RU2717557C1 - Method for evaluation of residual life of coils of reaction furnaces - Google Patents

Abstract

FIELD: reaction furnaces.SUBSTANCE: invention can be used to predict residual life of coils of reaction furnaces. Essence of the invention consists in the fact that the coil wall thickness is measured by the ultrasonic method, at that, at first, the pipe surface is scanned by the magnetic method, detecting the zones with the maximum intensity of the constant magnetic field, in which the wall thickness is measured using an ultrasonic method, wherein value of measured thickness is corrected, considering thickness of carburized layer and change of speed of passage in coil wall of coil of ultrasonic longitudinal waves, wherein the magnetic parameter is the resultant intensity of the constant magnetic field, and the ultrasonic parameter is the propagation velocity of longitudinal ultrasonic waves, and the remaining life is determined by a certain mathematical formula.EFFECT: high accuracy of estimating residual life of coil of reaction furnaces.1 cl, 4 dwg, 1 tbl

Description

The invention relates to the field of non-destructive testing and can be used to refine the assessment of the residual resource by determining the actual thickness in the zone of the combined magnetic and ultrasonic testing for early detection and measurement of hazardous zones in the coils of reaction furnaces.

When assessing the residual life of the coils of the radiant part of the pyrolysis furnace, both non-destructive and destructive control methods are used when a witness specimen is cut out of the coil, and its destruction test allows to establish the remaining life of the coil. At the same time, to increase the reliability of determining the residual life, along with the study of mechanical properties, the chemical composition and microstructure are studied [ITN-93 Instructions for technical supervision, methods of audit and rejection of tube furnaces, tanks, vessels and apparatuses of oil refining and petrochemical industries].

Currently, there are many methods for assessing the residual life of a coil, but all of them are divided into two main groups - deterministic and probabilistic. In addition, the measurement of controlled parameters or processes by diagnostic methods is not integral, but local. Moreover, measurements in one control zone, when passing from point to point, can give a significant discrepancy in the recorded parameters, which greatly complicates the determination of the residual life of the coil.

The probabilistic approach is based on the results of statistical processing, without taking into account any specific factors. The use of a statistical assessment of the residual resource is described in [Methodology for assessing the residual resource of tube furnaces in oil refining, petrochemical and chemical industries. - Volgograd: VNIKTI petrochemical equipment, 1999 - 44 p.]. So, when determining the residual life of the furnace elements, in the presence of only corrosion wear of the wall thickness of the pipe coils, the calculation of the resource is carried out by changing the current wall thickness. In the calculation, the values of the regulated and confidence probability are used, which are determined depending on the heated product, and the wear model (linear or power-law) is also used.

The deterministic method is based on the explicit and accurate consideration of the influence of factors adopted during the operation of the equipment, the use of numerical parameters (pressure, temperature, pipe wall thicknesses, mechanical characteristics of the metal). When using the deterministic approach to assess the resource of the coils of reaction furnaces, the main determinants are the results of studies of total corrosion wear, creep of the metal, and a decrease in the strength properties of the metal.

The article presents the results of a study of the dependence of the depth of the carbonized layer in steel 20X23H18, located in a hydrocarbon medium, on the time of exposure to high temperature. The proposed simplified technique shows the possibility of controlling the thickness of the carburized layer by measuring the surface energy and the intensity of the constant magnetic field [Naumkin EA, Chekenev OA Determination of the depth of high-temperature carbonization of steel 20X23H18 in contact with coke // NTZh “Oil and Gas Business”. - Ufa, 2008. - T. 6, - No. 1. - S. 123-125.].

There is a method of ultrasonic monitoring of the state of a metal operating under creep conditions and predicting its residual life, which consists in emitting an ultrasonic wave into a controlled product, receiving a wave transmitted through a controlled product with a constant base between the emitter and receiver, measuring the wave propagation time and then determining the metal state use a surface ultrasonic wave, measure the time of its propagation on the standard, then on the product in the direction of maximum tensile stresses acting in the metal during its operation, and in the same section in the direction perpendicular to it, and for each direction, the relative change in speed is determined, then the state of the metal is estimated using the known dependencies of the relative change in velocities on the density of micropores using the maximum of the obtained values micropore density, determine its residual life. To implement the above method, a device (acoustic unit) is proposed that contains two transducers of surface waves, while the prisms are interconnected by flexible metal plates and have magnets.

The disadvantage of this method is that this method does not take into account the presence of carburized and decarburized zones in the pipe wall; requires measuring the propagation time of the ultrasonic wave on the reference samples; to implement the method requires a special acoustic unit; has a high complexity, especially when searching for the most damaged area.

The closest technical solution, selected as a prototype, is a method for predicting the residual life of the coils of reaction furnaces, including ultrasonic testing [STO-SA-03-004-2009 “Requirements for technical supervision, revision and rejection”]. According to the prototype method, the inspection of the furnace coil is carried out in each scheduled repair and includes the following operations: the thickness of the walls of pipes and tubes (bends) is measured for the radiant part of the furnace coils completely; for the convection part of the furnace coil - in accessible places. The thickness measurement of the walls of pipes and tubs (bends) is carried out using portable ultrasonic thickness gauges with a measurement accuracy of +/- 0.1 mm in places of the most likely wear; for stamped welded rolls (bends) - near the longitudinal seam and on each half; for whole - at the largest and smallest radii of curvature and in the neutral zone; d) the measurement of the inner diameter of the pipes in twins is carried out for radiant coils depending on the corrosion rate: - up to 0.1 mm / year - selectively from different temperature zones, if wear is detected, a measurement of 100% is carried out; - from 0.1 to 0.3 mm / year - selectively from various temperature zones, in the amount of 100% through repair; - over 0.3 mm / year - in the amount of 100%.

As a result of the measurement, the desired thickness is calculated depending on the propagation velocity of the ultrasonic pulses in the material of the coil element under study.

The disadvantage of this method is that it does not take into account the depth of the carbonized layer. In addition, measurements are taken at random in randomly selected zones.

A significant drawback of all these methods is that they do not allow to determine with sufficient accuracy the actual wall thickness of the pipe, which, in turn, negatively affects the results of calculating the residual life of the reaction furnace coils.

The objective of the invention is to increase the reliability of the coil of the reaction furnace by increasing the accuracy of determining the wall thickness, and the resource of the coils of the radiant section of the reaction furnaces.

The technical result of the invention is to increase the accuracy of estimating the residual life of the coils of the radiant section of the reaction furnaces by identifying potentially dangerous zones and determining the actual pipe wall thickness in them using combined magnetic and ultrasonic control.

The technical result of the invention is ensured by the fact that in the method for predicting the residual life of the coils of the reaction furnaces, which includes measuring the wall thickness of the coil by the ultrasonic method, characterized in that the pipe surface is first scanned by the magnetic method to identify zones with a maximum value of the constant magnetic field in which the ultrasonic method measure the wall thickness, and the value of the measured thickness is adjusted, taking into account the thickness of the carburized layer and changes in speed the passage of ultrasonic longitudinal waves в through the material of the coil wall ϑ, and the resultant constant magnetic field strength (Hr, A / m) is used as the magnetic parameter, and the propagation velocity of longitudinal ultrasonic waves (ϑ, m / s) is used as the ultrasonic parameter, and residual life is determined by the formula:

where S _ISM is the measured wall thickness of the pipe coil in the delivery state, mm;

ΔS _UZV - thickness, taking into account the change in the transit time of ultrasonic waves in thickness in connection with the degradation of the metal structure during operation, mm;

S _random - the thickness of the carbonized layer on the outer and inner sides of the coil wall, mm;

S _select - rejection thickness according to (STO-SA-03-004-2009), mm;

And _f is the rate of thinning, mm / year, determined by the formula:

where S ₀ - initial (executive) thickness, mm;

t - period of operation, in years (starting from the moment the furnace was put into operation).

Moreover, the method also provides for the use of radiant coils made of nickel-chromium alloys subject to high-temperature carburization.

When scanning the pipe surface by the magnetic control method, zones with the maximum value of the constant magnetic field strength are detected, thickness measurement is carried out in these zones. The obtained value is adjusted taking into account the thickness of the carburized layer and the change in the speed of ultrasound waves (ϑ _knots , m / s) in the volumetric part of the pipe wall. In this case, the indicator of the resulting constant magnetic field strength (Hr, A / m) and the propagation velocity of longitudinal ultrasonic waves (ϑ, m / s) are used as magnetic and ultrasonic parameters, after which the residual life is determined by the modified formula (5.1) “Assessment Methodology Residual life of tube furnaces of oil refining, petrochemical and chemical industries ”developed by JSC“ VNIKTI petrochemical equipment ”:

The technical effect of the present invention, in contrast to the prototype, is achieved by the fact that this method increases the accuracy of determining the residual life of the coils of the reaction furnaces, due to the fact that the wall thickness is measured only in potentially dangerous zones, which are previously detected by magnetic control, and the accuracy of thickness measurement is ensured taking into account the depth of the carburized layer and changes in the speed of ultrasound in the bulk.

The invention is illustrated by drawings. In FIG. 1 shows the dependence of the resulting constant magnetic field strength of steel 20X25H20C2 on the degree of damage, in FIG. 2 - dependence of the propagation velocity of ultrasonic longitudinal waves in steel 20X25H20C2 on the degree of damage, in FIG. 3 - dependence of the resulting constant magnetic field strength (Hr) on the depth of the carbonized layer of the coil of the reaction furnace (a - outer surface, b - inner surface), FIG. 4 - scheme for measuring sections of the coil according to the proposed method (1 - coil, 2 - sections of the greatest thinning of the walls of the coil, 3 - sensor, 4 - thickness gauge).

When determining the residual life, it is necessary to know the ultimate state and level of accumulated damage. The rejection thickness is taken as the limiting state, and it is proposed to determine the level of accumulated damage by the calibration dependences (Fig. 1) after analyzing the measurements of the distribution of magnetic properties by the flux-gate method.

As an example, the results of the studies are presented and a calibration dependence is obtained for assessing the degree of damage to steel 20Kh25N20S02 by measuring the resulting intensity of a constant magnetic field (Fig. 1).

The resource rating of the coils is carried out according to the thickness of the pipe walls, by calculating the speed of its thinning after a certain period of operation. Since the carburized layer has a low bearing capacity, and the bulk of the pipe wall is subject to structural changes, these changes must be taken into account by reducing the speed of transmission of longitudinal ultrasonic waves.

To determine the change in the velocity of transmission of longitudinal ultrasonic waves, we turn to figure 2.

The established level of accumulated damage (Ni / Np) determines the difference between the transmission speeds of ultrasonic longitudinal waves in the metal in the delivery state and after operation, and then this value is used in further calculations.

In order to determine the thickness of the carburized layer, it is necessary to use a graph (Fig. 3).

From the obtained values of the intensity of the constant magnetic field is the value of the thickness of the carbonized layer (Fig. 3).

Thus, the calculation of the resource is as follows:

where S _ISM is the actual thickness of the element (when calibrating V _knots = 5700 m / s, reference data for austenitic steels), mm;

ΔS _UZV - thickness, taking into account the change in the transit time of ultrasonic waves in thickness in connection with the degradation of the structure in the metal during operation, mm;

S _random - the thickness of the carbonized layer on the outer and inner sides of the coil wall, mm;

S _select - rejection thickness according to (STO-SA-03-004-2009), mm;

And _f is the rate of thinning, mm / year, determined by the formula:

where S ₀ is the initial (executive) thickness of the most wearing element, mm;

t - period of operation, in years (starting from the moment the furnace was put into operation).

To assess the residual life (Fig. 4), first determine the most dangerous zones of the walls of the coil 1 - the areas of greatest thinning of the walls of the coil 2 1 by measuring the distribution of magnetic properties by the flux-gate method. Then, the thickness gauge 4 determines the wall thickness of the coil 1 from the signals received from the sensor 3.

Example. In order to increase the accuracy of determining the wall thickness of the coil in hazardous areas, the following studies were carried out. After six samples cut from the coils, after operation for 750-10000 hours, wall thicknesses were measured by the prototype method and the proposed method. The accuracy of estimating the equivalent, taking into account carburization, wall thicknesses was estimated by the metallographic method by cutting coils and comparing the results of the two compared methods. The measurement results showed that the deviations of the thicknesses that determine the most dangerous zones, according to the prototype method, are from 15.4 to 25%, while according to the proposed method, the deviation of the thicknesses is from 4 to 6%.

As an example, table 1 shows the obtained calculation of the true wall thickness of the coil of the reaction furnace after 10,000 hours of operation, as well as the rationale for the selection of sections for measuring the wall thickness of the coil of the reaction furnace of the radiant section based on the measurement of magnetic characteristics.

Thus, the use of the combination of essential features given in the claims allows achieving the set technical result of the present invention - improving the accuracy of estimating the remaining life of the coils of the radiant section of the reaction furnaces by identifying potentially dangerous zones and determining the actual pipe wall thickness in them using combined magnetic and ultrasonic control.

Claims (12)

1. A method for predicting the residual life of the coils of the reaction furnaces, including measuring the wall thickness of the coil by the ultrasonic method, characterized in that the pipe surface is first scanned by the magnetic method, identifying zones with a maximum value of the constant magnetic field in which the wall thickness is measured by the ultrasonic method, and thicknesses are adjusted, taking into account the thickness of the carburized layer and changes in the speed of passage in the wall material of the coil of ultrasonic longitudinal ϑ waves, moreover, the resultant constant magnetic field strength (Hr, A / m) is used as a magnetic parameter, and the propagation velocity of longitudinal ultrasonic waves (ϑ, m / s) is used as an ultrasonic parameter, and the residual life is determined by the formula:

where S _ISM is the measured wall thickness of the pipe coil in the delivery state, mm; ΔS _UZV - thickness, taking into account the change in the transit time of ultrasonic waves in thickness in connection with the degradation of the metal structure during operation, mm; S _random - the thickness of the carbonized layer on the outer and inner sides of the coil wall, mm; S _select - rejection thickness according to (STO-SA-03-004-2009), mm; And _f is the rate of thinning, mm / year, determined by the formula:

where S ₀ - initial (executive) thickness, mm; S _East - true wall thickness, mm; t - period of operation, in years (starting from the moment the furnace was put into operation). 2. The method according to p. 1 characterized in that the use of radiant coils made of nickel-chromium alloys susceptible to high-temperature carburization.

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