Physics Chapter 2: Key words to understand
... A property of a material (or particle) which can be positive or negative A region where a charge material or particle experiences a force A negatively charged particle found in atoms. Electrons move through a wire when a current flows A current through the air which produces light and sound The char ...
... A property of a material (or particle) which can be positive or negative A region where a charge material or particle experiences a force A negatively charged particle found in atoms. Electrons move through a wire when a current flows A current through the air which produces light and sound The char ...
question paper
... Q.No.19:-Two tiny spheres carrying charges 1.5µc & 2.5 µc are located 30cm apart. Find the potential and electric field at the mid point of the line joining the two charges. Q.No.20:-A steam of electrons traveling with speed ‘v’ m/s at right angles to a uniform electric field ‘E’ is deflected in a c ...
... Q.No.19:-Two tiny spheres carrying charges 1.5µc & 2.5 µc are located 30cm apart. Find the potential and electric field at the mid point of the line joining the two charges. Q.No.20:-A steam of electrons traveling with speed ‘v’ m/s at right angles to a uniform electric field ‘E’ is deflected in a c ...
Practice Questions for I Year/I Part Engineering Physics
... 20. Two capacitors of capacitance 4 μF and 12μ F respectively are connected in series and the combination is connected momentarily across a 200V battery. The charged capacitors are now isolated and connected in parallel, similar charge plates being connected, together, Calculate common potential. (7 ...
... 20. Two capacitors of capacitance 4 μF and 12μ F respectively are connected in series and the combination is connected momentarily across a 200V battery. The charged capacitors are now isolated and connected in parallel, similar charge plates being connected, together, Calculate common potential. (7 ...
Snímek 1
... The rotary field created by the stator has a higher speed than rotor revs. The basis of asynchronous motor function is a creation of the rotary magnetic field, which comes from the alternating current passing through the winding of the stator. This magnetic field induces the voltage in the rotor and ...
... The rotary field created by the stator has a higher speed than rotor revs. The basis of asynchronous motor function is a creation of the rotary magnetic field, which comes from the alternating current passing through the winding of the stator. This magnetic field induces the voltage in the rotor and ...
printer-friendly sample test questions
... Which of the following BEST describes the principle of electromagnetic induction? A. A magnetic field moving around a coil of wire causes an electric current, and an electric current in a coil of wire causes a magnetic field. B. The flow of electrons through either a series or parallel circuit is kn ...
... Which of the following BEST describes the principle of electromagnetic induction? A. A magnetic field moving around a coil of wire causes an electric current, and an electric current in a coil of wire causes a magnetic field. B. The flow of electrons through either a series or parallel circuit is kn ...
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changing magnetic field
... • The induced voltage in a coil is proportional to the product of the number of loops and the rate at which the magnetic field changes within those loops. • The amount of resulting current depends on the induced voltage but also on the resistance of the coil and the nature of the circuit (a property ...
... • The induced voltage in a coil is proportional to the product of the number of loops and the rate at which the magnetic field changes within those loops. • The amount of resulting current depends on the induced voltage but also on the resistance of the coil and the nature of the circuit (a property ...
Presentation 1
... H or B B determines • Force (e.g. in motor) • EMF (e.g. in alternator, transformer, RFID…) curl H = J gives magnetic field from any current carrying structure irrespective of the medium. From that we can determine B Describes the bending of B when going through ...
... H or B B determines • Force (e.g. in motor) • EMF (e.g. in alternator, transformer, RFID…) curl H = J gives magnetic field from any current carrying structure irrespective of the medium. From that we can determine B Describes the bending of B when going through ...
Chapter 20 Switching on
... 11. Calculate the power generated by a battery that produces 6.00 × 102 J of electric potential energy in 2.00 × 101 s. 12. Calculate the heat energy produced in 1.00 minute by a heater generating 5.00 × 102 W of power. 13. Calculate the time it takes a 4.00 × 101 W lamp to dissipate 8.00 × 102 J of ...
... 11. Calculate the power generated by a battery that produces 6.00 × 102 J of electric potential energy in 2.00 × 101 s. 12. Calculate the heat energy produced in 1.00 minute by a heater generating 5.00 × 102 W of power. 13. Calculate the time it takes a 4.00 × 101 W lamp to dissipate 8.00 × 102 J of ...
Pendahuluan Mesin Elektrik / Mesin Elektrik Secara Am
... Electric motors are used to operate washing machines, elevators, cranes etc while electric generators are used to generate electricity for power generation and alternator for charging car battery. ...
... Electric motors are used to operate washing machines, elevators, cranes etc while electric generators are used to generate electricity for power generation and alternator for charging car battery. ...
magnetic - Timber Ridge Elementary
... In our planet we have the North and South Poles. Earth acts like a giant magnet and is surrounded by a magnetic field. Earth’s magnetic field is what causes the needle of a compass to point in different directions and causes the poles of a magnet to point either North or South. ...
... In our planet we have the North and South Poles. Earth acts like a giant magnet and is surrounded by a magnetic field. Earth’s magnetic field is what causes the needle of a compass to point in different directions and causes the poles of a magnet to point either North or South. ...
Coilgun
A coilgun (or Gauss rifle, in reference to Carl Friedrich Gauss, who formulated mathematical descriptions of the magnetic effect used by magnetic accelerators) is a type of projectile accelerator consisting of one or more coils used as electromagnets in the configuration of a linear motor that accelerate a ferromagnetic or conducting projectile to high velocity. In almost all coilgun configurations, the coils and the gun barrel are arranged on a common axis.Coilguns generally consist of one or more coils arranged along a barrel, so the path of the accelerating projectile lies along the central axis of the coils. The coils are switched on and off in a precisely timed sequence, causing the projectile to be accelerated quickly along the barrel via magnetic forces. Coilguns are distinct from railguns, as the direction of acceleration in a railgun is at right angles to the central axis of the current loop formed by the conducting rails. In addition, railguns usually require the use of sliding contacts to pass a large current through the projectile or sabot but coilguns do not necessarily require sliding contacts. Whilst some simple coilgun concepts can use ferromagnetic projectiles or even permanent magnet projectiles, most designs for high velocities actually incorporate a coupled coil as part of the projectile.