SU920478A1 - Refractometer - Google Patents

Description

The invention relates to refractometry, in particular to differential refractometers, and can be used to control technological processes in the refining, chemical, pischee, biomedical, and other industries. A refractometer is known that contains a radiation source, an optical system, a differential cuvette and a two-element photodetector P. The closest technical solution to the present invention is a refractometer containing a radiation source, an optical system, a differential cuvette, a two-element photodetector mounted on a platform kinematically connected to a reversible motor, which is also connected to the recording amplifier 2. The disadvantage of the known device is limited accuracy, due to the dependence readings from the optical density of the analyzed liquid. The purpose of the invention is to improve the accuracy. This goal is achieved by the fact that a refractometer containing a radiation source, an optical system, a differential cuvette, a two-element photoreceiver mounted on a platform, kinematically connected, with a reversing motor, which is also connected to a recording device, and electrically connected to a differential amplifier, an adder, a comparison device, a reference voltage source and a photometer, whose photodetectors are installed on the platform, and the output ene with one input device, comparator, another input coupled to a source of reference voltage and its output and the output of the differential amplifier are connected to the inputs of the adder, the output of which is connected with a reversible motor. Figure 1 shows the location of the photodetectors of the refractometer and the photo meter; in fig. 2 is a block diagram of the device. The device contains photosensitive cells 1 and 2 of a two-element photodetector, photosensitive cells and k measuring channel and a photosensitive cell 5 of the reference channel of the photometer. All photosensitive cells 1-5 are combined in a photodetector device 6. The device also contains radiation sources 7 optical system 8, differential cell 9 platform 10, light guide 11 of the reference meter of the photometer, differential amplifier 12, photometer consisting of adder 13 and splitter device 1 the output of which is connected to one input of the comparison device 15, the other input of which is connected to the source of the reference voltage 16. The outputs of the differential amplifier 12 and the comparison device 15 are connected to the inputs of the adder 17 of One of which is connected to a reversible motor 18, which is kinematically connected to the recording device 19 and to the platform 10 on which the photoreceiver 6 is installed. The device works as follows. The light flux from the source 7 is transmitted by the optical device B. It is directed to a differential cell with a branch 9, the cavities of which are filled with comparative and measurable fluids with refractive indices n and Pu, respectively. The deviation of the light flux at the output of the differential cuvette 9 is proportional to the difference between the refractive indices of the comparative and measured liquids and leads to its displacement on the surface of the five-element photo.receiver 6. The photosensitive elements 1 and 2 of the photodetector 6 are connected to the input of the differential amplitude l 12, at the output of which a mean value is formed, proportional to the measured difference in the refractive indices of liquids. This signal arrives at the adder 17. If the optical density of the measured liquid does not change relative to its initial value, the signal from the differential amplifier 12 passes through the adder 17 without changing and enters the reversing motor 18, which, working on the signal of the difference of the refractive indices, shifts platform 10, on which the photodetector 6 is fixed, by an amount equal to the displacement of the light flux on the surface of the photodetector 6. Thus, I align the signals from the photosensitive elements 1 and 2 There is no electrical signal at the output of the differential amplifier, and the motor 16 stops working. The measurement of the measured signal is carried out by the device 19, associated with the rotation of the engine relative to the zero point. Under the initial conditions, when calibrating a refractometer, the optical densities of the comparative and the measured fluids are equal. During operation, the optical density of the liquid being measured can vary, as well. The luminous flux of the radiation source 7, which causes the appearance of an error, the value of which is determined by the expression q Hj K0ptgA, where k is the proportionality coefficient; d. - refracting angle of the cuvette; 0 (5 is the luminous flux of the radiation source; a is the width of the light beam; DV is the measurement of the optical density of the measured liquid. Relatively relative. The photosensitive elements 3 and k of the photodetector 6 are connected to the inputs of the adder 13, the output signal of which is proportional to the luminous flux incident on the photodetector 6 and does not depend on the displacement of the light beam on the surface of the photoreceiver. The output signal from the adder 13 is fed to a separating device C, where, is divided into a signal proportional to the light $ g flow, fixed photodetector element 5 obrazm 6. Thus the output signal from the divider (fotometpa) is independent of variations of the light source radiation flux 7.

An electrical signal proportional to the change in the optical density of the liquid being measured is balanced by the signal E (f of the source of the reference voltage 16 in the comparison device 15, Electric Signal Unit proportional to the initial optical density of the liquid being measured. The correction signal is fed to the second input of the adder 17, which allows at the output of the adder, to receive a signal proportional to the diversity of the refractive index of the measured and comparative liquid and invariant to changes in the optical density of fluid and light source of radiation.

Claims (2)

1. USSR author's certificate No. 12 “1b7. cl. G 01 N 21A6. 1959. 2.US Patent ff 368t) 963, cl. G 01 N 21 / t2, published. 1972 (prototype). .