• Led development and U.S. launch of OP17, OP13, OP4 LE, and Spartan camper models.

• Developed lean manufacturing plans for OP15, improving workflow and reducing inefficiencies.

• Managed 30 employees; established clear roles and created SOPs to maintain product quality.

• Collaborated with China-based teams to resolve design and quality issues; issued design change directives.

• Prepared technical reports for new products and campers, and developed evaluation reports for prototype products to support design improvements and development decisions.

• Created detailed CAD models and engineering drawings in SolidWorks for new product development.

• Created CAD models and performed FEA (Finite Element Analysis- Solidworks Simulation) to validate structural integrity and meet design requirements

• Designed NEC- and RVIA-compliant electrical systems and schematics.

• Conducted full-system testing on RV prototypes: brakes, plumbing, propane, and electrical systems.

• Proposed and implemented revised production layouts to eliminate bottlenecks and increase productivity.

• Maintained current SOPs and documentation in line with compliance and design updates.

• Led design and manufacturing of new teardrop camper prototype from concept to production.

• Contributed to Nemesis Plus product innovation using SolidWorks prototyping.

• Analyzed production costs; recommended design-based cost-reduction strategies.

• Integrated Hi-Pot and other industry-standard tests into production for improved reliability.

• Diagnosed and resolved recurring design/manufacturing issues with long-term improvements.

• Inspected all RV components to meet UL, ETL, CSA safety standards; specified compliant parts.

• Designed composite camper walls to reduce weight, improve strength, and enhance all-season insulation.

• Replaced wood flooring with honeycomb panels to reduce weight, maintain strength, and lower the camper’s carbon footprint.

• Redesigned OP15 for 2025 rebranding, improving quality, usability, and aesthetics.

• Addressed design, manufacturing, and cost challenges related to mechanical systems and components in the aerospace sector.

• Analyzed machine operation times and labor hours to identify inefficiencies and reduce overall production lead times.

• Developed and maintained weekly work schedules for technicians to ensure smooth workflow and resource allocation.

• Collaborated with cross-functional stakeholders to resolve complex design changes and drawing discrepancies, ensuring alignment across engineering and manufacturing teams.

UNT is a Carnegie-ranked Tier One public research university. I assisted faculty members with projects, instruction, and recordkeeping, and performed laboratory research. I worked with students at the College of Engineering in state-of-the-art instructional facilities and laboratories containing cutting-edge research equipment, assisting students with study and discovery.

Primary Activities:

• Prepared presentations for lectures, proctored examinations, recorded grades and met with students during office hours.

• Assisted in developing course plans and taught undergraduate courses.

Self-Powered Through-Wall Data Communication for Nuclear Environments - U.S. Department of Energy Project.

The objective is achieved with the collaborative effort of two universities a national laboratory and a company through three innovations: (1) directly harvest electrical energy from the gamma-ray using the gamma heating and thermoelectrics, and from the beta radiation using betavoltaics. My role in this project was to transmit sensory data through the metal wall and thick concrete via “mode conversion” based ultrasound technology and expand to different stages, and to creatively design and pack high-temperature electronics circuits with radiation-hardening and/or shielding inside the enclosed nuclear vessels.

I developed and demonstrated enabling technology for data communications for nuclear reactors and fuel cycle facilities. I utilized radiation and thermal energy harvesters and an Arduino controller/device to send the initial “Hello World” signal to the function generator.

• Designed AM modulator and AM demodulator circuit devices.

• Used PZT piezo transducers as the transmitter and the receiver to transmit data through the metal wall.

• Tested the experimental model in different ranges of temperatures.

• Employed a laser beam as a receiver to receive signals from the Metal wall.

Mobile NDT Monitoring Robot - Department of Defense Project.

I was the designer for the DoD-sponsored NDT Monitoring Robot project. I designed a Thermal camera able to capture a thermal image of an object, using raspberry pi 3B+ to send audio and thermal image signals via Wi-Fi, and designed a Robotic Arm with a hammer to perform a tapping test (coin tap method). The purpose of the project was to inspect the material to determine whether it was corroded and observed pressure leakage using a thermal camera.

The design process started with a root cause analysis for the remotely operated arm. A microphone was used to absorb sound created by the tapping test. The project was completed in three months and under budget.

• Used NRF24lo1 as wireless communication to operate the Robot car (joystick).

• Programmed stepper motor and robot car with Audino.

• Designed a functional prototype robot car to investigate the material structure with the ability to climb walls and roofs of a tactical shelter to inspect and monitor multiple aspects of the structure.

• The methodology of tapping material enabled observation of the frequency of impact via an oscilloscope.

• A microphone received the signal and transmitted it to Raspberry pi and sent to a desktop computer via Wi-Fi as a Wav file, which was converted to FFT graph to analyze the frequency.