초록 ▼

Systems and methods for generating transfer functions associated with calculating local stresses on pipe elements by post processing forces and moments of a pipe model representing the piping system. The transfer functions are reusable and allow recalculation with different sets of user data without

Systems and methods for generating transfer functions associated with calculating local stresses on pipe elements by post processing forces and moments of a pipe model representing the piping system. The transfer functions are reusable and allow recalculation with different sets of user data without requiring regeneration of the transfer functions.

대표청구항 ▼

1. A method for assessing hydrogen induced stress cracking associated with a subsea piping system comprising: (a) determining a one-dimensional model for an element of said subsea piping system; (b) performing a one-dimensional analysis for said element using said one-dimensional model and a plurali

1. A method for assessing hydrogen induced stress cracking associated with a subsea piping system comprising: (a) determining a one-dimensional model for an element of said subsea piping system; (b) performing a one-dimensional analysis for said element using said one-dimensional model and a plurality of operating conditions to identify at least one point associated with hydrogen induced stress cracking for said element; (c) applying at least one transfer function to said at least one point to transform said at least one point from a one-dimensional representation to a local stress assessment; (d) outputting said local stress assessment; (e) analyzing said local stress assessment for a first predetermined compliance; and (d) if said local stress assessment is non-compliant then determining and running a three-dimensional sub-model for said element and analyzing output from said three-dimensional sub-model for a second predetermined compliance. 2. The method of claim 1 wherein said first predetermined compliance is a linear hydrogen induced stress cracking compliance. 3. The method of claim 1 wherein said output from said three-dimensional sub-model is a local strain assessment. 4. The method of claim 1 wherein said second predetermined compliance is a non-linear hydrogen induced stress cracking compliance. 5. The method of claim 1, wherein said element comprises, bends, tees, manifolds, couplings, welds and hubs. 6. The method of claim 1, wherein said plurality of operating conditions comprises said element area and inertia. 7. A computer-executable system stored in a memory and executing on a processor for verifying subsea piping systems are compliant with hydrogen induced stress cracking assessments, the system comprising: (a) a transfer function generator component for creating transfer functions; (b) a transfer function engine component for executing said transfer functions; (c) a transfer function storage component for archiving said transfer functions; (d) determining a one-dimensional model for an element of said subsea piping system; (e) performing a one-dimensional analysis for said element using said one-dimensional model and a plurality of operating conditions to identify at least one point associated with hydrogen induced stress cracking for said element; (f) applying at least one transfer function to said at least one point to transform said at least one point from a one-dimensional representation to a local stress assessment; (g) outputting said local stress assessment; (e) analyzing said local stress assessment for a first predetermined compliance; and (f) if said local stress assessment is non-compliant then determining and running a three-dimensional sub-model for said element and analyzing output from said three-dimensional sub-model for a second predetermined compliance. 8. The system of claim 7 wherein said transfer function engine component and said transfer function storage component are located on different computers. 9. The system of claim 7, wherein said transfer function engine component transmits input data to a second transfer function engine component, located on a separate computer system, for transforming said input data into pipe element local stress values. 10. The system of claim 7 wherein said first predetermined compliance is a linear hydrogen induced stress cracking compliance. 11. The systems of claim 7 wherein said output from said three-dimensional sub-model is a local strain assessment. 12. The system of claim 7 wherein said second predetermined compliance is a non-linear hydrogen induced stress cracking compliance. 13. The system of claim 7, wherein said element comprises, bends, tees, manifolds, couplings, welds and hubs.