Solenoid

 

Solenoid

This is a straight wire, carrying current. We have seen the nature of the magnetic field generated around it.

The magnetic field due to straight wire is distributed along its length.

Strength of this field can be increased at a specific point if  we place many small wires like this or  form a loop by joining these two ends. 

Magnetic field formed due to a loop is very small and can be enhanced by having more such loops next to each other.  This can be achieved by closely winding wire into helical shape like this around a pipe.  We can wrap this wire with cellotape. Pipe is used to support the coil.

 In the study of electromagnetism, a solenoid is a coil whose length is substantially greater than its diameter. 

If I place the needle compass outside the solenoid, nothing happens. Same compass if placed near one end of the solenoid, and the needle is deflected.

The magnetic field is formed inside the coil. Let us find out more about it. 

We will place this needle compass such that part of the needle is inside the coil. When the current flows through the coil, the North pole of the needle is pulled inside. This end is behaving like the South Pole of the coil as we know that opposite poles attract.. Let us switch direction of current and find out if it is the same case. This time the needle is pushed away.  This end is now behaving like a North Pole as we know that similar poles repel. 

Let us perform the same activity with another needle compass on the right side of the coil ? 

Left and right side of the coil are behaving like a regular  magnet. It has the North Pole and South Pole. Type of the pole is decided by the direction of current. 

We can say that solenoid behaves like a regular magnet. The type of the pole is decided by the direction of current flowing through the coil.

How about the magnetic field inside the coil ? Let us form a rectangular pipe with this plastic sheet. We will wind this coated copper wire with 100 turns . When the needle compass is placed at various locations inside the coil, the needle aligns itself along the vertical axis of the coil. The direction of this alignment is decided by the direction, current is flowing through the coil. 

However, Solenoid is the generic term for a coil of wire used as an electromagnet. Electromagnets with fixed cores are not considered solenoids.

Solenoid refers to any device that converts electrical energy to mechanical energy using a solenoid which has a moving core. The device creates a magnetic field from electric current and uses the magnetic field to create linear motion. Common applications of solenoids are to power a switch, like the starter in an automobile, or a valve, such as in a sprinkler system.

These railway signals are all controlled by solenoids.

You can also build solenoid with coated copper wire wound around a pipe or you can use paper straw or pen for the same.

We can also build this solenoid with coated copper wire and more turns. It makes a magnetic field inside more powerful.

Let us pour iron filings into this solenoid. When current is passed, a magnetic field is created inside. This can be seen by the orientation of iron filings.

You can place it on the ring magnet and watch it jump .This will happen only when poles repel each other.

Do try this at home.

Thank you.

Calculating Strength of a magnet

 Magnets are everywhere. They can be permanent magnets or electromagnets. Magnets come in many shapes and sizes but they also come in different strengths. 

It depends on what is meant by strength.  Two common measures of a magnet’s strength are the strength of the magnetic field and pull force. 

The magnetic field strength is expressed in Gauss or Tesla (1 Tesla = 10,000 Gauss).  It depends on the size, shape, grade of the magnet and where the measurement is performed.

We will use a magnetometer sensor available in this smartphone to measure the strength of the magnetic field.  Science Journal App is used to visualize data captured by the sensor. 

As We move the bar magnet near the sensor, the strength of the magnetic field goes up. It comes back to original value as I move the bar magnet away. Same is true for other pole as well. 

Electromagnet also behaves in a similar manner. We can see the proportional increase in strength with increase in current. 

What if you don't have a magnetometer ? You can design your own scale with everyday things and compare the strength of the magnetic field quantitatively.

I will take this small steel ball and place it at a distance. I will slowly move the magnet towards the ball. The point at which ball is attracted towards the magnet is noted. We can note it down and compare the strength of all the magnets we have. Off-course this is our local scale. 

Another way is to place a magnet in the bowl filled with balls and measure how many are attracted. By calculating the average, you can arrive at some number.

We can also compare strength based on the weight magnet can lift as well. 

Let us attach this magnet to the wooden base here and calculate pull force. This nut with a container is stuck to the magnet. We will put balls in this container till it pulls the magnet down. This will be one measure of the strength of the magnet.

Same can be tried with a Neodymium magnet as well. It seems we need more force to pull the nut down. Let us tie this bottle and increase the force by adding water. It took 700 ml of water or approximately 7 Newtons.

You can try these variations to calculate the strength of the magnetic field. 

Thank You.

Learning concepts with activities

 

Mechanics

1. Physics and Measurement
1. Length
2. Mass 
3. Time
4. Density
5. Dimensional Analysis
6. Significant figures
2. Motion in one dimension
1. Position
2. Speed and velocity
3. Acceleration
4. One dimensional Motion with constant acceleration
3. Motion in two dimensions
1. Projectile Motion
2. Uniform circular motion
3. Tangential and Radial acceleration
4. Relative velocity and acceleration
4. Laws of motion
1. Force
2. Newton's First Law and Inertial Frames
3. Mass
4. Newton's Second Law
5. Gravitational Force and Weight
6. Newton's Third Law
7. Application of Newton's laws
8. Forces of Friction
5. Energy and Energy Transfer
1. Work
2. Potential and Kinetic Energy
3. Power
6. Potential Energy of a system
7. Linear Momentum and Collisions
1. Impulse
2. Momentum
3. Collision in one dimension
4. Collision in two dimensions
5. Center of Mass
6. Motion of system of particles
8. Rotation of Rigid objects about fixed point
1. Angular position, Velocity, Acceleration
2. Moments of Inertia
3. Torque
4. Rotational kinetic Energy
5. Work, Power and Energy in Rotational Motion
9. Angular Momentum
10. Static Equilibrium
11. Universal Laws of Gravitation
1. Kepler law
2. Gravitational Field
3. Gravitational Potential Energy
12. Fluid Mechanics
1. Pressure
2. Variation of Pressure with depth
3. Buoyant Force
4. Archimedes Principle
5. Bernoulli Principle
6. 
   

Areas

Mechanics

Electromagnetism

Optics

Heat

High School Physics - Mechanics

DIY activities to know more about concepts in Mechanics

Laws of Motion

1. Forces in equilibrium
2. Components of Force
3. Quantify forces in interaction
4. Balloon Boat
5. Simple Bottle Cart
6. Gravity Defying wheel
7. Calculate Speed of moving object with mobile app
8. Build balloon car
9. Anti Gravity Pipe
10. Magic with Shampoo Sachet
11. Steam Powered Raft
12. Straw sprinkler
13. CD Top
14. Broomstick Car
15. Rubber band Car
16. Cap Copter
17. Air store with balloons
18. Bernoulli seed blower
19. Bottle cap propeller
20. Levitating Pencil
21. Straw Raft with toothpaste
22. Pressure Diver
23. Pencil Spinner
24. 
    

Circular Motion

1. Simple Centrifuge

Universal Gravitation

1. Kepler - Visualizing equal areas

Fluid Mechanics

1. Force, Pressure with everyday things
2. Drinking Bird Toy
3. Pneumatic Car Jack
4. Pressure concepts with Manometer
5. Coil pump
6. Archimedes Screw
7. Talking coin

Static Equilibrium

1. Falling containers
2. Balance PVC Pipe
3. CG Toy with rubber soles
4. Timer with everyday things
5. Weighing Scale with Ruler
6. Water clock to measure time

Simple Machines

1. Screw - working model
2. Pulley with everyday things
3. Pulley Ratio

Misc

1. Tilt switch
2. Density with everyday things
3. Syringe air fan
4. Smoking Bottle
5. Colorful Holi
6. Fun with Density
7. Harmonic Motion
8. Water level and Shapes
9. Ball bearing with marbles
10. Paper fibers unfold the mystery
11. Understand Mechanical advantage
12. Straw Diver
13. Separate Egg Yolks
14. 
    

Oscillation and Mechanical Waves

Oscillation 

1. Sine Function
2. Radians for angle measurement
3. Angular Velocity
4. Period , Frequency and Amplitude
5. Uniform Circular Motion and Simple Harmonic Motion
6. Projection of Uniform Circular Motion
7. What is Phase ?
8. Angular Frequency
9. Relation between angular and linear velocity

Waves

1. Ripples in water

Sound

1. How Straw whistle works

Automata

1.  Cardboard automata for beginners
2.  Automata workshop VI18
3.  Flagman with Automata
4. Automata with everyday things

Activities

1. My cycle and Simple Machines

Simulations

1. Kinematics - Simulation
2. Simulation for High school Mechanics

Challenges

1. Guess pressure with Manometer
2. Two balls different size 
3. Which balls goes up first ?
4. Guess contents of the ball 
5. Will balloon burst ?
6. Move the marble up..
7. How balls of different mass will fall ?
8. Calculate rotational speed ...

Earlier Work

1. Tracing Simple Harmonic Motion - version 1
2. 
   

High School Physics - Heat

 Heat related activities

Concepts

1. Water analogy to understand Heat, Temperature and Specific Heat
2. Thermal Expansion of metals
3. Visualize water expansion
4. Build Hope Apparatus
5. Regelation 
6. Curie Point
7. Boiling point of water and altitude
8. Melt wax with different metals
9. Steam boat with egg shell

Challenges

1. Which Ice Melts first ?
2. What will be water level ?
3. Which is dense ? Hot or cold water
4. Which ice will melt faster ?
5. Which metal is good conductor of heat ?
6. Can we heat water in paper or plastic ?
7. Moody balloon
8. Hot or Cold
9. Know more about heat

Hight School Physics - Optics

DIY activities for high school optics. 

This is the compilation of activities I have designed to understand key areas in optics.

Before you begin

1. Learning Progression - Optics
2. Inputs for Optics related activities
3. Slit with everyday things

Concepts

1. Law of Reflection
2. Pinhole Camera - Ray Path Model
3. Origami Pinhole Camera
4. Secrets of colorful shadows
5. Umbra - Penumbra
6. Solar Eclipse
7. Ray model for spherical Mirror and lenses
8. Law of Reflection and Thick Mirrors
9. Image distance in plain mirror
10. Multiple images with wrappers
11. Infinite images with plain mirror
12. Image location with parallax

Curved Mirrors

1. Visualize ray paths for curved mirrors
2. Simple optics bench for concave mirror
3. Concave mirror ray paths with plain mirrors
4. Optical Aberration and Parabola
5. Magnification equation with ray paths
6. Mirror equation visualized
7. Focal length of Concave mirror
8. Ray path in Periscope
9. Total internal reflection

Lenses

1. Ray path with Acrylic Lenses
2. Focal length of lens with sun rays
3. Focal length of convex lens in water
4. Diverging Convex lens
5. Image formation when lens is partially blocked
6. Plastic lens for ray optics
7. Portable optics bench
8. Raindrop and Rainbow
9. Build Prism with Plastic
10. Fish bowl lens
11. Refractive index of water at home

Simulations

1. Simulation for lens and mirrors 
2. Simulation - High School Optics
3. Simulation - Refraction - Assignment
4. Simulation - Lens and Mirrors - Assignment

Activities

1. A4 Periscope 
2. Portable Kaleidoscope
3. Color mixer with plastic bottles
4. Zero Shadow day 
5. Colorful bands with soap film
6. Why light looks dimmer at a distance
7. What is power of your reading glasses ? 
8. Test your peripheral vision
9. Find your blind spot
10. Make reflecting metal
11. Build 3D glasses
12. Mix colors with PVC Pipe Batteries
13. Simulating blue sky
14. Rainbow with flashlight
15. 5 Unique ways to watch solar eclipse

Challenges

1. Identify spherical mirror

Earlier work

1. Version 1 - Pinhole Camera
2. Version 1 - Periscope at home
3. Color with layers
4. Version 1 - Law of reflection 

High School Physics - Electromagnetism

 DIY Activities to understand concepts related to Electromagnetism.

These activities can be performed in the classroom during interaction session with students.

Activities sub-section list projects based on these concepts

 

Before you begin 

1. High School Learning Progression - Electricity and Magnetism 
2. Key Inputs - Effects of electric current

Concepts 

1. Heating effect of an electric current 
2. Magnetic effect of an electric current
3. Electromagnet
4. Magnetic field with iron filings
5. Magnetic field lines in current carrying conductor
6. Magnetic field around current carrying coil
7. Right hand Thumb Rule - visualized
8. Fleming's Left hand rule 
9. DC Motor - Model and Analysis
10. DC Motor with split rings
11. Galvanometer - working model
12. Faraday's law of induction 
13. Solenoid
14. Induced current in Solenoid
15. Induced current with PVC pipe and Ring Magnets
16. Electromagnetic Induction
17. Fleming's Right Hand Rule - Activity
18. Simple Electric Generator
19. Build DC Generator
20. Magnetic field - Dot and Cross notations

Simulations

1. Simulations - Electromagnetism - Highschool Physics
2. PHET Simulation - DC Circuit construction

Electricity

1. Wonders with static electricity
2. Battery Holder
3. Electrical Circuits
4. Series and Parallel Connections
5. Lemon Battery
6. Build Rheostat
7. Simple Voltaic Pile

Activities

1. Calculate strength of the magnet
2. Break magnet in half 
3. Semaphore Signal - working model 
4. Build magnetic sensor
5. Circuit construction with Pencil
6. Curie Point
7. Effect of heating on Magnet
8. Build Needle compass
9. Break the magnet
10. Magnetization methods
11. Homopolar Motor - Force analysis
12. First electric motor
13. Lodestone as navigational aid
14. Effects of electric current in a box
15. Simple motor with pencil cell
16. This is how Telegraph works
17. Horseshoe Magnet with wires
18. Magnetic force between two currents in the same direction
19. Simple electric bell - Version 2
20. Magnetic Petroglyph
21. Needle compass with paper
22. Simple Battery Holder
23. Demo - Faraday's law of induction
24. Handy electric bell 
25. Electromagnetic crane
26. Build fuse wire mechanism
27. Comparing Magnetic Permeability
28. Simple Electric Generator - Version 2
29. Geometry with magnets 
30. Happy Diwali 2017

Earlier versions

1. Magnetic effects of an electric current - Version 2
2. Simple Electricity Generator - Version 2
3. Force on current carrying conductor in magnetic field
4. Magnetic field in current carrying coil
5. DC Motor with commutator
6. Version 1 - Fleming's Left Hand Rule 
7. Magnetic effect of an electric current - Version 1
8. Build simple galvanometer
9. Heating effect of an electric current

Food for Thought / Challenges

1. Orientation of Needle compass
2. Orientation of Horse Shoe Magnet
3. Attach pins to Magnet
4. How many steel balls magnet will attract ?
5. Guess final voltage 
6. Can plastic bobbin attract pins ?
7. Can Magnet attract pins ?
8. Identify poles of a magnet
9. Magnetic Mystery
10. Change compass orientation