A brownout is a drop in the magnitude of voltage in an electrical power system.
Unintentional brownouts can be caused by excessive electricity demand, severe weather events, or a malfunction or error affecting electrical grid control or monitoring systems.[1][2] Intentional brownouts are used for load reduction in an emergency, or to prevent a total grid power outage due to high demand.[3] The term brownout comes from the dimming of incandescent lighting when voltage reduces.
In some countries, the term brownout refers not to a drop in voltage but to an intentional or unintentional power outage (or blackout).[4][5][6]
YouTube Encyclopedic
-
1/5Views:7 578 2801 395 7561 2145 0534 983 023
-
Awesome Disconnector Switching with ❙ Electric Arc (ep-1)
-
I Applied HIGH VOLTAGE to Electric Toys! #6 (DANGEROUS)
-
Power Outage Preparedness: What to Unplug | Mr. Electric
-
Using my electric vehicle to power the house in a blackout
-
120V 240V Electricity explained - Split phase 3 wire electrician
Transcription
Effects
Different types of electrical apparatus will react in different ways to a voltage reduction. Some devices will be severely affected, while others may not be affected at all.
Resistive loads
The heat output of any resistive device, such as an electric space heater, is equal to the power consumption, which is directly proportional to the square of the applied voltage if the resistance stays constant. Therefore, a significant reduction of heat output will occur with a relatively small reduction in voltage. An incandescent lamp will dim due to lower heat creation in the filament, as well as lower conversion of heat to light. Generally speaking, no damage will occur but functionality will be impaired.
Motors
Commutated electric motors, such as universal motors, will run at reduced speed or reduced torque. Depending on the motor design, no harm may occur. However, under load, the motor may draw more current due to the reduced back-EMF developed at the lower armature speed. Unless the motor has ample cooling capacity, it may eventually overheat and burn out.
An induction motor will draw more current to compensate for the decreased voltage, which may lead to overheating and burnout. If a substantial part of a grid's load is electric motors, reducing voltage may not actually reduce load and can result in damage to customers' equipment.
Power supplies
An unregulated DC supply will produce a lower output voltage. The output voltage ripple will decrease in line with the usually reduced load current. In a cathode-ray tube television, the reduced output voltage will make the screen image smaller, dimmer and fuzzier.
A linear DC regulated supply will maintain the output voltage unless the brownout is severe and the input voltage drops below the drop out voltage for the regulator, at which point the output voltage will fall and high levels of ripple from the rectifier/reservoir capacitor will appear on the output.
A switched-mode power supply will be affected if the brownout voltage is lower than the minimum input voltage of the power supply. As the input voltage falls, the current draw will increase to maintain the same output voltage and current, until such a point that the power supply malfunctions or its under-voltage protection kicks in and disables the output.
Digital systems
Brownouts can cause unexpected behavior in systems with digital control circuits. Reduced voltages can bring control signals below the threshold at which logic circuits can reliably detect which state is being represented. As the voltage returns to normal levels the logic can latch at an incorrect state; to the extent that even 'can't happen' states become possible. The seriousness of this effect and whether steps need to be taken by the designer to prevent it depends on the nature of the equipment being controlled; for instance, a brownout may cause a motor to begin running backwards.[citation needed]
See also
References
- ^ Añel, Juan; Fernández-González, Manuel; Labandeira, Xavier; López-Otero, Xiral; de la Torre, Laura (October 27, 2017). "Impact of Cold Waves and Heat Waves on the Energy Production Sector". Atmosphere. 8 (12): 209. Bibcode:2017Atmos...8..209A. doi:10.3390/atmos8110209. hdl:1814/59695. ISSN 2073-4433.
- ^ Wyatt, Alan (1986). Electric Power: Challenges and Choices. Toronto: The Book Press Limited. p. 63. ISBN 0-920650-00-7.
- ^ Blume, Steven Warren (2007). Electric Power System Basics: For the Nonelectrical Professional. Hoboken, N.J.: John Wiley & Sons. p. 199. ISBN 978-0-470-12987-6.
- ^ "Beijing 'Brown-out' to Save Power". BBC News. July 22, 2004.
- ^ Burgos, Nestor P. Jr. (November 7, 2010). "Iloilo Power Firms Asked to Explain Brownouts". Philippine Daily Inquirer. Archived from the original on June 5, 2013. Retrieved June 21, 2012.
Both Peco and PPC were asked to submit their explanations on the power interruptions being investigated by Gerochi's committee.
- ^ Baxendale, Rachel (January 26, 2019). "Heatwave: AEMO Hits Go on Emergency Energy Supply Measures as Victoria Swelters". The Australian. Retrieved January 30, 2019.
| Authority control databases: National |
|---|
This page was last edited on 3 April 2024, at 20:44