SU769344A1 - Discrete level meter - Google Patents

Description

(54) DISCRETE LEVEL

The invention relates to the field of information-measuring technology and can be used in devices for measuring and controlling tests.

A discrete float uro-, 5 vnemer, containing a pin with a mag- netic duct section, shorting a U-shaped magnetic conductor with inductive excitation windings placed on it, and measuring device 1 is known.

In this design of the level gauge, the measurement windings cannot be located at a sufficiently close distance from each other, which does not allow one to achieve high resolution. At the intermediate positions of the section of the magnetic conductor, between the measurement windings, the ambiguity of the coupling is possible.

The closest in technical essence to the described is a discrete level gauge, containing a cylindrical magnetowire, and a silo with a ferromagnetic ring fixed on it, windings of excitation and measurement. Two additional jagged cores are used to eliminate the non-uniqueness of the readout, as well as a threshold device and a register of mA. Measurement windings are placed on coding jagged cores 2.30.

In the described construction of the level gauge, the measurement discreteness is limited by the size of the teeth of the coding toothed cores and the width of the ferromagnetic ring. The desire to reduce their size reduces the ratio of signals corresponding to the conditional "only and zero" scales. This does not allow to increase the accuracy of the gage.

The aim of the invention is to increase the accuracy of the discrete level meter.

This goal is achieved by the fact that the teeth of the coding core are made along a helical generator, and on the inner surface of the ferromagnetic ring the teeth are also made along the screw of the generator with the opposite thread and with a pitch equal to the pitch of the teeth of the coding core, while the measuring windings are located along the forming 1 on the surface of the coding core.

FIG. 1 shows the construction of the level gauge described; in fig. 2 is a section A-A of FIG. one; in fig. 3 - a scan of the wines, the toothed surface of the core with the placement of the read windings and the position of the ferromagnetic ring teeth relative to them (for definiteness, there is a special case when the width of the tooth is equal to the width of the groove and the number of measurement windings is three); in fig. 4 is a diagram of the output signals of the measurement windings.

The discrete level gauge contains a cylindrical magnetic core /, inside which an encoding toothed core 2 is installed, on which a float is located .3 s. ferromagnetic ring fixed on it, ring 4. On the surface of the toothed core 2, teeth are made along the helical generator, and teeth on the inner surface of the ferromagnetic ring 4 are also along the screw generator with opposite cutting and with a pitch equal to the pitch of the teeth of the core 2. Measurement windings 5 are located - forming on the surface of coding c; card 2, in the upper part of which excitation winding 6 is installed. flo forming the cylindrical magnetic core 1 there are grooves 7, which include protrusions 8 of ring 4.

Described discrete level gauge works as follows.

When the liquid level changes, the float moves the ferromagnetic ring 4 along the coding core 2. At the same time, the projections 8 on the ring 4 and the grooves 7 in the cylindrical magnetic core / do not allow the ring 4 to rotate when moving. The magnetic flux developed by the excitation winding 6 passes through the cylinder 1 through the ferromagnetic ring 4 along its toothed, screw surface and closes through the toothed surface of the heart. 2. 2. In this case, the flow in the windings of measurement 6- /, 6-2, 6-3 (see Fig. 3) induces an emf that depends on conductivity over the portions of the measurement coils that are at this time under the surface of the ferromagnetic ring four.

The areas where the tooth of the ring 4 is located opposite the tooth of the coding core 2 (shaded in Fig. 3) have the most. better conductivity, since at this point the path 1PO to the gap for the flow is twofold-alen. The combination of such areas - zones of increased conductivity creates a combination band of increased utilization. With selected, for definiteness, the conditions of a band of increased conductivity are located. vertically; moving the ring 4. Thus, reading windings 6-1, .6-2, 6-3 when moving the ferromagnetic ring 4. fall into different conductivity conditions. The emf induced in the THEM is modulated according to the position of the conduction bands, which is ultimately determined by the level of the liquid.

Thus, the use of combinative bands of increased productivity leads to the appearance of the effect of electrical reduction, which ultimately increases the accuracy of the level measurement.

Claims (2)

1. USSR author's certificate number 351086, cl. .G 01 F 23/10, 1970. 2. USSR author's certificate number i634ia2,: cl. G 01 F 23 // 12, 1977 (schrotype).