Difference between revisions of "PhET/C2/Energy-forms-and-changes/English-timed"
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|| 04:09 | || 04:09 | ||
− | || Next, drag and hold the slider of the heat regulator downwards to cool the water. | + | || Next, drag and hold the '''slider''' of the heat regulator downwards to cool the water. |
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|| 04:16 | || 04:16 | ||
− | || As the temperature decreases water freezes and becomes ice. | + | || As the temperature decreases, water freezes and becomes ice. |
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||04:26 | ||04:26 | ||
− | || Now drag the '''Iron''' block and place it on the first stand. | + | || Now, drag the '''Iron''' block and place it on the first stand. |
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|| 04:50 | || 04:50 | ||
− | || Drag and hold the slider of the heat regulator upwards to heat the '''Iron''' block. | + | || Drag and hold the '''slider''' of the heat regulator upwards to heat the '''Iron''' block. |
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|| 05:03 | || 05:03 | ||
− | || Here internal energy of '''Iron''' block increases. | + | || Here, internal energy of '''Iron''' block increases. |
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|| 05:39 | || 05:39 | ||
− | || This results in | + | || This results in decrease in the temperature of '''Iron''' Block. |
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|| 06:03 | || 06:03 | ||
− | || Now again place the '''Iron''' block on the heat regulator. | + | || Now, again place the '''Iron''' block on the heat regulator. |
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|| 07:05 | || 07:05 | ||
− | || As an assignment | + | || As an assignment: |
Heat '''Iron''' block and '''Brick''' block at the same time. | Heat '''Iron''' block and '''Brick''' block at the same time. | ||
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|| 07:31 | || 07:31 | ||
− | || This screen gives an idea about conservation of energy from everyday life. | + | || This '''screen''' gives an idea about conservation of energy from everyday life. |
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|| 07:38 | || 07:38 | ||
− | || Screen at the bottom has a set of- | + | || Screen at the bottom has a set of- energy sources, |
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|| 07:43 | || 07:43 | ||
− | || | + | || electrical energy generation systems and receivers. |
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|| 07:56 | || 07:56 | ||
− | || By default screen has a set up of- Faucet as energy source, | + | || By default, screen has a set up of- Faucet as energy source, |
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|| 08:02 | || 08:02 | ||
− | || | + | || turbine as electrical energy generation system and '''Water''' container with thermometer as a receiver. |
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|| 08:34 | || 08:34 | ||
− | || This mechanical energy turns the turbine which creates | + | || This mechanical energy turns the turbine which creates electrical energy. |
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|| 08:45 | || 08:45 | ||
− | || As the temperature increases water evaporates and | + | || As the temperature increases, water evaporates and vapors are observed. |
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|| 08:56 | || 08:56 | ||
− | || Here energy is conserved as total energy of the system remains constant. | + | || Here, energy is conserved as total energy of the system remains constant. |
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|| 09:14 | || 09:14 | ||
− | || Now instead of '''Water''' container, select incandescent bulb. | + | || Now, instead of '''Water''' container, select incandescent bulb. |
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|| 09:20 | || 09:20 | ||
− | || In this system, initially | + | || In this system, initially there is no cloud. |
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|| 09:24 | || 09:24 | ||
− | || Here the sun is the source of | + | || Here, the sun is the source of light energy. |
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|| 09:38 | || 09:38 | ||
− | || The incandescent bulb converts electrical energy into | + | || The incandescent bulb converts electrical energy into a lot of thermal energy and very little light energy. |
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|| 09:51 | || 09:51 | ||
− | || Next replace the incandescent bulb with the fluorescent bulb. | + | || Next, replace the incandescent bulb with the fluorescent bulb. |
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|| 10:00 | || 10:00 | ||
− | ||Notice that | + | ||Notice that the fluorescent bulb releases more Light energy and less thermal energy. |
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||10:24 | ||10:24 | ||
− | ||Due to the presence of clouds light energy does not reach the solar panel. | + | ||Due to the presence of clouds, light energy does not reach the solar panel. |
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|| 10:30 | || 10:30 | ||
− | || So generation of electrical energy stops. | + | || So, generation of electrical energy stops. |
|- | |- | ||
||10:34 | ||10:34 | ||
− | || As an assignment | + | || As an assignment: |
Select '''cycle-generator system'''. | Select '''cycle-generator system'''. | ||
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|| 11:02 | || 11:02 | ||
− | || In this tutorial we have demonstrated | + | || In this tutorial, we have demonstrated how to use '''Energy Forms and Changes''', '''PhET simulation'''. |
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|| 11:11 | || 11:11 | ||
− | || Using this '''simulation''' we have learnt | + | || Using this '''simulation''', we have learnt |
1. To conserve energy in real-life systems. | 1. To conserve energy in real-life systems. | ||
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|| Using this '''simulation''' we have, | || Using this '''simulation''' we have, | ||
− | + | 1. Predicted how energy flows when objects are heated or cooled. | |
|- | |- | ||
|| 11:35 | || 11:35 | ||
− | || | + | ||2. Designed energy systems. |
|- | |- | ||
|| 11:38 | || 11:38 | ||
− | || | + | ||3. Studied how energy changes from one form to another. |
|- | |- | ||
|| 11:43 | || 11:43 | ||
− | || The video at the following link summarizes the Spoken Tutorial project. | + | || The video at the following link summarizes the '''Spoken Tutorial''' project. |
Please download and watch it. | Please download and watch it. | ||
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|| 11:52 | || 11:52 | ||
− | || The Spoken Tutorial | + | || The '''Spoken Tutorial''' project team conducts workshops using spoken tutorials and |
− | + | gives certificates on passing online tests. | |
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||12:17 | ||12:17 | ||
− | || Spoken Tutorial Project is funded by NMEICT, MHRD, Government of India. | + | || Spoken Tutorial Project is funded by '''NMEICT, MHRD,''' Government of India. |
More information on this mission is available at this link. | More information on this mission is available at this link. |
Latest revision as of 20:34, 12 August 2018
Time | Narration |
00:01 | Welcome to this tutorial on Energy Forms and Changes simulation. |
00:07 | In this tutorial, we will demonstrate Energy Forms and Changes, PhET simulation. |
00:15 | Here I am using: Ubuntu Linux OS version 14.04, |
00:23 | Java version 1.7.0, |
00:27 | Firefox Web Browser version 53.02.2. |
00:33 | To follow this tutorial, learner should be familiar with topics in high-school physics. |
00:41 | Using this simulation, we will learn:
1. To conserve energy in real-life systems. |
00:50 | 2. To compare thermal conductivity of different objects. |
00:55 | 3. About different forms of energy. |
00:58 | Using this simulation, we will:
1. Predict how energy flows when objects are heated or cooled. |
01:07 | 2. Design energy systems. |
01:10 | 3. Study how energy changes from one form to another. |
01:15 | Energy is the capacity to do work on objects. |
01:20 | It is a scalar quantity. |
01:23 | In SI system, it is measured in joules. |
01:27 | Energy exists in nature in several forms such as- |
01:32 | mechanical energy, |
01:35 | electrical energy, |
01:38 | thermal energy, |
01:40 | Light energy and |
01:42 | chemical energy. |
01:45 | Use the given link to download the simulation. |
01:50 | I have already downloaded Energy Forms and Changes simulation to my Downloads folder. |
01:57 | To run the simulation, open the terminal. |
02:01 | At the prompt, type: cd Downloads and press Enter. |
02:08 | Then type: java space hyphen jar space energy hyphen forms hyphen and hyphen changes underscore en dot jar and press Enter. |
02:24 | Energy Forms and Changes simulation opens. |
02:28 | The simulation screen has 2 tabs at the top- Intro and Energy Systems. |
02:35 | By default, Intro screen opens. |
02:39 | Intro screen helps to predict how thermal energy flows when objects are heated or cooled. |
02:47 | Left side of the screen has a set of three thermometers. |
02:52 | Right side of the screen has Energy Symbols check-box. |
02:57 | Click on Energy Symbols check-box. |
03:01 | Energy chunks will appear in Iron block, Brick block and Water container. |
03:08 | Number of chunks is proportional to amount of energy in each of the objects. |
03:14 | In this set up, the energy transfer is in the form of thermal energy. |
03:19 | There are two heat regulators to heat or cool the system. |
03:24 | Heat regulators are provided with stands. |
03:28 | At the bottom of the screen, we have Normal and Fast Forward radio-buttons to control the speed of animation, |
03:37 | Play / Pause button,
Step button and Reset All button. |
03:42 | Drag the Water container onto the stand. |
03:46 | Drag and attach the thermometer to the container. |
03:50 | Now drag and hold the slider of the heat regulator upwards to heat the water. |
03:57 | As the temperature increases, water evaporates and vapors are observed. |
04:04 | Also, observe that energy chunks escape into the atmosphere. |
04:09 | Next, drag and hold the slider of the heat regulator downwards to cool the water. |
04:16 | As the temperature decreases, water freezes and becomes ice. |
04:22 | Drag and place the container on the workbench. |
04:26 | Now, drag the Iron block and place it on the first stand. |
04:31 | Drag and place the thermometer on the Iron block. |
04:35 | Move the Brick block and Water container to a side. |
04:40 | Before you start heating, note the number of energy chunks in the Iron block. |
04:46 | Observe the temperature on the thermometer. |
04:50 | Drag and hold the slider of the heat regulator upwards to heat the Iron block. |
04:56 | Observe that energy from heat is transferred to Iron block in the form of chunks. |
05:03 | Here, internal energy of Iron block increases. |
05:08 | This is due to the flow of heat from the heat source to Iron block. |
05:13 | Observe that some chunks from Iron block escape into the atmosphere. |
05:19 | This results in decrease in the temperature of Iron block. |
05:25 | Again heat the Iron block to maximum temperature. |
05:29 | Drag and place the heated Iron block in the Water container. |
05:34 | Energy chunks travel from hot Iron block into water. |
05:39 | This results in decrease in the temperature of Iron Block. |
05:44 | Water becomes hot and its temperature increases. |
05:49 | This heat transfer process continues till objects reach thermal equilibrium. |
05:55 | Let us choose Fast Forward option to make the process faster. |
06:03 | Now, again place the Iron block on the heat regulator. |
06:08 | Drag and hold the slider down to cool the Iron block. |
06:13 | Cool the Iron block until thermometer reaches its minimum temperature. |
06:19 | Again place the cooled Iron block in Water container. |
06:23 | Note the temperature changes and energy chunks transformation. |
06:29 | Now place both the blocks on to the stands. |
06:33 | Drag and place the thermometer on the Brick block. |
06:37 | Heat the blocks one by one until you will see maximum rise in temperatures. |
06:44 | Wait till thermal equilibrium is established. Observe the decrease in temperatures. |
06:53 | Observe that Iron block has more number of energy chunks than Brick block. |
06:59 | This indicates that Iron has more thermal conductivity than Brick. |
07:05 | As an assignment:
Heat Iron block and Brick block at the same time. |
07:13 | Place heated Iron block above the heated Brick block. And explain the observation. |
07:20 | Now we will move on to Energy Systems screen. |
07:24 | Click on Energy Systems tab. |
07:27 | Energy Systems screen opens. |
07:31 | This screen gives an idea about conservation of energy from everyday life. |
07:38 | Screen at the bottom has a set of- energy sources, |
07:43 | electrical energy generation systems and receivers. |
07:50 | Reset All button is available at the bottom right corner of the screen. |
07:56 | By default, screen has a set up of- Faucet as energy source, |
08:02 | turbine as electrical energy generation system and Water container with thermometer as a receiver. |
08:10 | Click on Energy Symbols check-box. |
08:14 | Forms of Energy panel will display. |
08:18 | Forms of Energy panel helps you to identify the various forms of energy. |
08:24 | Now drag the blue slider to turn on the faucet. |
08:28 | Notice that water flowing from faucet has mechanical energy. |
08:34 | This mechanical energy turns the turbine which creates electrical energy. |
08:40 | This energy causes the temperature of the water to increase. |
08:45 | As the temperature increases, water evaporates and vapors are observed. |
08:51 | It gives off more thermal energy into the atmosphere. |
08:56 | Here, energy is conserved as total energy of the system remains constant. |
09:02 | Let's set up another energy system. |
09:06 | Here we will select Sun as a energy source. |
09:11 | Replace the turbine with solar panel. |
09:14 | Now, instead of Water container, select incandescent bulb. |
09:20 | In this system, initially there is no cloud. |
09:24 | Here, the sun is the source of light energy. |
09:28 | This light energy is absorbed by the solar panel to create electrical energy. |
09:34 | This electrical energy causes the bulb to glow. |
09:38 | The incandescent bulb converts electrical energy into a lot of thermal energy and very little light energy. |
09:47 | This is because the filament gets heated up. |
09:51 | Next, replace the incandescent bulb with the fluorescent bulb. |
09:56 | Observe the energy output of fluorescent bulb. |
10:00 | Notice that the fluorescent bulb releases more Light energy and less thermal energy. |
10:07 | Therefore fluorescent bulb is more efficient. |
10:11 | Now let's see the effect of clouds on solar panel. |
10:15 | Drag the Clouds slider gradually from None to Lots. |
10:20 | As you drag the slider, clouds appear. |
10:24 | Due to the presence of clouds, light energy does not reach the solar panel. |
10:30 | So, generation of electrical energy stops. |
10:34 | As an assignment:
Select cycle-generator system. |
10:41 | Explain why the cyclist must be fed in order to continue to pedal. |
10:47 | Set up different systems and let it run for a while. |
10:52 | Observe the energy transformations in each system and tabulate your observations. |
10:59 | Let us summarize. |
11:02 | In this tutorial, we have demonstrated how to use Energy Forms and Changes, PhET simulation. |
11:11 | Using this simulation, we have learnt
1. To conserve energy in real-life systems. |
11:19 | 2. To compare thermal conductivity of different objects. |
11:24 | 3. About different forms of energy. |
11:27 | Using this simulation we have,
1. Predicted how energy flows when objects are heated or cooled. |
11:35 | 2. Designed energy systems. |
11:38 | 3. Studied how energy changes from one form to another. |
11:43 | The video at the following link summarizes the Spoken Tutorial project.
Please download and watch it. |
11:52 | The Spoken Tutorial project team conducts workshops using spoken tutorials and
gives certificates on passing online tests. |
12:01 | For more details, please write to us. |
12:05 | Please post your timed queries on this forum. |
12:09 | This project is partially funded by Pandit Madan Mohan Malaviya National Mission on Teachers and Teaching. |
12:17 | Spoken Tutorial Project is funded by NMEICT, MHRD, Government of India.
More information on this mission is available at this link. |
12:29 | This is Meenal Ghoderao from IIT-Bombay. Thank you for joining. |