Difference between revisions of "Sustainable Energy Vehicle Competition"

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= Overview =
= Overview =


While humans have been using renewable energy sources, such as sails to power boats, windmills to pump water, or water-driven wheels to power machinery that mills grains, for millennia, the environmental impact of burning fossil fuels, such as oil, natural gas, and coal, has prompted greater interest in and greater investment in renewable energy sources, including solar power, wind power, and hydroelectric power. But some renewable energy sources cannot generate power consistently, notably solar power and wind power, so there is equal interest in developing energy storage devices that can operate at grid-scale or hold sufficient energy to power entire communities for an extended time after being charged by a renewable energy source.
From sails to power boats, windmills to pump water, or water-driven wheels to power machinery that mills grains, humans have been using renewable energy sources for millennia. A significant amount of our energy production comes from non-renewable resources, such as oil, natural gas, and coal. The environmental and health impacts of burning fossil fuels have prompted greater interest and investment in renewable energy sources, including solar, wind, and hydroelectric power though hydroelectric power is not considered in this lab. Scientists and engineers must address concerns about the inability of some renewable sources, notably solar power and wind power, to generate power consistently so there is equal interest in developing energy storage devices that can operate at grid-scale or hold sufficient energy to power entire communities for an extended time after being charged by a renewable energy source.


== Types of Renewable Energy ==
== Types of Renewable Energy ==
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=== Solar Power ===
=== Solar Power ===


Sunlight, like any other type of electromagnetic radiation, contains energy. Typically, when sunlight hits an object, the energy that it contains is converted into heat. Certain materials can convert the energy into an electrical current. In this form, it can be used as a power source and it can be stored as energy.
Sunlight, like any other type of electromagnetic radiation, contains energy. Typically, when sunlight hits an object, the energy that it contains is converted into heat. Certain materials can absorb and convert that energy into an electrical current. In this form, sunlight can be used as a power source or stored for later use.


In a crystal structure, the materials used for <b>solar panels</b> contain covalent bonds where electrons are shared by the atoms within the crystal. When the light is absorbed, electrons within the crystal become excited and move to a higher energy level. When this occurs, the electron has more freedom of movement within the crystal. When the electrons move around the crystal structure an electrical current is generated. The reaction that occurs when sunlight hits a solar panel is shown in Figure 1 (Locke, 2008).
<b>Solar panels</b> are devices that generate electrical current from sunlight. The panels contain a crystalline material that absorbs and converts the sunlight into electricity. The crystalline material has a repeating structure formed by a network of covalent bonds where electrons are shared by atoms within the crystal. Traditional solar cells are made from crystalline silicon.
 
To produce a current, there must be a difference in the concentration of electrons between one area and another to cause their flow. In a silicon solar cell, a concentration difference is created using two types of silicon, <b>p-type</b> and <b>n-type</b>. The p-type silicon is created by adding atoms, such as boron, that have one less electron in their valence energy level than silicon has. As a result, a vacancy of electrons, or a hole, forms. The n-type silicon is created by adding atoms that have one more electron in their valence energy level than silicon has so that there is an excess of electrons that can move around the crystal structure and create an electrical current. In a solar cell, p-type and n-type silicon are sandwiched together to create a <b>p-n junction</b>, as shown in Figure 1 (Locke, 2008). The p-type area is positively charged,  and the n-type area is negatively charged.
 
When sunlight hits the silicon on the solar panel, the photons from the sunlight energize the electrons in the material. The electrons within the crystal move to a higher energy level, creating holes. If the p-type and n-type silicon are connected with a wire, the electrons will flow from the n-type layer to the p-type layer, and electrical current is generated.


[[Image:Lab_renewener_01.png|thumb|500px|center|Figure 1: A Silicon Solar Panel Showing the Electron Flow]]
[[Image:Lab_renewener_01.png|thumb|500px|center|Figure 1: A Silicon Solar Panel Showing the Electron Flow]]


Older solar panels use large crystalline structures made from silicon. When sunlight hits the silicon on the solar panel, the photons from the sunlight energize the electrons in the material. These energized electrons create a higher electrical potential in the material that is measured as a voltage between that material and ground.
Other materials have been used in the production of solar panels. Panels made from copper indium gallium (di)selenide (CIGS) have a smaller crystalline structure and are less expensive than silicon. CIGS panels are relatively flexible and can easily be shaped into flexible films. The use of CIGS to make solar panels is referred to as thin-film solar technology because of its flexible nature. CIGS panels are not as good at converting absorbed light into electrical current compared to silicon, but for mass production purposes, CIGS solar panels are the more cost effective approach to produce solar panels for frequent use (Locke, 2008). In the last decade, perovskite materials have also received attention for thin film technologies because of their competitive efficiency (Dey et al., 2021).
 
The material copper indium gallium (di)selenide (CIGS) is also used in the production of solar panels. Panels made from CIGS have a smaller crystalline structure and are less expensive than their silicon counterparts. CIGS panels are relatively flexible and can easily be shaped into flexible films. The use of CIGS to make solar panels is referred to as thin-film solar technology because of its flexible nature. CIGS panels are not as good at converting absorbed light into electrical current compared to silicon. But for mass production purposes, CIGS solar panels are the more cost effective approach to produce solar panels for frequent use (Locke, 2008).


=== Wind Energy ===
=== Wind Energy ===


<b>Wind turbines</b> are used to capture the wind’s energy and convert it into electrical energy. The blades on wind turbines are slanted so that as the wind passes over the blades it creates an uneven pressure on each side, causing them to rotate. The spinning blades drive a low speed shaft connected to a gearbox. The gearbox within the wind turbine converts the low speed rotation to a high speed rotation through a high speed shaft. The high speed shaft is connected to a brake and then into an electrical generator where mechanical energy is converted to electrical energy (Layton, 2011).
<b>Wind turbines</b> are used to capture the wind’s energy and convert it into electrical energy. The blades on wind turbines are slanted so that as the wind passes over the blades, it creates an uneven pressure on each side, causing them to rotate. The spinning blades drive a low speed shaft connected to a gearbox. The gearbox converts the low speed rotation to a high speed rotation through a high speed shaft. The high speed shaft is connected to a brake and then into an electrical generator where mechanical energy is converted to electrical energy (Layton, 2011).


A basic electrical generator is made of permanent magnets on each side with a rectangular coil connected to a commutator, which is a rotary electrical switch (Figure 2). The two permanent magnets on each side create a magnetic field. As the rectangular coil spins mechanically, the magnetic field through the area of the coil changes, creating an alternating current through the coil. The commutator switches the polarity of the coil just as the polarity of the alternating current changes, creating a direct current. The current is then output from the wind turbine (Layton, 2011).
A basic electrical generator is made of permanent magnets on each side with a rectangular coil connected to a commutator, which is a rotary electrical switch (Figure 2). The two permanent magnets on each side create a magnetic field. As the rectangular coil spins mechanically, the magnetic field through the area of the coil changes, creating an alternating current through the coil. The commutator switches the polarity of the coil just as the polarity of the alternating current changes, creating a direct current. The current is then output from the wind turbine (Layton, 2011).
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== Energy Storage ==
== Energy Storage ==


<b>Capacitors</b> have many uses in circuits and signal processing. In this lab, a capacitor can be used as the power source for the renewable energy vehicle. Fundamentally, a capacitor is an electrical device that is used to store charge temporarily. Some capacitors can be used in place of a battery, but they operate very differently from a battery. A capacitor is charged by a voltage source logarithmically, as shown in Figure 3.
<b>Capacitors</b> have many uses in circuits and signal processing. A capacitor is an electrical device that is used to store charge temporarily. Some capacitors can be used in place of a battery, but they operate very differently from a battery. A capacitor is charged by a voltage source logarithmically, as shown in Figure 3. In this lab, a capacitor will be used as the power source for the renewable energy vehicle.  
   
   
[[Image:Lab_renewener_06.png|thumb|500px|center|Figure 3: Capacitor Charging Curve]]
[[Image:Lab_renewener_06.png|thumb|500px|center|Figure 3: Capacitor Charging Curve]]


Because of their design, these capacitors are sensitive to the polarity of the voltage applied to them. The capacitors used in this lab must be connected with the proper polarity. In the lab, the capacitor’s negative lead must be connected to the negative applied voltage (Figure 4). Failure to do this will cause the capacitor to fail.
Because of their design, capacitors are sensitive to the polarity of the voltage applied to them. The capacitors used in this lab must be connected with the proper polarity. In the lab, the capacitor’s negative lead must be connected to the negative applied voltage (Figure 4). Failure to do this will cause the capacitor to fail.
   
   
[[Image:Lab_renewener_07.png|thumb|500px|center|Figure 4: Polarized Capacitor]]
[[Image:Lab_renewener_07.png|thumb|500px|center|Figure 4: Polarized Capacitor]]
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<p style="text-align:right">(1)</p>
<p style="text-align:right">(1)</p>


In (1), E is the energy, C is the capacitance, and V is the voltage. The capacitance value of a capacitor is measured in farads (F) and energy is measured in joules (J).
In (1), E is the energy, C is the capacitance, and V is the voltage.  


== Electrical Components ==
== Electrical Components ==
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[[Image:Capacitor Symbol.png|center|thumb|79px|Figure 5B: Symbol for Capacitor]]
[[Image:Capacitor Symbol.png|center|thumb|79px|Figure 5B: Symbol for Capacitor]]
[[Image:DC Source.png|center|center|thumb|79px|Figure 5C: Symbol for DC Source]]
[[Image:DC Source.png|center|center|thumb|79px|Figure 5C: Symbol for DC Source]]
<!--<b>Diodes</b> and <b>light emitting diodes (LEDs)</b> were introduced in the Prototyping with Microcontrollers, Sensors, and Materials lab. A diode has polarity and will only allow current to pass from its positive lead to its negative lead. A light emitting diode (LED) not only passes current, but also lights up when it is passing current. LEDs have a forward voltage and a reverse voltage. In the forward direction, the forward voltage and resistance are low and determined by the material used in the LED. The reverse voltage has a much higher resistance and a higher reverse voltage that prevents the flow of electrical current. The characteristic of the diode is to have low resistance to electrical flow in the forward direction and high resistance in the reverse direction. This provides the ability to control the flow of electricity in one direction only.
There is a threshold voltage in the forward direction for the LED to emit light. Below the threshold voltage, there is no light. At and above the threshold voltage, the LED emits light with intensity roughly linear with the forward voltage magnitude. The symbol for an LED is shown in Figure 6.


[[Image:Symbol_LED.png|thumb|center|150px|Figure 6: Symbol for LED]]-->
Different arrangements of electrical components allow engineers to design different devices. Components, such as resistors, inductors, and capacitors, can be arranged in two different ways. In a <b>series circuit</b>, the element's components are connected end to end. The current in a series circuit remains the same in all the electrical elements. In a series circuit, as shown in Figure 6, the sum of the voltages across each element is equal to the voltage of the power source (2).
Different arrangements of electrical components allow engineers to design different devices. Components, such as resistors, inductors, and capacitors, can be arranged in two different ways. In a <b>series circuit</b>, the element's components are connected end to end. The current in a series circuit remains the same in all the electrical elements. In a series circuit, as shown in Figure 6, the sum of the voltages across each element is equal to the voltage of the power source (2).


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In (4), P is the power in Watts, I is the current in Amperes, and V is the voltage in Volts.
In (4), P is the power in Watts, I is the current in Amperes, and V is the voltage in Volts.


<!--The <b>motor</b> provided in the lab is a 9V motor that will operate with voltages lower than 9V with reduced torque and speed (Figure 10). A motor with no load draws 9 mA, and a stalled motor draws well over 350 mA. Increasing the voltage provided to the motor increases the speed. Increasing the current increases the torque.
The <b>motor</b> provided in the lab is a 9V motor that will operate with voltages lower than 9V with reduced torque and speed (Figure 10). A motor with no load draws 9 mA, and a stalled motor draws well over 350 mA. Increasing the voltage provided to the motor increases the speed. Increasing the current increases the torque.


[[Image:LEGO 9V Motor.jpg|thumb|200px|center|Figure 10: LEGO 9V Motor]]-->
[[Image:LEGO 9V Motor.jpg|thumb|200px|center|Figure 10: LEGO 9V Motor]]
<!--
== VEX Robotics ==
== VEX Robotics ==
Vex Robotics is used globally for students to understand the fundamentals of robotics. It is commonly used to model the capabilities of vehicles.
Vex Robotics is used globally for students to understand the fundamentals of robotics. It is commonly used to model the capabilities of vehicles.
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Here's a video tutorial on how to  use the align tool:
Here's a video tutorial on how to  use the align tool:
[https://drive.google.com/file/d/1APz_kDAN3bZ4s7QPy4O5GOm3jZdfOs4G/view?usp=sharing Align tool tutorial]
[https://drive.google.com/file/d/1APz_kDAN3bZ4s7QPy4O5GOm3jZdfOs4G/view?usp=sharing Align tool tutorial]
Download the video is it does not play in the browser.
Download the video is it does not play in the browser.--!>


= Design Considerations =
= Design Considerations =

Revision as of 14:55, 21 October 2021

Objective

The experimental objective of this lab is to evaluate different sources of renewable energy and use the results of that evaluation to design a vehicle that is powered by a renewable energy source or a capacitor that is charged by a renewable energy source. The design will be entered in a competition that is judged by a ratio that uses distance traveled, travel time, and cost. The highest ratio wins.

Overview

From sails to power boats, windmills to pump water, or water-driven wheels to power machinery that mills grains, humans have been using renewable energy sources for millennia. A significant amount of our energy production comes from non-renewable resources, such as oil, natural gas, and coal. The environmental and health impacts of burning fossil fuels have prompted greater interest and investment in renewable energy sources, including solar, wind, and hydroelectric power though hydroelectric power is not considered in this lab. Scientists and engineers must address concerns about the inability of some renewable sources, notably solar power and wind power, to generate power consistently so there is equal interest in developing energy storage devices that can operate at grid-scale or hold sufficient energy to power entire communities for an extended time after being charged by a renewable energy source.

Types of Renewable Energy

Renewable energy is a type of energy that can be harnessed from naturally replenished resources. Some examples of this are sunlight, wind, and water. There are many benefits of using renewable energy. They are clean energy sources, and they come from an abundant source that do not become depleted. If these renewable resources can be harnessed efficiently, they can solve the problems with using non-renewable energy sources, such as fossil fuels (NextEra Energy Resources, 2012).

Solar Power

Sunlight, like any other type of electromagnetic radiation, contains energy. Typically, when sunlight hits an object, the energy that it contains is converted into heat. Certain materials can absorb and convert that energy into an electrical current. In this form, sunlight can be used as a power source or stored for later use.

Solar panels are devices that generate electrical current from sunlight. The panels contain a crystalline material that absorbs and converts the sunlight into electricity. The crystalline material has a repeating structure formed by a network of covalent bonds where electrons are shared by atoms within the crystal. Traditional solar cells are made from crystalline silicon.

To produce a current, there must be a difference in the concentration of electrons between one area and another to cause their flow. In a silicon solar cell, a concentration difference is created using two types of silicon, p-type and n-type. The p-type silicon is created by adding atoms, such as boron, that have one less electron in their valence energy level than silicon has. As a result, a vacancy of electrons, or a hole, forms. The n-type silicon is created by adding atoms that have one more electron in their valence energy level than silicon has so that there is an excess of electrons that can move around the crystal structure and create an electrical current. In a solar cell, p-type and n-type silicon are sandwiched together to create a p-n junction, as shown in Figure 1 (Locke, 2008). The p-type area is positively charged, and the n-type area is negatively charged.

When sunlight hits the silicon on the solar panel, the photons from the sunlight energize the electrons in the material. The electrons within the crystal move to a higher energy level, creating holes. If the p-type and n-type silicon are connected with a wire, the electrons will flow from the n-type layer to the p-type layer, and electrical current is generated.

Figure 1: A Silicon Solar Panel Showing the Electron Flow

Other materials have been used in the production of solar panels. Panels made from copper indium gallium (di)selenide (CIGS) have a smaller crystalline structure and are less expensive than silicon. CIGS panels are relatively flexible and can easily be shaped into flexible films. The use of CIGS to make solar panels is referred to as thin-film solar technology because of its flexible nature. CIGS panels are not as good at converting absorbed light into electrical current compared to silicon, but for mass production purposes, CIGS solar panels are the more cost effective approach to produce solar panels for frequent use (Locke, 2008). In the last decade, perovskite materials have also received attention for thin film technologies because of their competitive efficiency (Dey et al., 2021).

Wind Energy

Wind turbines are used to capture the wind’s energy and convert it into electrical energy. The blades on wind turbines are slanted so that as the wind passes over the blades, it creates an uneven pressure on each side, causing them to rotate. The spinning blades drive a low speed shaft connected to a gearbox. The gearbox converts the low speed rotation to a high speed rotation through a high speed shaft. The high speed shaft is connected to a brake and then into an electrical generator where mechanical energy is converted to electrical energy (Layton, 2011).

A basic electrical generator is made of permanent magnets on each side with a rectangular coil connected to a commutator, which is a rotary electrical switch (Figure 2). The two permanent magnets on each side create a magnetic field. As the rectangular coil spins mechanically, the magnetic field through the area of the coil changes, creating an alternating current through the coil. The commutator switches the polarity of the coil just as the polarity of the alternating current changes, creating a direct current. The current is then output from the wind turbine (Layton, 2011).

Figure 2: The Internal Structure of an Electrical Generator (Layton, 2011)

Energy Storage

Capacitors have many uses in circuits and signal processing. A capacitor is an electrical device that is used to store charge temporarily. Some capacitors can be used in place of a battery, but they operate very differently from a battery. A capacitor is charged by a voltage source logarithmically, as shown in Figure 3. In this lab, a capacitor will be used as the power source for the renewable energy vehicle.

Figure 3: Capacitor Charging Curve

Because of their design, capacitors are sensitive to the polarity of the voltage applied to them. The capacitors used in this lab must be connected with the proper polarity. In the lab, the capacitor’s negative lead must be connected to the negative applied voltage (Figure 4). Failure to do this will cause the capacitor to fail.

Figure 4: Polarized Capacitor

The energy a capacitor holds is proportional to the square of the voltage across the capacitor (1).

(1)

In (1), E is the energy, C is the capacitance, and V is the voltage.

Electrical Components

The design of a circuit determines its behavior. In this lab, one circuit design will increase the speed output of a motor and the other will increase the torque output of a motor. In electrical engineering, different electrical components are represented by different symbols. Figures 5A, 5B, and 5C show the symbols for a battery, capacitor, and DC source, respectively. They are all forms of energy storage devices.

Figure 5A: Symbol for Battery
Figure 5B: Symbol for Capacitor
Figure 5C: Symbol for DC Source

Different arrangements of electrical components allow engineers to design different devices. Components, such as resistors, inductors, and capacitors, can be arranged in two different ways. In a series circuit, the element's components are connected end to end. The current in a series circuit remains the same in all the electrical elements. In a series circuit, as shown in Figure 6, the sum of the voltages across each element is equal to the voltage of the power source (2).

(2)

In (2), Vout is the voltage output and VA, VB, and VC represent the voltage of the individual components.

Figure 6: A Series Circuit

In a parallel circuit, as shown in Figure 7, the element's components are connected at opposing ends. The current that is supplied by the voltage source equals the current that flows though elements D and E. The voltage across the elements that are parallel is the same (3).

(3)

In (3), Vout is the voltage output and VD and VE represent the voltage of the individual components.

Figure 7: A Parallel Circuit

A digital multimeter will be used in this lab to read the current and voltage across components in circuits. Multimeters usually have two leads that directly touch two nodes in a circuit or the leads of an electrical component. Please read the Digital Multimeter Guidelines before performing this lab in order to understand how to properly operate a digital multimeter. Digital multimeters are indicated by different symbols in electrical circuits, depending on the value being measured by the multimeter. When measuring voltage, the multimeter is referred to as a voltmeter (Figure 8A). When measuring current, the multimeter is referred to as an ammeter (Figure 8B).

Figure 8A: Symbol for Voltmeter
Figure 8B: Symbol for Ammeter

Depending on whether voltage or current is being measured in a circuit, the multimeter will be arranged in the circuit in a different manner. To measure the voltage across an electrical component, the multimeter must be placed in the circuit in parallel (Figure 9A). To measure the current across an electrical component, the multimeter must be placed in the circuit in series (Figure 9B).

Figure 9A: Multimeter in Parallel
Figure 9B: Multimeter in Series

After measuring the voltage and current across a component in a circuit, the electrical power output of that component can be calculated using the Power Law (4).

(4)

In (4), P is the power in Watts, I is the current in Amperes, and V is the voltage in Volts.

The motor provided in the lab is a 9V motor that will operate with voltages lower than 9V with reduced torque and speed (Figure 10). A motor with no load draws 9 mA, and a stalled motor draws well over 350 mA. Increasing the voltage provided to the motor increases the speed. Increasing the current increases the torque.

Figure 10: LEGO 9V Motor
  • Horizon wind-turbine
  • Sunforce 50013 1 W solar battery charger
  • Adjustable table fan
  • Heat lamp
  • 3V power supply
  • Digital multimeter
  • Music voltmeter
  • 9V DC motor
  • 1 F 5.5V capacitor
  • 3 alligator clip sets
  • Virtual VEX Kit

Procedure

This lab is divided into 4 sections:

  • The testing of the power storage device
  • The investigation of renewable energy sources
  • The fabrication of a sustainable energy vehicle
  • The data analysis of the United States’ renewable energy consumption

The power storage device and power sources will be tested individually. The results of the tests will be used in determining the best power source which will be chosen to design the sustainable energy vehicle.

Note for Hybrid Session

In-person students are expected to complete the physical circuits for Part 1 and Part 2, indicated by the label (In-Person). Remote students are expected to complete a similar circuit diagram via Tinkercad for Part 1 and Part 2 of the procedure. In-depth instructions on the Tinkercad circuits are provided under the physical procedures with the label (Remote). Any procedure labeled (Hybrid) is expected to be completed through a joint collaboration between remote and in-person students.

In order to create new circuits or copy an existing template of a circuit in Tinkercad, follow the steps below:

  • Go to tinkercad.com and sign in with an Autodesk account.
  • To start a new circuit, on the left side of the home screen select Circuit > Create new circuit.
  • If a template link is provided in the procedure:
    • Open the Tinkercad link for the part of the lab you want to work on. The links are provided in the procedure below.
    • Select the Copy & Tinker option. This will copy the template to the workspace so it can be edited.

1. Testing the Power Storage Device

Charging a Capacitor (In-Person)

  1. The circuit in Figure 16 will be created to charge a capacitor. Connect an alligator clip to each of the cables coming out of the 3V power supply. Red is the positive terminal and black is the negative terminal.
  2. Connect one of the unconnected alligator clips to one of the leads of the ammeter (the multimeter set to measuring current).
  3. Connect the rest of the unconnected cables (one from the ammeter and one alligator clip) in series to the leads of the capacitor with the polarity indicated in Figure 16.
  4. Charge the capacitor until the current in the circuit is zero.
  5. Discharge the charged capacitor by connecting it to the music voltmeter. The capacitor is discharging when the music voltmeter audibly plays a song.
Figure 16: Circuit to Charge a Capacitor

Charging a Capacitor (Remote)

  1. Open a new Tinkercad circuit. Refer to the starting the new Tinkercad circuit procedure given above.
  2. The circuit to charge a capacitor will be made in this part of the lab. The circuit is shown in Figure 17.
  3. Click and drag a 9V battery, 1 Farad capacitor, and multimeter on the interface as shown in Figure 17
  4. Wire the negative end of the 9V battery to the negative end of the multimeter. To wire these two components, simply click on the negative terminal of the battery, and click once again on the negative terminal of the multimeter. Red is the positive terminal and black is the negative terminal.
  5. Similarly, wire the positive end of the multimeter to terminal 1 on the capacitor. Wire terminal 2 on the capacitor to the positive terminal of the battery.
  6. To charge the capacitor click Start Simulation. Charge the capacitor until the current in the circuit is zero ampere (0A).
  7. Click on Stop Simulation once the multimeter reading is zero ampere (0A).
  8. Take a screenshot of your circuit.
Figure 17: Tinkercad Circuit to Charge a Capacitor

2. Testing the Power Sources

Four sources of energy will be analyzed in this part of the procedure: a wind turbine, a solar panel, a lemon battery, and a potato battery. The in-person students are responsible for building a circuit for and analyzing either the wind turbine or the solar panel, as determined by the TA. The remote students are responsible for building a circuit for and analyzing both the lemon and potato battery via Tinkercad. All voltage and current must be measured and recorded, and power must be calculated. Remote and in-person students (from the same group) will compare the data collected. Based on the results recorded, each group will choose a suitable power source from all four options.

Wind Turbine (In-Person)

  1. Connect the wind turbine to the music voltmeter using the alligator clips. Measure the voltage and current across the music voltmeter using the digital multimeter. The connections for measuring voltage and current across the music voltmeter are shown in Figures 9A and 9B.
  2. Adjust the position of the turbine blades against the wind to find the highest voltage and current that can be generated.
  3. Calculate and record the power generated by the turbine and give the information to a TA.

Solar Panel (In-Person)

  1. Connect the solar panel to the music voltmeter using the alligator clips. Place the solar panel near the heat lamp and measure the voltage and current across the music voltmeter using the digital multimeter.
  2. Adjust the position of the solar panel to find the highest voltage and current that can be generated.
  3. Calculate and record the power generated by the solar panel and give the information to a TA.

Lemon Battery (Remote)

  1. Click and drag two lemon batteries and a multimeter on the interface. If the lemon battery is not visible in the components menu on the right, click on Components > All.
  2. Create a circuit using two lemon batteries. Wire the multimeter to be in series with the circuit.
  3. Click on Start Simulation and record the final current produced by the circuit in series.
  4. Create a circuit using two lemon batteries. Wire a multimeter in parallel to the circuit. In order to create the circuit, diodes are required to connect more than two wires.
  5. Click on Start Simulation and record the final voltage produced by the circuit in parallel.
  6. Make sure to wire the positive terminal of the lemon battery with the positive terminal of the multimeter and the negative terminal of the lemon battery to the negative terminal of the multimeter.
  7. Take a screenshot of both the circuits with the voltage and current reading.
  8. Calculate and record the power generated by the solar panel and give the information to a TA.
  9. If you finished both the lemon battery circuit and the potato battery circuit before the in-person students finished their circuit, move on to Part 3 of the procedure in order to familiarize yourself with the given VEX parts and the align tool. Once the in-person students finished their circuit, everyone in the group should collaborate to complete the Data Analysis portion of Part 2.

Potato Battery (Remote)

  1. Click and drag two potato batteries and a multimeter on the interface. If the potato battery is not visible in the components menu on the right, click on Components > All.
  2. Create a circuit using two potato batteries. Wire the multimeter to be in series with the circuit.
  3. Click on Start Simulation and record the final current produced by the circuit in series.
  4. Create a circuit using two potato batteries. Wire a multimeter in parallel to the circuit. In order to create the circuit, diodes are required in order to connect more than two wires.
  5. Click on Start Simulation and record the final voltage produced by the circuit in parallel.
  6. Make sure to wire the positive terminal of the potato battery with the positive terminal of the multimeter and the negative terminal of the potato battery to the negative terminal of the multimeter.
  7. Take a screenshot of both the circuits with the voltage and current reading.
  8. Calculate and record the power generated by the solar panel and give the information to a TA.

If you finished both the lemon battery circuit and the potato battery circuit before the in-person students finished their circuit, move on to Part 3 of the procedure in order to familiarize yourself with the given VEX parts and the align tool. Once the in-person students finished their circuit, everyone in the group should collaborate to complete the Data Analysis portion of Part 2.

Data Analysis (Hybrid)

  1. Share and explain the circuits built and the data collected for the wind turbine, solar panel, lemon battery, and potato battery to your group.
  2. Based on the calculated power of each renewable energy source, determine the best power source in order to theoretically power a sustainable energy vehicle. Remote and in-person students have the option of choosing from all four options (solar panel, wind turbine, potato battery and lemon battery) regardless of the specific power source that they tested.
  3. With the chosen power source, create a circuit that would charge the capacitor. Use a multimeter to confirm that the capacitor is charged. The circuit should be made in person if the chosen power source is a wind turbine or a solar panel and should be made in Tinkercad if the chosen power source is a lemon or a potato battery.

Caution! The heat lamps and solar panels may become extremely hot when used for a long duration of time. Do not touch them immediately after use and turn them off when not in use.

3. Sustainable Energy Vehicle (Hybrid)

In this part, a simple vehicle will be designed and assembled in Fusion 360. This vehicle will utilize one motor that is powered by the capacitors in the previous steps.

Importing VEX Robotics Parts

  1. The VEX parts for the vehicle can be found in a ZIP folder here. The latest version of Fusion 360 must be downloaded for the parts to appear properly.
  2. Unzip the parts to a space on the computer.
  3. In Fusion 360, open the Data Panel (icon with 9 boxes at the top left) and click Upload (Figure 18). Select the unzipped part files to upload them to Fusion 360’s cloud memory. Fusion 360 can only import files uploaded to its cloud.
Figure 18: Data Panel

Design the Vehicle

Review the parts that are available. Consider the following restraints while designing your car:

  • A maximum of two motors are allowed.
  • The design must be able to hold the capacitors on top of it.
  • Modify the design to have a location to store the power storage device.
  • The motor must be connected to a minimum of two wheels.

Do not worry about inserting nuts and bolts. Primarily focus on the general shape of the design with shafts, wheels, and the structural components.

Assemble the Parts

  1. Ensure that the Design workspace is open in Fusion 360. This is indicated at the top left.
  2. The VEX part files can be inserted into a new Fusion 360 file by simply dragging and dropping them from the Data Panel into the space. Alternatively, right click the components and select Insert into Current Design. Save the blank file before assembling the vehicle by going to File > Save as.
  3. Import the other parts based on the design that was sketched. Connect all the parts using the Align tool to complete the model. Use the tips from the Fusion 360 section in the Overview and watch the short tutorial on the Align Tool for instructions to properly connect the components of the vehicle in Fusion 360.
  4. Take screenshots of the designed vehicle in Fusion 360 and send it to the lab TA.

Extra Credit

To receive extra credit, create two wires using the sweep tool that connects the capacitor to a motor. Use Google, online Fusion 360 forums, and Youtube tutorials to complete this. To receive extra credit, the entire vehicle design with the sweeped wires must be completed before the end of lab and also must be included in the team presentation.

Assignment

Individual Lab Report

This lab report is optional and you will receive extra credit for submitting it. Follow the lab report guidelines laid out in the EG1004 Writing Style Guide in the Technical Writing section of the manual. Use the outline below to write this report.

  • Define renewable energy
  • Explain how solar panels and wind turbines work
  • Explain the concept of the capacitor
  • Discuss the advantages and disadvantages of all four energy sources
  • Describe the renewable energy vehicle design and explain the choices made in the design
  • Discuss the power sources and their power output. How did the voltage measurements of the power sources impact the design?
  • Discuss whether one or two motors were used in design and why
  • Specify the power source chosen for the design
  • Discuss your design. Why did you choose the chassis or wheels? How did you factor in the constraints of the vehicle?
  • Discuss how the design compared to the other designs
  • Include screenshots of the lemon and potato battery circuits and pictures of the wind turbine or solar panel circuit
  • Discuss what part of the lab you completed for your group and why it was important to the overall experiment.


Remember: Lab notes must be taken. Experimental details are easily forgotten unless written down. EG1004 Lab Notes paper can be downloaded and printed from the EG1004 Website. Use the lab notes to write the Procedure section of the lab report. At the end of each lab, a TA will scan the lab notes and upload them to the Lab Documents section of the EG1004 Website. One point of extra credit is awarded if the lab notes are attached at the end of the lab report. Keeping careful notes is an essential component of all scientific practice.

Team PowerPoint Presentation

Follow the presentation guidelines laid out in the EG1004 Lab Presentation Format in the Technical Presentations section of the manual. When preparing the presentation, consider the following points.

  • Discuss why you chose your renewable energy source
  • Discuss the power sources and their power output. How did the voltage measurements of the power sources impact the design?
  • Discuss your design. Why did you choose the chassis or wheels? How did you factor in the constraints of the vehicle?
  • How would the renewable energy vehicle be improved?

References

Layton, J.. "How Wind Power Works." How stuff works. Discovery, 2011. Retrieved 24 July 2012. <http://science.howstuffworks.com/environmental/green-science/wind-power.htm>.

Locke, S.. "How Does Solar Power Work." Scientific American. Scientific American, 2008. Retrieved 24 July 2012. <http://www.scientificamerican.com/article.cfm?id=how-does-solar-power-work>.

NextEra Energy Resources, LLC. "Benefits of Renewable Energy." NextEra Energy Resources. NextEra Energy Resources, 2012. Retrieved 24 July 2012. <http://www.nexteraenergyresources.com/content/environment/benefits.shtml>.

Perlman, Howard.. "Hydroelectric Power: How it Works." U.S. Geological Survey, 2016. Retrieved 4 Jan 2018. <https://water.usgs.gov/edu/hyhowworks.html>.

Reg Tyler, . "Types of Fuel Cells." Energy efficiency and renewable energy. U.S. Department of Energy, 2011. Retrieved 24 July 2012. <http://www1.eere.energy.gov/hydrogenandfuelcells/fuelcells/fc_types.html>.