SU1002904A1 - Viscometer - Google Patents

Description

(S) VISCOSIMETER

one

The invention relates to viscometers and can be used to measure the viscosity properties of liquids.

The ball viscometer is known, which contains a device for releasing balls, a tripod, a tube, the lower end of which is closed by a stopper, as well as ultrasonic sensors. After 10-15 minutes, when the equipment warms up, the ball is released from the device into the tube, and as soon as it passes the top the mark where the first ultrasonic sensor is located, the resulting echo signal triggers the electrical stopwatch. A countdown of time begins, which continues until the ball reaches the second ultrasonic sensor J-lk, which turns off the electric stopwatch G 1.

The disadvantage of such a device is the complexity of the design and its low mobility, i.e. It is of little use for rapid analysis, for example, in field conditions or in conditions of small enterprises or workshops.

The closest technical solution to the invention is a viscometer containing two working bodies in the form of pistons, which are connected to the measuring system with rods fixed to the pistons.

10 One piston is immersed in the test liquid, and the second in a liquid with known viscosity. The measurement system is a mechanism in the form of a rocker arm associated with an indicator arm. If there are discrepancies in viscosity of the liquids described above, the pistons undergo various conditions, which is fixed 20 and converted by the measuring system to the angle of rotation of the indicator arrow 23.

The disadvantage of this device is that an additional liquid is needed for the measurement, with which the analyzed substance is compared. The viscosity of this additional fluid with a known viscosity varies with temperature and with time, and therefore it is necessary to introduce a correction to the measurement.

The purpose of the invention is to simplify the measurement process.

This goal is achieved by the fact that in a viscometer containing two working bodies connected with the measuring system by means of rods rigidly fixed on them, the working bodies are made in the form of balls made of ma-. materials of different density, different from each other diameters, and set coaxially, the larger ball is made with an axial hole, and its .. rod is hollow, with the smaller ball rod passes through the axial hole and the larger ball rod, while the larger ball is located above the smaller and has a lower density.

In addition, the measuring system is made in the form of a scale at the end of the rod of the smaller ball and a marker located on this rod with the possibility of contact with the end of the hollow rod.

The drawing shows the proposed viscometer.

It contains a housing 1 with the test liquid 2 and working bodies coaxially placed in it in the form of a ball 3 of larger diameter and a ball of smaller diameter A with different density, and the diameter of the larger ball 3 is chosen so that it can freely slide along the walls of the housing, and the diameter and the density of the smaller ball 4 is chosen based on the desired scale length. I -.

Through the larger ball 3 missed

The first rod 5 is rigidly connected to it, and inside it the second rod 6 passes freely, on which the marker 7 is located, in the initial state abutting against the end of the first rod 5. On the second rod 6 there is a scale 8, which is graduated in liquids. as the dependence of the velocities of the fall of the balls is proportional to the viscosity of the liquid, the scale will be linear, which simplifies the calibration.

The viscometer works as follows.

A node with a larger 3 and smaller Q balls, rods 5 and 6 is lowered into the housing 1 with the liquid under study 2. Since the falling speed of the smaller ball 4 will be higher than the falling speed of the larger ball 3 due to the larger annular gap between the ball and the wall of the housing 1, and also because of the greater density, the first rod 5 will move along the second rod 6, shifting the marker 7 on a scale of 8.

The greater the viscosity of the fluid, the shorter the distance

A marker 7 is made, for example, in the form of an arrow.

When reaching the bottom of the housing 1, the balls are combined, and the marker 7 is held on the second rod 6, due to

friction forces at the level to which the end of the first rod 5 displaced it. To automatically retrieve information, the rods can be made as integral parts of the sensor,

for example inductive. In this case, a coil can be located in one rod, and the second will serve as a core. The signal from the sensor can be used both for displaying a measuring instrument on the scale and for introducing automatic viscosity of a fluid into the system.

In order to reduce the wall effect, the inner walls of the body can be made with several edges located on its inner surface evenly around the circumference. Such a solution allows the edges to be used as guides for a larger ball while

It is the same time to minimize the contact surface of the ball with the vessel walls.

The economic effect of the viscometer is that, by means of design changes, the design of the device is simplified by its small size.

Claims (1)

1. A viscometer containing two working bodies connected to the measuring system by means of rods rigidly fixed on them, characterized in that, in order to simplify the measurement process, the working bodies are made in the form of balls