Custom Stand Up Paddleboard

Revision as of 21:32, 10 February 2016 by Cleyton (Talk | Contributions) (Possible Composites)

Revision as of 21:32, 10 February 2016 by Cleyton (Talk | Contributions) (Possible Composites)

Members

Cleyton Cavallaro

Christopher Grace

David Swanson

Background

The Custom Stand Up Paddleboard project is part of Michigan Technological University's BoardSport Technologies Enterprise. It is a senior capstone project that aims to develop a cheap and open source method for manufacturing top of the line paddleboards.

Materials and Techniques

Epoxy

SUPMaterials.PNG

Epoxy was chosen as a layer of Solarez epoxy between foam and fiber. This layer will give a more resilient layer to help with adhesion. Solarez epoxy does not harden fully, but remains a tacky epoxy to help give these properties. A layer of Super Sap INF from Entropy Resins was used for the outer layer. This will provide the hard shell needed for the board, and it will help increase overall strength. Both of these epoxies are resistant to UV light as well, which in essential when developing a board to be used in intense sunlight.

Super Sap INF was used for the sample testing. After running out, entropy has stopped making Super Sap INF. Super Sap One was substituted.

Foam

The Foam will be the center of the board. It will provide the buoyancy to keep the board afloat. After reducing our possible materials down to three foams, we selected Expanded Polystyrene (EPS), Divinycell Foam (PVC cross-linked), and I-Foam. Polypropylene(PP) was also tested as we did not have all material properties on I-Foam, which is a mix of PP and EPS. By testing PP we were able to predict some of the expected properties of I-Foam. These can be seen in table 1.

EPS foam was the final selection.

Fiber

The fiber layer of the board will be just across the bottom. Because of the loading of a paddleboard, the fiber on the bottom will be in tension. This is where they will lend to most strength to the board. Putting fibers on top of the board would just add to the cost with minimal strength benefits. The three fiber choices, seen in table 1, are Carbon Fiber, E-glass heavy weight, and E-glass light weight.

The final fiber choice is carbon fiber.

Stringer

Stringers help to provide additional stiffness to the board. While all testing we done without a stringer in it, the addition of a stringer is standard and cannot harm the board.

A 1/8" balsa stringer was chosen.

Blank Manufacturing

The model for the paddleboard is larger than any current CNC machine at Michigan Tech. To solve this problem, we considered both hand shaping the board and contracting out the board. Hand shaping would save on costs but would provide a lower quality board. The contracting of the board will obviously provide an easier and higher quality board, but with a cost. We decided to contract the board out to [markofoamblanks.net Marko Foam]. The total cost was $298.97 plus $233.00 for shipping. The blank was quickly cut and shipped. While we are currently still waiting on the blanks arrival, Marko has helped significantly during the entire process. The PO is linked.

Fin

Under Research

Layup Technique

Under Research

Possible Composites

During the selection of foams and fibers, CES Edupack was used to decide upon which materials were good possibilities. The 3 foams and 3 fibers were selected based on density, strength, price, and water acceptability. By optimizing these constraints we developed the final choices for testing. The charts we used to select the materials are below.


Fiber Selection
Density vs. Price  
Tensile Strength vs. Density  
Water vs. Price  

CAD Model

The CAD model was based off over several industry standard boards. The pointed tip will help with tracking across the water, maximizing use the material properties we are striving for.

3D Model
Top View  
Side View  
Front View  
Back View  
Full View  

Sample Testing

Semester Report

FEA Testing

Material Selection

Manufacturing

Has not begun