RU2085911C1 - Compact luminescent analyzer - Google Patents

Abstract

FIELD: optical instruments. SUBSTANCE: device has additional memory unit and unit which fires circuit which measures after-glow. EFFECT: increased functional capabilities. 1 dwg

Description

 The invention relates to optical instrumentation, and more particularly to the development of devices for luminescent analysis, and is intended for carrying out expression luminescent analysis in off-laboratory (field) conditions during geological studies, monitoring the environmental cleanliness of warehouses, landfills, quality control of agricultural products, expression analysis in forensics, banking and in other areas where increased reliability analysis in the field is required.

 Known devices designed for luminescent detection of various kinds of substances in off-laboratory conditions. Such devices are LSP-101 [1] and its advanced modification LSP-3. These devices are capable of irradiating the investigated object with ultraviolet radiation (short-wavelength λ254 nm or long-wavelength l365 nm) and observe its luminescence. The source of UV radiation is a VBS-1 high-frequency electrodeless mercury lamp. The power of the device is autonomous.

 The disadvantage is that the device allows only subjectively assess the intensity and color of the luminescence of the studied object.

 Known digital fluorometer "Digital Fluormeter Model 450" by Seguoia-Turner [2] which allows you to objectively assess the intensity of luminescence, to measure its spectral composition. The fluorimeter has a number of built-in amenities that make it possible to conduct a large series of measurements for express luminescent diagnostics.

 However, its use in some cases does not sufficiently ensure the accuracy of the luminescence analysis, since there is no possibility of measuring the luminescence attenuation, which is important when identifying objects, especially with a close spectral composition of the radiation. In addition, the lack of autonomous power and the large weight of the device (about 8 kg) do not allow using it as a portable analyzer for working in hard-to-reach areas.

 Known portable color luminometer "Luminance meter BM-5" for measuring the color of the object and the color of its luminescence with a built-in microcomputer company Tokyo optical co. [3] The device has portability and autonomous power and allows for express luminescence analysis on the ground. However, the disadvantage is the inability to differentiate objects by the duration of the luminescence decay.

 Also known is a portable luminescent mineral analyzer "LC-2" from Scintrex Ltd. [4] with the help of which it is possible to produce luminescent analysis of minerals in the field. The presence of a pulsed light source in the device makes it possible to differentiate luminescent minerals by the difficulty of luminescence. However, the disadvantage is the inability to determine the spectral composition of the radiation. The device also does not provide for the ability to excite luminescence in two different regions of ultraviolet excitation: short-wave or long-wave.

 Known portable luminescent analyzer [5] closest to the proposed invention for solving a technical problem. The analyzer allows you to measure the intensity and qualitatively determine the spectral composition of the luminescence of the studied object, and also has the ability to excite luminescence in two regions of ultraviolet radiation: short-wave or long-wave. To solve such problems, the device is equipped with a PMT with an appropriate amplifier, the signal from which is fed to a microammeter, which allows you to measure the relative magnitude of the signal. In addition, a filter system is built into the device, which makes it possible to qualitatively evaluate the spectral composition of luminescence, as well as a luminescent standard plate, which provides comparable results regardless of the stability of the flow of exciting light. A paralon washer allows you to firmly press the device against the radiated object and thereby make measurements in daylight.

 The disadvantages of the known device are the low reliability during the luminescent analysis of objects, especially with a close spectral composition of the radiation, as well as low comfort during the operational collection and processing of information during its operation. In addition, the known device has a limited scope. This is due to the fact that the device does not have devices for measuring the duration of the afterglow of luminescence, which is necessary to expand its functionality.

 The technical task of the proposed invention is to increase the reliability of luminescent analysis in off-laboratory conditions, as well as the creation of service amenities during operation of the device. In addition, the goal is to increase the scope of the device by expanding its functionality.

 This object is achieved in that in a well-known portable analyzer containing a source of ultraviolet radiation, a high-frequency generator, optical systems for exciting and recording luminescence, a photoelectronic current multiplier, voltage converters, a battery, a recording unit equipped with an analog-to-digital converter and digital indication, In this case, the source is optically coupled to an optical system for exciting luminescence and is connected to a high-frequency generator connected via cut voltage converters with a battery, a photomultiplier tube is optically connected to an optical system for detecting luminescence and connected to a DC amplifier connected to a recording unit, in accordance with the invention, the analyzer further comprises an afterglow measurement triggering device, a memory device and a chopper, afterglow measurement circuit trigger connected to an optical system to excite luminescence, device output and starting the afterglow measurement circuit through an analog-to-digital converter and a storage device is connected to a digital display, and through a chopper, for example, a shutter to a light source.

 The drawing shows a block diagram of a portable luminescent shock absorber.

 The portable luminescent analyzer contains an optical system 1 for exciting luminescence, a light source 2, a high-frequency generator (HF) 3, an optical system 4 for recording luminescence, a photoelectronic current multiplier (PMT) 5, a voltage multiplier for the PMT 6, a digital display 7, and analog-to-digital converter (ADC) 8, storage device (memory) 9, device for triggering the afterglow measurement circuit 10, DC amplifier 11, converter (10 B) 12, converter (25 B) 13, battery 14, converter (100 V) 15. E elements block circuit 1 11 can be located for ease of operation in the housing 1, and the elements 12 15 for the same purpose in the housing 2. In the drawing, the elements located in the housing 1 and 2 are separated by a dashed line.

 The proposed analyzer works as follows.

The luminescence of the sample is excited by ultraviolet radiation of a high-frequency discharge of mercury vapor that arises in a light source 2. A high-frequency discharge is generated by a high-frequency generator 3. Ultraviolet radiation through an optical excitation system 1, consisting of light filters that emit either a region of short-wave ultraviolet with l _max 254 nm, or long wavelength region with λ _max 365 nm, using a lens focuses on the sample.

 Luminescent radiation from a sample passes through an optical system for recording luminescence 4 and enters a PMT 5. Optical system 4 contains a set of light filters that allow recording intensity either in integrated light or in different parts of the visible wavelength range (blue, green, yellow orange or red); there is also a built-in luminescent plate standard, which provides comparable results regardless of the stability of the flow of exciting light.

 The PMT 5 is powered by a supply voltage multiplier 6, and the electric signal from the PMT is fed to the input of the DC amplifier 11 and from its output through the ADC 8 and the memory 9 to the digital indication 7. According to this scheme, the luminescence intensities are measured and its spectral composition is qualitatively determined.

 When measuring the afterglow of luminescence, an additional device 10 for starting the afterglow measurement circuit is additionally connected to the operation. One of the structural elements of this device is a chopper (photo shutter) included in the optical system 1 of the excitation of luminescence. When the shutter is closed, the access of the exciting light to the sample is terminated and the contact group is activated. As a result, the electrical signal from the converter 13 sets the storage device 9 to the standby mode, in which the value of the luminescence intensity of the sample is memorized at the moment the shutter is closed, i.e., the excitation is stopped. Subsequently, the afterglow signal from the sample through the optical system 4 enters the PMT 5 and then in the form of an electric signal, passing through the DC amplifier 11 and the analog-to-digital converter 8 enters the storage device 9, which, controlled by the launch device 10, remembers at regular intervals time sequentially 16 values of the radiation intensity of the sample decreasing during the afterglow.

 A primary battery 14 with a total voltage of 5 V is used as the primary power source for the device’s circuitry. Voltage converters stabilized with a voltage of 10 V and 25 V generate electrical signals that feed: an RF generator 3, a DC amplifier 11, through a converter 15 PMT 6 supply voltage multiplier, as well as a trigger device for the afterglow measurement circuit.

A specific implementation of the invention is illustrated by the following example. The device is made in the form of two buildings (drawing). Housing 1, having dimensions 230x170x90 mm and weight 1.5 kg, contains: a light source (high-frequency lamp VSB-1), an optical capacitor focusing the exciting light on the sample, a UFS-1 filter in combination with a cuvette in which there is an aqueous solution NiSO ₄ , which isolates the short-wavelength part from the emission spectrum of a source with λ _max 254 nm, and the UFS-2 light filter, which selects the long-wavelength part with λ _max 365 nm; luminescent standard against which measurements of sample intensities are carried out. In addition, the recording part of the device is located in the housing, which, in particular, includes filters that emit luminescence light from the test sample in the following regions of the visible spectrum: blue 400-460 nm, green 460-540 nm, yellow-orange 540-640 nm and red 640-800 nm, and for the integrated registration of luminescence light, a filter is used that transmits light in the region of 400 to 800 nm. The filters are located directly in front of the PMT 68. At the outlet of the housing there is a washer made of paralon, which allows you to firmly press the tube of the device to the emitted object and make measurements in daylight conditions. Through the viewing window, closed by a hinged lid, it is possible to visually observe the luminescence of objects before the start of measurements. Iris diaphragm located on the tube of the device, you can highlight the glow of a local area of the investigated surface.

 In case 2, having dimensions of 60x200x150 mm and a weight of about 2.5 kg, there are power and converting devices: the primary power source is a rechargeable battery with a total voltage of 5 V, and consisting of four nickel-cadmium batteries with a capacity of 7 A / h each, which ensure continuous operation of the device in the field without recharging them for 5 hours, as well as voltage converters stabilized at 10 V and 25 V and a 100 V converter. This housing can be carried on the belt through the shoulder during operation.

 Analyzer power consumption 7 W; the recorded afterglow duration of at least 10 ms; the memory capacity of the storage device is 256 bytes.

 To carry out measurements of the luminescence afterglow of the studied objects, an afterglow measuring circuit triggering device is additionally connected, the chopper of which, for example, made in the form of a light damper, stops the access of exciting light to the sample. At the time of termination of access to the exciting light, the device 10 generates an electrical signal that includes the memory 9, the input of which through the PMT, DC amplifier and ADC, receives a luminescence afterglow signal from the sample. At the same time, 16 values of afterglow intensities recorded with a time interval of 10 ms are recorded in the memory. The measurement results can be accumulated and stored for a long time in the memory of the device, and if necessary, can be displayed on a digital display. In addition, the measurement results can be processed in the form of a graph of the intensity versus time, from which the luminescence decay time (τ) can be calculated.

 The technical and economic efficiency of the invention compared with the world level of technology, which is adopted as a prototype, consists in the fact that the additional introduction of an afterglow measurement circuit into the device makes it possible to measure the afterglow duration and thereby allows more reliable luminescent diagnostics of the studied objects in non-authoritarian conditions, as the additional information obtained in this way increases the reliability of the luminescent analysis. This is especially important, for example, in the case of objects under study with a similar spectral composition of luminescent radiation. The presence of a storage device increases the efficiency of work, simplifies the taking of readings and makes it possible to process the results of a large series of measurements both directly on the ground in an inaccessible area, and the ability to store and further process them in the laboratory on a personal computer.

 The present invention is commercially feasible. A portable luminescent analyzer can be widely used for express luminescent diagnostics in off-laboratory conditions in geological studies for forecasting and searching for mineral raw materials, in the diamond mining industry for sorting technical and jewelry diamonds at their mining sites, in forensics, in agriculture, food and textile industries, in banking, in studies of the environmental cleanliness of premises, landfill areas from technical pollution. In addition, the alleged invention compares favorably with the prototype in that it has a set of built-in services that simplify the reading and processing of measurement results.

 Literature.

 1. Stepina Z. A. Berdnikov S. L. Zelikin Y. M. Field luminescent analyzers. Abstracts of the XXVII meeting on luminescence. Riga, 1980, p. 271.

 2. PC 13672-90 company "Sequia Turner" USA, "Digital fluorimeter. Model 450".

 3. PC 13110-89 from Tokyo optical co. Ltd, Japan, "Digital portable color luminometer with an integrated microcomputer for measuring color and luminescence."

 4. Supplement to the Catalog of Geophysical instrumentation and Services "Scintrex Limited", Canada, 1983, "LG-2 Portable Luminescencent Mineral Analyzer".

 5. Berdnikov S. L. Zelikin Ya. M. Trushin V. M. Portable luminescent analyzer LIGA-EF, PTE, 1982, N 1, p. 265.

Claims (1)

 A portable luminescent analyzer containing a source of ultraviolet radiation, a high-frequency generator, optical systems for exciting and recording luminescence, a photomultiplier tube with a power supply, a DC amplifier, voltage converters, a battery, a recording unit equipped with an analog-to-digital converter and digital indication, while the source is optically coupled to an optical system for exciting luminescence and is connected to a high-frequency generator connected through voltage converters with a storage battery, the photomultiplier is optically coupled to an optical system for detecting luminescence and connected to a DC amplifier connected to a recording unit, characterized in that it further comprises an afterglow measurement triggering device, a storage device and an interrupter, while the trigger of the afterglow measurement circuit connected to the optical system to excite luminescence, the output of the trigger of the measurement circuit luminescence through an analog-to-digital converter and a storage device is connected to a digital display, and through a chopper, such as a damper, to a light source.