SU832245A1 - Method of detecting damages of complex pipeline systems - Google Patents

Description

The invention relates to pipeline transport and can be used to detect damage in complex hydraulic systems. ^uh

Known methods for detecting places and time of damage to pipeline systems, which include creating a transient process in the system, installing pressure sensors and determining the time and place of damage from the difference in their response time [1].

The disadvantage of these methods is the impossibility of their use 15 for complex branched-closed pipeline hydraulic systems.

A known method for remote detection of a liquid leak in a pipeline, based on the creation of a transient with the help of a water hammer, consists in the fact that the change in the attenuation rate of the transient is measured in the pipeline, after which the equivalent diameter of the leak hole and the distance to it are successively determined. [2].

The disadvantage of this method is its low efficiency of detecting · 30 damage sites in complex branched-closed pipeline systems. This is due to the fact that in complex systems, in addition to direct transient pulses, a number of additional reflected pulses arise, which have a significant effect on transient attenuation rate. The reflected pulses significantly distort the process of damping of water hammer and introduce a large error in the calculation of the equivalent leakage diameter and distance to it.

The purpose of the invention is to increase the efficiency of damage detection in complex hydraulic systems.

This goal is achieved by the fact that in a complex hydraulic system create a hydraulic shock, for example using centrifugal pumps installed at one end of the system, and a high-speed valve installed at the other end. The pulses of the hydraulic shock signal reflected from various pipes are recorded using highly sensitive pressure sensors and a loop oscilloscope. The deviations of the amplitude of 3 reflected pulses from the calibrated values obtained previously in a similar way for a fully operational pipeline system are determined. In this case, for the oscillograms of calibrated pulses of hydraulic shock, a correspondence is established between the number of the pulse and the number of the pipeline of the hydraulic system. By the number of pulses with an amplitude different from the calibrated values, the location (number of the pipeline) of the damage is determined.

The presence of reflected hydraulic shock signals serves to achieve this goal, while in the known methods, in the analysis of the transition attenuation rate, they play a negative role and lead to large errors.

Using the method makes it possible to increase the detection efficiency of complex

832245 4 branched-closed pipeline systems.

Claims (2)

(54) METHOD OF DETECTING DAMAGES OF COMPLEX PIPELINE SYSTEMS 3 83 tons of reflected pulses from calibrated values obtained previously in a similar way for a fully serviceable pipeline system. In this case, for the oscillogram of calibrated hydraulic shock pulses, a correspondence is established between the pulse number and the pipeline number of the hydraulic system. By the number of pulses with an amplitude different from the calibrated values, the location (pipeline number) of the damage is determined. Available; of the reflected signals of a water hammer serves to achieve the goal, while in the known methods they play a negative role in analyzing the decay rate of the transient process and lead to large errors in error. Using the method makes it possible to increase the efficiency of detecting damage to complex 54 branched-closed pipeline systems. Claim method for detecting impinges of complex piping systems, implying the creation of a transient process using a hydraulic impact, characterized in that, in order to increase the efficiency of damage detection, the impulses of hydraulic impact signals reflected from various pipes of the system are detected, the deviation of the amplified impulses is determined From the calibrated values and by the number of the pulse and the magnitude of the amplitude deviation, the position of the damage is judged. Sources of information taken into account in the examination of 1 USSR author's certificate 208554, cl. F 17 D 5/02, 1963. 2. USSR author's certificate 232680, cl. F 17 O 5/02, 1967.