In-situ HIC growth monitoring probe

What is claimed is: 1. An intrusive probe system for flush insertion into a metal asset comprising: a hollow metal probe body having a solid first end portion defined by an exposed surface configured to be exposed to a corrodent located within the metal asset; an insert disposed within the hollow metal probe body so as to define a collection cavity defined between the insert and both an inner wall of the hollow metal probe body and an internal end wall that is part of the solid first end portion of the hollow metal probe body and defines one end of the collection cavity; a diffusion barrier disposed along the inner wall of the hollow metal probe body and formed of a material that is at substantially impermeable to a gas generated in the collection cavity by the corrodent so as to prevent passage of the gas from the collection cavity to the surrounding inner wall of the hollow metal probe body; a conduit in fluid communication with the collection cavity for receiving the gas generated by the corrodent; and a pressure measuring device coupled to the conduit for measuring a pressure of the gas generated by the corrodent. 2. The probe system of claim 1 , wherein the corrodent is a liquid transported inside the metal asset, wherein atomic hydrogen is a by-product of corrosion of the metal asset due to contact between the corrodent and the metal asset. 3. The probe system of claim 1 , wherein the gas generated by the corrodent in the collection cavity is molecular hydrogen gas. 4. The probe system of claim 1 , wherein a first end of the insert is in a flush abutting relationship to the internal end wall of the solid end portion of the hollow metal probe body, whereby the collection cavity is formed surrounding a side wall of the insert and spaced from an interface between the first end of the insert and the solid end portion. 5. The probe system of claim 1 , wherein the insert comprises a cylindrical shaped filler rod and the collection cavity has an annular shape. 6. The probe system of claim 1 , wherein the collection cavity extends longitudinally within the hollow metal probe body and terminates at an end wall that is spaced from the exposed surface. 7. The probe system of claim 1 , wherein the corrodent is a liquid transported inside the metal asset, wherein atomic hydrogen is a by-product of corrosion of the metal asset and the solid first end portion is formed of a material that permits diffusion of atomic hydrogen therethrough but has an HIC resistant microstructure. 8. The probe system of claim 1 , wherein the diffusion barrier is an oxide layer. 9. The probe system of claim 1 , wherein the diffusion barrier is an austenitic stainless steel sleeve. 10. The probe system of claim 1 , wherein the collection cavity is open at one end that is opposite the internal end wall to allow for insertion of the insert. 11. The probe system of claim 1 , wherein the insert is formed of a material that has low or no hydrogen diffusivity properties. 12. The probe system of claim 1 , wherein the insert is formed of an austenitic stainless steel material. 13. The probe system of claim 1 , further including a probe cap which is coupled to an end of the hollow metal probe body opposite the solid first end portion; an access fitting to which the hollow metal probe body is coupled; and a coupling mount that is sealingly inserted into an access hole formed in the metal asset and to which the access fitting is coupled. 14. The probe system of claim 1 , wherein the probe cap includes outer threads that mate with inner threads formed in the access fitting. 15. The probe system of claim 1 , wherein the corrodent is a liquid transported inside the metal asset, wherein atomic hydrogen is a by-product of corrosion of the metal asset and the collection cavity comprises a HIC-simulation cavity in which diffusing atomic hydrogen permeates to and recombines within the collection cavity to form hydrogen gas and as hydrogen gas content in the collection cavity increases, the pressure in the collection cavity increases correspondingly, mimicking a HIC process, the pressure measuring device monitors the pressure within the collection cavity with a hydrogen sensor and determines corresponding hydrogen build-up rates. 16. The probe system of claim 15 , wherein the pressure measuring device is configured to send an alert in response to pressure measurements within the collection cavity. 17. The probe system of claim 1 , wherein the diffusion barrier has a HIC-resistant microstructure. 18. The probe system of claim 1 , wherein an interface between one end of the insert and the solid end portion is resistant to atomic hydrogen passage, thereby causing the corrodent to pass into the collection cavity that surrounds a side wall of the insert. 19. The probe system of claim 1 , wherein the hollow metal probe body is configured such that the exposed surface is placed flush relative to an inner wall of the metal asset which comprises a hollow pipe in which the corrodent forms. 20. An intrusive probe system for flush insertion into a metal asset comprising: a hollow metal probe body having a solid first end portion defined by an exposed surface for exposure to a corrodent located within the metal asset; an insert disposed within the hollow metal probe body so as to define a collection cavity defined between the insert and both an inner wall of the hollow metal probe body and an internal end wall that is part of the solid first end portion of the hollow metal probe body and defines one end of the collection cavity; a diffusion barrier disposed along the inner wall of the hollow metal probe body and formed of a material that is at substantially impermeable to a gas generated in the collection cavity by the corrodent so as to prevent passage of the gas from the collection cavity to the surrounding inner wall of the hollow metal probe body; a conduit in fluid communication with the collection cavity for receiving the gas generated by the corrodent; and a pressure measuring device coupled to the conduit for measuring a pressure of the gas generated by the corrodent; wherein the solid first end portion, including the exposed surface, is formed of a same metal grade as the metal asset. 21. A method for warning for hydrogen induced cracking in a metal asset, the method comprising: inserting an intrusive metal probe system flush into the metal asset, the intrusive probe system having a hollow metal probe body with an access end portion that has an exposed metal surface that is placed flush to an inner surface of the metal asset, the access end portion being formed of a metal that permits diffusion of atomic hydrogen therethrough but has an HIC resistant microstructure, the hollow metal probe body having a collection cavity for receiving the atomic hydrogen that passes through the access end portion; allowing the atomic hydrogen to permeate the exposed surface; generating molecular hydrogen in the collection cavity of the hollow metal probe body; measuring the pressure of the molecular hydrogen in the collection cavity; and determining whether the measured pressure is greater than a value that is indicative of an increased risk of hydrogen induced cracking in the metal asset and if so, generating an alert. 22. The method of claim 21 , further including the step of: scheduling advanced ultrasonic testing according to the measured risk of hydrogen induced cracking.