AC-DC Power Supplies And Currents
Power Supplies can be divided into two types for electronic devices, linear and switching power supplies. A switching mode power supply has the same rating as a Linear Power Supply but will be a lot more complex and usually Switching Mode Power Supplies are smaller. A Linear Power Supply is used for high current devices. They tend to be a lot bigger and bulkier than the Switching Mode Power Supply and a lot simpler in design.
Linear Power Supplies powered by AC tend to require the use of a transformer to convert the voltage from the mains outlet to a different voltage, this tends to be converted to a lower voltage. However a Rectifier is needed if it is used to produce DC, In addition a capacitor will be used smoothing the pulsating current from the rectifier. AC Power Frequency's relate the frequency the pulsations occur at (a multiple of 50Hz or 60Hz is a good example).
An unregulated power supply will produce a varying voltage depending on the variations and on the load of the AC Supply Voltage. A Linear Regulator will be used for critical electronics applications, the Linear Regulator will adjust and stabilise the voltage. When a Linear Regulator is used with a DC current it will greatly reduce the noise and ripple in the output of the current. They can also protect the Power Supply from overcurrent due to current limiting.
The AC supply in series with a single resistor and diode form the simplest DC Power Supply Circuit, these are very common in the use of rechargeable flashlights.
AC
AC stands for Alternating Current, in Alternating Current the flow of electric charge reverses direction periodically, for instant an AC Current will move forward the backwards over and over again repeating the cycle of movement.
Electricity that is delivered to Residences and Businesses is in the form of AC Electricity. A 'Sine Wave' is the usual waveform of an Ac Circuit; different waveforms can be used in different applications tho such as: Square Waves or Triangular Waves. Another example of an alternating current is electrical wires passing audio and radio signals.
DC
DC stands for Direct Current and this is the unidirectional flow of electric current. Batteries, Solar Cells and Thermocouples are a few examples of sources that produce Direct Current. Semiconductors, Vacuum (Ion or Electron), insulators and wires are examples of conductors that DC (Direct Current) can flow through. Direct Current was formally known as Galvanic Current.
By use of a Rectifier, a Direct Current can be obtained from an Alternating Current. The rectifier contains electromechanical elements that will only allow the current to flow in one direction.
Nearly all electronic Power Supply Systems used Direct Current, it is also the current used to charge batteries. Electrochemical processes and the production of aluminium use very large amounts of direct current power supply, railway propulsion also requires a DC Current.
AC DC Power Supply is a very important source of power in the world we live in and many applications require them.
Daniel Owen writes about AC-DC power Supplies. To know more about AC-DC power Supplies, visit http://www.businessmagnet.co.uk
Article Source: ArticlesBase.com
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Fundamentals of Engineering Examination Elegibility?
I'm currently pursuing a degree relating to Electronics Engineering Technology and wish to someday take the FE exam followed by the PE exam. I'm currently Active Duty AF PMEL (calibration technician) and wish to continue with this career field. What I don't know is if the degree plan I wish to pursue will be enough to let me take the FE exam. The link to the degree plan is Thomas Edison State College: Electronics Engineering Technology. If the link doesn't work, I've copied the degree requirements below. Any help would be great. This degree is not ABET accredited and I am a Georgia resident (could also switch to NJ as I'm currently stationed in NJ).
Thanks,
Jason
BSAST in Electronics Engineering Technology
The Bachelor of Science in Applied Science and Technology (BSAST) degree in Electronics Engineering Technology is designed for technologists employed in various phases of the electronics industry, including computer hardware, avionics and communications. Required courses include DC Circuits, AC Circuits, Digital Electronics, Microprocessors, Control Systems, Electronic Devices, Communications Electronics and Engineering Graphics. Corollary requirements are Physics I and II, Calculus I and II, and Computer Programming. The degree is a 120-credit program.
Subject Area/Category Credits
I. General Education Requirements 60
A. English Composition 6
B. Humanities 12
Technical Report Writing
(3)
Humanities Electives*
(9)
C. Social Sciences 12
Psychology or Sociology
(3)
Social Science Electives*
(9)
D. Natural Sciences and Mathematics 21
Calculus I & II
(6)
Statistics
(3)
General Physics
(6)
Second Science
(3)
Computer Programming
(3)
E. General Education Electives 9
II. Area of Study: Electronics Engineering Technology 42
A. Electric Circuits
Direct Current (DC) Circuits
Alternating (AC) Circuits
6
B. Electrical Devices
Solid State Theory/ Semiconductor Devices
Integrated Circuits/ Electronic Circuits
6
C. Digital Electronics 3
D. Microprocessors 3
E. Communications Electronics
Communication Systems/Receivers and Transmitters
3
F. Control Systems 3
G. Electronics Engineering Technology Electives
Industrial Electronics
Instrumentation or Electronic Tests and Measurements
Advanced Digital Circuits
Computer Architecture or Logic and Automata
Instrumentation and Control/Robotics
Radar/Microwaves/Avionics
Data Communication/Telecommunication
Drafting and CAD
Radio and TV/Radar and Navigation Systems
Electrical Machines/Electronics Lab
Motor Controls/Electrical Networks
Biomedical Electronics/Power Generation and Transmission
Fiber Optics/Laser Electro-Optic Devices
21
III. Current Trends and Applications 3
IV. Free Electives 15
Total 120
*Must include at least two subject areas.
Note: Courses listed in the Area of Study are offered as a guide. Other courses may also be considered appropriate for the program. The inclusion of similar courses must be reviewed by the Evaluation team. Students must submit their program plan for review to ensure that course selection is appropriate for the degree.
Learner Designed Area of Study (LDAS)
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In the simple AC circuit?
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dlta vR = 0.250 dlta Vmax
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Please show work! Thanks!!
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Two capacitors are connected to an AC source as shown in the figure. Assume VAC = Vmax sin(2pi f t), with Vmax = 20 V and f = 2948 Hz.
The capacitors in the figure are in series with values C1=1.0 uF and C2=2.0 uF.
What is the amplitude (peak value) of the current through the capacitors? _____ A
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a car charger is powered by 230v ac mains and charger get 5.4A rms current with 40% second harmonic current.Charger is powered through a 10 ohm series resistor
1)input power taken from supply
2)power supplied to the charger
3)second harmonic voltage
4)power factor
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