SU1642322A2 - Device of measurement of liquid viscosity - Google Patents

Abstract

This invention relates to a study of the viscosity of various liquids. The purpose of the invention is to improve the measurement accuracy. The device contains a container, a rotor, a cup, a lid, a scale, a permanent magnet of the cup, a permanent magnet of the rotor, a flywheel, two electromagnets, a tachometer, a stop with a shock absorber, an engine, a hole made in the bottom of the rotor, a rack, a spring, a holder, a constant magnet holder and reverse gear. The motor is connected to a reversing gearbox, to which an electromagnet is connected, which is installed with the ability to interact with permanent magnets mounted on the edges of the rotor rim. The essence of the invention is to pre-accelerate to the opposite sides of the rotor and the flywheel, followed by mutually compensating joint rotation. Preliminary acceleration of the rotor in the opposite direction allows a large amount of kinetic energy to be accumulated, while rotor deceleration to zero does not require visual monitoring of the number of revolutions and, thus, there is no limitation on the rotational speed due to the physiological capabilities of the human eye, which significantly improves the measurement accuracy. 3 il. (L

Description

The invention relates to studies of the viscosity of various liquids under production conditions and concerns the improvement of the known device according to the author. d ° 1520395,

The aim of the invention is to improve the measurement accuracy.

The physical essence of the invention lies in the preliminary acceleration of the rotor and the flywheel in opposite directions, followed by their mutually compensating joint rotation.

FIG. Figure 1 shows a device for measuring the viscosity of liquids before measuring, section; Fig 2 is the same, top view; in fig. 3 is the same at the end of the measurement.

Viscosity measuring device

The fluid contains capacitance 1, rotor 2, cup 3, cover 4, scale 5, arrow 6, permanent magnet 7 cup 3, permanent magnet 8 of the rotor 2, flywheel 9, electromagnet 10, tachometer 11,

lynop 12 with shock absorber, engine 13,

YU

with

YU

to

1H

hole 14, made in the bottom of the rotor 2 rack 15, spring 16, holder 17, permanent magnet 18 holder 17, reversing gear 19 and second electromagnet 20. Scale 5 is attached to cover 4, and arrow 6 is made on the rotor 2 "

A rotor 2 is placed in a container 1 with a controlled fluid, in the center of which a cone-shaped cup 3 is spring-mounted with the help of a spring 16 and fixed at the edge of the rim with permanent magnets 7 which can be attached to the rotor 2 fixed on the rim edge. With these magnets 8, and in the base of the tank 1, the stop 12 with a shock absorber is reinforced. The device is equipped with an engine 13, mounted on a rack 15, with an electromagnet 10 fixed on its axis, which in the switched on state attracts a metal cone-shaped flywheel 9, and permanent magnets 18 are attached to the electromagnet 10 with the help of holders 17 with permanent magnets 7, reinforced along the rim of the rim of the cone-shaped bowl 3. The device is also equipped with a reversible gear 19 connected to the motor 13 connected to the second electromagnet 20, which can be installed The interaction with permanent magnets 8, incremented along the edge of the rim of the horn 2. The scale 5 is graded in viscosity units. A device for measuring the viscosity of liquids operates as follows.

Remove the cover 4 from the container and pour the controlled liquid into it to a certain level. Po iop 2 with a cone-shaped cup 3 spring-loaded by means of a spring 16 is placed in the center of the tank 1 and placed on the cover 4. Place, holding the magnetic cone-shaped flywheel 9 close to the electromagnet 10, turn it on and turn on the power supply of the second electromagnet 20. At the rack 1.5, they reach the position at which the interaction of the permanent magnets 7, 18, as well as the permanent magnet 8 and the second electromagnet 20, then turn on the engine

13. With the help of the stop 12, the rotor 2 is held in the center of the tank 1. The process of simultaneous acceleration of the flywheel 9 and the cone &

3 in one direction and rotor 2 in the opposite direction. When the flywheel 9 reaches a certain rotational speed (controlled by the tachometer 11) after some time the cone-shaped cup 3 reaches the same speed, and through the reverse gear 19 a certain speed, the rotor 2 reaches the reverse direction, after which the electromagnet 10 and the second electromagnet 20 are powered simultaneously being disconnected, and the flywheel 9, disengaging from the electromagnet 10, comes into contact with the cup 3, which continues to rotate together with the rotor 9 as a whole. In this case, under the influence of the weight of the flywheel 9, the spring 1b is compressed, the permanent magnet 7 and 18 are uncoupled and the permanent magnets 7 and 8 are coupled. The simultaneous rotation of the cone-shaped flywheel 9 and the cup 3 causes the deceleration of the rotor 2 until it stops completely, and then unwinding in the opposite direction in the medium of the controlled fluid until the speed of rotation of the cone-shaped flywheel 9, the cup 3 and the rotor 2 is equalized, after which their combined damping rotation occurs, and Their rotation using the stop 12 with a shock absorber and the hole 14 in the bottom of the rotor 2 is carried out coaxially with capacity 1. It is from the moment of the start of unwinding of the rotor 2 together with the head 9 and the cone-shaped cup 3 that the rotor 2 is visually counted controlled fluid. The viscosity value is determined by special calibration curves, taking into account the magnitude of the preliminary unwinding of the rotor 2 in the opposite direction and visually readings of the number of rotor revolutions 2.

The greater the viscosity of the controlled fluid, the greater the resistance it renders to the rotation of the rotor 2 and the smaller the angle through which the rotor turns until it stops completely. The scale 5 can be graduated in a spiral curve within a few turns. Preliminary acceleration of the rotor 2 in the opposite direction allows to accumulate a significantly larger kinetic energy reserve, while due to the braking of the rotor 2 down to zero, visual control is not required.

nineteen

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 Afig.

Claims (1)

The claims ι Device for measuring the viscosity of liquids according to ed. No. 1520395, which is distinguished there, in order to increase the measurement accuracy, it is equipped with a reversible gearbox connected to the electric drive, to which a second electromagnet is connected. It is installed with the possibility of interaction with permanent magnets mounted along the edge of the rotor rim. fig.Z Compiled by S. Ginger> Editor A. Makovskaya Tehred L. Oliinyk Proofreader L. Natai Order 1142 Circulation 390 Subscribed VNIIIPI State 113035, Committee for Inventions and Discoveries under the USSR SCST Moscow, Zh-35, Raushskaya nab., D. 4/5 Production and Publishing Plant Patent, Uzhhorod, st. Gagarina, 101