RU186036U1 - TRANSPARENT PROTECTIVE WALL ELEMENT FOR USE IN METHOD OR IN DEVICE FOR OPTICAL EMISSION SPECTROSCOPY OF FLUIDS WITH LASER EXCITATION - Google Patents

Abstract

A utility model relates to a transparent protective wall element for use in a method or device for optical emission spectroscopy of laser-excited fluids. The transparent protective wall element (1) comprises a transparent plate having a first flat side and a first flat side, wherein the first flat side and the first flat side are parallel. The transparent plate is mounted in the frame of the transparent protective wall element so that the first flat side and the first flat side of the transparent protective wall element are inclined with respect to the first flat end alignment surface by an inclination angle A of 1 to 10 °. The frame, which at least partially surrounds the transparent plate and has the shape of a body of revolution, has an outer circumferential surface, an inner circumferential surface, a first end surface between the outer circumferential surface and the inner circumferential surface, and an opposite second end surface between the outer circumferential surface and the inner circumferential surface , there is a first alignment element for interacting with the second alignment element on the device for optical emission spectroscopy fluid media with laser excitation. The technical result is to protect the laser device from partial reflection of the laser beam back to the laser device. 9 s.p. f-ly, 5 ill.

Description

Technical field

This utility model relates to a transparent protective wall element for use in a method or device for optical emission spectroscopy of laser-excited fluids, as defined in the preamble of independent clause 1.

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, plasma is formed in the sample, and the electrons in the element are excited to a higher level; as electrons return to a lower energy level, they emit photons with a characteristic wavelength. Light, that is, photons emitted by plasma, is perceived and analyzed in a spectroscopic system. The wavelength is proportional to the difference in energy between the excited state and the state in which the electron returns. The measured intensity is proportional to the concentration of the measured element in the plasma, while the atomic characteristics of the measured transition include the probability of transition and the energy of the excited state, and the plasma characteristics include electron density and temperature.

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

In methods and devices for optical emission spectroscopy of laser-excited fluids, for example, in the method and apparatus presented in WO 2015/082752, a transparent medium can be placed between the fluid to be measured and the measuring devices including the laser and the spectroscopic system a protective wall element to protect the measuring devices from this fluid.

In methods and devices for laser-excited optical emission spectroscopy of fluids, the problem is that if the laser beam generated by the laser device is directed perpendicular to the surface along which the analyzed fluid flows, the laser beam is partially reflected back from the surface to the laser device, and The laser device is damaged.

Utility Model Purpose

The purpose of this utility model is to provide such an application of a transparent protective wall element in a method or apparatus for optical emission spectroscopy of laser-excited fluids that solves the above problem.

Brief Description of Utility Model

A useful model of a transparent protective wall element for use in a method of optical emission spectroscopy of laser-excited fluids or in a device for optical emission spectroscopy of laser-excited fluids is characterized by what is defined in independent clause 1.

Preferred embodiments of the transparent protective wall element are defined in dependent clauses.

This utility model is based on the placement of a transparent plate of a transparent protective wall element in a frame of a transparent protective wall element so that the transparent protective wall element is inclined with respect to the frame. The inclination of the transparent plate of the transparent protective wall element causes the laser beam to bend when passing through the transparent plate of the transparent protective wall element, thereby preventing at least partial reflection of the laser beam in the opposite direction towards the laser.

List of drawings

Below this utility model is described in more detail with reference to the drawings, where:

- in FIG. 1 shows a sectional view of the principle of operation of one embodiment of a device for optical emission spectroscopy with laser excitation,

- in FIG. 2 shows, in more detail, the laser excitation optical emission spectroscopy device shown in FIG. one,

- in FIG. 3 shows one embodiment of a transparent wall element,

- in FIG. 4 shows at a different angle the image of the transparent wall element shown in FIG. 3, and

- in FIG. 5 shows the transparent wall element shown in FIG. 3, in a section.

Detailed description of utility model

This utility model relates to a transparent protective wall element.

1 for use in a laser optical excitation optical emission spectroscopy method, or in a laser excitation optical optical emission spectroscopy method.

The transparent protective wall element 1 comprises a transparent plate 2 having a first flat side 3 and a first flat side 4, as well as an edge 5 between the first flat side 3 and the first flat side 4; wherein the first flat side 3 and the first flat side 4 are parallel.

The transparent protective wall element 1 has a frame 6 at least partially surrounding the transparent plate 2.

The frame 6 has first coupling means 7 for interacting with second coupling means 8 on a laser optical excitation fluid optical spectroscopy device to detach and align the transparent protective wall element 1 between the fluid sample stream 9 flowing through the flow cell 10 of the device for optical emission spectroscopy of laser-excited fluids and a laser unit 11 of the device for optical emission spectroscopy of fluids with nuclear excitation so that between the transparent protective wall element 1 and flow 9 of the fluid sample flowing through the flow cell 10, to form a gap (not marked by the position in the drawings), and that the laser beam 12 emitted by the laser device 11 penetrates through the transparent plate 2 transparent protective wall element 1.

The first means 7 for connecting the frame 6 has a first flat end alignment surface 13 for aligning the position of the transparent protective wall element 1 with a second alignment surface 14 of the laser excitation optical fluid emission spectroscopy device.

The transparent plate 2 is placed in the frame 6 so that the first flat side 3 and the first flat side 4 of the transparent protective wall element 1 are inclined with respect to the first flat end alignment surface 13 at an inclination angle A from 1 to 10 °, preferably from 2 to 7 ° for example, about 3 °.

The first means 7 for connecting the frame 6 may have an outer circumferential alignment surface 15 for aligning the position of the transparent protective wall element 1 with the inner circumferential surface 16 for combining laser optical excitation optical fluid spectroscopy.

The frame 6 may be in the form of a body of revolution so that the frame 6 has an outer circumferential surface 17, an inner circumferential surface 18, a first end surface 19 between the outer circumferential surface 17 and the inner circumferential surface 18, and an opposite second end surface 20 between the outer circumferential surface 17 and inner circumferential surface 18.

If the frame 6 has the shape of a body of revolution, as described above, the largest inner diameter of the inner circumferential surface 18 of the frame 6 can be from 50 to 60 mm, preferably about 55 mm, and the smallest outer diameter of the outer circumferential surface 17 of the frame 6 can be from 70 to 80 mm, preferably about 75 mm.

If the frame 6 is in the form of a body of revolution, as described above, the transparent protective wall element 1 may include a first alignment element 21 for interacting with the second alignment element 22 on a laser excitation optical emission spectroscopy device; wherein the first alignment member 21 is located on the outer circumferential surface 17 of the frame 6. The first alignment member 21 may include a steel pin, preferably a stainless steel pin, located in the through hole 23 on the outer circumferential surface 17 of the frame 6.

If the frame 6 is in the form of a body of revolution, as described above, the transparent protective wall element 1 may include a first sealing ring 24 located in the first circumferential groove 25 on the outer circumferential surface 17 of the frame 6.

If the frame 6 has the shape of a body of revolution, as described previously, the edge 5 of the transparent plate 2 has a cylindrical shape, so that the edge 5 of the transparent plate 2 has a shape and dimensions corresponding to the shape and dimensions of the cross section of the inner circumferential surface 18 of the frame 6; and the transparent plate 2 is fixed relative to the frame 6 in the indicated section of the inner circumferential surface 18 of the frame 6 between the second sealing ring 26 located in the second circumferential groove 27 on the inner circumferential surface 18 of the frame 6 and the clamp 28, for example, a retaining ring located in the third circumferential a groove 29 on the inner circumferential surface 18 of the frame 6. In this case, the transparent plate 2 may have a diameter of from 50 to 60 mm, for example, about 55 mm.

If the frame 6 is in the form of a body of revolution, as described above, the transparent protective wall element 1 may include a first magnet 30 on the outer circumferential surface 17 of the frame 6 for interacting with a second magnet (not shown) on a laser excitation optical emission spectroscopy device; while the magnets are made to indicate the correct connection and alignment of the transparent protective wall element 1 relative to the device for optical emission spectroscopy of laser-excited fluids.

If the frame 6 is in the form of a body of revolution, as described above, the frame 6 may be provided with at least one hole 31, designed to facilitate the connection of the transparent protective wall element 1 with a device for optical emission spectroscopy of laser-excited fluids, as well as to facilitate the separation of the transparent protective wall element 1 from the device for optical emission spectroscopy of laser-excited fluids.

The transparent plate 2 of the transparent protective wall element 1 has a transmittance of at least 80% for wavelengths from 190 to 1100 nm, preferably at least 85% for wavelengths from 190 to 1100, more preferably at least 90% for wavelengths from 190 to 1100 nm.

The transparent plate 2 of the transparent protective wall element 1 may include at least one of the following substances: CaF ₂ , fused silica, sapphire, MgF ₂ and crystalline quartz.

The distance between the first flat side 3 of the transparent plate 2 and the first flat side 4 of the transparent plate 2 can be from 2 to 8 mm, preferably from 3 to 7 mm, more preferably from 4 to 6 mm, for example, about 5 mm

It is obvious to a specialist that as the technology develops, the basic idea of this utility model can be implemented in various ways. Thus, this utility model and its embodiments are not limited to the above examples and may vary within the scope of the utility model formula.

Claims (26)

1. A transparent protective wall element (1) for use in a method of optical emission spectroscopy of laser-excited fluids or in a device for optical emission spectroscopy of laser-excited fluids, characterized in that: the transparent protective wall element (1) comprises a transparent plate (2) having a first flat side (3) and a first flat side (4), and an edge (5) between the first flat side (3) and the first flat side (4); wherein the first flat side (3) and the first flat side (4) are parallel, the transparent protective wall element (1) has a frame (6) that at least partially surrounds the transparent plate (2), frame (6) has first coupling means (7) for interacting with second coupling means (8) on a laser optical excitation optical fluid spectroscopy device for detachable coupling and alignment of the transparent protective wall element (1) between the sample stream (9) laser fluid flowing through the flow cell (10) of a laser optical excitation fluid spectroscopy device and a laser unit (11) of an optical optical emission spectroscopy fluid with laser excitation so that a gap is formed between the transparent protective wall element (1) and the fluid sample stream (9) through the flow cell (10), and the laser beam (12) emitted by the laser unit (11) penetrates through a transparent plate (2) of a transparent element (1) of the protective wall, the first means (7) for connecting the frame (6) has a first flat end alignment surface (13) for aligning the position of the transparent protective wall element (1) with a second flat alignment surface (14) for laser optical excitation optical fluid spectroscopy, the first means (7) for connecting the frame (6) has an outer circumferential alignment surface (15) for aligning the transparent protective wall element (1) with the inner circumferential alignment surface (16) of the laser excitation optical emission spectroscopy device, the transparent plate (2) is placed in the frame (6) so that the first flat side (3) and the first flat side (4) of the transparent protective wall element (1) are inclined with respect to the first alignment surface (13) of the flat end at an inclination angle A from 1 to 10 °, preferably from 2 to 7 °, for example, about 3 °, frame (6) has the shape of a body of revolution, the frame (6) has an outer circumferential surface (17), an inner circumferential surface (18), a first end surface (19) between the outer circumferential surface (17) and the inner circumferential surface (18), and an opposite second end surface (20) between the outer circumferential surface (17) and inner circumferential surface (18), there is a first alignment element (21) for interacting with a second alignment element (22) on the device for optical emission spectroscopy of laser-excited fluids, moreover, the first alignment element (21) is located on the outer circumferential surface (17) of the frame (6), and in the first circumferential groove (25), on the outer circumferential surface (17) of the frame (6), a first O-ring (24) is located. 2. A transparent protective wall element (1) according to claim 1, where the largest inner diameter of the inner circumferential surface (18) of the frame (6) is from 50 to 60 mm, preferably about 55 mm, and the smallest outer diameter of the outer circumferential surface (17) of the frame (6) is from 70 to 80 mm, preferably about 75 mm. 3. A transparent protective wall element (1) according to any one of paragraphs. 1 or 2, where the first alignment element (21) includes a steel pin, preferably a stainless steel pin, located in a through hole (23) on the outer circumferential surface (17) of the frame (6). 4. A transparent protective wall element (1) according to any one of paragraphs. 1-3 where the edge (5) of the transparent plate (2) has a cylindrical shape, the edge (5) of the transparent plate (2) has a shape and dimensions corresponding to the shape and dimensions of the cross section of the inner circumferential surface (18) of the frame (6), and the transparent plate (2) is fixed relative to the frame (6) in the indicated section of the inner circumferential surface (18) of the frame (6) between the second sealing ring (26) located in the second circumferential groove (27) on the inner circumferential surface (18) of the frame (6) ) and a clamp (28), for example, a circlip located in the third circumferential groove (29) on the inner circumferential surface (18) of the frame (6). 5. The transparent protective wall element (1) according to claim 4, wherein the transparent plate (2) has a diameter of 50 to 60 mm, for example, about 55 mm. 6. Transparent protective wall element (1) according to any one of paragraphs. 1-5, where on the outer circumferential surface (17) of the frame (6) there is a first magnet (30) for interacting with the second magnet on a device for optical emission spectroscopy of laser-excited fluids; moreover, the magnets are made to indicate the correct connection and alignment of the transparent protective wall element (1) relative to the device for optical emission spectroscopy of laser-excited fluids. 7. Transparent protective wall element (1) according to any one of paragraphs. 1-6, where the inner circumferential surface (18) of the frame (6) is provided with at least one hole (31) designed to facilitate the connection of the transparent protective wall element (1) with a device for optical emission spectroscopy of laser-excited fluids and to facilitate the separation of the transparent protective wall element (1) from the device for optical emission spectroscopy of laser-excited fluids. 8. The transparent protective wall element (1) according to any one of paragraphs. 1-7, where the transparent plate (2) of the protective wall element (1) has a transmittance of at least 80% for wavelengths from 190 to 1100 nm, preferably at least 85% for wavelengths from 190 to 1100 mm, more preferably at least 90% for wavelengths from 190 to 1100 nm. 9. A transparent protective wall element (1) according to any one of paragraphs. 1-8, where the transparent plate (2) of the transparent protective wall element (1) includes at least one of the following substances: CaF ₂ , fused silica, sapphire, MgF ₂ and crystalline quartz. 10. Transparent protective wall element (1) according to any one of paragraphs. 1-9, where the distance between the first flat side (3) of the transparent plate (2) and the first flat side (4) of the transparent plate (2) is from 2 to 8 mm, preferably from 3 to 7 mm, more preferably from 4 to 6 mm, for example, about 5 mm.

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