Science - Grade 6 - Electricity
Science - Grade 6 - Electricity ajlill Mon, 01/19/2009 - 01:06Rationale
Why are you spending class time on this? Why would their futures be ruined if they didn't know this?
Unit Goals
This unit focuses on electricity and electrical devices. The big ideas in this strand is that many different forms of energy can be transformed in to electricity and that electricity can be transformed into many different form of energy; that it plays a significant role in society; and that we must reduce the impact on the environment. While teaching about the transformation of different energies to electricity, we will be emphasizing the differences between renewable and non- renewable energy sources, and the environmental and economic costs of these differences. For example, when teaching about coal, we will be talking about the effectes of mining, the carbon and other emissions when burning, and the toxic ash that's left over. When teaching about the transformation of electricity to other forms of energy, we will emphasize conservation, as well as examining the benefits that electricity brings to society and how to balance that against the cost to generate it. For example computers now use as much energy as transportation
The students will be using their skills of research and critical thinking to do basic cost-benefit analysis of generation technologies and to produce a reasonable and justifiable action plan to reduce electricity consumption. They will be using their inquiry skills to discover the principals of building simple circuits and how batteries work. Finally they will be using their technological design skills to build an renewable energy device.
Along with the big ideas mentioned above, the students will also gain a knowledge of the fundamental nature of electricity, how to build simple circuits, and the safety issues around dealing with electricity.
Expectations
Overall Expectations
- demonstrate an understanding of the principles of electrical energy and its transformation into and from other forms of energy.
Specific Expectations
- 1.1 assess the short- and long-term environmental effects of the different ways in which electricity is generated in Canada (e.g., hydro, thermal, nuclear, wind, solar), including the effect of each method on natural resources and living things in the environment
- 1.2 assess opportunities for reducing electricity consumption at home or at school that could affect the use of non-renewable resources in a positive way or reduce the impact of electricity generation on the environment
- 2.1 follow established safety procedures for working with electricity (e.g., ensure hands are completely dry when working with electricity; be aware of electrical hazards at home, at school, and in the community)
- 2.4 design, build, and test a device that produces electricity (e.g., a battery built from a lemon or potato; a wind turbine)
- 2.5 use technological problem-solving skills (see page 16) to design, build, and test a device that transforms electrical energy into another form of energy in order to perform a function (e.g., a device that makes a sound, that moves, that lights up)
- 2.6 use appropriate science and technology vocabulary, including current, battery, circuit, transform, static, electrostatic, and energy, in oral and written communication
2.7 use a variety of forms (e.g., oral, written, graphic, multimedia) to communicate with different audiences and for a variety of purposes (e.g., using scientific and technological conventions, create a labelled diagram showing the component parts of the device they created to transform electrical energy into another form of energy and perform a function) - 3.4 describe how various forms of energy can be transformed into electrical energy (e.g., batteries use chemical energy; hydroelectric plants use water power; nuclear generating stations use nuclear energy; wind turbines use wind power; solar panels use energy from the sun; wave power stations use energy from ocean waves)
- 3.5 identify ways in which electrical energy is transformed into other forms of energy (e.g., electrical energy is transformed into heat energy in a toaster, light and sound energy in a television, mechanical energy in a blender)
Settings
Students
The students will know how to design and build simple circuits from previous work in this strand.
Teacher
What you need to study up on before you can handle this unit. List teacher resources.
Classroom
What you need or would like in your classroom to do this lesson.
Community
Any community resources you need or could draw on to enhance the project.
Assessment
poster/interview, electromechanical device, STSE
Task Overview
- Introduction - what is electricity - safety - electrocute a pickle - Bill Nye, Electirc currnet (25 min), Static Electircuty (25 min) - kwl chart - three ways electricity is made: electromagnetic (generator), chemical (batteries), quantum mechanical (solar cells) - edible batteries
- How we generate electricity now - pros and cons
- Alternative electricity - wind, solar, fuel cell, etc. - pros and cons
- First task - poster on/interview with different generation technologies
- finish task + gallery walk + update kwl
- Major uses of electricity - big items for conservation
- Light incandescent, CFL, LED, how motors work, how motors can be used as generators
- Build electromechanical device - can use any energy source except hydro or commercial batteries (e.g. lemon battery, solar cell, wind turbine), can do anything - or have them design something that performs some task that currently uses hydro.
- finish task + presentations
- STSE
Accommodations
Level 4
What will your best students do when they finish early, or how you will keep them busy.
Level 1/IEP
What modifications will be applied to the assessment. Differentiated instruction will probably be listed on the individual task plans.
Circuits
Circuits ajlill Mon, 02/23/2009 - 21:20Overall Expectations
6s35 2. investigate the characteristics of static and current electricity, and construct simple circuits.
Specific Expectations
6s39 2.1 follow established safety procedures for working with electricity (e.g., ensure hands are completely dry when working with electricity; be aware of electrical hazards at home, at school, and in the community)
6s44 2.6 use appropriate science and technology vocabulary, including current, battery, circuit, transform, static, electrostatic, and energy, in oral and written communication
6s46 3.1 distinguish between current and static electricity
6s48 3.3 identify materials that are good conductors of electricity (e.g., copper, gold, silver, aluminum, water [when it has a high mineral content]) and good insulators (e.g., glass, plastic, rubber, ceramics)
6s51 3.6 explain the functions of the components of a simple electrical circuit (e.g., a battery is the power source; a length of wire is the conductor that carries the electrical current to the load; a light bulb or motor is the load)
6s52 3.7 describe series circuits (components connected in a daisy chain) and parallel circuits (components connected side by side like the rungs of a ladder), and identify where each is used (e.g., some strings of patio lights are in series circuits - when one light burns out, the whole string goes out; parallel circuits are used for wiring lighting and electrical outlets in your house - when one light burns out, the others keep burning)
Materials
A rig to safely demonstrate the hazzards of household current and electrocute a pickle.
Batteries, wires, lamps, 1.5V light bulbs with holders.
Important Terminology
Background Knowledge
Hook
Imagine your life without electricity. Remember the last blackout. For homework, have them keep a journal of all the electrical things they come in contact with.
Lesson Sequence
Explore - how a circuit works - give the students a battery, some wires and a lightbulb or motor. -
Explain - on what was needed to make the bulb glow. Why do you need the battery.
Elaborate -
Explore - what is a good conductor, insulator. - exend the circuit from above to allow you to put varous materiels in series with it. Predict what will happen, then experiment .
Explain - how did your circuit tester show which materiels conduct electricity. Which materiels conduct best, How do you know. How does your experiment results help you understand how electicty flows.
Elaborate - where would you use this, how is this related to safety - demostrate electicity flow through water, pickcle.
Explore - series and parallel circuits
Explain - where a series and parallel circuit would be used
Elaborate - design a circuit where a light can be switched on or off from two different switches.
water circuit as an analogy to electrical circuit - pressure = volts, flow = amps
watts
Key Questions
Leading questions given by you to the students and expected questions from the students
Assessment
Enrichment
Remediation
Implications for Future Lessons
Electricity Resources
Electricity Resources ajlill Mon, 01/19/2009 - 18:32Static Electricity
Static Electricity ajlill Mon, 02/23/2009 - 22:19Overall Expectations
6s35 2. investigate the characteristics of static and current electricity, and construct simple circuits.
Specific Expectations
6s39 2.1 follow established safety procedures for working with electricity (e.g., ensure hands are completely dry when working with electricity; be aware of electrical hazards at home, at school, and in the community)
6s41 2.3 use scientific inquiry/experimentation skills (see page 12) to investigate the characteristics of static electricity Sample guiding questions: Is static electricity really static? Explain. What causes static electricity? Is it easier to generate static electricity in a dry room or a humid room? Why? Which materials accept a charge better than others? Where would you find static electricity in action?
6s44 2.6 use appropriate science and technology vocabulary, including current, battery, circuit, transform, static, electrostatic, and energy, in oral and written communication
6s46 3.1 distinguish between current and static electricity
6s47 3.2 use the principles of static electricity to explain common electrostatic phenomena (e.g., the attraction of hairs to a comb that has been rubbed on a piece of wool; the attraction of small pieces of paper to a plastic ruler that has been rubbed with a rag; the attraction of pieces of clothing to each other when they come out of a clothes dryer)
Materials
Important Terminology
Background Knowledge
Hook
Lesson Sequence
jam jar electroscope
explore what material can build up a charge
balloons and sugar, little paper people
Key Questions
Leading questions given by you to the students and expected questions from the students
Assessment
Enrichment
Remediation
Implications for Future Lessons