SU718714A1 - Discrete level meter - Google Patents

Description

one

The invention relates to the field of instrumentation and can be used to measure the level of petroleum products in the petroleum, chemical and other industries.

A discrete level gauge is known comprising a float with a permanent magnet and a ferromagnetic shield located on a non-magnetic tube, inside of which magnetic-controlled contacts are installed throughout the entire measuring range, connected via AND and NOT gates to the encoder input connected to the secondary device 1.

Such a level gauge has a complex structure and insufficient measurement accuracy, since with a very dense arrangement of magnetically controlled contacts, the ferromagnetic screen becomes ineffective and the lower magnetized contacts begin to affect the upper ones.

Of the known discrete level gauges, the closest one to the present invention is a discrete level gauge containing a permanent magnet float mounted on a guide non-magnetic tube, inside which throughout the entire measuring range there are magneto-controlled contacts connected to the secondary device 2 along the helix line.

In this level gauge, when the distance between the magnetically controlled contacts is reduced, two of them immediately appear in the action zone of the constant magnetic flux magnetic flux, which leads to measurement error.

The purpose of the invention is to improve the accuracy

and the resolution of the device.

This goal is achieved by the fact that on the inner surface of the opening of the float there is a double vntoobraznaya groove, and on the outer side surface of the non-magnetic pipe there is a double helical thread, the pitch of which is equal to the pitch of the internal line along which the magnetically controlled contacts are located.

FIG. 1 schematically shows the proposed level gauge; in fig. 2 is a view A of FIG. one.

The discrete level gauge contains a torondal-shaped float 1 with a permanent magnet 2, on one side of which a ferromagnetic screen 3 is vertically mounted. In the non-top 1 there is a hole through which the non-magnetic pipe 4 passes, and the double-rotor thread 5 is on the outer side surface. On the inner surface of the hole in the float 1, two helical grooves 6 are made. The float 1 with the non-magnetic pipe 4 forms a helical pair.

Inside the pipe 4, over the entire measurement range, are located along a helical line with the same pitch as the thread 5, magnetic contacts 7, the outputs of which are connected to the input of the secondary device 8, which has an output to the block 9 of digital indicators. On the bottom base of the float 1, the blades 10 are radially mounted.

Discrete gauge works as follows.

When the liquid level changes, the float 1 moves along the non-magnetic pipe 4 guide. Thanks to the helical thread 5, the float 1 rotates around the non-magnetic pipe 4 simultaneously with the vertical movement. The execution of the toroid-shaped float 1 increases the stability of the moving system. In this case, the magnetic field of the permanent magnet 2 closes the corresponding magnetically controlled contact 7.

The ferromagnetic screen 3 shields the magnetic field from the action of the above magnetically controlled contacts 7.

In the secondary device 8, the information received from the magnetic contacts 7 is transformed and indicated by a block of 9 digital indicators.

With a sharp change in the level, for example, when it is increased, a large volume of the float 1 for some time appears in the liquid, which increases the buoyancy force that tends to push the float to the surface. In this case, the float 1 is moved but the screw thread 5, making a rotational movement, the blades 10

718714

they increase the frontal resistance to this rotation, i.e., the rotation of the float 1 is impeded by the significant hydrodynamic resistance of the fluid and the sharper the level drop occurs, the greater the resistance that the float 1 experiences during its rotation. With a decrease in the level of the fluid, everything is proceeding in the same order, only the damage of the float 1 is caused by the action of its own weight, which is not compensated by the pushing force of the fluid.

Thus, with the same discreteness in the described level gauge, greater accuracy is achieved and the resolving power increases by increasing the distance traveled by the permanent magnet from one magnetically adjustable contact to another.

Claims (2)

1. USSR author's certificate number 469890, cl. G GIF 23/12, 1973. 2. US patent number 3200645, cl. 73-313, onubl. 1975 (prototype).