Advertisements
Advertisements
प्रश्न
Derive the expression for the heat produced due to a current ‘I’ flowing for a time interval ‘t’ through a resistor ‘R’ having a potential difference ‘V’ across its ends. With which name is the relation known? How much heat will an instrument of 12W produce in one minute if it is connected to a battery of 12V?
Advertisements
उत्तर
Consider a resistor of resistance R. Let the current flowing through this resistor be I and the potential difference across it be V.
In time t, let Q amount of charge flows through the resistor.
Work done on moving this charge, W = VQ ... (1)
According to the definition of electric current,
`1=Q/t`
Q = I × t
Putting this in equation (1),
W = V × I × t
This work done is dissipated as heat.
Hence,
Heat produced, H = W = VIt
H = VIt ... (2)
According to Ohm’s law, V = IR.
Putting this in equation (2),
H = IR × It
H = I2Rt
This relation is known as Joule’s law of heating.
Power, P = 12 W
Potential difference, V =12 V
Time duration of current flow, t = 1 min = 60 s
`P = H/t`
H = P × t
= 12 W × 60 s
= 720 J
The heat generated by the instrument of 12 W in a minute is 720 J.
APPEARS IN
संबंधित प्रश्न
The following diagram shows a spiral coil wound on a hollow carboard tube AB. A magnetic compass is placed close to it. Current is switched on by closing the key.
- What will be the polarity at the ends A and B?
- How will the compass needle be affected? Give reason.
State two ways by which the magnetic field due to a current carrying solenoid can be made stronger.
A current carrying solenoid behaves like a ______.
The adjacent diagram shows a small magnet placed near a solenoid. State whether the magnet is attracted or repelled, as the switch is pressed. Give a reason.
Under what conditions permanent electromagnet is obtained if a current carrying solenoid is used? Support your answer with the help of a labelled circuit diagram.
Ansari Sir was demonstrating an experiment in his class with the setup as shown in the figure below.
A magnet is attached to a spring. The magnet can go in and out of the stationary coil. He lifted the Magnet and released it to make it oscillate through the coil.
Based on your understanding of the phenomenon, answer the following question.
Is there any difference in the observations in the galvanometer when the Magnet swings in and then out of the stationary coil? Justify your answer.
Observe the given figure of a current-carrying solenoid and write the labels of A and B correctly.
Refer to the image below and state how the magnetic field pattern indicates regions where the magnetic field is stronger outside the magnet. What happens to the magnetic field when the current in the circuit is reversed?
Draw a neat diagram of a solenoid and name its various components.
Current is flowing through a coil as shown in the figure. Which one of the given figures will correctly depict the magnetic polarity and the direction of the lines of force along the axis of the coil?
