Here are your physics notes on Power and Collisions, presented in a simple and friendly way! 😊“`html

⚡ Power: The Rate of Doing Work

Power tells us how fast work is done or energy is transferred. Think of climbing stairs: It’s not just how many stairs you climb, but how quickly you climb them! 🏃

🔧 Key Definitions

  • Average Power (\(P_{av}\)): Work done divided by total time taken. \[P_{av} = \frac{W}{t}\]
  • Instantaneous Power (\(P\)): Power at a specific moment (as time interval → 0). \[P = \frac{dW}{dt} \tag{5.20}\]
  • Power with Force & Velocity: If force \(F\) acts on an object moving at velocity \(v\): \[P = F \cdot v \tag{5.21}\]

🔢 Units & Fun Facts

  • SI Unit: Watt (W), where 1 W = 1 J/s ⚡
  • Horsepower (hp): 1 hp = 746 W (used for cars 🚗, bikes 🏍️)
  • Kilowatt-hour (kWh): Energy unit! Example: A 100 W bulb 💡 running for 10 hours uses: \[100 \, \text{W} \times 10 \, \text{h} = 1 \, \text{kWh} = 3.6 \times 10^6 \, \text{J}\]

📚 Example: Elevator Power Calculation

An elevator (max load 1800 kg) moves up at 2 m/s. Friction opposes with 4000 N. Minimum motor power required?

  1. Total downward force = weight + friction \[F = mg + F_r = (1800 \times 10) + 4000 = 22000 \, \text{N}\]
  2. Power = Force × Velocity \[P = F \cdot v = 22000 \times 2 = 44000 \, \text{W}\]
  3. In horsepower: \[P = \frac{44000}{746} \approx 59 \, \text{hp}\]

💥 Collisions: Bounce, Crash, Conserve!

When objects collide (like billiard balls 🎱 or marbles), we study their motion using conservation laws.

🌟 Key Ideas

  • We focus on momentum conservation and energy conservation during collisions.
  • Typical setup: Mass \(m_1\) moves at initial speed \(v_{i1}\), hits stationary mass \(m_2\) (Fig. 5.10).
  • After collision, masses fly off in different directions. We can relate:
    • Masses (\(m_1\), \(m_2\))
    • Velocities (before & after)
    • Angles of motion

Note: “No loss of generality” if we assume \(m_2\) starts at rest – this simplifies problems!

🎯 NEET High-Yield Concepts

  1. Power formula \(P = F \cdot v\) (e.g., elevators, vehicles).
  2. Unit conversions: Watts (W) ↔ Horsepower (hp) ↔ kWh ↔ Joules (J).
  3. Collision setup: Conservation laws for momentum/energy when masses collide.
  4. Force balance: Calculating net force (like in elevator example: \(mg + F_r\)).
“`### Notes for Students: – **Power** is all about **speed of energy transfer** – like how fast a motor lifts an elevator! – **Collisions** use **conservation laws** to predict motion after objects crash. – **NEET Tip**: Practice unit conversions (W → hp → kWh) and force/power calculations – they’re super common! 💯 – Stay curious: Why do heavier objects need more power to move? 🤔