SU842485A1 - Vtscometer - Google Patents

Description

one

The invention relates to instruments for measuring the viscosity of fluids, preferably liquids, and can be applied in chemical, petroleum refining and other branches of the national economy.

Lime viscometer measuring. viscosity opaque fluid. It contains a ball placed in a container.

with the test liquid using ni-fQ

suspended from one of the arms of the recorder, with the help of which the speed of the ball moving in the liquid 1 is recorded.

However, fixing the ball with

This thread in this device and moving it with the help of levers entails an error. When measuring. In addition, the measurement results are recorded by the female. By scribing a non-transform into an optical signal, which makes it difficult to transfer measurement results over a distance. The device is bulky, difficult to operate and has little accuracy.

The closest in technical essence to the present invention is a ball viscometer with a magnetic lift. Its measuring capacity is a cylinder placed inside another thick-walled cylinder with two cavities sealed with a screwed on roof and fixed on two supports. There are nozzles in the caps to pass the measured fluid. The measuring element is a ferromagnetic ball, the transit time of which between two 15 magnetically sensitive sensors is recorded by an electric stopwatch. In the initial position, the ball is lifted by means of a magnetic elevator, which is a C-shaped guide channel connecting the upper and lower parts of the measuring capacitance, i located on its outer side. Moving the ball in the channel

It is made using a permanent magnet mounted on a bracket that rotates around the viscometer thanks to a gear motor t2.

However, the presence of an electric motor and mechanical connections in the drive complicates the design of this device.

The purpose of the invention is to simplify the design.

The goal is achieved by the fact that in a viscometer that contains a measuring capacitance with inlet and outlet openings, magnetic sensors installed at different levels of the measuring capacitance and connected to the recording unit, a ferromagnetic measuring ball, a magnetic elevator in the form of a C-shaped guide channel, connecting the upper and lower parts of the measuring capacitance, and the drive of the magnetic elevator, the measuring capacitance is made in the form of a cone, the C-shaped guide channel is made with openings throughout surface and placed inside the measuring capacitance, and the drive of the magnetic elevator is made in the form of an inductor running magnetic field with poles along the C-shaped guide channel, with the on and off switches of the traveling magnetic field placed at the lower and upper points of the C-shaped direction kdego channel.

The drawing shows the proposed device.

The device consists of a cone-shaped container 1, an inlet 2, a C-shaped channel 3, a ferromagnetic ball 4, an upper 5 and a lower 6 magnetically sensitive sensors, an outlet 7, a doubled8 moving magnetic field, date-; Chips 9 and 10 turn on and turn off the inductor respectively.

The device works as follows.

In the initial state, the ball 4 is located in the lower part of the C-shaped channel 3 in the zone of the sensor 9. The signal from this sensor goes to the actuator (not shown) and if there is a supply voltage on it, it turns on the inductor 8. As an executive body Sensor 6 is applied. By means of the traveling magnetic field of the inductor 8, the voltage 4 moves to the upper point of the guide channel 3. The position of the ball is fixed by the magnetic sensor 10, by which the inductor is turned off. Freed from the effect of the magnetic field of the inductor 8, the ball 4 falls freely in the test fluid, its free fall rate depends on the viscosity of the fluid. By the time the level at which the sensor 5 is installed, the ball acquires a uniform motion and its speed is proportional to the viscosity of the test liquid.

The free-falling ball first turns on the magnetically sensitive sensor 5 of the podaccias, the signal of the beginning of the time, and then the sensor 6, at the signal of which the time runs out. After that, the ball again falls into the guide channel and rolls to its lower point in the area of sensor 9 and the viscosity measurement cycle is repeated. The time of the ball from sensor 5 to sensor 6, recorded by the electron circuit, is proportional to the viscosity of the medium under study. The temperature of the test medium is monitored and maintained at a predetermined level.

The proposed device makes it possible to measure the viscosity of a fluid automatically in a continuous flow, and its simplicity of design and reliability in operation can be used in automated process control systems (APCS) in various national economic areas where continuous viscosity control is required.

Claims (1)

Invention Formula A viscometer containing a measuring capacitance with inlet and outlet openings, magnetically sensitive sensors installed at different levels of the measuring capacitance and connected to the recording unit, a measuring ferromagnetic ball, magnetic cable in the form of a C-shaped guide channel connecting the upper and lower parts of the measuring capacity, drive magnetic elevator, characterized in that, in order to simplify the design, the measuring capacity is made in the form of a cone. C-about different guide channel is made with