SBIR-STTR Award

The SMA reinforced aluminum composites show self-strengthening by compressive stresses in Al matrix due to shape memory shrinkages of the embedded TiNi fibers (Furuya, 1996). The increases in tensile properties such as yield stress as well as fatigue resistance (crack growth retardation) at higher temperature were experimentally confirmed by Furuya (1996). Based on the new requirements for Future Combat Systems (FCS), there is a great need to develop MMCs with (1) minimal machining and joining requirements (near net-shape capability), (2) complex shape manufacturability, (3) improved fracture toughness (KIC) and impact toughness (Charpy)over 75% that of hardened 4340 steel, and (4) a density that is 25% lighter than steel. In Phase I of this SBIR program, our team will investigate the feasibility of using SMAs to make Al MMC with SiC particulates and/or whiskers to develop tough and durable MMCs with a manufacturing process that is capable of making complex structural parts for application in FCS. SMA based aluminum MMC offer self-induced compressive residual stresses which will increase the durability and damage tolerance of MMC for application in demanding Army vehicle applications such as in Future Combat Systems (FCS). Processing routes proposed can be used to develop materials in various forms allowing maximum flexibility and increasing the possibility of applications of SMA based MMCs in various structural parts. The process technology can be applied to produce tough composite parts in commercial automotive applications as well.

Shape memory alloy (SMA) fiber reinforced aluminum composites, SMA-MMC offer excellent properties, particularly, fracture toughness and damage tolerance which are due to induced compressive residual stresses. In Phase I, we have demonstrated through casting and warm rolling that viable SMA-MMC can be dveloped with desirable mechanical properties. In Phase II, we plan to model the behavior of these new class of composites to develop material design tools and to explore three competing processing methods e.g., (1) deformation processing, (2) powder/hydroforming and (3) squeeze casting for producing MMC to determine which one is most efficient to produce SMA composites with improved thermomechanical properties. One of these processing methods will be selected to develop demonstration articles such as track-shoe inserts e.g., in Future Combat System (FCS)- an advanced next generation vehcile for the US Army. Newaz Technologies, Inc. has teamed up with University of Washington (Professor Minoru Taya), Cast Metal Composites, Inc. (CMCI) of Cleveland with considerable experience in MMC component development for Army and Dr. Xin Wu (consultant)- an expert in manufacturing technology with advanced materials. The team involves national and international experts to provide Army with this unique technology of SMA composites for structural applications. Phase II success in this program is expected to lead to a Phase III program. The proposed program is unique in that this is the only SMA-MMC R&D effort in the US for potential DoD and commercial applications.

Keywords:
Shape Memory Alloy, Metal Matrix Composite, Fracture Toughness, Compressive Residual Stress, Nickel-Titanium (Niti) Fibers, Martensite, Austenite, Tra