1200W Flyback Driven Capacitor Charger

This is a 12ooW charger which uses a coilcraft GA3460-BL flyback transformer in conjunction with the LT3751 microchip. In theory it is capable of charging a 12000uF 400V capacitor in only a few seconds. The LT3751 microchip controls the charging of the capacitor and offers charging cutoff and safety features. The charger is powered by a 4s 2200mAh Li-Po battery pack capable of 20c continuous discharging. This supplies the charger with 740 watts of power.

Being that this was only my second attempt at surface mount soldering, unfortunately, several of the solder pads beneath the resistors were damaged. I am unable to be sure whether or not the charging circuit would have been functional and I decided to abandon the project due to the danger of working with such high powers.




Mini Power Supply

This is a miniature power supply which accepts voltage inputs between 12 and 18 volts. It uses a 12 position dip switch to program the output of the power supply. The power supply can output 12v, 5v, and 3.3v. At 5v the power supply is switchable between 5mA, 10mA, 20mA, 30mA and it can also output a square wave signal of 0.1Hz, 1Hz, 10Hz, 100Hz, and 1kHz. The power supply is built with three voltage regulators and a 555 timer. It includes two LEDs indicating power output and frequency.


1/10 Traxxas Summit

Weight = 16lbs

Top Speed = 35mph



-Tekin RX8 210A ESC

-Tekin 2250kV Brushless Motor

-Integy Aluminum A-Arms

-Integy Aluminum Servo Guards

-Integy Titanium Skid Plates

-Integy Steel Roll Cage

-MIP Steel Splined CVDs

-RC4WD 8.3″ Rok Lox 4.0 Tires

-Axial 8 Hole Bead lock Wheels Black

-2x Blue LiPo 2S 7.4v 30C 5000mAh LiPo

-Novak 12T 5mm Steel Pinion

3D Printed Nylon Composite Quadrocopter Frame

In order to achieve a unique and customizable quadrocopter frame I decided it would be most affordable to design the frame using Autodesk Inventor and then print the frame through the services offered by Shapeways. The frame is constructed by a process know as selective laser sintering in which a 3D printer bonds together 0.1mm layers of nylon powder with a laser. This process yields highly accurate and detailed models and costs approximate $1.50 per cubic centimeter of material from Shapeways. The nylon material, more specifically know as polyamide 2200, is somewhat flexible and very light weight with a density of 0.93 grams per cubic centimeter, lighter than carbon fiber. PA2200 has a fairly high tensile strength of 48MPa, higher than most plastics including ABS plastic; and it is capable of elongating by 24% before failing. Due to its flexible properties, it should be well suited for absorbing some of the motor vibrations and it should also hold together well in minor crashes and hard landings. Although it is not nearly as strong a carbon fiber or G10 fiberglass, it is one of the strongest and lightest materials available for 3D printing.


Revision 1:

Below is the first revision of the quadrocopter frame. It incorporates an octagonal frame with landing skids mounted to the bottom of the frame and a simple roll bar across the top. The volume of plastic necessary to print this model is approximately 22 cubic centimeters.

After receiving the completed plastic parts, I noticed several design flaws. The web like design of the frame had many areas of excess plastic which weren’t equally distributing the load on the frame. Since the frame was opened at the center and there were no supporting beams to distribute the load of the arms across the center, the frame was more flexible than anticipated.


Revision 2:

Below is the second revision of the quadrocopter frame. In order to address the structural defects of the first revision the frame was redesigned from the ground up. This revision uses square tubes which run along the entire length of each inserted arm, adding much rigidity and equally distributing the applied load. The walls to hold the control board seen in the first revision were removed so that any quadcopter board with 45mm hole spacing could be mounted atop the frame. Additionally, rails were added between each arm for not only structural support but increased range of mounting possibilities for the receiver or any other electronic sensors or accessories. Each rail is designed with a hole for mounting the controller board with bolts as well as two slots for anchoring electronics to the frame using zip-ties. Instead of attaching conventional helicopter like landing gear to the base of the central frame, springy legs were attached to each of the motor mounts in order to prevent tipping of the quadrocopter upon takeoff and landing. The volume of plastic necessary to print this model is approximately 21 cubic centimeters.

Stress Analysis:

This stress analysis simulates the effects all four rotors pulling up on the frame at maximum throttle (10N), assuming that the frame is grounded.


Revision 1:

Revision 2:


Average displacement of revision two is 46% of the displacement from the first revision making the second revision more than twice as rigid. The first principle stress shows that the first frame focuses massive amounts of pressure on several small points at the center of the frame. This pressure builds to 14MPa at each of the corners in the center of the frame between each arm. In contrast, the second frame more evenly distributes the stress and focuses a maximum load of 7Mpa at any point on the frame. Ultimately, this means that the strength of the second frame revision is approximately twice that of the first revision. While the first frame would fail with a load or impact of approximately 50N on each arm, the second frame should be able to withstand forces upwards of 100N on each arm. This is a significant increase in the load bearing efficiency of the second design.

UPDATE: 10/10/11

After finally recieving all of my parts from hobbyking I was able to complete the assembly of my quadrocopter. Unfortunately, the first revision of the frame needed improvements which I added to revision 2, however, the printing of a second frame put me over budget so I decided to assemble the frame from some lighter weight balsa arms and sheet metal. Pictures of the completed quadrocopter are linked below, hopefully I will have some video up in the future and maybe some fpv.

Revision 1 Pictures

Completed Quadrocopter

Quadrocopter Parts List

This is my latest design for a quadrocopter capable of lifting a digital camera or GoPro, additionally it should be able to lift a foscam incorporating pan/tilt and IR night vision functions.





– 4x Exceed Optima 910kV 250W brushless outrunner


– 2x plastic 10×6

– 2x plastic 10x6R


– 4x Hobbyking 25A Red Brick


Generic 6CH Tx/Rx


Hobbyking Quadrocopter Controller


Turnigy 3S 5000mAh 20C

Zippy 3S 2200mAh 25C

After completing the build, I determined that a 2000mAh – 3000mAh 3S Li-Po battery would suffice. A 5000mAh 3S Li-Po battery will work but is significantly larger and heavier than the 2200mAh battery which I am currently using.


– 4x 10″ aluminum square tube with 1/16″ outer wall

After completing the build, I determined that although the 3D printed frame was designed to work with 3/4″ tubing, ideally 1/2″ tubing should have been used to minimize weight and size. Instead of printing a second frame I decided to build a frame from balsa and sheet metal.


3D Printed Nylon Composite


– Scratch Built Frame



Optional Components:

16 Gauge Wire

XT60 or Banana Connectors

Solder / Flux / Soldering Iron / Soldering Tools



Maximum Thrust ~ 1400g/motor

Maximum Power ~ 1000W