System and method for non-destructive, in-situ, positive material identification of a pipe

What is claimed: 1. A method for in-situ non-destructive positive material identification of a pipe which is part of a pipeline, the pipe including a plurality of selected test areas on a surface of the pipe, each test area being separated axially, circumferentially, or both axially and circumferentially from other test areas of the plurality, the method comprising: Preparing the surface of the pipe within at least a portion of each selected test area to be suitable for testing; collecting within the prepared portion of each test area, by testing the yield strength and tensile strength using a tensile property tester including a ball indenter, a predetermined number of mechanical property data readings of the pipe, the predetermined number of mechanical property data readings representing a mechanical property data collection run; calculating a yield strength and a tensile strength mean of the pipe from the mechanical property data collection run; collecting from the prepared portion of each test area, by testing using a spectrometer, a predetermined number of chemical property data readings of the pipe, the predetermined number of chemical property data readings representing a chemical property data collection run; calculating a chemical element percentage mean of the pipe from the chemical property data collection run; calculating an overall yield strength and tensile strength mean of the mechanical property data collection runs and an overall chemical percentage mean of the chemical property data collection runs, each overall mean being calculated using at least two of its respective data collection runs; each overall mean representing a material identification of the pipe; comparing each material identification of the pipe to a known API material standard; and identifying a grade of the pipe based upon the comparing. 2. The method of claim 1 , further comprising: buffing the prepared portion of a test area to remove indentations made by the ball indenter. 3. The method of claim 1 , further comprising: using a magnetic particle tester on the pipe within the prepared portion of at least one test area to determine a presence of a surface-breaking anomaly on the pipe. 4. The method of claim 3 , further comprising: performing phased-array ultrasonic testing to determine a depth of the surface-breaking anomaly. 5. The method of claim 1 , further comprising: performing an inspection to identify a weld seam type. 6. The method of claim 5 , the inspection further comprising: using an ultrasonic flaw detector within the prepared portion of a test area to identify the weld seam type. 7. The method of claim 1 , at least one chemical properties test location being located adjacent to a respective mechanical properties test location. 8. The method of claim 1 , further comprising: discarding any reading falling outside a predetermined variance from a calculated mean of a respective mechanical or chemical property data collection run. 9. The method of claim 8 , wherein the predetermined variance is ±5% from the calculated mean. 10. The method of claim 8 , wherein the predetermined variance is ±10% from the calculated mean. 11. The method of claim 8 , wherein an additional reading replaces the discarded reading. 12. The method of claim 1 , wherein the method provides, at a 95% confidence level, mechanical property data sufficient to determine ultimate yield strength and ultimate tensile strength at least within +/−10% of the known API material standard. 13. The method of claim 1 , wherein method provides, at an 85% confidence level, chemical property data sufficient to calculate a carbon percentage in a range of at least +/−25% to the known API material standard. 14. The method of claim 1 , wherein the method provides, at a 90% confidence level, chemical property data sufficient to calculate a manganese percentage in a range of at least +/−20% to the known API material standard. 15. The method of claim 1 , wherein the predetermined number of readings for the mechanical and chemical property data collection runs is a minimum of five readings and a maximum of ten readings. 16. A method for in-situ non-destructive positive material identification of a pipe which is part of a pipeline, the pipe including a plurality of selected test areas on a surface of the pipe, each test area being spaced from other test areas of the plurality, the method comprising: preparing the surface of the pipe within at least a portion of each test area to be suitable for testing; collecting from the prepared portion of each test area, by testing using a tensile property tester including a ball indenter, a predetermined number of mechanical property data readings, the predetermined number of mechanical property data readings representing a mechanical property data collection run and used to calculate a yield strength and a tensile strength mean of the mechanical properties test location; collecting from the prepared portion of each test area, by testing using an optical spectrometer, a predetermined number of chemical property data readings, the predetermined number of chemical property data readings representing a chemical property data collection run and used to calculate a chemical element percentage mean of the chemical properties test location; routing the collected mechanical and chemical property data readings for analysis. 17. The method of claim 16 , further comprising: restoring the surface of the pipe within the prepared portion of a test area by buffing, the buffing removing any indentations made on the pipe by the ball indenter, burns made on the pipe by the optical spectrometer, or the indentations and the burns. 18. The method of claim 16 , further comprising: etching the surface of the pipe within the prepared portion of the test area, the etching identifying any burns on the pipe caused by the preparing, the optical spectrometer, or the preparing and the optical spectrometer. 19. The method of claim 16 , further comprising: calculating the yield strength and the tensile strength mean of each mechanical property data collection run; calculating the chemical element percentage mean of each chemical property data collection run; and calculating an overall yield strength and tensile strength mean of the mechanical property data collection runs and an overall chemical element percentage mean of the chemical property data collection runs, each overall mean being calculated using at least two of its respective data collection runs and each representing a material identification of the pipe. 20. The method of claim 19 , further comprising: comparing each material identification to a known API material standard; and identifying a grade of the pipe based upon the comparing. 21. The method of claim 16 , wherein the chemical element percentage mean is at least one of a carbon percentage mean and a manganese percentage mean. 22. A system for non-destructive, in situ, positive grade identification of a pipe which is part of a pipeline, the system comprising: a grinder including successively finer polishing media for preparing a plurality of polished test areas on the surface of the pipe, each polished test area being separated from other polished test areas of the plurality; a tensile property tester including a ball indenter for collecting mechanical property data of the pipe the polished test areas on the surface of the pipe, the collected mechanical property data being use