Your search keyword '"Karhi, Ryan W."' showing total 8 results

1. Secondary arc formation within a distributed energy railgun

Author

Karhi, Ryan W., Mankowski, John J., Dickens, James C., Kristiansen, Magne, and Wetz, David A., Jr.

Subjects

Plasma astrophysics -- Analysis, Plasma arc cutting -- Analysis, Business, Chemistry, Electronics, Electronics and electrical industries

Abstract

Experimental results comparing a breech-fed scheme and two distributed energy schemes for a free-running arc are presented. Analysis and observations of the issues associated with distributed energy switching of a plasma arc in the railgun are explored. The use of a free-running arc allows experiments to emulate the ablation and restrike phenomenon of a plasma armature railgun at high speeds (> 5 km/s) without the requirement of a large amount of stored energy. Numerous experimental tests were conducted to investigate the dynamics of plasma arcs within a distributed energy source railgun. Variations of switch timing, bore pressure, bore material, current amplitude, and current pulse length within each stage have been tested. These data reveal important design parameters for distributed energy railguns. The arc length, stage length, and stage trigger timing play a crucial role in distributed energy railgun performance. Failure to take these parameters into consideration will result in velocity reduction through plasma arc restrike and/or splitting. Index Terms--Distributed energy railgun, plasma armature railgun, railgun.

Published

2008

2. A multi-stage distributed energy plasma arc railgun

Author

Karhi, Ryan W., Giesselmann, Michael G., Bayne, Stephen B., Rasty, Jahan, McNab, Ian, Wetz, David A., and Mankowski, John J.

Subjects

Plasma, Railgun, Plamsa arc, Distributed energy store

Abstract

The development process pertaining to the design, fabrication, coding, and testing of multi-stage distributed energy plasma arc railguns are presented. In collaboration on an Air Force Office of Scientific Research (AFOSR) funded Multidisciplinary University Research Initiative (MURI) project, the Center for Pulsed Power and Power Electronics (P3E) at Texas Tech University is responsible for developing and investigating a functional scale model of a multi-stage distributed energy store (DES) railgun to analyze its effectiveness to suppress a restrike phenomenon and increase plasma armature railgun performance [1]. The term “restrike” denotes the formation of an electrical breakdown in the railgun bore some distance behind a traveling plasma armature. The formation of this secondary arc reduces the driving force on the primary armature and has led to a velocity ceiling of approximately 6 km/s on all breech-fed plasma armature railguns. Numerous solutions have been theorized as viable methods of restrike prevention but lack experimental verification. The primary objective of our research team within the MURI effort is to experimentally test Dr. Jerry Parker’s theoretical restrike suppression technique [2] that was developed at Los Alamos National Laboratory in the 1980’s. The project tasks are organized to identify potential problematic issues and verify theoretical concepts before implementation of a full scale system.

Published

2010

3. Intrumentation and control of electromagnetic launchers

Author

Karhi, Ryan W., Dickens, James C., Hemmert, David J., and Mankowski, John J.

Subjects

Distributed, Electromagnetic launcher, Railgun

Abstract

The instrumentation and control of electromagnetic launch technology is presented. All of the experimental work and theory presented refer to one specific type of launcher know as a railgun. Two railgun projects supported by the AFOSR are described. One is an STTR phase 1 contract to develop a fast transient control system for solid state switching of numerous capacitor banks for implementation on a railgun. The other is a MURI project in collaboration with the IAT at the University of Texas for low cost access to launch micro-satellites into orbit. A project goal for both funded projects was to design and test control systems for the application of multi-stage railgun timing control. This relatively new area of railgun research is attributed to the need for complex multi-stage systems. The paper starts with control systems for proof of principle solid armature experiments and ends with a controlled asynchronous free-running arc distributed energy system.

Published

2007

4. Theoretical and Experimental Analysis of Breech Fed and 40-Distributed Energy Stage Plasma Arc Railguns

Author

Karhi, Ryan W., primary, Wetz, David A., additional, Mankowski, John J., additional, and Giesselmann, Michael, additional

Published

2012

5. Analysis of Distributed Energy Railguns to Suppress Secondary Arc Formation

Author

Karhi, Ryan W., primary, Mankowski, John J., additional, and Kristiansen, Magne, additional

Published

2008

6. A Synchronous Free-Running Arc Distributed Energy Railgun

Author

Karhi, Ryan W., primary, Mankowski, John J., additional, and Dickens, James C., additional

Published

2007

7. Real Time Feedback Control System for an Electromagnetic Launcher

Author

Karhi, Ryan W., primary, Mankowski, John J., additional, Hemmert, David J., additional, and Holt, Shad L., additional

Published

2006

8. A 40-Stage Synchronous Distributed Energy Railgun.

Author

Karhi, Ryan W., Wetz, David A., Giesselmann, Michael, Mankowski, John J., Diehl, Jeff P., and Kelly, Patrick M.

Subjects

*PLASMA gases, *ELECTRONIC probes, *ELECTRIC switchgear, *ELECTROMAGNETIC waves, *ELECTRIC lines, *CAPACITORS, *HYPERVELOCITY

Abstract

The development process pertaining to the design, fabrication, and testing of a 40-stage free-running arc synchronous distributed energy railgun is presented. Research efforts are still ongoing to suppress the restrike phenomenon that is responsible for causing a velocity ceiling around 6 km/s to exist on plasma armature breech-fed railguns. Numerous solutions have been theorized as viable methods of restrike prevention but lack experimental verification. In collaboration on an AFOSR Multidisciplinary University Research Initiative project, the team at Texas Tech University is responsible for characterizing a functional scale model of a synchronous distributed energy railgun to investigate the effectiveness of a distributed energy scheme to suppress the plasma restrike phenomenon and increase plasma armature railgun performance. The distributed energy scheme is theorized to suppress restrike arc formation because the back-EMF voltage is localized to active stage regions. Synchronous operation refers to the speed of an electromagnetic wave in the LC transmission line formed by the rails and capacitors being matched to the velocity of the armature. The railgun drives a hypervelocity (8 km/s) plasma armature, with no payload, to emulate the conditions of a high-altitude microsatellite launch while relieving the financial burden of a large stored energy facility. Experimental data collected from a seven-stage prototype distributed energy system are discussed which will mimic the design and operation of the first seven stages associated with the final 40-stage system, which is currently under construction. The data collected from this prototype as well as the final 40-stage system will be analyzed for secondary arc formation in an attempt to verify the distributed energy scheme's success in suppressing restrike formation. [ABSTRACT FROM AUTHOR]

Published

2011