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Caleb Vanderpleog Resume and Academic Summary
- 1. Caleb Vanderploeg Mechanical Engineer, BSE cjvanploeg@gmail.com ▪ (632) 670-3257 ▪ 4110 W Charlotte Dr ▪ Glendale, AZ 85310 EDUCATION Arizona State University, Tempe, AZ May 2015 Bachelor of Science Engineering, Mechanical Engineer 3.9/4.0 WORK EXPERIENCE WireBuzz LLC Scottsdale, Arizona VIDEO EDITOR September 2015-Present Edit videos and apply color grading using Adobe Premiere and SpeedGrade Create 2D animations using Adobe After Effects GoPro Inc. San Mateo, California MECHANICAL ENGINEERING INTERN- Aerial Products June 2015 – August 2015 Performed competitor consumer device teardown and analysis for cost estimation Designed waterproofing methods to meet IPx8 standards Designed and prototyped potential future products and test fixtures in Creo Assisted in completing technical drawings for tool release Division Design, Engineer, Machine LLC Mesa, Arizona MACHINIST March 2014 – October 2014 Generated 3D CAD models in Solidworks using mechanical fabrication drawings Utilized GD&T methods for creating mechanical fabrication and assembly drawings Programmed G-Code using the HSMWorks add-on in Solidworks for a 3-Axis CNC Mill Varsity Tutoring Tempe, Arizona TUTOR December 2014 – June 2015 Communicated directly with clients for scheduling and understanding student needs Developed lesson plans for unique student needs
- 2. Academic Projects Summary Problem Statement: Fully design a reverted gearbox for a given windmill with specified initial conditions and requirements that includes all mechanical components minus the outer housing. Method: Utilize stress, strain, and fatigue equations for shafts, gears, cantilever beams, and bearings as well as me- chanical property data sheets to select proper materi- als and design the layout and dimensions for a revert- ed gearbox, both by hand and using FEA software. ï‚· Calculated proper gear sizes, teeth geometry, and wear conditions by hand for each gear ï‚· Calculated shaft diameters by hand using stress/ strain equations for shafts using an iterative pro- cess in order to achieve specified safety factors. ï‚· Verified calculations using ANSYS Workbench ï‚· Calculated endurance limits for shafts and gears. Team Size: 3 Deliverables: Report including BOM, CAD models for BOM, detailed calculations for shaft and gear geometries, ANSYS simulations. Problem Statement: Design and prototype a camera stabilization platform for the GoPro Hero line of Cameras. Conceptual Design: Develop an actively stabilized 3-axis gimbal system driven by brushless motors controlled by a PID sys- tem . Team Role: Lead Design Engineer/Systems Engineer ï‚· Designed mechanical components using SolidWorks to meet structural requirements and to have visual appeal. ï‚· Designed the transfer function for the motorized gim- bals and tuned the PID values of the control system using Simulink ï‚· Performed failure modes and effects analysis and fi- nite element analysis of product components ï‚· Drafted technical drawings for numerous parts and managed the bill of materials for the project. Senior Capstone Design Project Fall 2014 - Spring 2015 Handheld GoPro Gimbal System Class Grade: A Project Grade: A+ Team Size: 6 Deliverables: Functional prototype, project report and presentation Financial Budget: $300.00 Total Cost: $297.56 Labor Budget: 1100 hr Total Labor: 1132 hr Mechanical Design Final Project Spring 2014 Windmill Reverted Gear Box Class Grade: A Project Grade: A
- 3. Academic Projects Summary Problem Statement: Perform finite element analysis on a bicycle frame us- ing ANSYS Workbench Method: Use ANSYS Workbench to simulate static loads and modal analysis on different parts of a bicycle frame and wheel for various initial conditions. ï‚· Assigned material selection and mesh characteris- tics to imported bicycle CAD. ï‚· Performed static loading analysis on bicycle frame and petals under various conditions ï‚· Identified critical failure points and proposed de- sign modifications to improve bicycle design ï‚· Performed modal analysis on wheel and spokes under given loads. Computer Aided Engineering Project Spring 2015 ANSYS Bicycle FEA Class Grade: A- Project Grade: A Team Size: 1 Deliverables: Report consisting of results and step by step report on how analysis was set up and performed Problem Statement: Design and simulate guidance commands for a mis- sile intercept scenario using TPN and Optimal guid- ance laws. Method: Developed a Simulink block diagram capable of simu- lating the flight path of a target missile with given initial conditions and the flight path of an intercept- ing missile guided equations for both TPN and Opti- mal Guidance ï‚· Wrote MatLab code to facilitate Simulink operation ï‚· Designed complex Simulink block diagrams using given guidance laws and initial conditions. ï‚· Analyzed results to determine optimum use cases for the two guidance methods. GNC: TPN and Optimal Guidance Spring 2015 Target Intercept Project Class Grade: A+ Project Grade: A+ Team Size: 1 Deliverables: Report including Simulink block diagrams, MatLab Code, plotted trajectories, results and conclusions.
- 4. Personal Project Summary Problem Statement: Develop a device that could be used for in- put in both the virtual world as well as a typi- cal computer interface. Concept: A PC mouse that could be easily integrated into a VR system where VR is not the primary method of interfacing with the computer. Design: Two motion tracking handles used to map out user movements in 3D space that can be magnetically connected to form a familiar mouse. Triggers under the handles are used to input user commands while in VR mode, IMU sensors within the handles are used to track user movement Touch sensitive mouse buttons similar to that used in the Apple Magic Mouse would be used to input user directional control while in both the VR and "normal" mouse op- eration. Design and Surface Modeling Project August 2015 VR Controller / Computer Mouse