RU1786398C - Fluid viscosity measuring device - Google Patents

Abstract

The invention relates to the field of studying the viscosity of various liquids under industrial conditions. The essence is that the device for measuring the viscosity of liquids contains a container for the test fluid, a rotor, a centrifugal regulator, a screw, a rack-mounted sleeve with a non-self-locking thread corresponding to a screw thread, a self-locking thread at the ends of the screw corresponding to a thread made coaxial to the screw inside the rotor, stops in the upper and lower parts of the screw at equal distances from its ends, a dial-scale, an arrow and a rod mounted inside the rod and rigidly fixed in the threaded sleeve. An adjusting nut is mounted on the stem, a spring, a container cover, a second and third centrifugal regulators are mounted with the possibility of adjusting the spring tension force. The first and second control magnets are located on the inner side of the stops with the possibility of interaction with the first and second magnetically controlled contacts located in the upper and lower parts of the sleeve. The movable contacts of the first and second magnetically controlled contacts are connected to the power source, and the fixed contacts, respectively, to the start input and stop input of the time measuring unit. The adjusting nut. And the spring mounted on the stem allow adjustment. to force the pressure of the clamp and the release of the sleeve mounted on the rack. The invention improves the accuracy of viscosity measurements. 3 sludge.

Description

The invention relates to the field of studying the viscosity of various liquids under industrial conditions.

A device for measuring the viscosity of liquids is known, comprising a rotor with a centrifugal regulator immersed in a container for the studied liquid and a screw, a sleeve with a non-self-locking thread corresponding to the screw thread, mounted on a horizontal rod movable relative to a vertical strut, and the sleeve is rotatable around the axis of the rod, and at the ends of the screw a self-braking thread is made corresponding to a self-braking thread made coaxially to the screw inside the rotor, the screw is equipped with two equal stops distance x from its ends.

The disadvantage of the prototype is the low accuracy due to the lack of

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any adjustment affecting the acceleration speed of the screw and the rotor freely screwed on it during their joint sliding down. In the prototype, it is also difficult to evaluate the accuracy parameters of the technical condition of the screw pair (sleeve-screw) by measuring the screw passage time between the stops, for example, the method using a stopwatch cannot be acceptable due to the subjectivity of the method.

An object of the invention is to provide an opportunity to increase accuracy.

In FIG. 1 shows an apparatus for measuring viscosities of liquids, sectional view; figure 2 is the same, the device is a top view; Fig. 3 is a diagram for measuring device parameters.

A device for measuring the viscosity of liquids contains a container 1 for the test fluid, a rotor 2, a first centrifugal regulator 3, a screw 4, a sleeve b placed on a rack 5 with a non-braking thread 7, corresponding to the thread of the screw 4, a self-braking thread 8 at the ends of the screw 4 corresponding to the thread made coaxially to the screw 4, inside the rotor 2, the stops 9 in the upper and lower parts of the screw 4 at equal distances from its ends, a dial-scale 10, an arrow 11, a rod 12 mounted inside the rod 13 and fixed in threaded sleeve 6, adjusting nut 14 mounted on the stem T2, spring 15, cover 16 of the container 1, second 17 and third 18 centrifugal regulators with the ability to adjust the tension of the springs, and on the inner side of the stops 9 are the first 19 and second 20 control magnets that can interact with the first 21 and second 22 magnetically controlled contacts located in the upper and lower parts of the sleeve 6, and the movable contacts of the first 21 and second 22 magnetically controlled contacts are connected to the power source 23, and fixed - respectively, with the start input and input 24 becomes a block of time measurement.

The scale 10 is applied to the cover 16, and the arrow 11 is made on the rotor 2. A self-locking thread 8 at the ends of the screw 4 and at the base of the rotor 2 is made of 2-3 screws and eliminates the spontaneous screwing of the rotor 2 from the screw 4 at the initial moment of operation devices. The adjusting nut 14 and the spring 15 mounted on the rod 12, allow you to adjust the clamping force and the release of the sleeve 6 mounted on the rack 5.

A device for measuring the viscosity of liquids operates as follows.

The lid 16 is removed from the container 1 and a controlled liquid is poured into it. The rotor 2 is screwed onto the thread 8 in the upper part of the screw 4 so as to ensure

free screwing of the rotor 2, rotate the sleeve 6 around its axis by 180 °. Thus, the bottom of the rotor 2 is turned to the tank 1 and the rotor 2 with the screw 4 is released. At the initial moment of the first 3,

0 second 17 and third 18 centrifugal regulators are pressed to the center of rotation, then they are under the influence of increasing centrifugal forces, overcoming the resistance of the springs, diverge to the sides, while

5, the second 17 and the third 18 centrifugal regulators prevent excessive acceleration of the screw 4, thereby stabilizing its rotation speed, and the first centrifugal regulator 3 acts as a drive

0 energy of rotor 2. If for some reason the coefficient of friction of mutually working parts decreases, then screw 4 tends to increase the acceleration speed, while the second 17 and third 18 centrifugal regulators prevent this, slowing down the acceleration of screw 4.

In case of slowing down the acceleration speed of the screw, the second 17 and third 18 centrifugal regulators increase the speed of acceleration of the screw 4. Thus, the rotation speed of the moving elements of the device is stabilized, which reduces the measurement error as a whole. In contact with the stop 9 of the screw 4 with the sleeve

5 6, the screw 4 suddenly stops, while the rotor 2, which is in a freely screwed state on the thread, continues to spin on the self-braking thread 8 until it disengages from the screw 4. The bottom of the rotor 2 touches the surface of the controlled fluid, with the arrow 11 on the rotor 2 coincides with the original risk of the scale 10 on the cover 16, and the rotor 2 continues fading

5 inertia rotation, partially immersed in a controlled fluid. In this case, the centrifugal forces decrease and the loads of the first centrifugal controller 3 smoothly return to their original position, which leads to an increase in the number of its revolutions in the medium of the controlled fluid. The higher the viscosity of the controlled fluid, the greater the resistance it renders to the rotation of the rotor 2 and the

5 a smaller angle he turns to his shelf stop. Scale 10 can be graduated within an arc of one circle (ie, within 360 or along a spiral curve within two or more revolutions. Spiral calibration does not cause 2

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