ΔV of battery. = ε - Ir or εmf = I(R+r) (for this particular series circuit) March 04, Emf and internal resistance. Emf and internal resistance

Similar documents
Power lines. Why do birds sitting on a high-voltage power line survive?

Agenda for Today. Elements of Physics II. Resistance Resistors Series Parallel Ohm s law Electric Circuits. Current Kirchoff s laws

1) Two lightbulbs, one rated 30 W at 120 V and another rated 40 W at 120 V, are arranged in two different circuits.

52 VOLTAGE, CURRENT, RESISTANCE, AND POWER

Clicker Session Currents, DC Circuits

Electric Charge. Electric Charge ( q ) unbalanced charges positive and negative charges. n Units Coulombs (C)

Copyright 2008 Pearson Education, Inc., publishing as Pearson Addison-Wesley.

Chapter 19. Electric Current, Resistance, and DC Circuit Analysis

1. A1, B3 2. A1, B2 3. A3, B2 4. A2, B2 5. A3, B3 6. A1, B1 7. A2, B1 8. A2, B3 9. A3, B1

physics 4/7/2016 Chapter 31 Lecture Chapter 31 Fundamentals of Circuits Chapter 31 Preview a strategic approach THIRD EDITION

Circuits. PHY2054: Chapter 18 1

Chapter 19 Lecture Notes

DC Circuits. Electromotive Force Resistor Circuits. Kirchoff s Rules. RC Circuits. Connections in parallel and series. Complex circuits made easy

PHY232 Spring 2008 Jon Pumplin (Original ppt courtesy of Remco Zegers) Direct current Circuits

AC vs. DC Circuits. Constant voltage circuits. The voltage from an outlet is alternating voltage

Chapter 28. Direct Current Circuits

Chapter 21 Electric Current and Direct- Current Circuits

Direct-Current Circuits. Physics 231 Lecture 6-1

Parallel Resistors (32.6)

Information for Makeup exam is posted on the course website.

ConcepTest PowerPoints

Physics 1402: Lecture 10 Today s Agenda

Physics 214 Spring

Capacitance. A different kind of capacitor: Work must be done to charge a capacitor. Capacitors in circuits. Capacitor connected to a battery

Parallel Resistors (32.6)

Physics 7B-1 (A/B) Professor Cebra. Winter 2010 Lecture 2. Simple Circuits. Slide 1 of 20

ELECTRIC CURRENT. Ions CHAPTER Electrons. ELECTRIC CURRENT and DIRECT-CURRENT CIRCUITS

Temperature coefficient of resistivity

Chapter 18 Electric Currents

Electron Theory of Charge. Electricity. 1. Matter is made of atoms. Refers to the generation of or the possession of electric charge.

Chapter 28 Direct Current Circuits

1 of 23. Boardworks Ltd Electrical Power

Physics Circuits: Series

Tactics Box 23.1 Using Kirchhoff's Loop Law

AP Physics C. Electric Circuits III.C

ConcepTest Clicker Questions. Chapter 26 Physics: for Scientists & Engineers with Modern Physics, 4th edition Giancoli

4 Electric circuits. Serial and parallel resistors V 3 V 2 V Serial connection of resistors:

Introduction. Pre-lab questions: Physics 1BL KIRCHOFF S RULES Winter 2010

Physics 2401 Summer 2, 2008 Exam II

2/25/2014. Circuits. Properties of a Current. Conservation of Current. Definition of a Current A. I A > I B > I C B. I B > I A C. I C D. I A E.

Chapter 18. Direct Current Circuits

1. How does a light bulb work?

Physics 2135 Exam 2 March 22, 2016

ENERGY AND TIME CONSTANTS IN RC CIRCUITS By: Iwana Loveu Student No Lab Section: 0003 Date: February 8, 2004

Physics Tutorial - Currents and Circuits

Electric Current & DC Circuits

Chapter 21 Electric Current and Circuits

This week. 3/23/2017 Physics 214 Summer

Physics 102: Lecture 05 Circuits and Ohm s Law

This week. 6/2/2015 Physics 214 Summer

PHYS 1102 EXAM - II. SECTION: (Circle one) 001 (TH 9:30 AM to 10:45AM) 002 (TH 3:30 PM to 4:45 PM) You have 1 hr 45 minutes to complete the test

Notes on Electricity (Circuits)

Circuit 3. Name Student ID

Coulomb s constant k = 9x10 9 N m 2 /C 2

Current and Resistance. February 12, 2014 Physics for Scientists & Engineers 2, Chapter 25 1

Lecture 11. Power in Electric Circuits, Kirchhoff s Rules

5. In parallel V 1 = V 2. Q 1 = C 1 V 1 and Q 2 = C 2 V 2 so Q 1 /Q 2 = C 1 /C 2 = 1.5 D

Physics 2135 Exam 2 October 18, 2016

in series Devices connected in series will have the same amount of charge deposited on each capacitor. But different potential difference. That means

Brian Blais Quick Homemade Guide to Circuits

Circuits. 1. The Schematic

POWER B. Terms: EMF, terminal voltage, internal resistance, load resistance. How to add up resistors in series and parallel: light bulb problems.

I depicted in Figure 1. When a current of I amps (A) flows through the resistor, a voltage drop V AB volts (V) appears across the terminals A and B.

PHYS 1444 Section 003 Lecture #12

Current. I = ei e = en e Av d. The current, which is Coulomb s per second, is simply

Electricity & Magnetism

Class 8. Resistivity and Resistance Circuits. Physics 106. Winter Press CTRL-L to view as a slide show. Class 8. Physics 106.

Chapter 17 Electric Current and Resistance Pearson Education, Inc.c

EXPERIMENT 12 OHM S LAW

Physics 1502: Lecture 9 Today s Agenda

Notes and Solved Problems for Common Exam 2

Lab 8 Simple Electric Circuits

ELECTRICITY. Electric Circuit. What do you already know about it? Do Smarty Demo 5/30/2010. Electric Current. Voltage? Resistance? Current?

Current and Resistance

4 pt. (in J) 3.A

Version 001 CIRCUITS holland (1290) 1

What is an Electric Current?

A Review of Circuitry

R R V I R. Conventional Current. Ohms Law V = IR

Chapter 16. Current and Drift Speed. Electric Current, cont. Current and Drift Speed, cont. Current and Drift Speed, final

Physics for Scientists & Engineers 2

PHYSICS 171. Experiment 3. Kirchhoff's Laws. Three resistors (Nominally: 1 Kilohm, 2 Kilohm, 3 Kilohm).

ELECTRIC CIRCUITS. Checklist. Exam Questions

Physics 2135 Exam 2 October 20, 2015

Chapter 28. Direct Current Circuits

Notes on Electricity (Circuits)

Review. Multiple Choice Identify the letter of the choice that best completes the statement or answers the question.

8. Electric circuit: The closed path along which electric current flows is called an electric circuit.

Greek Letter Omega Ω = Ohm (Volts per Ampere)

9. Which of the following is the correct relationship among power, current, and voltage?. a. P = I/V c. P = I x V b. V = P x I d.

Ohms Law. V = IR V = voltage in volts (aka potential difference) I = Current in amps R = resistance in ohms (Ω)

Chapter 25 Electric Currents and Resistance. Copyright 2009 Pearson Education, Inc.

Phys 2426: University Physics II

CHARGE AND ELECTRIC CURRENT:

Name... Class... Date...

POE Practice Test - Electricity, Power, & Energy

Al-Saudia Virtual Academy Pakistan Online Tuition Online Tutor Pakistan Electricity

Electric Current & DC Circuits How to Use this File Electric Current & DC Circuits Click on the topic to go to that section Circuits

CLUSTER LEVEL WORK SHOP

University of Maryland Department of Physics

Transcription:

Emf and internal resistance Emf and internal resistance ΔV of battery = ε - Ir or εmf = I(R+r) (for this particular series circuit) As the current in the circuit increases the voltage, supplied to the external circuit, by the battery goes down. Sources of electromotive force? Application temporary dimming of lights with large current draw

I total = 3.14 A March 04, 2013

I A Which Bulb is Brighter - Concepts I B What determines brightness? If all bulbs have the same resistance, order the bulbs in order of brightest to least bright? Can resistance of a bulb change? explain I D What happens to order of brightness if bulb B is removed? I C Will bulb D glow? why or why not? explain page 598

Adjustable or Variable Resistor in a circuit adjustable or variable resistor (dimmer switch) ΔV battery = 120 volts Variable resistor = R v Resistance of Light Bulb = 220 Ω Light Bulb - that emits light of varying brightness, due to the variable resistor (that limits current flow) What current would be required in the circuit to give the light bulb an output of 60 watts? What resistance would the variable resistor have to be? If the variable resistance doubled, what would happen to the current flow through the circuit? and the power output of the light bulb? (brightness) If I want to add a stereo to this circuit that required 120 volts all the time (even if I adjusted the variable resistor), how would I do it? explain? Adjustable or Variable Resistor in a circuit adjustable or variable resistor (dimmer switch) ΔV battery = 120 volts Variable resistor = R v Resistance of Light Bulb = 220 Ω Light Bulb - that emits light of varying brightness, due to the variable resistor (that limits current flow) What current would be required in the circuit to give the light bulb an output of 60 watts? p = I 2 R ( of light only) What resistance would the variable resistor have to be? find I V = IR eq, find R eq for full circuit, it is larger than 220, If the variable resistance doubled, what would happen to the current flow through the circuit? and the power output of the light bulb? (brightness) If I want to add a stereo to this circuit that required 120 volts all the time (even if I adjusted the variable resistor), how would I do it? explain?

Electrical Power and Mechanical Power P = W/Δt Rate at which work is done or energy is used, measured in watts (J/s) Power = Work/time Power can also be: P = F*v Work = F*d P = W/t = F*d/t or F*v Work is done in raising an elevator upward. The power consumption of the motor will be related to the rate at which work is done or, in this case, the rate at which the elevator is lifted. P = N*m/s or J/s or w (watt) Simple Resistor and Capacitor in Combination Circuits switch If ΔV = 10 volts, R= 5 ohms and C = 4 Farad What is charged stored on capacitor? (while the switch is closed) V R C What is the current through the resistor when the circuit is closed? What is the power of the bulb? (resistor) When the switch is opened R How long would the light bulb "run" with the energy stored in the capacitor at designed power rating of the light bulb? C What about this orientation? It is different than your initial logical thoughts.

Power Loss in high voltage lines March 04, 2013 17.34 (modified) A high-voltage transmission line with a resistance of 0.31Ω/km carries a current of 1000 A. The line is at a potential of 700kV at the power station and carries the current to a city located 160 km from the station. a. What is the power loss due to the resistance of the line? b. What total power is transmitted? c. What is the fraction of the transmitted power does this loss represent? fractional loss = power loss/ Power in d. What is the actual potential at the city (adjusting for loss)? e. If the distribution cost (cost related to this energy loss above) is.026396 dollars/ kwhr, how much would it cost to run this line for a month, (just for energy loss)? f. How much energy is lost (distribution costs) in transporting the energy each month in kwhr and Joules? 17.34 (with additional) Power Loss in high voltage lines A high-voltage transmission line with a resistance of 0.31Ω/km carries a current of 1000 A. The line is at a potential of 700kV at the power station and carries the current to a city located 160 km from the station. a. What is the power loss due to the resistance of the line? P = I 2 R = 49,500,000 watts b. What total power is transmitted? P = IV = 1000A * 700,000 Volts = 700,000,000 watts c. What is the fraction of the transmitted power does this loss represent? fractional loss = power loss/ Power in 50 MW/ 700 MW = 7.1 % (loss) d. What is the actual potential at the city (adjusting for loss)? current remains the same, energy per charge goes down P = IV, 650,000 W = 1000A *V, V = 650 kvolts e. If the distribution cost (cost related to this energy loss above) is.026396 dollars/ kwhr, how much would it cost to run this line for a month, (just for energy loss)?.026396 dollars/kwhr * 50,000 kw*24hr*30 days/month =.95 million dollars/month (lost) f. How much energy is lost (distribution costs) in transporting the energy each month in kwhr and Joules?

Kirchoff's Laws Junction rule demonstrates conservation of? The loop rule demonstrates conservation of?

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback