SETTING UP TSA WITH SPECIFIC ADD DIAGRAMS DURING ULTRASONIC TESTING OF ROLLED WHEEL CENTERS OF THE RAILWAY ROLLING STOCK

Operation of railway rolling stock is accompanied by high costs of maintaining its operating condition throughout the entire period of operation. To improve the operation efficiency of rolling stock, methods and diagnostics tools have been developed, which are used both in its manufacture and in carrying out maintenance and repairs, and as an independent technological process. Diagnostics allows to increase the availability factor and the probability of uptime of the rolling stock, reduce the complexity and cost of periodic maintenance of its nodes. The article proposes a new integrated method for estimating discontinuities in parts and units of railway rolling stock according to the amplitude — distance — diameter diagrams by the standardless method with the possibility of determining the type of discontinuity by the dual-frequency method of flaw-detection with a manual ultrasonic testing with a single-channel ultrasonic flaw detector. Developed method is most relevant in the control of cast parts of railway rolling stock, since castings can be equally likely to contain bulk (pores, shells, nonmetallic inclusions, etc.) and planar discontinuities (cracks of different origin; flocks; segregations that lead to violation continuity, etc.). Proposed method allows estimating the discontinuity by comparing the amplitude of the echo signal from it with the corresponding type of tuning reflector: if the discontinuity is planar as a result of using the two-frequency flaw-detection method, the comparison is carried out with the amplitude of the flat-bottomed cylindrical reflector; if the discontinuity is volumetric, then the comparison is made with the amplitude from the spherical reflector. The article describes the algorithm that was developed to automate the calculation of the parameters of the amplitude — distance — diameter diagram, the parameters of the use of the two-frequency method, and also the estimation of the detected discontinuities, and, based on it, the NDTRT-25 software that allows ensuring the convenience of the operator-diagnostician.

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Increase of informativity of two-frequency method of defectometry at ultrasonic control of details and units of railway rolling stock

Vestnik of the Railway Research Institute ◽

10.21780/2223-9731-2018-77-3-182-187 ◽

2018 ◽

Vol 77 (3) ◽

pp. 182-187 ◽

Cited By ~ 1

Author(s):

A. N. Kireev

Keyword(s):

Experimental Studies ◽

Rolling Stock ◽

Non Destructive Testing ◽

Destructive Testing ◽

Frequency Method ◽

Ultrasonic Control ◽

Software Product ◽

Non Destructive ◽

Rolled Wheel ◽

Railway Rolling Stock

When forecasting the technical state of the parts and units of railway rolling stock in operation, an important task is to determine the shape of the discontinuity in ultrasonic non-destructive testing in order to predict its behavior in further operation (this is especially important if the discontinuity in the results of such control is acceptable). Author proposed a solution for the improvement of the two-frequency defectometry method. A mathematical apparatus was developed and a method for determining the coefficient of the discontinuity shape was elaborate on its basis. The method makes it possible to determine the shape of both a point and an extended discontinuity. The software product NDTRT-07.03.01.18 was developed to automate calculations in determining the shape of discontinuity by a two-frequency method. The article gives a description of the experimental studies carried out to evaluate the reliability of the proposed method. This method can be used in determining the shape of the discontinuity in the details of the rolling stock, in which the defect can have a different shape, for example: cast wheel centers; various shaped castings used in the manufacture of rolling stock units (brackets for locomotive bogies, cast sidewalls for cars), as well as in parts manufactured by the method of plastic deformation, including wheel treads, axles, all-rolled wheels, rolled wheel centers, etc. In these details discontinuities are predominantly planar in nature, but voluminous discontinuities are also encountered - non-deformable nonmetallic inclusions, therefore the developed method can be applied to such objects of rolling stock railways.

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Validity and informativity enhancement of ultrasonic testing of cast parts of railway rolling stock

Vestnik of Don State Technical University ◽

10.23947/1992-5980-2019-19-4-335-341 ◽

2020 ◽

Vol 19 (4) ◽

pp. 335-341

Author(s):

A. N. Kireev ◽

Y. K. Sklifus ◽

M. A. Kireeva

Keyword(s):

Ultrasonic Testing ◽

Rolling Stock ◽

Dual Frequency ◽

Destructive Testing ◽

Pulse Input ◽

Advantages And Disadvantages ◽

Input Surface ◽

Pulse Echo ◽

Cast Parts ◽

Railway Rolling Stock

Introduction. Due to the process reasons, the structure of cast parts of the railway rolling stock (RRS) often has embedded flaws that affect drastically their strength. The degree of impact depends on many factors including the shape and location of defects in the product. The shape of the defect has the greatest effect under alternating loads. This often refers to dynamically loaded parts of the RRS underframe. The defect oriented perpendicularly to the direction of tensile loads reduces the component life to the maximum. To identify embedded flaws, the parts are subjected to ultrasonic testing by the classical pulse-echo technique. However, such methods require increased validity and informativity. For example, they do not provide the determination of the type and orientation of the defect. Materials and Methods. Features, advantages and disadvantages of the classical pulse-echo technique of the ultrasonic non-destructive testing, which is based on the registration of the following echo signals, are considered: sent; reflected from the opposite surface (bottom) of the object; reflected from the defect (if any). The pulse arrival time is proportional to the thickness of the part. If there is a defect, this time is proportional to the distance from the pulse input surface to the defect. This method can determine the presence of a defect, but it cannot determine its type. Research Results. To determine the shape of a defect, a dualfrequency defectometry method is proposed. Its principle, algorithm and implemented analytical dependencies are described. When an echo signal from a defect is detected in the monitoring object, the amplitudes of the bottom signals and the amplitudes of the echo signals from the defect are measured at the ultrasonic wave frequencies of 2.5 MHz and 5.0 MHz. The defect shape factor is calculated from the analytical dependence; and the type of defect is determined. It can be volume (pores, shells, non-metallic inclusions) or planar (cracks, segregations, etc.). Discussion and Conclusions. A dual-frequency defectometry method to determine the type of defect under the manual ultrasonic testing of the RRS cast parts is proposed in the paper. For an express automated use of the proposed method, the software product NDTRT-07.04-L is developed, and its operation algorithm is described. The application of the technique can increase the validity and informativity of the test results

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Experimental Research of Flaw Detection Technique at Manual Ultrasonic Testing of Railway Rolling Stock Elements

NDT World ◽

10.12737/15939 ◽

2015 ◽

Vol 18 (4) ◽

pp. 72-75 ◽

Cited By ~ 2

Author(s):

Киреев ◽

Andrey Kireev

Keyword(s):

Form Factor ◽

Ultrasonic Testing ◽

Experimental Studies ◽

Flaw Detection ◽

Rolling Stock ◽

Dual Frequency ◽

Frequency Method ◽

Limit Values ◽

Defect Type ◽

Railway Rolling Stock

Introduction. The work aim was to carry out experimental studies of dual-frequency method reliability for defect type determination at manual ultrasonic testing of railway rolling stock elements. Method. The method of discontinuity type determination includes: measuring amplitude characteristics of echo signals from the detected defect on the frequency of 2.5 and 5.0 MHz; calculation a defect form-factor; comparing the form-factor with the certain limit values, one of which corresponds to a planar defect and the other corresponds to a volume defect. The defect is considered planar/volume, if its form-factor differs from the appropriate limit value by no more than 30%. The method gives an opportunity to determine types for both point and extensive defects. For the experiment a sample was manufactured, in which various artificial reflectors of different types and dimensions were made. The type of each reflector was determined with dual-frequency method. The relative error and reliability of type determination were calculated. Results. Experimental studies have shown that reliability of defect type determination with dual-frequency method is quite high. The average accuracy of point defect determination has been 97,389%; extensive defect determination has been 93,588%.

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