SU1167312A1 - Fluid flow transmitter for oil wells - Google Patents

Abstract

OIL WELLS FLUID SENSOR containing a check valve with direction to qimi and a ball, the main inductor installed in the seat of the check valve and connected to the oscillatory circuit of the measuring autogenerator, the reference generator and the mixer filter, 4TOj, in order to expand the oscillator circuit It is equipped with additional inductors, which are installed in the check valve guides and are connected in series with the main coil.

Description

The invention is intended for operational continuous monitoring of the flow rate of oil wells and can be used in telemechanical complexes and automated control systems in the oil industry.

The aim of the invention is to expand the measuring range.

This goal is achieved by the fact that the fluid supply sensor for oil wells, comprising a check valve with guides and a ball, a main inductor installed in the seat of the check valve 15 and connected to the oscillating circuit of the measuring oscillator, a reference generator and a mixer filter, is equipped with additional coils inductors that are mounted in guides and connected in series with the main coil.

The drawing shows a diagram of the proposed sensor fluid supply for oil wells. 25

The sensor contains a non-return valve ball 1, a non-return valve seat 2, a main inductance coil 3, guides 4 balls, additional inductance coils 5, a ₃ θ measuring oscillator 6, a reference oscillator 7, a mixer filter 8, a ball guide consisting of three limiters located under 120 ^e in relation to each other. Within each stop usta- ³⁵ Credited additional inductor.

The principle of operation of the sensor is as follows. *

If there is no fluid flow, the check valve is closed. The distance between the check valve ball and the main inductor 3 is minimal and, therefore, the impedances introduced into the coil are maximal. Accordingly, the frequency of the measuring oscillator 6 is minimum and greater than the frequency of the reference generator 7 by the value of the sensor zero. Therefore, the frequency difference between the measuring oscillator 6 and the reference oscillator 7, obtained by adding and detecting their output signals and highlighted by an active low-pass filter, corresponds to a sensor zero, i.e. start measuring the sensor. When the feed increases under the influence of the dynamic pressure of the fluid flow, the ball 1 rises up, which in turn leads to a decrease in the resistances introduced into the main coil 3. As a result, by increasing the natural frequency of the oscillating circuit and changing the phase of the feedback voltage, the frequency of the measuring oscillator 6 is increased. This increases the output frequency of the liquid supply sensor for oil wells.

With large fluid flows, the ball 1 of the check valve moves away from the main 3 inductors and approaches an additional 5 inductors. Since the main and additional inductors are connected in series and connected to the oscillatory circuit of the measuring oscillator 6, the total change in inductance and thereby the change in the output frequency of the measuring oscillator in a fairly wide range remains constant. This can significantly reduce the non-linearity of the output characteristic and increase the measuring range of the sensor.

This sensor is used as a flow meter and has a larger measuring range and higher sensitivity.

Claims (1)

OIL WELL LIQUID SENSOR, comprising a check valve with guides and a ball, a main inductor installed in the seat of the check valve and connected to the oscillating circuit of the measuring oscillator, a reference generator and a mixer filter, characterized in that, in order to expand the measurement range, it is equipped with additional inductors, which are installed in the guides of the check valve and connected in series with the main coil.