Presentation is loading. Please wait.

Presentation is loading. Please wait.

Electrical Current Electrical current (measured in amps) is the rate of flow of charge. Electrical current is a flow of electric charge through a medium.

Published byMoris Nichols Modified over 8 years ago

Similar presentations

Presentation on theme: "Electrical Current Electrical current (measured in amps) is the rate of flow of charge. Electrical current is a flow of electric charge through a medium."— Presentation transcript:

1 Electrical Current Electrical current (measured in amps) is the rate of flow of charge. Electrical current is a flow of electric charge through a medium. This charge is typically carried by moving electrons in a conductor such as wire, or… It can also be carried by ions in an electrolyte, or by both ions and electrons in plasma.

2 What is 1 ampere? (a.k.a. 1 amp?) It is 1 coulomb of charge passing through a wire cross-section over 1 second. How many electrons? It is about 6.2x10 18 electrons passing a cross-section during one second Current I=Q/t 1 A = 1 C/s The unit is the ampere (A). Current I=Q/t 1 A = 1 C/s The unit is the ampere (A).

3 Electrical Current Electrical current in amps is the rate of flow of charge. Conventional d.c. current flows out of the positive terminal of a battery, around a circuit, and into the negative terminal. In metals, the charge carriers are electrons, which move in the opposite direction.

4 Modelling current (using people!) This shows: Purpose of current is to move energy from a supply to a user Current keeps going. Current is NOT used up in components.

5 Electrical Current Current is measured using an ammeter - a device used in series that does not impede current flow but which has a deflection proportional to current. Current I=Q/t The unit is the ampere (A). 1 A = 1 C/s Current I=Q/t The unit is the ampere (A). 1 A = 1 C/s

6 Quick experiment Prove to yourself that current in a loop circuit is the same everywhere.

7 Potential Difference Potential difference (p.d.) in volts is the “driving force” that makes current flow around a circuit. Quite similar to a gravitational potential difference of a waterfall Potential difference is V. The units is the volt (V). 1 V=1 J/C Potential difference is V. The units is the volt (V). 1 V=1 J/C

8 Potential Difference It is the energy delivered to the components of the circuit per unit charge.

9 Potential Difference It is the energy delivered to the circuit per unit charge. Often called “voltage”. The voltage generated by the chemical reactions in a battery is called the electromotive force (e.m.f.).

10 Potential Difference Potential difference is measured using a voltmeter, which goes in parallel with the circuit. V Potential difference has symbol V. The units are volts (V). 1 V=1 J/C V = W/Q Potential difference has symbol V. The units are volts (V). 1 V=1 J/C V = W/Q

11 Visual models of pd and emf: (1) A simple circuit

12 Visual models of pd and emf: (2) A series circuit

13 Visual models of pd and emf: (3) A parallel circuit

14 Visual models of pd and emf: (4) A more complex circuit

15 Sketch these! Then try Q1

16 Electrical Resistance All conductors offer resistance to the flow of electrical current. Symbol - In electric circuits resistors is usually shown as:

17 Electrical Resistance An electrical component specifically made to limit current is called a resistor. Resistance is the pd required for unit current to flow. If V is proportional to I, R is constant: Ohms law.

18 Electrical Power How to estimate how much electrical power was used or delivered? We know the voltage supplied and the current used. What about power?

19 Electrical Power Electrical power is the energy delivered per unit time in a circuit. The power is the voltage times the current. The unit is the watt, W. 1 W = 1 J/s. Power P=VI Example: The iron uses 8 A. What is its power? Since the standard voltage supply is 240V, then the iron’s power is 8A x 240V = 1920W (Almost 2kW).

20 Electrical Power Using equation P=VI and Ohm’s law I=V/R lets express power in several different forms. P=IV=(V/R)V=V 2 /R Lets rearrange Ohm’s law as V=IR P=IV=I(IR)=I 2 R Power, P=VI =I 2 R=V 2 /R The unit is the watt (W). Power, P=VI =I 2 R=V 2 /R The unit is the watt (W). I=V/R V=IR

21 Electrical Power In a resistor, the power delivered manifests itself as heating caused by electrons colliding with atoms and giving them energy. Power, P=VI =I 2 R=V 2 /R The unit is the watt (W). Power, P=VI =I 2 R=V 2 /R The unit is the watt (W). Why do we have huge energy release in short circuit? If voltage is fixed then the power is inversely proportional to the resistance: P=V 2 /R.

22 Electrical Power Electrical power is the energy delivered per unit time in a circuit. The power is the voltage times the current. The unit is the watt, W. 1 W = 1 J/s. Power P=VI Since V=IR then the power is P=I 2 R=V 2 /R. In a resistor, the power delivered manifests itself as heating caused by electrons colliding with atoms and giving them energy. Power, P=VI =I 2 R=V 2 /R The unit is the watt (W). Power, P=VI =I 2 R=V 2 /R The unit is the watt (W).

23 Try Qs 2, 3 and 4

24 Resistance and resistivity Resistance R is a property of a particular resistor. Resistivity  is a property of material of which the resistor is made. We can write: R=  L/A  is the resistivity in  m A cross-sectional area, L length

25 Resistance and Resistivity The unit of resistance is the ohm (  ). What is the unit of resistivity? Let’s rearrange R=  L/A as   =R A/L.  A is the cross sectional area, thus, it is measured in m 2. L is the resistor length, thus, it is measured in m.  Thus, the unit A/L is m, while the resistance unit is ohm.  Thus, the resistivity units are ohm m. (Ωm)

26 Resistance and Resistivity All conductors offer resistance to the flow of electrical current. R=  L/A  is the resistivity in  m A cross-sectional area, L length The unit of resistance is the ohm (  ). An electrical component specifically made to limit current is called a resistor. The current that a potential difference drives through a resistor is given by I=V/R –ohms law.

Download ppt "Electrical Current Electrical current (measured in amps) is the rate of flow of charge. Electrical current is a flow of electric charge through a medium."

Similar presentations

Current Electricity & Ohm's Law.

Current Electricity & Ohm's Law.
Electric currents Chapter 18. Electric Battery Made of two or more plates or rods called electrodes. – Electrodes are made of dissimilar metals Electrodes.

Electric currents Chapter 18. Electric Battery Made of two or more plates or rods called electrodes. – Electrodes are made of dissimilar metals Electrodes.
Electricity Technical Stuff. Electric Field An uneven distribution of charge produces an “ Electric Field” We can deduce this by an electric potential.

Electricity Technical Stuff. Electric Field An uneven distribution of charge produces an “ Electric Field” We can deduce this by an electric potential.
Ohm’s Law Objective: TSW understand the concepts of Voltage, Current, and Resistance by developing and applying Ohm’s Law.

Ohm’s Law Objective: TSW understand the concepts of Voltage, Current, and Resistance by developing and applying Ohm’s Law.
What do you already know about it?

What do you already know about it?
Electric Circuits AP Physics 1.

Electric Circuits AP Physics 1.
CLASS :- X MADE BY :- MANAS MAHAJAN

CLASS :- X MADE BY :- MANAS MAHAJAN
Concept Summary Batesville High School Physics. Potential Difference  Charges can “lose” potential energy by moving from a location at high potential.

Concept Summary Batesville High School Physics. Potential Difference  Charges can “lose” potential energy by moving from a location at high potential.
Current and Resistance

Current and Resistance
Current and Circuits. Current current: the flow of charged particles. E Current is measured in Amperes (A) which is made of the unit of a Coulomb/sec.

Current and Circuits. Current current: the flow of charged particles. E Current is measured in Amperes (A) which is made of the unit of a Coulomb/sec.
C H A P T E R 20 Electric Circuits

C H A P T E R 20 Electric Circuits
Electricty. Object gain or lose electrons to become charged. Opposite charge attract likes repel. Any charge will attract a neutral object. When touching.

Electricty. Object gain or lose electrons to become charged. Opposite charge attract likes repel. Any charge will attract a neutral object. When touching.
Current Electricity.

Current Electricity.
Unit 3 Day 1: Voltage, Current, Resistance & Ohm’s Law Batteries Electric Current Conventional Current Resistance Resistors Energy Dissipated in a Resistor.

Unit 3 Day 1: Voltage, Current, Resistance & Ohm’s Law Batteries Electric Current Conventional Current Resistance Resistors Energy Dissipated in a Resistor.
Chapter 22 Current Electricity.

Chapter 22 Current Electricity.
Ohms Law V = IRV = IR V = voltage in volts (aka potential difference)V = voltage in volts (aka potential difference) I = Current in ampsI = Current in.

Ohms Law V = IRV = IR V = voltage in volts (aka potential difference)V = voltage in volts (aka potential difference) I = Current in ampsI = Current in.
Lecture Outline Chapter 21 Physics, 4th Edition James S. Walker

Lecture Outline Chapter 21 Physics, 4th Edition James S. Walker
Circuits Electric Circuit: a closed path along which charged particles move Electric Current: the rate at which a charge passes a given point in a circuit.

Circuits Electric Circuit: a closed path along which charged particles move Electric Current: the rate at which a charge passes a given point in a circuit.
Solve for Z ABCDE HKMNP STVX WYZ =. Chapter 22 Current Electricity.

Solve for Z ABCDE HKMNP STVX WYZ =. Chapter 22 Current Electricity.
ELECTRIC CIRCUITS. Electric Circuits What is an electric circuit? SO EASY! A circuit is a loop of wire with its ends connected to an energy source such.

ELECTRIC CIRCUITS. Electric Circuits What is an electric circuit? SO EASY! A circuit is a loop of wire with its ends connected to an energy source such.

Similar presentations

Ads by Google