RU2094778C1 - Multipurpose analyzer - Google Patents

Abstract

FIELD: examination and analysis of materials. SUBSTANCE: analyzer has sequentially arranged light source, automizer, monochromator, and photoreceiver the output of which is connected to signal processor input. Data output of signal processor is connected to recording unit input. Analyzer is provided with operating mode control unit. Signal processor is manufactured to operate in absorption, fluorescence and/or emission mode. Light source is pulsed and controlled device. It can also operate in absorption and fluorescence modes. First and second groups of outputs of operating mode control unit are connected to control inputs of signal processor and light source, supply inputs of which are connected to control outputs of signal processor. EFFECT: more efficient results. 8 cl, 2 dwg

Description

 The invention relates to magnetic measurements, the study of the composition of substances by determining their magnetic, magneto-optical and spectral characteristics and can be used for qualitative and quantitative control of the composition of rocks, technological products, biological objects, etc. by examining their magnetic properties.

 A typical scheme of a magnetic atomic absorption spectrophotometer contains a sequentially located light source, an atomizer with a permanent magnet that performs Zeeman splitting of the levels, a monochromator and a photodetector, the output of which is connected through the preamplifier to the input of a signal processor or analog-to-digital converter. Typically, a circuit has a reference channel and a processor that performs data correction (US Pat. Nos. 4,948,250, CL G 01 N 27/72, 1990 and N 4815847, CL G 01 R 33/12, 1989).

 Such analyzers allow measurements in complex matrices, but are characterized by insufficient sensitivity.

 Fluorescence analyzers have a higher sensitivity, the block diagram of which is similar to that described above (US patents N 4572668, CL G 01 R33 / 12, 1986 and N 5030832, CL G 01 R 33/12, 1991).

 However, these instruments do not give reliable readings in complex matrices.

 Known universal heterodyne analyzer, capable of operating both in absorption mode and in fluorescence mode (US patent N 5022757, CL G 01 R 33/14, 1991).

 It contains a scanner, a spectral filter, a spatial filter, a detector, a bandpass filter, a laser with a beam splitter and a frequency shift unit, a signal processor and a central processor, a display processor, and a display with corresponding connections. Two beams of different frequencies are sent to the object, both signals are recorded. The signal at the beat frequency is used to correct and determine the amount of substance. However, the optical system and circuitry of this analyzer are extremely complex.

 Closest to the proposed one is an analyzer containing sequentially located light sources, a measuring chamber with a permanent magnet and an atomizer in the form of a burner, a monochromator and a photodetector, as well as a series-connected amplifier, signal processor and display or registration unit (US patent N 4718763, class G 01 N 27/72, 1988).

 This device is characterized by the aforementioned drawback of atomic absorption analyzers: insufficient sensitivity. In addition, since this analyzer can work only in one mode, its readings are not reliable enough. All this narrows the scope of the possible use of a well-known analyzer.

 Thus, the technical result expected from the use of the invention is to increase the sensitivity of the analyzer and the reliability of its indications, the creation of a device that provides accurate quantitative analysis of substances of any composition, while being simple, inexpensive and reliable.

 This result is achieved by the fact that a universal analyzer containing a sequentially located light source, an atomizer, a monochromator and a photodetector, the output of which is connected to the input of the signal processor, the information output of which is connected to the input of the registration unit, is equipped with an operating mode control unit, the signal processor is configured to operate in the modes of absorption, fluorescence and / or emission, and the light source is made pulsed and controlled, with the ability to work in modes of absorption and fluorescence events, while the first and second groups of outputs of the operation mode control unit are connected to the control inputs of the signal processor and the light source, the power inputs of which are connected to the control outputs of the signal processor, respectively.

 It is also recommended to connect the third group of outputs of the control unit to the control inputs of the monochromator.

 In addition, the signal processor can be made in the form of a current-voltage converter, a background compensation unit, a pulse generator, a pulse distributor, two integrators, a logarithmic amplifier, a key, an inverter, three multiplexers, a subtraction unit, a reference voltage source, a scaling unit, and a sampling unit -storage, while the input of the signal processor is connected to the input of the current-voltage converter, the output of which is connected to the information input of the background compensation unit, the output of which is connected to the info the input input of the first integrator, the output of which is connected to the inputs of the key and the logarithmic amplifier, the outputs of which are combined and connected to the first input of the subtraction unit, the second input of which is connected to the output of the first multiplexer, the information inputs of which are connected to the output of the reference voltage source and the common bus, respectively, the output the subtraction unit is connected to the information input of the sample-storage unit, the output of which is connected to the inverter input and the first information input of the second multiplexer, the second the information input of which is connected to the output of the inverter, the output of the second multiplexer connected to the information input of the second integrator and the first information input of the third multiplexer, the second information input and output of which are connected respectively to the output of the second integrator and the input of the scaling unit, the output of which is connected to the information output of the signal processor, the control inputs of which are connected to the control inputs of the multiplexers, the key and the second integrator, and the output is pulse the second generator is connected to the input of the pulse distributor, the outputs of which are connected to the control inputs of the sample-storage unit, the background compensation unit and the first integrator, as well as to the control outputs of the signal processor.

 It is also advisable to provide the signal processor with a second key and a correction unit, the output and information input of which is connected respectively to the third input of the subtraction unit and the output of the second key, the information and control inputs of which are connected to the output of the sample-storage unit and one of the control inputs of the signal processor.

 In this case, the second input of the correction unit can be connected to the control input of the pulse distributor.

 In addition, the signal processor can be performed with two comparison units connected to the outputs of the first integrator and the correction unit.

 It is also recommended that one of the outputs of the operating mode control unit be connected to the control input of the scaling unit and / or background compensation unit.

 And finally, the background compensation unit can be made in the form of an integrator, multiplexer and subtraction unit, the information input of the background compensation unit being connected to the first information input of the multiplexer and the inputs of the integrator and subtraction unit, the output of which is connected to the second information input of the multiplexer, the output of which is connected with the output of the background compensation unit, the control inputs of which are connected to the control inputs of the integrator and multiplexer.

 In FIG. 1 shows a functional diagram of the proposed analyzer; in FIG. 2 diagram of the background compensation unit.

 Shown in FIG. 1, the analyzer contains light sources 1 and 2, an atomizer (burner) 3, a monochromator 4, a photodetector (for example, a photomultiplier tube) 5, a current-voltage converter 6, a background compensation unit 7, a first integrator 8, a first switch 9, and a logarithmic amplifier 10. a subtraction unit 11, a sample-storage unit 12, a pulse distributor 13, a pulse generator 14, a reference voltage source 15, a first multiplexer 16, an operating mode control unit 17, an inverter 18, a second multiplexer 19, a second integrator 20, a third multiplexer 21, block 22 scaling bl ok 23 registration, block 24 comparison (overload to the maximum), the second key 25, block 26 correction and block 27 comparison 9 overload to a minimum).

 Sources 1 and 2 form a controlled light source, which can operate in the absorption mode (source 1 is on), fluorescence (source 2 is on) and emission (both are on).

 As a controlled light source, one source that can change the radiation parameters (spectrum, intensity) or work in at least two modes without changing the parameters can also be used.

 The signal processor is formed by elements 6-16, 17-22, 24-27. It is configured to operate in absorption, fluorescence and emission modes.

 Converter 6 can be made in the form of an operational amplifier.

 The implementation of block 7 is shown in FIG. 2. It may contain an integrator 28, a subtraction unit 29, and a multiplexer 30. The latter provides block 7 shutdown. In the absence of a multiplexer 30, the output of block 7 is the output of block 29.

 The control inputs of integrators 8, 20, and 28 are control buses to which sampling signals are applied (this signal closes the integrator input key, thus determining the integration time) and / or reset.

 At the second input of block 11, a decremented one is fed, and the rest are subtracted.

 As a distributor 13, a standard microcircuit is used (in this case, some redundancy occurs) or a decoder that provides the required time diagram, the form of which is uniquely determined by the description of the operation of the device below. At the outputs of the distributor 13, connected to sources 1 and 2, power amplifiers are installed that provide power to the sources 1 and 2 by a pulse current. Amplifiers can be assigned to sources 1 and 2. They can be supplied with output keys controlled from block 17. It is also possible to use one power amplifier (pulse power supply) installed between the distributor 13 and sources 1 and 2, with an output multiplexer controlled from unit 17. In all of the modifications described, unit 17 provides the on and off of any of the sources 1 and 2. At the outputs of unit 13 connected to the control inputs of the integrator 8 and / or integrator of unit 7, controlled forms can be set pulse followers, changing (simultaneously or separately) the duration (duty cycle) of pulses that specify the integration time, under the action of one or two signals supplied to the distributor 13 from block 26.

 Block 17 may be made in the form of a keyboard, typesetting field, toggle switch block, etc. equipped with a timer for controlling the integrator 20 (setting the integration time and reset signal).

 Block 22 is implemented as an amplifier with a variable transmission coefficient.

 As block 23, an analog or digital voltmeter may be used.

 The above implementation of the signal processor is not the only possible. For example, you can use a series-connected analog-to-digital converter and a microprocessor, and use the display as block 23. The only important thing is the ability of the signal processor to provide the analyzer in two or three different modes. Moreover, the processor operation algorithm is entirely determined by the following description of the analyzer.

 At the outputs of the comparators of blocks 24 and 27 set indicators of overload.

 Block 26 can be made in the form of a constant voltage source controlled by voltage. It can also be made as an integrator. To control the duration of the output pulses of the distributor 13, the block 26 is performed two-channel (the same channels are combined at the input) or is equipped with an adjustable voltage source, another regulator acting, for example, on the variable resistor of the controlled pulse expander in the distributor 13.

 The analyzer works as follows.

 In the absorption mode, using block 17, a source 1 is switched on, the radiation of which is absorbed by the atoms of the test substance in the atomizer 3. The transmitted light monochromator 4 is registered by the photodetector 5 and the information signal in the form of current pulses is fed to the input of the transducer 6.

 Block 7 is designed to exclude from the information signal the constant component of the background. In principle, this can be achieved using a sampling-storage unit, which stores the signal level between information pulses, and a subtraction unit, which reduces the information signal by this value. However, the use of integrator 28 is preferable, since it allows to reduce the influence of interference.

 The output of the integrator 8, integrating each incoming pulse, a voltage occurs proportional to the volt-second area of the next pulse. The logarithm of this voltage (key 9 open) from the output of amplifier 10 is supplied to block 11, where it is subtracted from the constant voltage of source 15 (5V). After fixing the difference value by block 12, the integrator 8 is reset. As a result, the output voltage of block 12 changes only under the influence of the informative component of the signal. This voltage, bypassing the inverter 18, is supplied to the block 22 directly or through an integrator 20, which provides exposure for a given time. The intensity of this spectral line is displayed in block 23.

 In fluorescence mode, only source 2 works. In this case, the key 9 is closed, and a zero signal from the common bus is applied to the input of the subtracted block 11. The sign change necessary for this is achieved by the inverter 18, the output voltage of which is supplied through the multiplexer 19 to the integrator 20 or directly to the block 22. It is also recommended that when switching to the fluorescence mode in the atomizer 3, a round burner be turned on, which can be done automatically by the signal from the block 17.

 Similarly, in automatic mode, for example using an electric drive, the monochromator 4 can be adjusted.

 In the emission mode, both sources 1 and 2 and block 7 are turned off by supplying not the subtractor 29 output signal but the input signal of block 7 through the multiplexer 30. Otherwise, this mode coincides with the fluorescence mode with the exception of the corresponding changes in the monochromator 4 wavelength, exposure time, and coefficient transmission unit 22.

 The analyzer is set up on a blank and / or reference sample. At the same time, in the corresponding analyzer operating mode, using the block 17, close the key 25. The easiest way is to execute the block 26 in the form of an integrator. In this case, a voltage appears at the output of the latter, which compensates for the input signal of block 26. After opening the key 25, this voltage is stored, so that the analyzer is ready for operation in one mode or another. If the block 26 is made with two channels and two outputs, then the key 25 is recommended to be doubled, so that according to the corresponding control signals of the block 17, separately adjust the voltage at the third input of the block 11 and the duration of the output pulses of the distributor 13.

 Thus, the proposed analyzer allows you to work in two or three selected modes. It is very significant that in the absorption, fluorescence or emission modes, the same blocks and elements of the analyzer and the signal processor are used. This allows not only to simplify the device, reduce its cost and dimensions, but also provides comparability of the results of the analysis carried out by various methods. This is necessary to clarify the results of the analysis carried out by one of the methods. The need to use several operating modes at the same time also arises in the analysis of objects of uncertain composition. For example, in the analysis of wastewater, the salt composition is first determined in the absorption mode, the influence of the matrix and in the case of insignificant non-selective absorption go to the fluorescence mode. Sodium and potassium are better identified in the emission mode, and when determining copper, it is necessary to use both the absorption mode and the fluorescence mode.

 The tests showed that in the absorption mode, the analyzer sensitivity is 0.02 μg / ml, and in the fluorescence mode 0.01 μg / ml.

 Due to its small dimensions, the analyzer can be portable and used for automated magnetic express analysis.

Claims (8)

 1. A universal analyzer containing a sequentially located light source, an atomizer, a monochromator and a photodetector, the output of which is connected to the input of the signal processor, the information output of which is connected to the input of the registration unit, characterized in that it is equipped with an operating mode control unit, the signal processor is configured to work in the modes of absorption, fluorescence and / or emission, and the light source is made pulsed and controlled with the ability to work in modes of absorption and fluorescence, while ervaya and second mode control unit outputs the work groups are connected to the control inputs of the signal processor and the light source power inputs are connected to control outputs of the signal processor.  2. The analyzer according to claim 1, characterized in that the third group of outputs of the control unit is connected to the control inputs of the monochromator.  3. The analyzer according to claim 1, characterized in that the signal processor is made in the form of a current-voltage converter, a background compensation unit, a pulse generator, a pulse distributor, two integrators, a logarithmic amplifier, a key, an inverter, three multiplexers, a subtraction unit, a reference voltage source , a scaling unit and a sample-storage unit, while the input of the signal processor is connected to the input of the current-voltage converter, the output of which is connected to the information input of the background compensation unit, the output of which connected to the information input of the first integrator, the output of which is connected to the inputs of the key and the logarithmic amplifier, the outputs of which are combined and connected to the first input of the subtraction unit, the second input of which is connected to the output of the first multiplexer, the information inputs of which are connected to the output of the reference voltage source and a common bus accordingly, the output of the subtraction unit is connected to the information input of the sample-storage unit, the output of which is connected to the inverter input and the first information input of the second mule an multiplexer, the second information input of which is connected to the inverter output, the output of the second multiplexer being connected to the information input of the second integrator and the first information input of the third multiplexer, the second information input and output of which are connected respectively to the output of the second integrator and the input of the scaling unit, the output of which is connected to the information the output of the signal processor, the control inputs of which are connected to the control inputs of the multiplexers, the key and the second integrator a, and the output of the pulse generator is connected to the input of the pulse distributor, the outputs of which are connected to the control inputs of the sample-storage unit, the background compensation unit and the first integrator, as well as to the control outputs of the signal processor.  4. The analyzer according to claim 3, characterized in that the signal processor is equipped with a second key and a correction unit, the output and information input of which is connected respectively to the third input of the subtraction unit and the output of the second key, the information and control inputs of which are connected to the output of the sample-storage unit and one of the control inputs of the signal processor.  5. The analyzer according to claim 4, characterized in that the second output of the correction unit is connected to the control input of the pulse distributor.  6. The analyzer according to claim 4, characterized in that the signal processor is made with two comparison units connected to the outputs of the first integrator and the correction unit.  7. The analyzer according to claim 3, characterized in that one of the outputs of the operation mode control unit is connected to a control input of the scaling unit and / or background compensation unit.  8. The analyzer according to claim 3, characterized in that the background compensation unit is made in the form of an integrator, multiplexer and subtraction unit, wherein the information input of the background compensation unit is connected to the first information input of the multiplexer and the inputs of the integrator and subtraction unit, the output of which is connected to the second information the input of the multiplexer, the output of which is connected to the output of the background compensation unit, the control inputs of which are connected to the control inputs of the integrator and multiplexer.

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