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Vol. 2017 Núm. 2, Historical Fact Sheets

Vol. 2017 Núm. 2

Water Hammer In Irrigation Systems: CIR828/AE066, 8/2017

Historical Fact Sheets

https://doi.org/10.32473/edis-ae066-1994

Publicado 1994-02-02 — Actualizado el 2017-02-02

G. A. Clark⁺⁻
D. Z. Haman⁺⁻

G. A. Clark

University of Florida

D. Z. Haman

University of Florida

Emergent growth of East Indian hygrophila. Figure 1 from publication SS-AGR-411/AG413: East Indian Hygrophila: Hygrophila polysperma (Roxb.) T. Anderson. Credit: Lyn Gettys, UF/IFAS.

Versiones

PDF-2017 (English)

Palabras clave

irrigation

Cómo citar

Clark, G. A., y D. Z. Haman. (1994) 2017. «Water Hammer In Irrigation Systems: CIR828 AE066, 8 2017». EDIS 2017 (2). Gainesville, FL. https://doi.org/10.32473/edis-ae066-1994.

Resumen

Irrigation system design includes pump sizing and selection, valve sizing and selection, and pipe sizing as well as the proper selection and placement of many other components. Good design involves selecting and sizing components to perform their intended tasks within the constraints of the system, to ensure an efficient, cost effective, and durable irrigation system. Cost effectiveness will result when oversizing is avoided. Undersizing of components will cut initial costs but often results in poor irrigation distribution uniformity or the complete or partial failure of the system through ruptured pipes, damaged valves, or pump damage.

Like any other moving fluid, flowing water has momentum. When subjected to a sudden change in flow, shock waves propagate through the system. This occurrence is referred to as "water hammer." Flow changes can occur due to operation of valves, starting and stopping of pumps, or directional changes caused by pipe fittings. The intensity of water hammer effects will depend upon the rate of change in the velocity or momentum. This publication discusses the causes of water hammer and the importance of proper system design and management to ensure a cost effective, long-lasting irrigation system.

https://doi.org/10.32473/edis-ae066-1994

PDF-2017 (English)

Citas

ANSI/ASABE S376.3 FEB2016 (R2020) Standard. Design, Installation and Performance of Underground Thermoplastic Irrigation Pipelines. ASAE Standards 1985. 32nd edition. American Society of Agricultural Engineers, St. Joseph, MI. pp. 478–488.

Daily, J. W. and D. R. F. Harleman. 1966. Fluid Dynamics. Addison-Wesley Publishing Co., Inc. Mass. pp. 341–343.

Pair, C. H., W. W. Hinz, C. Reid and K. R. Frost. 1975. Sprinkler Irrigation, 4th ed. The Irrigation Association, Silver Spring, Maryland. pp. 247–248.

Seipt, W. R. 1974. Water Hammer Considerations for PVC Pipeline in Irrigation Systems. Transactions of the ASAE. pp. 417–423.