Fire Protection and Prevention
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Transcript Fire Protection and Prevention
Fire Protection and Prevention
Fire Protection and Prevention
Fire protection includes procedures for
preventing, detecting, and extinguishing fire.
The procedures in these three areas of fire
prevention aim to protect employees and
property and to assure the continuity of a plant’s
operations.
To accomplish these goals, it is necessary to
develop a plant wide fire protection program:
FACILITY FIRE PROTECTION
PROGRAM
The
primary purpose of such a program is
to prevent fires from starting.
If,
a fire starts, employees should know
their role in the following procedures:
immediately detecting the fire and promptly
transmitting an alarm
initiating evacuation of the building
confining the fire
extinguishing the fire
Objectives of a Fire Protection
Program
When planning a fire protection program, first make a
statement of objectives for fire safety. When designing
the plant’s building and laying out its operations, include
greater measures of fire safety.
Architects and engineers must realize that designing for
fire protection is a legitimate part of their responsibilities.
They must understand
the special thermal load that fire puts on structural
plans of buildings, and
the preventive measures that can be included into
their design.
Some general facts about fire protection
No facility is absolutely fireproof. Nearly everything can burn, by given
ignition, adequate fuel, and sufficient Oxygen.
Fire and flame will spread in a building both vertically and horizontally
The spread of the heat, smoke, and toxic gases is possibly the greatest
single danger to life and takes place in much the same manner as does the
spread of fire.
Smoke and toxic gases are responsible for 66% of deaths from fire in
buildings.
On-site early detection of a fire is absolutely essential.
The use of a building—its occupancy—will influence the degree of fire
hazards. The more hazardous the – materials handled in a plant area are,
the more likely is the chance for a – fire to start and rapidly spread.
The contents of a building are usually a more important factor in the start
of a fire than the physical structure of the building.
Very often only a few minutes pass between the beginning of combustion
and the development of a destructive fire
What happens, or does not happen, in the first few minutes of a fire
determines whether it can be controlled or not.
Fire Protection Engineering
Fire protection engineering is a highly developed
specialized field. The solution of many fire protection
problems requires the special training and perspective of
an experienced fire protection engineer.
Achieving the most efficient fire protection system requires
the involvement of the architect, interior designer, urban
planner, building contractor, electrical and structural
engineers, fire detection system manufacturers, building
safety engineer, and local fire marshal.
Fire Drills
Fire drills, conducted at frequent intervals, demonstrate
management’s concern and sincere interest in all fire prevention
activities. The drills should serve as a reminder to employees and
supervisors that all fire prevention practices are important.
Prepare an emergency manual to outline procedures and drills and
to assign responsibilities to each individual involved. Make
prevention of personal injury and lost of life the main objective of
emergency planning.
Carefully plan and periodically carry out fire drills. Conduct them in a
serious manner under rigid discipline. To eliminate panic in the
event of an emergency and guarantee the smooth functioning of the
emergency plan, carefully develop the plan.
Post up to date instruction sheets, including evacuation routes, and
distribute them to all employees. In addition, when going through fire
drills, from time to time, block off an exit to see how employees
would react to this situation in a real fire.
Fire brigades
Management cannot depend on automatic fire protection
equipment, municipal fire departments to prevent fire
losses. Fires can get out of control before municipal fire
department arrives.
One method of providing additional fire protection is to
form a fire brigade. Brigade members should be regular
plant employees from all departments, thoroughly trained
in using the plant’s fire fighting equipment.
Electricians, engineers, mechanics, and safety and fire
inspectors all have special skills, thus making them
valuable members of the plant’s emergency team.
FIRE PREVENTION ACTIVITIES
As a first step, all companies and plants should hold design
review meetings for all new construction, as well as for
changes in existing construction.
Every establishment should institute procedures and
regulations to assure that proper fire-extinguishing equipment
is on hand and those employees are organized and trained to
use the equipment correctly.
Regularly schedule thorough inspections of all fire protection
equipment. Keep a written record of these inspections.
Fire prevention includes activities directed specifically toward
preventing a fire from starting.
Generally, these activities include inspections, fire drills,
training fire brigades, and a good communication system.
Inspections
Set up a system of periodic fire inspections for every operation. Some buildings,
operations, and processes require daily inspection, while others can be inspected weekly,
monthly, or at other intervals.
Buildings that are well designed and provided with protective devices and construction
elements intended to act as fire safety features still need a periodic, detailed inspection
program.
In some establishments or plants, the safety and health committee locates and reports fire
hazards.
In large plants, this job is handled by a special subcommittee of the safety committee or by
a person trained to manage fire risk.
The inspector, fire chief, or other individual from the plant who is in charge of fire
prevention and fire protection should establish inspection schedules, determine the
direction-finding of reports, and have a complete list of all items to be inspected.
Inspection of fire equipment should cover the following items:
control valves on piping that supplies water for fire protection
hydrants
fire pumps
hose houses and associated equipment
sprinkler system water supplies including tanks
automatic sprinkler systems
special type of protection
portable fire extinguishers
fire doors, exits and aisles
alarm and communication systems and routines
communication to fire department
Protecting Adjacent Buildings
When a fire breaks out in a building, protect adjacent buildings by (1) closing every window facing the
burning building. (2) stationing fire brigade workers with fire extinguishers or fire hoses at each window
nearest the fire, and (3) stationing fire fighters on the exposed building’s roof with hose lines to keep the roof
wetted down and with extinguishers to put out any burning embers.
Training Employees
Because extinguishers are effective only when fires are in their first stages, ensure that extinguishers are
immediately reachable and promptly used by trained personnel.
Extinguishers are only as good as the operators using them. Therefore, thoroughly train key workers on
each shift. Fire extinguisher training is intended to teach employees how to stop small fires from spreading
out of control.
Use demonstrations to instruct employees in the use of extinguishers. At the demonstrations, simulate fire
conditions.
Have an instructor explain the fundamentals of fire fighting and the use of the equipment. Allow employees
to get the “feel” of the extinguisher in small organizations, have everyone in the plant attend and participate
in the demonstrations.
In large plants, train a suitable number of employees so that personnel trained in fire fighting are distributed
throughout the plant.
One of the most difficult decisions any employee faces is whether to fight a fire or to get out safely.
If the following conditions are met, an employee might decide to fight a fire with an extinguisher: (1) there is
a clear exit, (2) the fire brigade or department has already been called, (3) the fire is small, (4) the employee
knows how to use the extinguisher, and (5) the extinguisher is in working order.
An employee should-not fight a fire if (1) the fire is clearly spreading beyond its point of origin, (2) the fire
could block the exit, or (3) the employee is unsure of how to use the extinguisher.
Continue the training of employees with demonstrations, practice drills, and lectures at yearly interval or
more often if a special fire hazard exists. Be sure that employees have printed instructions regarding the use
of fire extinguishers.
Communications
Once a fire has been detected, especially in a potentially disastrous
situation, good communications are necessary (1) as a means of
alerting occupants to the emergency and (2) as a way to mobilize
fire protection forces, whether a plant’s fire brigade, the municipal
fire department, or both.
A coded fire alarm system, with alarm boxes and bells, horns, or
other sounding devices suitably situated, is usually needed. In very
small plants, however, a steam whistle or similar device might be
adequate. In any case, the alarm system is no better than
employees’ training in how to respond when the alarm is sounded.
In addition, install a backup-alarm system in-case electrical power is
lost.
Power is often lost during fires, especially if sabotage is involved:
Also install a secondary power source, especially if electric pumps
supplement the regular sprinkler system and standpipe system.
Make sure that all persons can be alerted and that there is some
way for everyone to get out of the building, regardless of the power
source in use.
FIRE DETECTION
Statistical data shows that, despite good construction, cleanliness, and
modern fire-fighting methods, a considerable number of losses from
fire however occur.
Losses would be reduced if each developing fire were detected so it
could be attacked and extinguished.
Thus, fire detection devices must be a part of every fire protection
system.
Means of detection could be a human observer; automatic sprinklers;
smoke, flame, or heat detectors; or, more likely, a combination of
these.
The detecting part of a fire protection system has two main tasks:
(1) Giving an early warning to enable building occupants to escape
(2) Starting extinguishing procedures.
Each automatic fire-detection system requires a sensor, which
observes a physically measurable quantity of smoke, flame, or heat.
Human Observer
A human observer is a good fire-detection system for the
following reason: He can take immediate action in a flexible
way, whether calling the fire department or putting out a fire with
an extinguisher. Be sure that employees report any fire that
they have put out.
Automatic Fire-Detection Systems
In general, there are three possible errors in any non-human
fire-detection system:
(1) giving a false alarm,
(2) not detecting a fire,
(3) detecting it too late.
The cause of false alarms may be human interference,
mechanical or electrical faults, or special environmental effects.
When planning an automatic fire-detection system,
use the following checklist of questions:
What is the main purpose of the system?
What are the possible sources of ignition?
What kinds of material will probably be ignited first?
What kind of building construction is used?
What are the environmental conditions?
What kind of detection system has been installed and what are the
reasons for choosing this system?
How long can a fire be allowed to go undetected?
There are many types of fire detectors to handle
various situations and to detect various states of
the beginning of a fire.
Most manufacturers and distributors offer several
or all of the commonly used types.
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Thermal Detectors
Fixed-Temperature Detectors
Line Thermal Detectors
Smoke Detectors
Flame Detectors
Sensor Systems
ALARM SYSTEMS
Alarm systems can be divided into four groups: local,
auxiliary, central station, and proprietary.
All types of alarm systems should be equipped with a
signal system that clearly communicates to all persons in
the building, plant, or laboratory.
Whenever an alarm is sounded in any portion of the
building or area, all employees must know what the sound
means.
Local Alarm Systems
A local alarm consists simply of bells, horns, lights,
sirens, or other warning devices right in the building.
Local alarms are generally used for life protection – that
is, to evacuate everyone and thus limit injury or loss of
life from the fire.
A local alarm can be tied in with another system to call
the fire department.
Local alarm systems are inexpensive, available from a
wide range of suppliers, and easy to install.
Auxiliary Alarm Systems (supplementary)
Auxiliary alarm systems are even less expensive than
local alarm systems.
Such a system simply ties a fire detector to a nearby fire
call box. In effect, it becomes a transmit station triggered
by fire detectors inside the building.
Central Station Systems
Central station systems are available in most major cities around the
country.
Operated by trained personnel, a central station continually monitors
a number of establishments and, in case of an alarm, calls a nearby
fire station and alerts the building’s personnel.
Central station devices are almost always leased.
Proprietary Alarm Systems
Proprietary alarm systems feed alarms to the building’s maintenance
force, and, optionally, to the fire department as well.
One reason for their acceptance is that insurance regulations
generally require security officers.
Fires usually start in a facility’s contents or operations
rather than in its structure. Therefore, consider the
following:
What materials are flammable?
What materials in a process or operation are most likely to ignite? Burn?
Explode?
What in the facility could be a source of ignition? Are any open sparks or flames
present? Are high temperatures involved in any operations?
Where are flammable and combustible materials located? Are flammable
materials stored together? Do indirect connections exist? If one of the materials
should burn, could the others easily ignite?
Might any of the materials ignite because of convection or radiation?
What toxic gases might develop into a fire?
How much time might it take for a fire to spread to other areas? to adjacent
facilities?
Smoke and toxic gases, and sometimes heat, are largely responsible for fire
deaths. What toxic gases might develop from the burning of contents?
How many people are likely to be involved in the facility, in adjacent facilities, or
in facilities nearby?
FIRE-SAFE BUILDING DESIGN AND SITE PLANNING
The objective of fire safety is primarily to protect life and
secondly property from the destruction of fire in a building.
Building design and construction must take into account a
wide range of fire safety features. Not only the interiors and
contents of buildings are protected from the dangers of fire,
but the building site it self must have adequate water
supplies and easy accessibility by the fire department.
Architects, builders, and owners may assume that state
codes provide adequate measures; however, these codes
specify only minimal measures for fire safety. Planning and
construction based upon such codes may limit fire safe
design seriously.
Objectives of Fire Safety Design
Before a building designer can make effective decisions relating to fire safety design, the
specific function of the building and the general and unique conditions that are to be
incorporated into it must be clearly identified.
Decisions regarding the fire safety design and construction of the building have the same
objectives as do all fire protection measures, namely (1) life safety, (2) continuity of
operations, and (3) property protection.
Life Safety
Design considerations for life safety must address two major questions:
(1) Who will use the building?
(2) What will the people using the building do most of the time?
Continuity of Operations
Continuity of operations, the second major area of building design decision making, must
take into consideration those specific functions conducted in a building that are very
important to continued operation of the business and that can not be transferred to another
location.
Property Protection
One of the most important questions to be asked about the design of buildings with regard
to protection of property is: Is there any specific high-value content that will need special
design protection?
Materials of high value that are particularly vulnerable to fire and/or water damage can
usually be identified in advance of building design.
Fire Extinguisher
How Does a Fire Work?
Need all three
components to start a fire
Fire extinguishers
remove one or more of
the components
Types of Fires
Class A - fires occur in ordinary materials,
such as wood, paper, cloth, carpets, and
rubbish.
Class B - fires occur in the vapor-air mixture
over the surface of flammable liquids, such
as gasoline, oil, grease, paints, and thinners.
Class C - fires occur in or near energized
electrical equipment
Class D - fires occur in combustible metals
such as magnesium, titanium, zirconium,
lithium, potassium, and sodium.
Different Kinds of Extinguishers
The 4 most common fire extinguishers:
All Purpose Water
Carbon Dioxide
Multi-Purpose Dry Chemical
Dry Powder
Each kind of extinguisher has a specific use
All Purpose Water
Use on CLASS A fires
Pressurized water
Pressure gauge
Carbon Dioxide
Use on CLASS B and
CLASS C fires
Hard, plastic nozzle
Multi-Purpose Dry Chemical
Use on CLASS A,
CLASS B, and
CLASS C fires
Fine powder under
pressure
Pressure gauge
Emergency Procedures
Building Evacuation
• Proceed to nearest exit in an orderly fashion
• Assemble at least 100 feet from building
• Provide emergency crews with information
about people still in the building
• Provide information to emergency crews about
the reason for evacuation
• Never re-enter a building until instructed to by
the police department, fire department.