Active fire protection
Fire alarm control panel
A smoke detector or smoke alarm is a device that detects smoke and issues an alarm to alert nearby people that there is a potential fire. A household smoke detector will typically be mounted in a disk shaped plastic enclosure about 150 millimeter (mm) in diameter and 25mm thick, but the shape can vary by manufacturer.
Being an important aspect for fire safety, smoke detectors have been a major life saving device by alerting people to the danger of fire.
Most smoke detectors work either by optical detection or by ionization, but some of them use both detection methods to increase sensitivity to smoke. Smoke detectors may operate alone, be interconnected to cause all detectors in an area to sound an alarm if one is triggered, or be integrated into a fire alarm or security system. Smoke detectors with flashing lights are available for the deaf or hearing impaired. A smoke detector cannot detect carbon monoxide to prevent carbon monoxide poisoning unless it has an integrated carbon monoxide detector.
In 1902 George Andrew Darby, an electrical engineer of 211 Bloomsbury Street, Birmingham, England, patented the electrical Heat-Indicator and Fire Alarm. The device was a heat detector rather than a smoke detector and indicated an increase temperature in the apartment where it was fixed. The device operated by closing an electrical circuit to sound an alarm if the temperature rose above the safe limit. The contact was made by bridging a gap with a conductor, or allowing one plate to fall on another. The connection of the two plates was caused simply by a block of butter which melted as the temperature rose. This early device subsequently gave way to more modern fire and eventually smoke alarms.
An optical detector is a light sensor. When used as a smoke detector it includes a light source (infra-red LED), a lens to collimate the light into a beam, and a photodiode or other photoelectric sensor at right-angles to the beam as a light detector. In the absence of smoke, the light passes in front of the detector in a straight line. When smoke enters the optical chamber into the path of the light beam, some light is scattered by the smoke particles, and some of the scattered light is detected by the sensor. An increased input of light into the sensor sets off the alarm.
Another type of optical detector works by using a straight line infra-red beam from the sender to the receiver. When smoke enters the beam, some light is scattered which results in less light detected by the receiver. A decreased input of light into the receiver sets off the alarm.
Also seen in large rooms, such as gymnasia and auditoria, are projected beam detectors. A unit on the wall sends out a beam, which is either received by a receiver, or reflected back via a mirror. When the beam is less visible to the "eye" of the sensor, it sends an alarm signal to the Fire alarm control panel.
Optical smoke detectors are quick in detecting slow burning, smoky fires. They are less sensitive to false alarming from cooking and bathroom steam than are ionization smoke alarms.
This type of detector is cheaper than the optical detector, however it is sometimes rejected for environmental reasons. It can detect particles of smoke that are too small to be visible. It includes a tiny mass of radioactive americium-241, which is a source of alpha radiation. The radiation passes through an ionization chamber, which is an air-filled space between two electrodes, and permits a small, constant current to flow between the electrodes. Any smoke that enters the chamber absorbs the alpha particles, which reduces the ionization and interrupts this flow of current, setting off the alarm.
Also known as ultra violet flame detectors, this type is used to stop smokers from lighting cigarettes in designated non-smoking areas such as restrooms. It works by sensing UV light, so it is triggered immediately when a flame is lit. This is different from a conventional smoke detector which is triggered by sufficient levels of airborne smoke.
In the early 1990s Texas A&M University did a full scale scientific investigation into the effectiveness of optical and ionization smoke detectors in different types of fires. The study determined that in a smoldering fire, with its relatively low number of large smoke particles, optical detectors fail 4.06 percent of the time, while ionization detectors have a 55.8 percent failure rate. For flame ignition fires, which have a large number of small, energetic smoke particles, ionization smoke detectors had a 19.8 percent probability of failure while optical smoke detectors have a 3.99 percent failure rate.
In 2004, NIST issued a comprehensive report on the efficacy of home smoke alarms. The report concluded, among other things, that "smoke alarms of either the ionization type or the photoelectric type consistently provided time for occupants to escape from most residential fires," and '"consistent with prior findings, ionization type alarms provided somewhat better response to flaming fires than photoelectric alarms, and photoelectric alarms provided (often) considerably faster response to smoldering fires than ionization type alarms."
Smoke detectors are usually powered by one or more batteries but some can be connected directly to household wiring. Often the smoke detectors that are directly connected to household wiring also have a battery as a power supply backup in case the household wiring goes out. It is usually necessary to replace the batteries once a year to ensure appropriate protection.
Most residential smoke detectors run on 9 volt alkaline batteries. If these batteries run out, the smoke detector will become inactive. Most smoke detectors should signal a low battery condition, but it is common for houses to have smoke detectors with dead batteries. As a result, public information campaigns have been created to remind people to change their smoke detector batteries regularly. In regions using daylight saving time, these campaigns usually suggest that people change their batteries when they change their clocks. Another option is to change batteries on a birthday.
Some detectors are also being sold with a lithium battery that can run for about 7 to 10 years, though this might actually make it less likely for people to change batteries since their replacement is needed so infrequently. By that time, the whole detector should be replaced. Though relatively expensive, user-replaceable 9 volt lithium batteries (in the same configuration as the common alkaline ones) are also available. They should only be used in a fairly new detector.
Smoke detectors with missing batteries are also a concern. As a result, many detectors sold today are designed to provide a visual indication of a missing battery. One popular brand of smoke detector will not allow the user to close the battery door until a battery has been placed in the alarm; another contains a spring-loaded protrusion obstructing the attachment holes when the battery is missing, preventing reattachment to the wall or ceiling and making a missing battery situation immediately obvious. Some local governments do not permit the installation of smoke detectors with removable batteries.
In new construction, most building codes today require smoke detectors that are wired to the main electricity flow of buildings. Many of these units also include a battery backup to ensure operation during a power outage.
Rechargeable batteries should never be used in smoke detectors, since common NiMH and NiCd rechargeable batteries have a short life in between charges—in other words, they self-discharge relatively quickly. This is true even though they may provide much more power than alkaline batteries if used soon after charging. Also, a problem particularly prevalent in older technology rechargables is a rapid voltage drop at the end of their useful charge. This is concerning in devices like smoke detectors since the battery may transition from "charged" to "dead" so quickly that the low battery warning from the detector is either very brief, or may not occur at all.
A quality alkaline battery should be installed and replaced every six months or so. The used battery will still probably have the majority of its charge, and can be reused in less critical applications such as a backup for a digital alarm clock. For those living in areas that observe daylight saving time, one handy way to remember this important maintenance event is to replace your smoke detector batteries the same day you adjust your clocks for the new season.
The alarm may chirp at intervals if the battery is low, though if there is more than one unit within earshot, it can be hard to locate.
Virtually all modern smoke alarm units come equipped with a "test" button. Alternatively, artificial smoke can be purchased, which has the advantage of also testing the detection mechanism itself. Many people simply wave a lit match underneath the detector to test it, however this is dangerous as it can set the smoke alarm and the rest of the house on fire. A better way is to blow out a match or candle and wave the smoke under the detector.
The National Fire Protection Association, through its fire protection program, urges homeowners to replace smoke detector batteries every six months when changing your clock for Daylight saving time, and to replace the entire smoke detector after ten years of use.
Installation and placement
In the United States, most state and local laws regarding the required number and placement of smoke detectors are based upon standards established in Article 72 of National Fire Protection Association (NFPA) fire code.
Laws governing the installation of smoke detectors vary depending on the locality. Homeowners with questions or concerns regarding smoke detector placement are encouraged to contact their local fire marshal or building inspector for assistance. However, there are some rules and guidelines that are relatively consistent throughout the country. In older existing homes, smoke detectors are generally required on every habitable level and within the vicinity of all bedrooms. Habitable levels include attics that are tall enough to allow access. In new construction, the minimum requirements are typically much greater. All smoke detectors must be hooked directly to the electrical wiring, be interconnected and have a battery backup. In addition, smoke detectors are required either inside or outside every bedroom, depending on local codes. Smoke detectors on the outside will detect fires more quickly, assuming the fire does not begin in the bedroom, but the sound of the alarm will be reduced and may not wake some people. Some areas also require smoke detectors in stairways, main hallways and garages.
Because smoke rises, most detectors are mounted on the ceiling or on a wall near the ceiling. To avoid the nuisance of false alarms, most smoke detectors are mounted away from kitchens. To increase the chances of waking sleeping occupants, most homes have at least one smoke detector near any bedrooms; ideally in a hallway as well as in the bedroom itself.
Detectors on the ceiling should be placed several inches away from any wall. If the ceiling is not flat, the detector should be placed at or near the highest point. If the highest point is a small recess, then the detector should be placed at the next highest level. Detectors placed on the wall should be several inches, but no more than a foot, from the top. Detectors should not be placed on a wall if the ceiling has a deep recess or if the ceiling slopes steeply or for a long distance. Detectors should be several horizontal feet away from a heating or cooling register, window, corner, the edge of a ceiling fan's sweep and doors to a kitchen or bathroom. They should be placed as far as possible away from combustion sources, like oil and gas-fired furnaces, space heaters, clothes dryers and water heaters, without compromising coverage or safety. Smoke detectors in a basement should be placed at the bottom of the stairs and an additional detector should be placed in or near sleeping areas in the basement.
It is recommended, and sometimes required, that smoke detectors not be placed in kitchens because the small amounts of smoke and particulates generated while cooking can set them off. Detectors designed for use near a kitchen may have a silence button to cancel accidental triggering.
Detectors should not be placed in a bathroom or near a bathroom door because moisture may cause false alarms or damage the detector. False alarms reduce the effectiveness of smoke detectors in preventing harm and property damage because people soon begin to assume that the alarm is false. Heat detectors, which sound an alarm when the temperature reaches a certain point and/or when it climbs more rapidly than a certain rate, can be used in kitchens, garages and areas with combustion sources that would otherwise generate nuisance alarms.
Canada requires a building to have a working smoke detector on every level.
- Carole Ellis, About Cigarette Smoke Detectors Retrieved July 19, 2019.
- Skip Walker, Silent Alarms; Deadly Differences ASHI Reporter, June 2013. Retrieved July 19, 2019.
- Larry Grosse, The Results in Layman's Terms August 13, 1997. Retrieved July 19, 2019.
- NIST, Home Smoke Alarm Tests Retrieved July 19, 2019.
- Air Force Inst of Tech Wright. Application of Smoke Detector Technology to Minimize Smoke Exposures to Wildland Firefighters. Washington, DC: Storming Media, 2001. ISBN 1423528360.
- Journal of Applied Fire Science, Volume 6, Number 2, June 1997. Risk Analysis of Residential Fire Detector Performance.
- Langston, John M. Smoke detectors: Wake up! get out! and live!. Fayettevill, AR: Cooperative Extension Service, University of Arkansas, U.S. Dept. of Agriculture, and county governments cooperating, 1993. ASIN B0006P31HI
- United States Dept of Interior. In-Mine Evaluation of Smoke Detectors. Washington, DC: United States Dept of Interior, 1992. ISBN 9992467967
All links retrieved November 16, 2019.
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