 18 of the tube 17 to form the fluid sample stream 1, the flow cell being in fluid communication with the separation element 20.

The device may comprise, as shown in FIG. 3, a tube 17 configured to pass a fluid stream 22, the tube 17 having an inclined portion 18 of the tube, the tube 17 restricting the flow channel for the fluid flow 22, the outlet 19 in the inclined portion 18 of the tube 17, and the vertical screen element 23 in the outlet the hole 19 in the inclined portion 18 of the tube 17. In this case, the fluid stream 22 is formed to direct it to the vertical screen element 23 from the outlet 19 in the inclined portion 18 of the tube 17 to form the flow 1 of the liquid sample, and a vertical screen nny member 23 is configured to permit flow of liquid sample along one vertical screen element 23 in flowcell 2.

The hole 11 in the protective screen 10 may be configured to allow electromagnetic energy 3 generated by the electromagnetic energy source 4 to pass through the protective screen 10.

It is obvious to a person skilled in the art that as the technology develops, the basic idea of a utility model can be implemented in various ways. Therefore, the utility model and its implementation options are not limited to the above examples, but may vary within the framework of the utility model formula.

Claims (45)

1. Device for optical emission spectroscopy of liquids, containing a flow cell (2) configured to receive and discharge a fluid sample stream (1) in such a way that the fluid sample stream (1) flows through the flow cell (2), an electromagnetic energy source (4) for supplying electromagnetic energy (3) to the surface (5) of the fluid sample stream (1) that flows through the flow cell (2) to create a plasma (6) in the fluid sample stream (1) that flows through the flow cell (2), a spectroscopic system (9) comprising a spectrometer (8) for receiving light (7) emitted by a plasma (6), a protective screen (10) between the flow (1) of the liquid sample that flows through the flow cell (2) and the spectrometer (8) of the spectroscopic system (9), so that a gap is formed between the protective screen (10) and the flow (1) of the liquid sample that flows through the flow cell (2), wherein the shield (10) has an opening (11) to allow light (7) emitted by the plasma (6) to pass through the shield (10), characterized in that the protective screen (10) has a first side (12), which is facing the flow (1) of the fluid sample flowing through the flow cell (2), the flow cell (2) contains the surface (14) of the vertical stabilizer, which faces the protective screen (10), the horizontal distance between the first side (12) of the shield (10) and the surface (14) of the vertical stabilizer is from 20 to 40 mm, and the diameter of the hole (11) on the first side (12) of the shield (10) is from 4 to 9 mm. 2. The device according to p. 1, characterized a protective screen (10) having a second side (13), which is facing in the direction away from the flow (1) of the fluid sample flowing through the flow cell (2). 3. The device according to p. 2, characterized in that the first side (12) is flat and the second side (13) is flat, as well as the fact that the first side (12) and the second side (13) are parallel. 4. The device according to any one of paragraphs. 1-3, characterized in that the horizontal distance between the first side (12) of the protective screen (10) and the surface (14) of the vertical stabilizer is from 25 to 35 mm, for example 28 mm 5. The device according to any one of paragraphs. 1-4, characterized by means of gas purging (16), configured to purge gas (15) to the second side (13) of the shield (10). 6. The device according to claim 5, characterized in that the gas purge means (16) is configured to purge the gas (15) to the second side (13) of the shield (10) so that the gas (15) passes through the hole (11) ) in the protective screen (10). 7. The device according to any one of paragraphs. 1-6, characterized in that the hole (11) in the shield (10) has a conical configuration that tapers towards the first side (12) of the shield (10), as well as the fact that the diameter of the hole (11) on the first side (12) of the shield (10) is from 5 to 7 mm, for example about 6 mm. 8. The device according to claim 7, characterized in that the inner surface (24) of the hole (11) is inclined at an angle B from 5 to 15 ° with respect to the central axis A of the hole (11). 9. The device according to any one of paragraphs. 1-8, characterized in that the diameter of the hole (11) on the first side (12) of the shield (10) is from 5 to 7 mm, for example about 6 mm 10. The device according to any one of paragraphs. 1-9, characterized in that the hole (11) in the protective screen (10) has a circular cross section. 11. The device according to any one of paragraphs. 1-10, characterized in that the hole (11) in the protective screen (10) has at least partially a parabolic cone shape. 12. The device according to any one of paragraphs. 1-11, characterized in that the hole (11) in the protective screen (10) has at least partially the shape of a hyperbolic cone. 13. The device according to any one of paragraphs. 1-12, characterized in that the hole (11) in the protective screen (10) has a circular cross section and a diameter of from 4 to 9 mm, preferably from 5 to 7 mm, for example about 6 mm 14. The device according to any one of paragraphs. 1-13, characterized in that the protective screen (10) contains a polymer, for example PFTE. 15. The device according to any one of paragraphs. 1-14, characterized in that the electromagnetic energy source (4) and spectrometer (8) of the spectroscopic system (9) are separated from the flow cell (2) by means of a window (21), and by the presence of a protective screen (10) between the liquid sample and the window ( 21). 16. The device according to any one of paragraphs. 1-15, characterized in that the device is configured to transmit light (7) emitted by the plasma (6) into a spectrometer (8) of a spectroscopic system (9) in a gas. 17. The device according to any one of paragraphs. 1-15, characterized in that the device is configured to transmit light (7) emitted by the plasma (6) into the spectrometer (8) of the spectroscopic system (9) in vacuum. 18. The device according to any one of paragraphs. 1-15, characterized in that the device is configured to transmit light (7) emitted by the plasma (6) into the spectrometer (8) of the spectroscopic system (9) without using optical fibers. 19. The device according to any one of paragraphs. 1-18, characterized in that the source (4) of electromagnetic energy is any one of the following: a laser, for example an Nd: YAG laser, and an arc spark generator. 20. The device according to any one of paragraphs. 1-19, characterized a tube (17) configured to pass a fluid stream (22), the tube (17) having an inclined portion (18), the tube (17) restricting the channel for the flow of fluid (22), a dividing element (20) located in the outlet (19) in the inclined section (18) of the tube (17) to separate part of the fluid stream (22) flowing in the inclined section (18) of the tube (17) to form a stream (1) fluid sample as well as the fact that the flow cell (2) is in fluid communication with the separation element (20). 21. The device according to any one of paragraphs. 1-19, characterized a tube (17) configured to pass a fluid stream (22), the tube (17) having an inclined portion (18), the tube (17) restricting the channel for the flow of fluid (22), the fact that the inclined section (18) of the tube (17) has an outlet (19), a vertical screen element (23) in the outlet (19) in the inclined section (18) of the tube (17), the fact that the fluid stream (22) is formed for supplying to the vertical screen element (23) from the outlet (19) in the inclined section (18) of the tube (17) to form the fluid sample stream (1), and also the fact that the vertical screen element (23) is configured to pass a stream (1) of a fluid sample along the vertical screen element (23) to the flow cell (2). 22. The device according to any one of paragraphs. 1-21, characterized in that the hole (11) in the protective shield (10) is configured to allow electromagnetic energy (3) generated by the electromagnetic energy source (4) to pass through the protective shield (10).

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