Designers of advanced gun systems have been tasked with increasing barrel life in the face of the extreme erosion and wear of the interior ballistics environment. The addition of refractory metal coatings, such as chromium or tantalum, have greatly boosted service life, but even with these applications the erosion resistance of the underlying gun steel is the service-life limiting factor. The U.S. Army Research Laboratory (ARL) is currently undertaking an effort to determine the feasibility of ceramic gun barrels. Ceramics are attractive for liner materials because of their high-temperature performance and erosion-resistance characteristics. Unfortunately, their drawbacks are low tensile strength, low fracture toughness, and brittle fracture. Previous research into the replacement of metals with a ceramic liner has met with limited success, at best, but advances in ceramic manufacturing technology, probabilistic design, and sheathing technology have led to renewed interest in this area. The work at ARL has focused on developing a material property database of commercially available ceramics, extensive finite element and analytic modeling, experimental verification, and, ultimately, demonstration of the ceramic gun barrel technology. This body of work will focus on the derivation of analytic models for an N-layered tube to calculate the Weibull failure probabilities for a ceramic liner. Model results are verified through high-pressure burst testing of blank and sheathed ceramic tubes. The application of the models as a design tool is explored by generating failure surface plots to investigate optimal geometries and prestress levels for a variety of different liner and sheath materials across various caliber systems.

1.
Harlow
,
R.
, and
Kimball
,
R.
, 1972, “
Composite Barrel Materials Research and Development
,” Air Force Armament Laboratory Technical Report No. AFATL-TR-72-3, Eglin Air Force Base, FL.
2.
Harlow
,
R.
,
Briggs
,
W.
, and
Kimball
,
R.
, 1973, “
Development of Full Length, Insulated Composite Barrels for Aircraft Machine Guns
,” Air Force Armament Laboratory Technical Report No. AFATL-TR-73-10, Eglin Air Force Base, FL.
3.
Fischman
,
S.
, and
Palmer
,
C.
, 1975, “
The Design and Fabrication of a Ceramic-Lined Gun Barrel Insert
,” Naval Surface Weapons Center/Dahlgren Laboratory Technical Report No. TR-3342, Dahlgren, VA.
4.
D’Andrea
,
G.
,
Cullinan
,
R.
, and
Croteau
,
P.
, 1978, “
Refractory Lined Composite Pressure Vessels
,” Technical Report No. ARLCB-TR-78023, U.S. Army Armament Research and Development Command, Benet Weapons Laboratory, Watervliet, NY.
5.
Giles
,
R.
,
Bunning
,
E.
, and
Claxton
,
D.
, 1981, “
Feasibility of Ceramic Lined Gun Tube
,” U.S. Army Armament Research and Development Command Report ARLCD-CR-80058, prepared by Maremont Corporation, Saco, ME.
6.
Stephan
,
P.
, and
Rosenfield
,
A.
, 1982, “
Survey of Ceramics in Gun Barrels
,” Report No. AMMRC SP-82-1, Materials Technology Laboratory, Watertown, MA.
7.
Katz
,
R.
, 1996, “
Ceramic Gun Barrel Liners: Retrospect and Prospect
,”
Proceedings of the Sagamore Workshop on Gun Barrel Wear and Erosion
, Army Research Laboratory, Wilmington, pp.
67
84
.
8.
Weibull
,
W.
, 1939, “
A Statistical Theory of the Strength of Materials
,”
Proc. R. Swedish Inst. Eng. Res.
,
151
, pp.
1
45
.
9.
Carter
,
R.
, 2003, “
Model Development for Parametric Design of Pressurized Ceramic Tubing
,”
Ceram. Eng. Sci. Proc.
0196-6219,
24
(
4
), pp.
477
482
.
10.
Rousseau
,
C.
, 1987, Master’s thesis “
Stresses and Deformations in Angle-Ply Composite Tubes
,” Virginia Tech, Blacksburg, VA.
11.
Rousseau
,
C.
,
Hyer
,
M.
, and
Tompkins
,
S.
, 1987, “
Stresses and Deformations in Angle-Ply Composite Tubes
,” CCMS-87-04, Virginia Tech, Blacksburg, VA.
12.
Eduljee
,
R.
, and
Gillespie
,
J.
, 1996, “
Elastic Response of Post- and In Situ Consolidated Laminated Cylinders
,”
Composites, Part A
1359-835X,
27
, pp.
437
446
.
13.
Swab
,
J.
,
Wereszczak
,
A.
,
Tice
,
J.
,
Caspe
,
R.
,
Kraft
,
R.
, and
Adams
,
J.
, 2005, “
Mechanical and Thermal Properties of Advanced Ceramics for Gun Barrel Applications
,” Army Research Laboratory Technical Report No. ARL-TR-3417.
14.
ASTM C1239-00, 2004, “
Standard Practice for Reporting Uniaxial Strength Data and Estimating Weibull Distribution Parameters for Advanced Ceramics
,” ASTM Standards, Vol.
15.01
.
15.
Bates
,
D. M.
, and
Watts
,
D. G.
, 1988,
Nonlinear Regression Analysis and Its Application
,
Wiley
, New York.
16.
Seber
,
G. A. F.
, and
Wild
,
C. J.
, 1989,
Nonlinear Regression
,
Wiley
, New York.
17.
Carter
,
R. H.
, 2001, “
Characterizing the Mechanical Properties of Composite Materials Using Tubular Samples
,” Ph.D. dissertation, Virginia Tech, Blacksburg, VA.
19.
Underwood
,
J.
,
Todaro
,
M.
,
Witherell
,
M.
, and
Parker
,
A.
, 2005, “
Analysis of Firing and Fabrication Stresses and Failure in Ceramic-Lined Cannon Tubes
,”
Ceram. Eng. Sci. Proc.
0196-6219,
26
(
8
), pp.
281
291
.
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