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Name ____________________________________ Group _____________________ Period___________

3D Printing Solar Car Challenge 200pts.



SQ: Which group can build the fastest solar powered vehicle?

Assignment

Points Possible

Points Earned

  1. Solar Electric: Questions

5




  1. Car basics

5




  1. Gears

10




  1. Calculating Vehicle Speed (VELOCITY)

10




  1. 2D Vehicle Plan (blueprints and materials list)

10




  1. Introduction to Sketch up: bookmark assignment

20




  1. 3D Wheels

50




  1. Vehicle Build Deadline

40




  1. Vehicle Testing

50






  1. Solar Electric: Questions

    1. What does SPV stand for?

    2. What does PV stand for?

    3. How does a solar powered vehicle run without sunlight?



    1. When did research begin to develop solar powered vehicles?



    1. What did Roland and Robert Boucher do? In what year?



    1. What was the “Pathfinder’?



    1. Who built the first solar powered car? When? What where 3 features of this vehicle?



    1. What is an EV?



    1. Why is aluminum or lightweight composites used when building SPV’s and EV’s?



    1. What did John Mitchell Systems do for vehicle design?



    1. Explain the maintenance of an SPV:



    1. What is the safety concern with EV’s?



    1. How do they measure the efficiency of solar cars?



    1. What is the advantage of a silver zinc battery? What is the disadvantage?



    1. What is the major benefit of solar powered vehicles?



  1. Car basics

http://web.csulb.edu/projects/solarcar/WhatIsSolrCar/basic_car.html

    1. What is the body of the car?



    1. What is the chassis of the car?



    1. What should you keep in mind when building the body and chassis of your solar car?



    1. What is the battery box? And what is it used for?



    1. What is the solar cell?



    1. What is sunlight used for?

Diagram of Solar Car parts:




Wheels

Purpose

Wheels support the chassis and allow the car to roll forward. Bearings support the wheel

while allowing them to rotate.

Ideas

Wheels can be large, small, and narrow; wide...here are some ideas to start you thinking:



Concept: Friction

Friction keeps things from sliding against each other. When you build your cars, there are

some parts that you want to slide easily, and there are other parts you don’t want to slide

at all.


Tire Traction

When you have two things that must roll against each other, like a wheel rolling along the

road, friction keeps them from slipping. This type of friction is also called “traction,” and

is important to remember when building your wheels.


Why do mountain bikes have big, fat knobby tires? If you have to bike up a muddy hill

covered with leaves, your tires will slip if they don’t have enough traction. And the big

knobs of rubber can grip onto the dirt and rocks and keep the tires from slipping on the

ground.
Now, the question is, why don’t racing bicycles have fat, knobby tires if these wheels

have good traction? Once again, there is a tradeoff in designing a wheel.

Mountain bike tires have two main disadvantages. The first disadvantage is the thick,

knobby rubber which gives them such great traction also makes them inefficient. Every

time a rubber “knob” is compressed and bent by the road, energy is lost. Where does this

energy go? If you have ever felt an automobile tire after it has been on the road, you

probably noticed that it was hot. The energy it took to compress the rubber and air in the

tire was lost as heat.

The heavier the wheel, the more energy it takes to get the wheel turning.

Surprisingly, the bigger the wheel diameter (even if it is the same weight), the more

energy it takes to get the wheel turning.

So, racing bicycles do not have mountain bike tires, because traction is not as important.

But what is important is efficiency, so that the bicyclist does not need to expend a lot of

energy. The bicycle designers have made a conscious decision to use different tires

designed for efficiency and speed and not traction.




  1. What kind of wheels do you need to make for your vehicle and why?



  1. Draw a sketch of your four wheels. Be sure to include the diameter measurements (cm) and the thickness measurements in (cm)



  1. Gears (see gears power point)

  1. Define mechanical advantage:



  1. What advantage do you gain from using gears?



  1. What is a ratio?



  1. How do you determine the ratio between two sets of gears?



  1. How are gear ratios written?



  1. Why is torque important?



  1. What are the relationships between speed, torque, wheel size, and rotations per minute (RPM’s)?

Always remember to reduce to the lowest common denominator. Gear ratios are written Driven gear to Driving gear, so if gear 1 has 10 teeth and is driving gear 2 having 5 teeth, the ratio is 5:10, or more correctly, 2:1.

What is the gear ratio between gears 1 and 2 if:

Gear 1 has A teeth and gear 2 has B teeth.

RATIO HOW MANY TIMES

  1. A= 10; B=20 ___________ If A turns one time, B will turn _____________________________.

  2. A= 10; B=40 ___________ If A turns one time, B will turn _____________________________.

  3. A= 3; B=27 ___________ If B turns one time, A will turn ___________________________.

  4. A= 10; B=200 ___________ If B turns one time, A will turn ___________________________.

  5. A= 12; B=48 ___________ If A turns one time, B will turn ___________________________.F

  6. A= 26; B=130 ___________ If A turns one time, B will turn ___________________________.

  7. A= 5; B=55 ___________ If B turns one time, A will turn ____________________________.

Rotation is measured in the number of times an item makes a 360 degree movement turning completely around to where it started, within a given time frame. Revolutions per minute or RPM is the standard and is considered a measurement of speed.

If a motor turns a gear on a shaft at the speed of 10 RPM, then the gear, whether it bears 10 teeth or 100 teeth will spin ten times in one minute. That is one revolution every 6 seconds. Half of a revolution every 3 seconds.

Given: A motor turns a shaft with a 24 tooth gear 8 ½ times in 10 seconds. That gear is meshed to a gear having A teeth which is connected to a second shaft.

  1. How fast is the shaft on the motor turning? _______________

  2. A= 24 How fast is the second gear turning? _______________

  3. A= 48 How fast is the second gear turning? _______________

  4. A= 8 How fast is the second gear turning? _______________

  5. A= 12 How fast is the second gear turning? _______________

  6. A= 100 How fast is the second gear turning? _______________

Torque is relative to speed, gear ratio, and all the info we have been discussing. Therefore, torque can be talked about reference to its formula t=f*l (torque equals force times lever arm length {radius of gear}). It can also be looked at reference gear ratio too.

Given: A motor turns a shaft with a 24 tooth gear. That gear is meshed to a gear having _A teeth which is connected to a second shaft. The motor can lift 8 lbs.

  1. A= 24 How much can the second shaft lift? _______________

  2. A= 48 How much can the second shaft lift? _______________

  3. A= 8 How much can the second shaft lift? _______________

  4. A= 12 How much can the second shaft lift? _______________

  5. A= 100 How much can the second shaft lift? _______________

  6. On a separate sheet of paper draw all of the gear ratios for your set of gears.

    1. Title: Gear Ratios

    2. Include your group number and period next to the title at the top of the page

    3. Trace all 4 gears and label A-D largest to smallest

    4. Trace all of the gear combinations (hint there are 12)

    5. Below each pair write the ratio (make sure it is reduced)

    6. Questions:

      1. Which gear pair will provide the greatest speed?



      1. Which gear pair will provide the greatest torque (force)?



      1. Which gear pair does your group plan to use and why?



  1. Calculating Vehicle Speed (VELOCITY (m/s))



    1. Gear

      # of teeth

      Diameter (cm)

      Circumference (cm)

      Circumference (m)

      A













      B













      C













      D













    2. If our motor turns at 5000rpm how many revolutions is that per second?



    1. RPS (motor) /Gear ratio = RPS (drive wheel) for the gear attached to our drive wheel:



    1. What is the circumference (m) of the drive wheel (back) for your car design?



    1. What is the velocity of your solar car? (V=C (drive wheel) x RPS(motor))




Group #


Velocity of Solar Car (m/s)

Time to complete track

(Track is 20meters V=d/t)

1







2







3







4







5







6







7







8









    1. Which group is predicted to pass the finish line first?



    1. What other variables (2) will affect this speed?



  1. 2D Vehicle Plan (blueprints and materials list)

Materials: motor, solar panel, gear box, battery box and wires, 2 bamboo skewers, gears….


On attached sheets of graph paper construct 2D

1:2 scale drawings of your solar car be sure to include:

        1. Side view

          1. Length and width measurements for the body of your vehicle.

          2. Diameter measurements for the wheels.

        2. Top View

          1. Length and width measurements for solar panel, gear box, and battery pack.

          2. Length measurements for the axles.

          3. Diameter measurements for the gears.

Be sure to label all parts of your vehicle: motor, solar panel, battery pack, gear box, wheels, gears, body and axles.



**All measurements should be in centimeters**






  1. Introduction to Sketch up: bookmark assignment

Open Sketch Up 2016


Template 3D printing: Millimeters

Start Using Sketch Up

View: Toolbars and mark Large Tool Set

  1. Choose the rectangle tool and begin to drag and pull from the corner (X,Y,Z 0 corner)

  2. Dimensions: type in 100,40 (which will make your rectangle 100mm long and 40mm wide)

  3. Use the zoom tool to enlarge the view of your rectangle and the pan tool to center your object as necessary

  4. Create a guideline using the measuring tape tool from the midpoint on the Y axis (green) in from the end 6mm on the X axis (red) at the 100mm end

  5. Use the circle tool to create a circle with 24 sides and a radius of 4mm centered on the guideline and midpoint

  6. Use the push/pull tool to pull the circle up to any height (this is where a string would be added to your bookmark).

  7. Use the cursor (arrow tool) to highlight the top of the circle blue and then use the eraser tool to delete the top of the circle. (This should make an empty circle on your bookmark)

  8. Use the orbit tool to check underneath your object that the circle has gone all the way through to the endpoint.

  9. Use the tape measure tool to set a guideline at the height of .5mm on the Z axis (blue)

  10. Use the push/pull tool to adjust the height of your bookmark to .5mm

  11. Use the 3D text tool to type your first name at a height of 18mm and 6mm (adjust as necessary to fit)

  12. Use the arrow tool to highlight the template box in blue. Once it is blue use the eraser tool to delete the template box before saving.

File: Save As: Bookmark (first initial last initial) period #group#

Ex. BookmarkLD61

File: Export STL

Make sure to save on your group flash drive as an STL file with the proper name

Ex. BookmarkLD61

**do not add extra characters or spaces**

  1. Wheels

Complete a 2D sketch on graph paper of the front and back wheel:

  • This is an actual size drawing

  • Give your sketch a title: 2D Wheel Designs Period _Group _

  • Label each of the following on the front and back wheel designs:

    • Each spoke is __________ degrees apart

    • Hub diameter _________mm

    • Hub width _________mm

    • Hub thickness ______mm

    • Wheel diameter _______ mm

    • Wheel width _______mm

    • Wheel thickness ______mm

Open Sketch Up 2016

Template 3D printing: Millimeters

Start Using Sketch Up

View: Toolbars and mark Large Tool Set

  1. Wheels cannot have a thickness greater than 10mm.

  2. Wheels must have a spoke design and cannot be solid.

  3. Create one front and one back wheel as separate files.

  4. Hub diameter should be 4mm

File: Save As: Wheels period #group# (front or back)

Ex. Wheels61back

File: Export STL

Make sure to save on your group flash drive as an STL file with the proper name

Ex. Wheels61back

**do not add extra characters or spaces**

  1. Vehicle Build Deadline ______________________________

  2. Vehicle Testing

  1. Question: Which group has designed and built the fastest solar vehicle?

  2. Variables:

    1. IV

    2. DV

    3. Controls:

  3. Hypothesis:



  1. Materials:



  1. Procedure:



  1. Data Table:



  1. Graph:




  1. Analysis

Claim

Evidence




  1. Conclusion


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