QUESTION 2 A coil with inductance of 1 H and negligible resistance carries the current shown...
A coil with a self-inductance of 4 H and a resistance of 14 ohm is connected across a 22 V battery of negligible internal resistance. What is the final current? A How much energy is stored in the inductor when the final current is attained? J
A coil with inductance of 3.0 H and a resistance of 34.0 ? is suddenly connected to a resistanceless battery with ? = 100.0 V, by closing the switch. What is the equilibrium current? How much energy is stored in the magnetic field when this current exists in the coil?
A coil with an inductance of 1.8 H and a resistance of 11 Ω is suddenly connected to an ideal battery with ε = 130 V. At 0.12 s after the connection is made, what is the rate at which (a) energy is being stored in the magnetic field, (b) thermal energy is appearing in the resistance, and (c) energy is being delivered by the battery?
A coil with an inductance of 1.9 H and a resistance of 11 Ω is suddenly connected to an ideal battery with ε = 97 V. At 0.10 s after the connection is made, what is the rate at which (a) energy is being stored in the magnetic field, (b) thermal energy is appearing in the resistance, and (c) energy is being delivered by the battery?
A coil with an inductance of 2.5 H and a resistance of 11 Ω is suddenly connected to an ideal battery with ε = 77 V. At 0.10 s after the connection is made, what is the rate at which (a) energy is being stored in the magnetic field, (b) thermal energy is appearing in the resistance, and (c) energy is being delivered by the battery?
A coil with an inductance of 1.9 H and a resistance of 14 Ω is suddenly connected to an ideal battery with ε = 77 V. At 0.14 s after the connection is made, what is the rate at which (a) energy is being stored in the magnetic field, (b) thermal energy is appearing in the resistance, and (c) energy is being delivered by the battery?
A coil with an inductance of 1.9 H and a resistance of 9.3 Ω is suddenly connected to an ideal battery with ε = 140 V. At 0.13 s after the connection is made, what is the rate at which (a) energy is being stored in the magnetic field, (b) thermal energy is appearing in the resistance, and (c) energy is being delivered by the battery?
A coil with an inductance of 5.2 H and a resistance of 5.2 2 is suddenly connected to a resistanceless battery with an ε = 178.0 V. At 0.98 s after the connection is made, what is the rate at which energy is being stored in the magnetic field? Submit Answer Tries 0/10 What is the rate at which thermal energy is appearing, Submit Answer Tries 0/10 What is the rate at which energy is being delivered by the battery?
4. Suppose that you are supplied with this equipment = 0.012 2), plus 2 switches and plenty of wire (of negligible resistance) 1 non-ideal battery (with internal resistance 1 parallel-plate capacitor, initially uncharged 4 identical ohmic resistors, each with resistance R 4.00 Q 2 solenoid inductors, with inductance values L and L, respectively. Inductor A is half as long as inductor B Inductor A has a diameter of 5.30 cm; inductor B has a diameter of 6.36 cm. r And...
The inductor in has inductance 0.600 H and carries a current in the direction shown that is decreasing at a uniform rate, di/dt = - 3.00×10-2. Find the self-induced emf.