Electrical first aid kit

Electrical first aid kit

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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.

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ELECTROMAGNETISM ACCESSORIES

ELECTROMAGNETISM ACCESSORIES

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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.

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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.

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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.

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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 

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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.

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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.

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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.

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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.

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EXPERIMENTS WITH POWER AMPLIFIER

Exp-1 Standing waves on a string.

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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.

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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.

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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.

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