Categories starting with E


Electricity (20)

The focus is on electricity and magnetism, including electric fields, magnetic fields, electromagnetic forces, conductors and dielectrics, electromagnetic waves, and the nature of light.

Electrostatic (13)

The focus is on electricity and magnetism, including electric fields, magnetic fields, electromagnetic forces, conductors and dielectrics, electromagnetic waves, and the nature of light.

Items starting with E

Electrical first aid kit

Electrical first aid kit

Electrical first aid kit

ELECTRICITY KIT

ELECTRICITY KIT

Exp-1 To show the change in intensity of bulb with adding cells.
Exp-2 To interrupt the electricity by using push switch.
Exp-3 The series and parallel combination of bulbs.
Exp-4 To demonstrate the effect of variable resistance.
Exp-5 The working of change over switch.
Exp-6 To demonstrate the difference between diode and resistance. 
and many more......
PHYSICS, Class Xll, Part-1, Chapter - 3, Current electricity.
SCIENCE, Class X, Chapter - 12, Electricity.
Chapter - 13, Magnetic effects of electric current.

ELECTROMAGNETISM ACCESSORIES

ELECTROMAGNETISM ACCESSORIES

ELECTROMAGNETISM ACCESSORIES

ELECTRON DIFFRACTION

ELECTRON DIFFRACTION

  • Electron Diffraction Tube with built-in graphite foil and fluorescent screen.
  • Adjustable Anode voltage from 0V to 5000V range.
  • Diffraction Patterns are noticed in fluorescent screen.
  • De-Broglie Wavelength.
  • Wave nature of electron.
  • Diffraction of Wave.
  • Bragg's Law.

ELECTRON SPIN RESONANCE AND NUCLEAR MAGNETIC RESONANCE (ESR-NMR)

ELECTRON SPIN RESONANCE AND NUCLEAR MAGNETIC RESONANCE (ESR-NMR)

  • Modular set for ESR/NMR
  • Table top experiment.
  • Easy to setup.
  • Glycerin, Teflon, and polystyrene sample for NMR
  • DPPH sample for ESR
  • Resonance absorption.
  • Magnetic fields.
  • Resonant line widths.
  • Electron and proton spin.
  • Magnetic moment.
  • Nuclear g-factors.
  • Nuclear-spin tomography.

ELECTRONIC PLUG IN KIT

ELECTRONIC PLUG IN KIT

  • Student uses Plug- in Modules for circuit design.
  • This ‘Do It Yourself Approach’ provides better learning.
  • The plug-in modules are design in transparent housing for visibility of the components.
  • The symbols and name of the components printed for easy identification.
  • Very convenient & easy to use 4mm sockets provided to Plug the modules in circuit board.
  • Economical & Flexible method of performing all experiment on one circuit board in case you buy a complete set.
  • Safety as per European standard.
  • Ohm's law.
  • Charging and discharging.
  • Rectifier circuits.
  • Zener diode characteristics.
  • LED characteristics.
  • Clipper and clamper circuit.
  • Transistor characteristics.
  • Analog & digital circuits.
  • Logic gates.
  • Amplifiers & oscillators.
  • Flip-flops.
  • Transistor & Op-Amp.

ELECTRONIC PLUG IN KIT (VARIOUS INDIVIDUAL KITS)

ELECTRONIC PLUG IN KIT (VARIOUS INDIVIDUAL KITS)

CURRENT AND VOLTAGE SOURCES 

 

TRANSISTORS CHARACTERSTICS 

 

DIODE CIRCUIT AND POWER SUPPLY 

 

TRANSISTORS AS AMPLIFIER 

 

TRANSISTORS AS OSCILLATOR 

 

DIODES CHARACTERISTICS 

 

COMBINATORIAL & SEQUENTIAL CIRCUITS 

 

BASIC LOGICAL OPERATIONS 

Electroscopes & Electrometer

Electroscopes & Electrometer

Am electroscope is an early scientific instrument that is used to detect the presence and magnitude of electric charge on a body. It was the first electrical measuring instrument. The first electroscope, a pivoted needle called the versorium, was invented by British physicianWilliam Gilbert around 1600.[1] The pith-ball electroscope and the gold-leaf electroscope are two classical types of electroscope that are still used in physics education to demonstrate the principles of electrostatics. A type of electroscope is also used in the quartz fiber radiation dosimeter. Electroscopes were used by the Austrian scientist Victor Hess in the discovery of cosmic rays.

ELECTROSTATIC KIT

ELECTROSTATIC KIT

The kit is used for demonstrating a number of electrostatics experiments. It consists of various elements and a gold leaf electroscope with a transparent front window and ground glass rear window.

Engine Model

Gasoline Engine Model

Gasoline Engine Model
This unit is to show to the student about the working principle of gasoline engine made of aluminum.
 Same as above, only made of Plastic.

EXPERIMENTS WITH MICROPHONE

EXPERIMENTS WITH MICROPHONE

STANDING WAVES IN A TUBE
Objectives:

  • Set up standing wave patterns in a column of air in open-end and closed-end tubes.
  • Determine the relationship between tube length and wavelength for these standing waves.
  • Use transverse wave patterns to describe the nodes and antinodes that occur in a column of air in open-end and closed-end tubes.
  • Determine the speed of sound in air.

EXPERIMENTS WITH POWER AMPLIFIER

EXPERIMENTS WITH POWER AMPLIFIER

Exp-1 Standing waves on a string.

Experiments with Rotary Motion Sensor and Vernier Data Logger

Experiments with Rotary Motion Sensor and Vernier Data Logger

ROTATIONAL DYNAMICS
Objectives:

  • Collect angular acceleration data for objects subjected to a torque.
  • Determine an expression for the torque applied to a rotating system.
  • Determine the relationship between torque and angular acceleration.
  • Relate the slope of a linearized graph to system parameters.
  • Make and test predictions of the effect of changes in system parameters on the constant of proportionality.

CONSERVATION OF ANGULAR MOMENTUM
Objectives:

  • Collect angle vs. time and angular velocity vs. time data for rotating systems.
  • Analyze the θ-t and ω-t graphs both before and after changes in the moment of inertia.
  • Determine the effect of changes in the moment of inertia on the angular momentum of the system.

EXPERIMENTS WITH SPECTROVIS OR SPECTROVIS PLUS

EXPERIMENTS WITH SPECTROVIS OR SPECTROVIS PLUS

RYDBERG CONSTANT
Objectives:

  • Use a spectrometer to determine the wavelengths of the emission lines in the visible spectrum of excited hydrogen gas.
  • Determine the energies of the photons corresponding to each of these wavelengths.
  • Use a modified version of Balmer’s equation to relate the photons’ energies to specific transitions between energy levels.
  • Use your data and the values for the electron transitions to determine a value for Rydberg’s constant for hydrogen.

EXPERIMENTS WITH VERNIER GAS PRESSURE SENSOR, STAINLESS STEEL TEMPERATURE

EXPERIMENTS WITH VERNIER GAS PRESSURE SENSOR, STAINLESS STEEL TEMPERATURE

IDEAL GAS LAW
Objectives:

  • Collect pressure vs. volume, pressure vs. number, and pressure vs. temperature data for a sample of air in an enclosed container.
  • Determine relationships between these pairs of variables.
  • Determine a single expression relating these variables.
  • Determine the constant of proportionality for the relationship between pressure, volume, and temperature.
  • Use kinetic molecular theory (KMT) to model the behavior of the gas at various points on each graph.