Difference between revisions of "Apps-On-Physics/C2/Simple-Machines/English"
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|- | |- | ||
||Point to '''Pulley system App'''. | ||Point to '''Pulley system App'''. | ||
| − | ||To open Pulley system app press Ctrl+F keys simultaneously. | + | ||To open the Pulley system app press Ctrl+F keys simultaneously. |
| − | In the search bar type Pulley system. | + | In the search bar type Pulley system. |
|- | |- | ||
||Right click on '''pulleysystem_en.htm''' file. | ||Right click on '''pulleysystem_en.htm''' file. | ||
| Line 157: | Line 157: | ||
|- | |- | ||
||Point to the '''Springscale.''' | ||Point to the '''Springscale.''' | ||
| − | ||We can either raise or lower the load | + | ||We can either raise or lower the load using a '''Springscale. ''' |
|- | |- | ||
||Show the movement of the '''Springscale''' by the pressed mouse. | ||Show the movement of the '''Springscale''' by the pressed mouse. | ||
| Line 165: | Line 165: | ||
||Click and drag the mouse to raise or lower the load. | ||Click and drag the mouse to raise or lower the load. | ||
| − | Observe that there is no | + | Observe that there is no change in the value in the right panel. |
This is because the necessary force required to drag the load remains the same. | This is because the necessary force required to drag the load remains the same. | ||
| Line 184: | Line 184: | ||
| − | We can change value of weight from 1 '''Newton''' to 40 '''Newton'''. | + | We can change the value of the weight from 1 '''Newton''' to 40 '''Newton'''. |
|- | |- | ||
||Move the cursor to show the Weight of the loose pulleys. | ||Move the cursor to show the Weight of the loose pulleys. | ||
| Line 190: | Line 190: | ||
|- | |- | ||
|| Point to the black pulleys. | || Point to the black pulleys. | ||
| − | || This is the | + | || This is the total weight of the 4 pulleys. |
|- | |- | ||
||Point to show '''Necessary force'''. | ||Point to show '''Necessary force'''. | ||
| Line 210: | Line 210: | ||
||Point to the load. | ||Point to the load. | ||
| − | Point to the 4 sections of the rope. | + | Point to the 4 sections of the rope. |
Point to '''Necessary force'''. | Point to '''Necessary force'''. | ||
| Line 217: | Line 217: | ||
Each section of the rope has one forth of the total weight. | Each section of the rope has one forth of the total weight. | ||
| − | In the '''App''' | + | In the '''App''' force required to raise the weight in air is calculated. |
|- | |- | ||
||'''Slide Number 8''' | ||'''Slide Number 8''' | ||
| Line 255: | Line 255: | ||
This is because the '''Springscale’s''' limit is 10 '''Newton'''. | This is because the '''Springscale’s''' limit is 10 '''Newton'''. | ||
| − | Values more than 10'''Newton'''are automatically changed | + | Values more than 10'''Newton'''are automatically changed. |
| Line 296: | Line 296: | ||
|- | |- | ||
||Point to the torque measured. | ||Point to the torque measured. | ||
| − | ||At | + | ||At the bottom left of the screen torque is calculated. |
|- | |- | ||
||'''Slide Number 10''' | ||'''Slide Number 10''' | ||
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|- | |- | ||
||Point to green and orange rectangles. | ||Point to green and orange rectangles. | ||
| − | || | + | ||Green and orange rectangles indicate perpendicular distances. |
|- | |- | ||
||Remove one weight from the left side of the fulcrum. | ||Remove one weight from the left side of the fulcrum. | ||
| − | ||We can change the hanging weight by clicking and holding mouse. | + | ||We can change the hanging weight by clicking and holding the mouse. |
|- | |- | ||
||Point to fulcrum. | ||Point to fulcrum. | ||
| Line 341: | Line 341: | ||
| − | This is because | + | This is because torque on both the sides is not same. |
|- | |- | ||
||Point to 0.9 Nm. | ||Point to 0.9 Nm. | ||
| Line 357: | Line 357: | ||
||Click and hold the mouse to add one weight on the third rectangle. | ||Click and hold the mouse to add one weight on the third rectangle. | ||
| − | + | Add two weights on the fourth rectangle. | |
One weight on the fifth rectangle. | One weight on the fifth rectangle. | ||
| Line 398: | Line 398: | ||
'''Summary''' | '''Summary''' | ||
| − | ||Using these ''' | + | ||Using these '''Apps''' we have |
* Observed how a pulley system works. | * Observed how a pulley system works. | ||
Revision as of 13:09, 25 April 2019
| Time | Narration |
| Slide Number 1
Title Slide |
Welcome to this spoken tutorial on Simple Machines. |
| Slide Number 2
Learning objective |
In this tutorial we will demonstrate,
Pulley system Lever Principle Apps. |
| Slide Number 3
System Requirements |
Here I am using,
Ubuntu Linux OS version 16.04 Firefox Web Browser version 62.0.3 |
| Slide Number 4
Pre-requisites |
To follow this tutorial,
learner should be familiar with topics in basic physics. |
| Slide Number 5
Learning Goals |
Using these Apps we will,
|
| Slide Number 6
Pulley A pulley is a simple machine that is used to lift heavy objects. We can either use a single pulley or a combination of pulleys.
wells, escalators, rock climbing, flag poles and others.
|
First we will define a pulley
A pulley is a simple machine that is used to lift heavy objects.
wells, escalators, rock climbing, flag poles and others. |
| Slide Number 7
Link for Apps on physics . https://www.walter-fendt.de/html5/phen/
|
Use the given link to download the Apps.
https://www.walter-fendt.de/html5/phen/
|
| Point to the file in the downloads folder. | I have already downloaded Apps on Physics to my Downloads folder. |
| Point to html5phen folder in the Downloads folder. | After downloading, html5phen folder appears in the Downloads folder.
|
| Double-click on html5phen folder.
|
Double-click on html5phen folder.
|
| Double-click on phen folder.
|
Now double-click on the phen folder.
|
| Point to the htm formats Apps. | We will use the Apps with htm file format.
|
| Point to Pulley system App. | To open the Pulley system app press Ctrl+F keys simultaneously.
In the search bar type Pulley system. |
| Right click on pulleysystem_en.htm file.
|
Right click on pulleysystem_en.htm file.
|
| Point to the App interface.
Move the cursor to the yellowpanel. Move the cursor to the green panel. |
The App interface opens with two panels.
An yellow panel with a pulley system and A green panel to change and display parameters. |
| Move the cursor on the load – pulley-rope. | In the yellow panel, notice that a load is attached to the pulley with the help of a rope. |
| Point to the Springscale. | We can either raise or lower the load using a Springscale. |
| Show the movement of the Springscale by the pressed mouse.
|
Click and drag the mouse to raise or lower the load.
Observe that there is no change in the value in the right panel. This is because the necessary force required to drag the load remains the same. |
| Click on drop down list to show the numbers of pulleys | On the top of the green panel you can see a drop down list of pulleys.
List has 2, 4, and 6 pulley systems. |
| Point to the Weight.
|
The weight of the load is displayed in the white box.
|
| Move the cursor to show the Weight of the loose pulleys. | We can change the Weight of the loose pulley in this box. |
| Point to the black pulleys. | This is the total weight of the 4 pulleys. |
| Point to show Necessary force. | The Necessary force used to lift the load is calculated using the App. |
|
Point to Springscale and Force vectors. |
At the bottom of the green panel we have Springscale and Force vectors radio buttons.
|
| Let us demonstrate the working of the pulley. | |
| Point to the load.
Point to the 4 sections of the rope. Point to Necessary force. |
Observe that weight of 20 Newton is hanging from the 4 pulley sections of the rope.
Each section of the rope has one forth of the total weight. In the App force required to raise the weight in air is calculated. |
| Slide Number 8
Necessary force F= (Wl+ Wp)/4 Wl is Weight of the load. Wp is Weight of the loose pulley. |
The Necessary force is calculated using formula.
F= (Wl+ Wp)/4 Wl is weight of the load. Wp is weight of the loose pulley. |
| Edit the Weight of the loose pulley to 20 Newton.
Point to Necessary force |
Now change the Weight of the loose pulley to 20 Newton.
Observe that the Necessary force is changed to 10 Newton. |
| Change the Weight of the load to 30 Newton. | Next change the weight of the load to 30 Newton. |
|
Point to the Weight of the loose pulley. Highlight the last line from the App. |
observe that the weight of the loose pulley has changed to 10 Newton.
This is because the Springscale’s limit is 10 Newton. Values more than 10Newtonare automatically changed.
|
| Slide Number 9
Assignment Change the weight of the load to 25 N and weight of the loose pulley to 10 N. Calculate the necessary force and verify your answer from the App. |
As an assignment,
Change the weight of the load to 25 N and Weight of the loose pulley to 10 N. Calculate the necessary force and verify your answer from the App. |
| To open Lever Principle App right-click on lever_en.htm file and Open With Firefox Web Browser. | Next we will move on to Lever Principle App.
To open Lever Principle App right-click on lever_en.htm file and Open With Firefox Web Browser. |
| Point to the screen(highlight the sentence from the App.) | This App shows a symmetrical lever with some mass pieces.
Each mass piece weighs 1 Newton. |
| Scroll down to show the lever principle.(pink box) | At the bottom of the interface Lever Principle is defined.
A lever is in balance if the total left side torque is equal to the total right side torque. |
| Scroll up to see the App.
|
Observe that the lever arm is shown by green and orange rectangles.
Length of each rectangle is 0.10 m. |
| Point to the torque measured. | At the bottom left of the screen torque is calculated. |
| Slide Number 10
Torque Torque is the twisting force that tends to cause a rotation. The point where the object rotates is aixs of rotation. |
Torque is the twisting force that tends to cause a rotation.
The point where the object rotates is the axis of rotation. |
| Point to the fulcrum. | In the App fulcrum is the axis of rotation. |
| Slide Number 11
Torque (tau) τ = F r⟂ F is a force applied by the load. r⟂ is a perpendicular distance from the fulcrum. |
We can calculate the torque using the formula.
(tau)τ = F* r⟂(perpendicular) .
|
| Point to green and orange rectangles. | Green and orange rectangles indicate perpendicular distances. |
| Remove one weight from the left side of the fulcrum. | We can change the hanging weight by clicking and holding the mouse. |
| Point to fulcrum.
|
Observe that, the lever is unbalanced.
|
| Point to 0.9 Nm. | Notice that the value of left side torque is reduced to 0.9 Nm
(Newton-meter). |
| In the text-box type. (What happens when hanging weights are removed from both the sides) | What happens when hanging weights are removed from both the sides. |
| Point to the left side of the fulcrum. | Let us hang the weights at different distances to the left of the fulcrum. |
| Click and hold the mouse to add one weight on the third rectangle.
Add two weights on the fourth rectangle. One weight on the fifth rectangle. |
Click and hold the mouse to add one weight on the third rectangle.
Add two weights on the fourth rectangle. And one weight on the fifth rectangle. |
| Point to the lever. | Observe that the lever is now unbalanced. |
| Point to the right side. | Let us add weights to the right side of the fulcrum to balance the lever. |
| Use pressed mouse to add the weights from
right to 1st rectangle. |
Click and hold the mouse to add one weight to the first rectangle. |
| Hang the weight to 3rd, 4th, and 5th rectangles. | Continue to add weights to third, fourth and fifth rectangles. |
| Point to the lever. | Notice that the lever is now balanced. |
| Slide Number 12
Assignment On the same side of the fulcrum, if a block weighing 5 N is kept at 0.5 m and a block weighing 3 N is kept at 0.6 m, then how far a block weighing 7 N should be kept on the other side of the fulcrum to achieve a balance condition. |
As an assignment solve this numerical. |
| Let us summarize | |
| Slide Number 13
Summary |
Using these Apps we have
|
| Slide Number 14
License These Apps are created by Walter-fendt and his team. This video is released under CC-BY-NC-SA license.
|
These Apps are created by Walter-fendt and his team.
This video is released under CC-BY-NC-SA license. |
|
Slide Number 15 About Spoken Tutorial project. The video at the following link summarizes the Spoken Tutorial project. Please download and watch it.
|
The video at the following link summarizes the Spoken Tutorial project.
Please download and watch it. |
| Slide Number 16
Spoken Tutorial workshops. Spoken Tutorial Project team, conducts workshops using spoken tutorials and gives certificates on passing online tests. For more details, please write to us.
|
Spoken Tutorial Project team,
conducts workshops using spoken tutorials and gives certificates on passing online tests. For more details, please write to us. |
| Slide Number 17
Forum for specific questions: Do you have questions in THIS Spoken Tutorial? Please visit this site Choose the minute and second where you have the question. Explain your question briefly Someone from our team will answer them.
|
Do you have questions in THIS Spoken Tutorial?
Please visit this site Choose the minute and second where you have the question. Explain your question briefly Someone from our team will answer them. |
| Slide Number 18
Forum for specific questions: The Spoken Tutorial forum is for specific questions on this tutorial Please do not post unrelated and general questions on them This will help reduce the clutter With less clutter, we can use these discussion as instructional material
|
The Spoken Tutorial forum is for specific questions on this tutorial
Please do not post unrelated and general questions on them This will help reduce the clutter With less clutter, we can use these discussion as instructional material. |
| Slide Number 19
Acknowledgement |
Spoken Tutorial Project is funded by MHRD, Government of India. |
| This is Himanshi Karwanje from IIT-Bombay.
Thank you for joining. |
