By Jouya N POPSICLE STICK BRIDGE PROJECT INTRODUCTION
By: Jouya N POPSICLE STICK BRIDGE PROJECT
INTRODUCTION � � � Unit of Inquiry: Bridge Unit “Can I span the distance? ” Statement of Inquiry: Historical inventions have led to great advances in technology. Objective: To design a bridge that can span 30 cm and support load. Leonard P. Zakim Bunker Hill Memorial Bridge Design Specifications: • A maximum of 75 popsicles used • Must span a length of 30 cm • Superstructure cannot exceed a height of 20 cm • Substructure cannot exceed a depth of 20 cm • A maximum of three glue sticks used The Lions Gate Bridge
DESIGN CYCLE Reflection and testing Create Bridge Research Bridge Design and Selection
INVESTIGATION What forces are applied to a bridge? � What shapes are the strongest? � Why are those shapes the strongest? � What type of bridge supports the most weight? �
PLANNING � We chose four bridges that we thought were appropriate to the maximum material list, bridge span minimum, height and depth limit of the structure, and those that we thought were the Chart Title strongest and would support the most weight. Jouya=design lab 18% 35% 16% 34% 65% 16% Jouya=bridge design Kristian=bridge design
RESEARCH � Triangles are a strong shape and are used through out bridges � Quadrilaterals are weak structures as they rack easily but can be reinforced with a diagonal beam � Beam, truss, arch, and cantilevered bridges are all possibilities for a design
DESIGNS We designed four bridges Double Intersecting warren bridge Arch Bridge Cantilevered Bridge Bowstring Bridge
DOUBLE INTERSECTING WARREN BRIDGE Pros • There a lot of triangles making it a strong structure • Weight is evenly distributed due to design Cons • If a popsicle stick is missing the structure could fail • There is no substructure to support the structure
Cons BOWSTRING BRIDGE Pros Difficult and time consuming to build Half circles are strong Missing popsicle sticks could weaken the structure Load is equally distributed There is no substructure for extra support It would support weight well
CANTILEVERED BRIDGE Pros • There is a substructure that provides extra support in preventing tension • Weight is well distributed in the structure and supported due to the substructure Cons • Structure might fail at weak points at ends • Consumes many popsicle sticks just for sides of bridge • It’s is the most complicated to build compared to the others
ARCH BRIDGE Pros Cons Force distributed to ends of structure Less support in the middle of structure Equal distribution of weight Structure relies on ends of structure to not fail Large amount of popsicle sticks consumed for just one side of structure
SELECTED BRIDGE In the end we decided to create a cantilevered bridge as it has both a superstructure and a substructure that both add extra support to the bridge. We inferred that it would be stronger than the other bridges as the substructure adds extra support against compression and tension. Also, compared to the other bridges, the design is more thought out so it can hold more weight.
MODIFYING SELECTED BRIDGE Observing selected bridge we realized that the ends of the substructure were not supporting the structure that much against tension so we removed them and added them to the deck of the bridge which gave more support against compression and reinforced it. Also, the substructure was not supporting the load in the center so we flipped two of the popsicle sticks creating an X in the middle of the structure adding a lot more support. Finally we add horizontal supports on any equilateral triangles creating right angle triangles. This would add even more support to the structure against racking.
BUILDING PROCEDURE Using the blueprint, we created first one side of the structure working left to right by using wooden popsicle sticks and hot glue Next using paper we copied the blueprint of the side to create a template for making the other side Create the other side using the template Join both sides with more popsicle sticks and hot glue to form a triangle to prevent racking Reinforce any area showing weakness under either compression or tension with left over hot glue or popsicle sticks
MITER JOINT � Where two materials are cut in such a way to create usually a 45 degree angle corner � It creates stronger joints � It compresses crowed joints which reinforce and creates a more presentable look to the structure
TESTING � We inferred that our bridge would hold 60 lbs yet it was only able to hold 30 lbs � We tested the bridge by attaching a chain to a box and gradually increasing the weight of it
REFLECTION After observing the bridge we realized that our bridge failed under minor weight due to the end of the deck where the bridge failed to be angled. This caused a glue joint to fail since the bridge end tried to right itself forcing it out of place causing the bridge to be pulled down by the load. To prevent this from happening if we took more time and care in make sure that everything was at the right angle. If we were to rebuild this our design would be able to hold a lot more since we now know where the weak points are
WORKS CITED � � � � Historyofbridges. com, . (2015). Bridge Types - Different Types of Bridges. Retrieved 11 June 2015, from http: //www. historyofbridges. com/facts-aboutbridges/types-of-bridges/ Mathsinthecity. com, . (2015). Most stable shape- triangle | Maths in the City. Retrieved 11 June 2015, from http: //www. mathsinthecity. com/sites/most-stableshape-triangle Pbs. org, . (2015). BUILDING BIG: Forces Lab. Retrieved 11 June 2015, from http: //www. pbs. org/wgbh/buildingbig/lab/forces. html Google Images
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