RU2269101C1 - Turbopolarimeter - Google Patents

Abstract

FIELD: the turbopolarimeter refers to polarimeter arrangements for measuring of optical activity of substances, for industrial control and scientific researches in analytical chemistry, biotechnology and medicine.

SUBSTANCE: the turbopolarimeter has successively installed a source of radiation, a polarizer, a cuvette for the sample and also connected with a microprocessor a sensor of comparison of intensity of orthogonal polarized components of radiation passed through a measuring cuvette. An optical sensor of zero reading and an electric engine with an arrangement installed on its shaft for transmission of rotation on a flywheel in whose pivotal channel a polarizer is attached. The arrangement for transmission of rotation on a flywheel has a noncontact current collector with an immobile and a rotating parts, the magnetic circuit of the rotating part is firmly connected with the flywheel on which the source of radiation is installed. A magnetic reader interactive with a magnetic mark is linked up to the gating input of the microprocessor.

EFFECT: increases accuracy of measuring of optical activity due to reducing the influence of partial polarization of radiation.

4 cl, 1 dwg

Description

The field of technology.

The invention relates to optical instrumentation, specifically to polarimetric devices for measuring the optical activity of substances, and can be used for industrial control and scientific research in analytical chemistry, biotechnology and medicine.

The prior art.

A deploying polarimeter containing a radiation source, a light filter, a rotating polarizer, a polarizer rotation motor, a measuring cell for a sample, a stationary measuring analyzer — a beam splitter, two photodetectors and a comparator of measuring photodetector signals is known (see, for example, USSR Auth. Certificate No. 1402817 from 1988). g.).

The main disadvantage of such a polarimeter is the low accuracy of measurements for analytical studies of small amounts of optically active substances, due to the influence of uneven rotation of the polarizer and the instabilities of the registration time of the zero angular position of the polarizer.

The closest technical solution to the invention is a turbopolarimeter containing sequentially installed in the housing and optically coupled radiation source, a polarizer, a sample cell, as well as a sensor for comparing the intensity of orthogonal polarized radiation components transmitted through the measuring cell, an optical zero sensor and an electric motor connected to the microprocessor with a rotation transmission device mounted on its shaft to a flywheel, in the axial channel of which a polarizer is fixed ( m., for example, RF patent number 1696896 of 1989).

However, this device also has insufficient measurement accuracy due to spurious uncontrolled modulation distortions of the information signal due to partial polarization of the radiation source.

Disclosure of the invention.

In order to increase the accuracy of measuring the optical activity of samples by reducing the effect of partial radiation polarization on the measurement process, in a turbopolarimeter that contains a radiation source, a polarizer, a sample cuvette, and also a sensor for comparing the intensity of orthogonal polarized components connected to the microprocessor radiation transmitted through a measuring cell, an optical zero-point sensor and an electric motor mounted on its shaft a rotation transmission device of a flywheel, in the axial channel of which a polarizer is fixed, the rotation transmission device of a flywheel according to the invention is made in the form of a rotating part of a contactless current collector, which comprises a winding and a magnetic circuit fixed to the flywheel, and a fixed part of a contactless current collector - fixed winding and a magnetic circuit rigidly connected to the polarimeter body, the radiation source is mounted on the flywheel and electrically connected to the winding of the rotating part okosemnika, winding of a stationary part connected to the output of the microprocessor.

In order to increase the reliability of the operation of the turbopolarimeter, the contactless current collector is made in the form of a rotating transformer with rotating and fixed windings coaxially mounted on the shaft.

In order to further improve the accuracy of work by increasing the accuracy of fixing the zero position during measurements, the turbopolarimeter is equipped with at least one magnetic mark mounted on the rotating part of the polarimeter and mounted on the polarimeter body with the ability to interact with the magnetic mark, a magnetic reader connected to the gate input of the microprocessor .

In addition, in order to simplify the design of the polarimeter, the rotating radiation source is made in the form of a semiconductor laser with linearly polarized radiation.

A brief description of the figures of the drawings.

The drawing shows a diagram of a turbopolarimeter according to the invention.

The best embodiment of the invention.

The turbopolarimeter contains sequentially installed in the housing and optically coupled radiation source 1, lens 2, monochromator 3, polarizer 4, cuvette 5 for placement of the analyzed sample, a polarization analyzer - beam splitter 6, measuring photodetectors 7 and 8 installed at its outputs, which together with the measuring comparator 9 form a sensor for comparing the intensity of orthogonal polarized components of the radiation transmitted through the cell 5 with the sample. The turbopolarimeter also contains an optical zero-point sensor made in the form of an autocollimation unit containing a zero-channel light source 10 based on a semiconductor laser, a zero-channel beam splitting prism 11 with a photodetector 12, an objective 13 deflecting the prism 14, and at least one zero mirror 15 channel mounted on the side surface of the flywheel 16, in the axial channel of which a lens 2, a monochromator 3 and a polarizer 4 are mounted. The use of a deflecting prism 14 allows you to constructively increase the focal length lens 13, thus ensuring the compactness of the device due to parallel arrangement of the axes and the measuring optical path polarimetric sensor zero reference. The radiation source 1 is equipped with a power converter 17 in the form of a rectifier-stabilizer. The turbopolarimeter contains a contactless current collector with rotating and fixed parts. At least one magnetic mark 18 is mounted on the rotating part, and a magnetic reader 19 is mounted on the polarimeter body. The magnetic reader is mounted with the possibility of its interaction with the magnetic mark. The rotating part of the contactless current collector consists of a magnetic circuit 20, rigidly connected to the flywheel 16, and a winding 21, electrically connected to the radiation source. The magnetic circuit 20 and the winding 21 are mounted on an electric motor rotation shaft 23 provided with bearings 22. The bearings 22 are fixed in the fixed part 24 of the motor housing formed by the stator windings 25 located on the fixed part 24 and the rotor 26, rigidly fastened to the shaft 23, which through the rotation transmission device mounted thereon to the flywheel 16, in this case the magnetic circuit 20 of the rotating part of the contactless collector, transfers rotation to a flywheel. The electric motor is equipped with a tachogenerator 27 and a magnetic sensor 28 of the position of the rotor 26 of the engine. The fixed part of the contactless current collector contains a magnetic circuit 29 and a winding 30 connected, as well as a controlled multiphase generator 31 connected to the stator winding 25, a sensor 28, a tachogenerator 27, a magnetic reader 19, a photodetector 12 and a measuring comparator 9, to a microprocessor 32 with an information board 33. Thus, the microprocessor is connected to a sensor for comparing the intensity of orthogonal polarized components of the radiation transmitted through the measuring cell, an optical sensor of zero reference and electric motor elem. As can be seen, the contactless current collector is made in the form of a rotating transformer with a rotating and fixed windings coaxially mounted on the motor shaft. Two magnetic marks are installed on the rotating part of the turbopolarimeter, and the magnetic reader is connected to the gate input of the microprocessor. The radiation source is made in the form of a semiconductor laser with linearly polarized radiation.

The turbopolarimeter works as follows.

Before starting measurements using the tachometer and sensor 28 set the required speed of rotation of the turbopolarimeter. Then, using a magnetic reader, gate pulses are formed. And only after that directly measure the angle of rotation of the polarization.

The luminous flux from the optical emitter 1, made in the form of a semiconductor laser or LED, is collimated by the lens 2 and is directed through the monochromatic interference filter 3 and polaroid polarizer 4 into the cuvette compartment (cuvette) of the turbopolarimeter with the measured sample. Moreover, all of the above optical elements are rigidly fixed in the axial channel of the massive flywheel 16, rotating on a shaft 23 with bearings 22. Radiation with a rotating plane of polarization emerging from the polarizer 4, through the cell 5 with the measured sample falls on the polarization analyzer - beam splitter 6, separating the incident radiation into two orthogonally polarized beams. In this case, one beam is directed to the measuring photodetector 7, and the other beam to the measuring photodetector 8. Both receivers simultaneously record the intensities of the orthogonal polarized components of the received radiation. The measuring comparator 9 compares the signals coming from the photodetectors 7-8, and generates a signal pulse arriving at the time-pulse input of the microprocessor 32 at the time of equality of these signals.

The luminous flux reflected from the mirror 15 of the zero channel, at the moment the polarizer passes through the initial zero position, is received by the photodetector 12 (photoelectric zero-point sensor), which generates a zero-count pulse, arriving at the reference information input of the microprocessor 32. The microprocessor 32 measures the time interval between the zero pulse, coming from the photodetector 12 of the zero channel, and a measuring pulse coming from the comparator 9 at the moment of the equality of the signals of the photodetectors 7 and 8. Multiplying the value of the measured time period by a factor equal to the angular velocity of rotation of the polarizer, the microprocessor 32 determines the angle of rotation of the polarizer 4, thereby measuring the angle of rotation of the plane of polarization in an optically active manner, while the measurement result is displayed on the information board 33. At the same time, the microprocessor 32, measuring the time interval between two consecutive pulses of zero reference, determines the speed of rotation of the polarizer 4 and through the control circuit containing a multiphase generator p 31 and the stator field winding 25, keeps the rotational speed of the rotor 26 of the electric motor constant. Thus, to determine the angular position of the polarizer, the effect of uniform continuous angular rotation is used. The accuracy of determining the current angular position of the polarized radiation emitter is determined by the uniformity of its rotation, therefore it is rigidly connected to the massive flywheel 16, which enables smooth rotation of the radiation source with the polarizer around the axis of the shaft 23. Uniform rotation of the polarized radiation source assembly is carried out by the electric motor rotor 26 by phase-frequency control currents of windings 25 of the stator of the electric motor. connected to the control PWM (pulse width modulation) outputs of the microprocessor 32, to the information inputs of which a tachogenerator 27 and a magnetic sensor 28 of the position of the rotor 26 of the electric motor are connected. Using a similar design of the polarizer drive assembly can sharply increase the uniformity of its rotation by reducing the influence of disturbing factors of the electric motor.

To reduce the effect of partial polarization of the radiation source, it rotates together with the polarizer, therefore, power is supplied to it from the control microprocessor 32 through the converter 17 of the optical emitter power supply in the form of a stabilizer rectifier and from a contactless current collector including a rotating magnetic circuit 20, a rotating winding 21, and a fixed magnetic circuit 29 , a stationary winding 30, and the input of the radiation source is connected to the output of the rotating windings of a contactless current collector, the fixed windings of which dineny to the control output of the microprocessor 32. In this case, in order to increase reliability of the polarimeter rotary contactless current collector is designed as a rotary transformer mounted coaxially on a shaft rotating and stationary windings.

The photodetector 12 is connected to the reference synchronizing input of the microprocessor 32. The zero-position photoelectric sensor has a low accuracy of determining the zero reference, due to the strong influence of the photon and amplitude noise of the laser. Therefore, in order to increase the accuracy of fixing the zero position, the pulse from the photodetector 12 of the zero signal is additionally gated by the microprocessor using an auxiliary reference pulse generated by the magnetic reader 19 of the zero signal 19 when its magnetic mark 18 passes, fixed in the zero position on the rotating magnetic circuit 20.

Industrial applicability.

The turbopolarimeter can increase the accuracy of polarimetric measurements by 3-4 times, which allows it to be widely used in polarimeters in various industries, in particular in biotechnology and medicine.

Claims (5)

1. A turbopolarimeter containing sequentially installed in the case and optically coupled radiation source, a polarizer, a sample cell, as well as a sensor for comparing the intensity of orthogonal polarized radiation components passing through the measuring cell, an optical zero sensor and an electric motor mounted on its shaft, connected to the microprocessor a device for transmitting rotation to a flywheel, in the axial channel of which a polarizer is fixed, characterized in that the device for transmitting rotation to a flywheel made in the form of a rotating part of the contactless current collector, which contains a winding and a magnetic circuit mounted on the rotation shaft, rigidly connected to the flywheel, and the fixed part of the contactless current collector - fixed winding and a magnetic circuit, rigidly connected to the polarimeter body, the radiation source is mounted on the flywheel and is electrically connected to the winding the rotating part of the current collector, the winding of the fixed part is connected to the output of the microprocessor. 2. The turbopolarimeter according to claim 1, characterized in that the contactless current collector is made in the form of a rotating transformer with rotating and fixed windings coaxially mounted on the shaft. 3. The turbopolarimeter according to claim 1 or 2, characterized in that it is equipped with at least one magnetic mark mounted on the rotating part of the polarimeter and mounted on the polarimeter body with the possibility of its interaction with the magnetic mark with a magnetic reader connected to the gate input of the microprocessor. 4. The turbopolarimeter according to claim 1 or 2, characterized in that the radiation source is made in the form of a semiconductor laser with linearly polarized radiation. 5. The turbopolarimeter according to claim 3, characterized in that the radiation source is made in the form of a semiconductor laser with linearly polarized radiation.