Re-autofrettage has been identified as a significant, cost-effective method to achieve higher reyield pressure (RYP) and/or weight reduction in large caliber gun tubes. For a given overstrain, residual stress profiles for hydraulic and swage autofrettage may differ significantly in their intensity. The simplest representation of this “intensity” effect is the magnitude of the bending moment “locked in” via the residual hoop stress. Hill’s analytical, plane strain, Von Mises analysis predicts a larger “locked-in” moment than does the equivalent open-end condition. By assuming a range of stress-field intensities (f) scaling from 1.0 to 1.4 times that were produced by open-end hydraulic autofrettage, it was possible to assess reyield behavior following initial autofrettage via a generic numerical study. In cases where Bauschinger effect is absent, reyield initiates at the original elastic–plastic interface. This includes the ideal Hill distribution. When Bauschinger effect is present, reyield for initiates at the bore and after further pressurization at the original elastic–plastic interface within two zones. For , the reverse is the case, with initial yield at the original elastic–plastic interface and subsequently at the bore. RYP increases with increasing f up to f = 1.175 and then decreases significantly. This loss of RYP may be mitigated by hydraulic re-autofrettage. At f = 1.0 re-autofrettage increases RYP by 4%. At f = 1.4, RYP is increased by 19%. There are modest increases in safe maximum pressure (SMP) as a result of re-autofrettage. RYP closely approaching re-autofrettage pressure is achievable for . Within this range, re-autofrettage offers a significant benefit. Re-autofrettage also produces beneficial effects via increased bore hoop compressive stress, this increase varying from 20% for f = 1% to 0% for f = 1.4. Such increased compression will benefit fatigue lifetime for fatigue cracks initiating at the bore. Conversely, tensile outside diameter (OD) hoop stress increases, with increasing f, by a maximum of 6%.
Skip Nav Destination
e-mail: parker.ETR@tiscali.co.uk
Article navigation
August 2012
Research Papers
Impact of Intensity of Residual Stress Field Upon Reyielding and Re-Autofrettage of an Autofrettaged Thick Cylinder
Anthony P. Parker,
Anthony P. Parker
Defence Academy of the United Kingdom,
e-mail: parker.ETR@tiscali.co.uk
University of Cranfield
, Swindon, SN6 8LA, England
Search for other works by this author on:
John H. Underwood
John H. Underwood
Search for other works by this author on:
Anthony P. Parker
Defence Academy of the United Kingdom,
University of Cranfield
, Swindon, SN6 8LA, England
e-mail: parker.ETR@tiscali.co.uk
Edward Troiano
John H. Underwood
J. Pressure Vessel Technol. Aug 2012, 134(4): 041003 (4 pages)
Published Online: July 9, 2012
Article history
Received:
November 7, 2011
Revised:
January 6, 2012
Online:
July 9, 2012
Published:
July 9, 2012
Citation
Parker, A. P., Troiano, E., and Underwood, J. H. (July 9, 2012). "Impact of Intensity of Residual Stress Field Upon Reyielding and Re-Autofrettage of an Autofrettaged Thick Cylinder." ASME. J. Pressure Vessel Technol. August 2012; 134(4): 041003. https://doi.org/10.1115/1.4006349
Download citation file:
Get Email Alerts
Cited By
Surface Strain Measurement for Non-Intrusive Internal Pressure Evaluation of A Cannon
J. Pressure Vessel Technol
The Upper Bound of the Buckling Stress of Axially Compressed Carbon Steel Circular Cylindrical Shells
J. Pressure Vessel Technol (December 2024)
Crack Growth Prediction Based on Uncertain Parameters Using Ensemble Kalman Filter
J. Pressure Vessel Technol (December 2024)
Defect Detection of Polyethylene Gas Pipeline Based on Convolutional Neural Networks and Image Processing
J. Pressure Vessel Technol
Related Articles
Full Thermal Simulation of an Arbitrary, Plane Axisymmetric Residual Stress Field
J. Pressure Vessel Technol (February,2020)
Residual Stress Measurements of Explosively Clad Cylindrical Pressure Vessels
J. Pressure Vessel Technol (February,2012)
An Axisymmetric Stress Release Method for Measuring the Autofrettage Level in Thick-Walled Cylinders—Part II: Experimental Validation
J. Pressure Vessel Technol (November,1994)
Stress Intensity, Stress Concentration, and Fatigue Crack Growth Along Evacuator Holes of Pressurized, Autofrettaged Tubes
J. Pressure Vessel Technol (August,1996)
Related Proceedings Papers
Related Chapters
Use of Large Standoff Magnetometry for Geohazard Pipeline Integrity Investigations
Pipeline Integrity Management Under Geohazard Conditions (PIMG)
Failure Initiation and Ultimate Strength of Composite Laminates Containing a Center Hole
Composite Materials: Fatigue and Fracture, Fourth Volume
Application of a Multiaxial Load-Notch Strain Approximation Procedure to Autofrettage of Pressurized Components
Advances in Multiaxial Fatigue