Number of the records: 1
Pressure behavior of a steel pipeline experiencing creep at normal temperatures
- 1.
SYSNO ASEP 0482444 Document Type J - Journal Article R&D Document Type Journal Article Subsidiary J Článek ve WOS Title Pressure behavior of a steel pipeline experiencing creep at normal temperatures Author(s) Gajdoš, Lubomír (UTAM-F) RID, SAI
Šperl, Martin (UTAM-F) RID, SAI
Pavelková, R. (CZ)Number of authors 3 Article number 05018001 Source Title Journal of Aerospace Engineering. - : American Society of Civil Engineers - ISSN 0893-1321
Roč. 31, č. 3 (2018)Number of pages 9 s. Publication form Print - P Language eng - English Country US - United States Keywords tightness test ; pressure decrease ; steel pipe ; room temperature creep (RTC) Subject RIV JL - Materials Fatigue, Friction Mechanics OECD category Audio engineering, reliability analysis R&D Projects TE02000162 GA TA ČR - Technology Agency of the Czech Republic (TA ČR) Institutional support UTAM-F - RVO:68378297 UT WOS 000427957100014 EID SCOPUS 85043536008 DOI 10.1061/(ASCE)AS.1943-5525.0000846 Annotation This work was motivated by the need for knowledge about the natural decrease in water pressure due to room temperature creep, as distinct from the decrease in pressure caused by leakage in tightness tests of new and/or repaired pipelines. In this context, a case study was conducted regarding the decrease in water pressure in a test pipe with dimensions of 530 mm in outside diameter and 7.8 mm in wall thickness.The system was pressurized to a pressure of 8.985 MPa, after which the water supply was stopped. The test pipe 4 m in length was made from line pipe steel L360NB and was closed by torispherical heads at both ends. Special attention was given to the thermal insulation of the test pipe, ensuring an average temperature of 14.5°C, with variation within 0.1°C over a period of 24 hours. A non-linear ordinary differential equation was derived to describe the time gradient of the water pressure in the test pipe in relation to time, pressure, coefficient of compressibility of water and cross sectional dimensions of the test pipe. The necessary creep parameters and static tensile properties were obtained from specimens manufactured from a ring 30 cm in width taken from the same pipe. The orientation of the specimens was circumferential. The creep tests were performed over a period of 24 hours at ambient temperature. The creep strains were measured by the strain gauge technique, and the effect of temperature variation during the test period was compensated by the use of a compensating strain gauge. The calculated decrease in pressure with time compared quite well with experimental results when the beginning of the pressure decrease was considered two hours after reaching the initial pressure of water and the supply of water was ended. The time period of 2-24 hours follows the recommendations of the CGA standard. A family of 'pressure-time' curves were constructed for a pipe from steel pressurized by water to specific initial pressure levels taken as multiples of the pressure at the yield. These curves cover a time interval of 2 - 24 hours, and they can be used to check the total decrease in water pressure after the tightness test has been completed. Workplace Institute of Theoretical and Applied Mechanics Contact Kulawiecová Kateřina, kulawiecova@itam.cas.cz, Tel.: 225 443 285 Year of Publishing 2019 Electronic address https://doi.org/10.1061/(ASCE)AS.1943-5525.0000846
Number of the records: 1