Chapter 9 – CASING AND CEMENTING                                 203






                 The top joint of casing in this case will therefore have to resist 707,000 lb
                 (320 tonnes) of tensile force (again neglecting buoyancy).
                    Burst.  Casings must be able to withstand internal pressure. Internal
                 pressure will come from downhole formation pressures, hydrostatic
                 pressures, and pressure tests.

                    Collapse.  The  opposite  of  internal  pressure  is  where  the  pressure

                 outside of the casing is higher than the pressure from the fluids inside
                 the casing. It is possible for casing to be squashed flat like a ribbon by

                 external pressure.
                    Cemented casing is much harder to collapse (takes a much higher
                 pressure) than uncemented casing.
                    Flowing salt was discussed in chapter 1. Thick salt deposits flow under

                 pressure from the rocks above. Thus salt acts a lot like a hydraulic fluid in

                 these conditions and can impose very high collapse pressures on a string
                 of casing. Two factors then are important when cementing in flowing salts.

                 The casing has to be very strong (thick wall and/or high-strength steel),
                 and the cement around the casing must form a complete sheath. If there are

                 unfi lled areas without cement, the salt can flow into that area and place a
                 very high point loading (as opposed to an even loading) on the casing. No
                 casing can resist a high point loading.

                    Driving forces.  Conductor pipes are sometimes driven (hammered
                 in place) by a pile driver into the ground to allow the well to be spudded
                 with a closed circulating system. Conductor is thick-walled pipe (often 1"
                 or greater wall thickness), so the pipe itself is strong enough to drive. The
                 connections must be selected to be suitable to transmit the heavy shock
                 loads of driving.
                    Temperature.  When a steel casing gets hot, it expands. Where the
                 casing is cemented, this does not cause any problems, but the uncemented
                 pipe between the top of cement and the surface wellhead may buckle as
                 expansion takes place. This can be compensated for  by stretching the
                 casing before setting it in the wellhead.
                    Steel also loses strength as temperature increases. In a deep, hot well,
                 this loss of strength can be significant. At a temperature of 200°C, steel will

                 have lost 19% of its strength. This has to be accounted for when designing
                 casings for high-temperature wells.









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