Laserfiche WebLink
r si <br /> p 111 1 <br /> the designer may want Examination of equation(1)or(2)shows that for any / <br /> it flow is likely to be stopped, iven set of thermal conditions an increase in AY will <br /> to provide a.means to drain the pipeline partially or g - <br /> . increase L and vice versa. Increasing AY and L to the <br /> completely. if,for some unforeseen reason,the <br /> Driscopipe pipeline should plug and freeze,the maximum will reduce the number of anchor points <br /> needed but may increase wear on the pipe from <br /> pipeline will not be damaged.The frozen fluid may <br /> swell the diameter of the pipe but it will return to movement and may increase the possibility of kinking <br /> nominal size as the fluid thaws.Due to the nature of the line if lateral movement does not occur uniformly <br /> polyethylene pipe,a flame(such as a propane or One practical approach to design is to calculate L <br /> acetylene torch)cannot be used to thaw a frozen using formula(3)for strain(s)in the pipe wall equal to <br /> section of pipe.Other methods must be used. <br /> 1%and(s)equal to 5%.The L value at 5%strain will <br /> The toughness and excellent abrasion resistance of <br /> give the shortest distance between anchor points and <br /> should be considered maximum for strain(s)and <br /> briscopipe will take the abuse of movement across minimum spacing for L.The spacing for L should be <br /> sand and soil without detrimental effects on its as large as possible considering other installation <br /> strength or service life.However,in rocky areas, location factors,such as available right-of-way,slope <br /> sharp rocks which could cut the pipe should be of the ground,etc.Higher values for L mean less <br /> removed and may be replaced with a bed of sand strain(s)and fewer anchor points and,consequently, <br /> or soil. lower costs,generally. <br /> Lateral Deflection Due to Thermal Movement in Overland Type 3:Buried Pipelines <br /> Pipelines. <br /> L L _ Introduction: When pipelines are buried,they are <br /> subjected to external loads.The effect of external <br /> pressure on flexible Driscopipe is more complex than <br /> LAY _Pipe <br /> the effect of internal pressure only.For design <br /> Pipe Anchor purposes,a distinction is usually made between rigid <br /> and flexible pipes.A rigid pipeline(such as concrete) <br /> The following formulae will allow the designer to is considered to be the total structure and must be <br /> calculate lateral deflection of the pipeline and anchor designed to sustain all external loads as well as <br /> point spacing. internal pressure.But.Driscopipe is a flexible pipe <br /> AY = LT (1) and is considered to be only one component of the <br /> "pipe-soil system,as described more fully on <br /> AY page 35. <br /> L 5 (2) Thus,in a buried situation,the SDR of the pipe and <br /> V. a <br /> the-strength of the soil envelope must be specified in <br /> D� (3) order to keep the three burial design parameters(wall <br /> L = e crushing,wall buckling and ring deflection)within <br /> acceptable limits.The pipe and soil envelope <br /> Where: AY =Lateral deflection(inches) become one system.The mutual interaction and <br /> L =Length of pipe between strength contribution of the pipe to the soil and the <br /> anchors(inches) <br /> a =Coefficient of thermal expansion soil to the pipe result in a highly successful integral <br /> structure.Correct design centers around two points: <br /> (in in/°F) <br /> AT =Change in temperature(OF) a)matching the proper wall-thickness to the externa <br /> e =Strain e in temperature- <br /> soil pressure and b)the analysis of how Driscopipe <br /> D =Pipe outside /inch)dia (inches) and the soil surrounding the pipe accept the backfill <br /> earthloading and transfer it to the undisturbed walls <br /> AY of the ditch or trench such that the pipeline will deflect <br /> slightly into static equilibrium with the soil. <br /> R=Radius <br /> R=4AY2+L2 <br /> 8AY <br /> 34 <br />