Pipe sizing for district cooling distribution network
An implicit solution of Colebrook-White equation was developed in calculating the friction factor for commercial steel pipes using iterative approach such as Newton-Raphson method with Reynolds number ranging from 4.0×103 to 5.9×106. The initial value for iterative friction factor estimation was bas...
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2013
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oai:animorepository.dlsu.edu.ph:faculty_research-139902024-03-11T07:07:49Z Pipe sizing for district cooling distribution network Augusto, Gerardo L. Culaba, Alvin B. Tanhueco, Renan T. An implicit solution of Colebrook-White equation was developed in calculating the friction factor for commercial steel pipes using iterative approach such as Newton-Raphson method with Reynolds number ranging from 4.0×103 to 5.9×106. The initial value for iterative friction factor estimation was based on expanded form of Colebrook-White equation for larger values of Reynolds number. Numerical results were compared with known explicit solutions and iterative procedure proposed by Lester by evaluating their mean difference, root-mean square deviation, mean relative error and correlation coefficient. Correlation coefficients equal to unity with overall mean relative error of 2.6135x10-8 were achieved for all cases when compared with iterative solution suggested by Lester. It was also found that the use of Hazen-Williams equation for friction factor estimation as an alternative to Colebrook-White equation was strongly discouraged.Combining the subroutine of friction factor identification with the main program that determines the pipe size of distribution network defines the boundaries of chilled-water velocities at different pressure drop limits as a function of commercial steel pipe diameter. 2013-11-01T07:00:00Z text https://animorepository.dlsu.edu.ph/faculty_research/12012 Faculty Research Work Animo Repository Friction Pipe Steel Electric power distribution Newton-Raphson method Mechanical Engineering |
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Friction Pipe Steel Electric power distribution Newton-Raphson method Mechanical Engineering |
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Friction Pipe Steel Electric power distribution Newton-Raphson method Mechanical Engineering Augusto, Gerardo L. Culaba, Alvin B. Tanhueco, Renan T. Pipe sizing for district cooling distribution network |
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An implicit solution of Colebrook-White equation was developed in calculating the friction factor for commercial steel pipes using iterative approach such as Newton-Raphson method with Reynolds number ranging from 4.0×103 to 5.9×106. The initial value for iterative friction factor estimation was based on expanded form of Colebrook-White equation for larger values of Reynolds number. Numerical results were compared with known explicit solutions and iterative procedure proposed by Lester by evaluating their mean difference, root-mean square deviation, mean relative error and correlation coefficient. Correlation coefficients equal to unity with overall mean relative error of 2.6135x10-8 were achieved for all cases when compared with iterative solution suggested by Lester. It was also found that the use of Hazen-Williams equation for friction factor estimation as an alternative to Colebrook-White equation was strongly discouraged.Combining the subroutine of friction factor identification with the main program that determines the pipe size of distribution network defines the boundaries of chilled-water velocities at different pressure drop limits as a function of commercial steel pipe diameter. |
| format |
text |
| author |
Augusto, Gerardo L. Culaba, Alvin B. Tanhueco, Renan T. |
| author_facet |
Augusto, Gerardo L. Culaba, Alvin B. Tanhueco, Renan T. |
| author_sort |
Augusto, Gerardo L. |
| title |
Pipe sizing for district cooling distribution network |
| title_short |
Pipe sizing for district cooling distribution network |
| title_full |
Pipe sizing for district cooling distribution network |
| title_fullStr |
Pipe sizing for district cooling distribution network |
| title_full_unstemmed |
Pipe sizing for district cooling distribution network |
| title_sort |
pipe sizing for district cooling distribution network |
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Animo Repository |
| publishDate |
2013 |
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https://animorepository.dlsu.edu.ph/faculty_research/12012 |
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