CAMP Research and Publications

At OHIO's Center for Advanced Materials Processing (CAMP), research focuses on advanced “high-tech” materials as well as more conventional ones. Projects involve materials processing technology for titanium, nickel-based (super) alloys, polymers, carbon fibers and nano-tubes, composites (both polymer and metal matrix), and other new materials and coatings.

CAMP researchers are also involved with developing innovative processes for conventional materials such as steel, copper, and aluminum alloys. CAMP engineers develop novel processing and experimental methods while promoting cost-optimization through analytical modeling of these methods.

Research Projects

Current CAMP research projects are focused on four areas:

Metal Additive Manufacturing
Manufacturing and Material Simulation
Dynamic Testing
Process Monitoring

Publications

Our researchers publish regularly in major peer-reviewed journals, present at national and international conferences, and deliver targeted results to our research partners. Visit the CAMP Affiliate Faculty and Students page and click individual faculty profiles to learn more about their publications and research.

Relevant Journals

Some relevant industry journals where you may find CAMP publications include:

ASME Transactions
The Journal of Structures
The Journal of Materials Processing Technology
Annals of CIRP
SAE Transactions
TMS and ASM publications
The International Journal of Heat Exchangers
The Journal of Air and Waste Management
Journal of Materials Research
Composites Part A
Polymer Composites

Patents

CAMP faculty have patented novel manufacturing processes and advanced materials in the U.S. and abroad.

CAMP Patents

U.S. Patent Number 4,642,227, "Reactor for Producing Large Particles of Materials from Gases” R. Flagan and Khairul Alam 1987; describes a method for producing particles in a reactor
U.S. Patent Number 6,231,643, "Membrane Electrostatic Precipitator (H. Pasic, Khairul Alam and D. Bayless), 2001; describes a novel ESP using membranes or fabric
U.S. Patent Number 6,783,575, “Membrane Laminar Wet Electrostatic Precipitator” (H. Pasic, K. Alam, D.Bayless), 2004; describes a wet ESP using membrane with a flow of liquid
U.S. Patent Number 6,878,192, “Sieving Electrostatic Precipitator” (H. Pasic), 2005; describes a novel ESP using mesh as a collector
European Patent Number 1,307,331, “Improved Polymer Matrix Composite” (K. Alam, R. Kuriger), 2000; describes a method for producing polymer composites with aligned nanofiber
U. S. Patent 8,191,393 B2, “Micro-Channel Tubes and Apparatus and Method for Forming Micro-Channel Tubes” (F.F. Kraft), June 5, 2012; describes a process by which copper and copper alloy multi-channel tube can be manufactured
- Canadian Patent 2,672,098, July 30, 2013
- Japanese Patent 5227972, March 22, 2013
- European Patent 2104577, August 3, 2011
- Finnish Patent EP07853351.0, October 31, 2011
- Greek Patent EP/37584, October 12, 2011
- Italian Patent EP 2 104 577, August 3, 2011

Electrostatic Precipitation Lab Patents

U.S. Provisional Patent “Vibrating Wet ESP” Filed June 2015 (With H. Pasic)
U.S. Provisional Patent: “Wet Electrostatic Precipitator and Method of Treating an Exhaust”– Filed Oct, 2014 (With H. Pasic)
U.S. Patent 7,976,616, “Composite Discharge Electrode” 2011
Pasic, H. Low Cost Composite Discharge Electrode. 2009/009787 A1.
U.S. Patent Number 6,783,575, “Membrane Laminar Wet Electrostatic Precipitator” (with H. Pasic, D. Bayless), 2004 US Patent
U.S. Patent Number 6,231,643, “Membrane Electrostatic Precipitator” (with H. Pasic, D. Bayless), 2001
U.S. Patent Number 4,642,227, “Reactor for Producing Large Particles of Materials from Gases” (with R. Flagan), 1987
Pasic, H. Electrostatic Sieving Precipitator. 6,878,192.
Pasic, H., Hermann, G. Method of Removing Particulate Matter from Precipitator Plate. 4,276,056.

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