SU1272174A1 - Device for continuous measuring of contamination degree of liquid - Google Patents

Abstract

The invention relates to a device for continuous measurement of the degree of contamination of a liquid, can be used in the chemical industry, and allows an increase in the measurement accuracy by reducing the time drift. The device contains a vessel 37 with nozzles 40 and 41

Description

with: - -, SL / DL for inlet and outlet of the analyzed liquid 39, vessel 38 with clean liquid Koctbro, connected to vessel 37 through a filter 42 by pipe 43. In vessels 37 and 38 there are floats 27 and 28 fixed on hangers 15 and 16. On the latter, rods 74 or 30 and 30 are mounted with disks 33 and 34 and counterweights 35 and 36 suspended on opposite ends. Disks 33 and 34 and floats 27 and 28, mounted on the same suspension, are located in different vessels and have the same diameter, mass and volume. 2 Il.

Claims (1)

The invention relates to devices for measuring the degree of measurement of a contaminated liquid. The purpose of the invention is to improve the measurement accuracy by reducing the time drift. Figure 1 shows a device diagram; Figure 2 shows vessels with liquids and scales hangers, top view. The beam 1, installed with a prism 2 and a pillow 3 on the base 4, is equipped with sensitivity adjusting nuts 5 and a balancer 6, end prisms 7 and 8 for balls 9 and 10, and an I1 inductive non-compensation converter 12 that creates an unbalance electrical signal for amplifier 13, which, together with inductive non-compensation converter 12, is powered by a high-frequency signal (frequency on the order of 100–200 kHz) from generator 14. Suspensions 15 and 16 are mounted on hinges 9 and 10, respectively, with moving permanent magnets and 1 7 and 18, interacting with compensation coils 19 and 20, connected to reference resistors 21 and 22, from which the voltage on the concentration recorder 23 and the digital reading device 24, calibrated in units of impurity concentration, are removed. Suspensions 15 and 16 are equipped with gigs 25 and 26, respectively, with the main and additional floats 27 and 28 equal in weight and volume to one another. On horizontal rods xx 29 and 30, mounted on hangers 15 and 16, on one side are mounted ti 31 and 32 with discs 33 and 34, the same weight, diameter and volume, and on the other side, 35 and 36, and 32 hangers 15 with the main float 27 immersed in vessel 37 C with contaminated (analyzed) liquid carry the disk 34 immersed in vessel 38 with the purified liquid, and vice versa, the suspension 31 of suspension 16 with additional float 28 immersed in vessel 38 with the purified liquid, bears on itself the disk 33, immersed in the vessel 37 with the contaminated liquid. In order to increase the time stability of the weights, the diameters of the disks 33 and 34 are chosen to be equal to the diameters of the floats 27 and 28, made in the form of cylinders. Vessel 37 for contaminated fluid 39 is provided with nozzles 40 and 41 for inlet and outlet of the test fluid and is connected via filter 42 and conduit 43 to vessel 38 for purified fluid. To ensure that the suspensions (precipitations) 44 and 45, as well as the suspensions 46 and 47, which fall out during the long-term measurements, the main float 27 and the disk 33, as well as the additional float 28 and the disk 34, are equal in mass, which creates an increased temporary stability and balancing loads on the yoke 1, floats 27 and 28 and discs 33 and 34 are placed in vessels 37 and 38 symmetrically and at equal distances relative to the intake and. drain pipelines (figure 2). The device works as follows. In the initial position, when the floats 27 and 28 and the discs 33 and 34 are in the air, the rocker 1 is brought into balance by means of the imbalance adjustment nuts 6, its flag 11 is in the middle part of the inductive non-compensation converter I2 and the latter gives the imbalance signal equal to zero to the amplifier 13, while the output voltages supplied to the concentration recorder 23 and the reading device 24 are also zero (ka and the readings of the recorder 23 and device 24), when the floats 27 and 28 and the disks 23 and 24 in vessels 37 and 38. Due to the presence of difference Archimedean forces pushing out the floats 27 and 28 and the disks 33 and 34 with different forces from the contaminated and purified liquid, the rocker arm 1 together with the flag 11 is unbalanced. Since the action of force of gravity, i.e. the weight, the weight of the suspension 44, settled on the float 27, is balanced by the weight of the suspension 45, settled on the disk 33, and the weight of the residual suspension 46, passed through the filter 42 and settled on the float 28, is balanced by the weight of the suspension weight 47, settled on the disk 34, then the beam 1 does not experience a temporary imbalance, and hence the drift in time. The imbalance of the rocker arms 1, proportional to the differential Archimedean force, is obscured by the flag 11, and the inductive non-compensation converter 12 causes the unbalance signal to the amplifier 13, which forms the compensation current and the corresponding one. the reference signals for the recorder 23 to the concentration and the readout device 24 are proportional to the measured concentration of suspensions in the contaminated liquid. The concentration recorder 23 and calibrated device 24 were calibrated directly in units of concentration, for example, in mg / l or mg / ml using standard suspensions, the concentration of contaminants in which is known. The compensation current entering the compensation coils 19 and 20 returns the beam 1 to its original 1744 position, carried out an electric power balance and made it possible to conduct continuous measurement of the current contamination and concentration of suspensions in the flow of liquid entering the vessel 37. As shown by preliminary experiments and studies The proposed device allows to increase the accuracy of measuring the degree of contamination of a liquid by 2-3 times; reduce the additional error from sedimentation of suspension on test bodies (- 10 times or more); increase the time stability of the balance (by 8–10 times), as well as automate the process of continuous measurement and recording of the current concentration of suspensions in the flow of contaminated liquid. The proposed device can be widely used in chemical, processing and other industries of the national economy for physico-technical measurements and monitoring of the degree of contamination of fluids in a stream, for technological and logical control and optimization of wastewater treatment processes, etc. Apparatus of the Invention A device for continuous measurement of the degree of contamination of a liquid, comprising a vessel with sockets for inlet and outlet of the analyzed liquid, a vessel with pure liquid, a connecting pipe and floats, placed in the vessels and fixed on the balance beam with the help of suspensions, I distinguish by the fact that In order to improve the measurement accuracy by reducing the time drift, it is equipped with rods fixed to the suspensions. suspended at opposite ends, disks and counterweights and a filter installed in the connecting pipe, the disks and floats fixed on the same suspension, are located in different vessels and have the same diameters, and the disks have the same mass, diameter and volume. 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