This document provides information on fire safety and prevention. It begins with an introduction to fires and statistics on fire deaths in Europe. It then discusses European fire safety standards and devices such as sprinklers, smoke detectors and fire simulations software. The document analyzes a case study of a fire starting in the laboratory of a university building in Bulgaria and provides recommendations to improve fire safety such as installing sprinklers, double glazed windows and automatic doors. It also summarizes using fire simulation software to model the building and predict fire spread to help first responders.

1. FIRE SAFETY AND PREVENTION
Guided by –Prof. Svetlin Antonov
Presented by- Karan Sarvade
Sujit Shelke

2. TABLE OF CONTENTS
1. Introduction
2. Fire Statistics
3. European Standards
4. Fire Safety Devices
5. Fire Simulation Model
6. Recommendation
7. Conclusion
8. References

3. Introduction:
Fire is an important phenomenon and it has been useful to man since
Stone Age. Even though fire is useful for us in our day to day life, it has
many drawbacks too.
The accidents occurring due to fire in a residential building or offices are
common to everyonenow-a-days. Such accidentalfire inside a building
or houses may resultinto damage of human lives as well as of
properties.
In Europe, huge deaths are occurring dueto such fire and around 70,000
people are hospitalized & 4000 people die each year due to these fire
accidents. Around half of the deaths due to fire accidents happen
because of smoke, rather than fire. The smokebeing toxic to human
health, leads to severe disorders causing breathing problems and may
even result in death.
Along with the loss of human lives, which is a threat to any nation
around the world, there is also a loss of property occurring dueto
damage of the buildings and houses due to the fire. The European Union
is suffering a yearly property loss of about €126 Billion, which
contributes to about 1% of its GDP. Such kind of loss of property & lives
is not good for the financial strength of any country.
Various standards havebeen made by the European Union to for the
prevention of loss of property as well as lives. Fire Safe Europe is a firm
established by the EuropeanUnion in order to prevent the fire accidents
and to take the required actions whatever necessary.
In caseof fire emergencies, firefighters need to be awareof the
blueprint of the building or the housewhich has caughtfire. Also they
need to locate the sourceof fire, as well as the safer places inside a
building, so that they can evacuate the people inside the building more
easily.
Various softwareareavailable now-a-days to simulate the fire, which
will tell us exactly the situation in case of fire like the temperature at
various points inside the room, the pressurecreated inside a roomdue

4. to fire, the velocity of spreading of smokeetc. All this parameters we will
be analyzing in this case of fire further.
Fire Statistics
The graphical representation of the deaths occurring due to fire accident
worldwide is shown below:

5. Graph 1. Report based on year 2011
Graph 2. Report from the year 2000 to 2008
Fire Safe Europe:
Considering the loss of human lives as well as the properties of the
European countries, the European Union has established a firm Fire Safe
Europe which checks for the preventive measure of the fire and ensure
fire safety of various buildings and houses across Europe
The safety measures vary from country to country. All the countries in
EU may not have the same safety measures but they have the measures as
suggested by Fire Safe Europe. In many countries across Europe, the
some buildings are outdated and do not have enough safety measures in
case of fire emergencies.
Research has revealed that more than half of the death occurring due to
fire accident is due to the smoke itself. The humans trapped inside a
building which has caught fire, inhale the smoke which is hazardous to
human health. This causes death of many people inhaling smoke

6. Fire Safe Europe does not have measures to check for the toxicity of the
smoke inspite of more deaths occurring due to the smoke itself.

7. To reduce impact and possibility of fire-
1 .Buildings are designed to separate and enclose areas.
2. Includes fire prevention devices, alarm, smoke detectors, exit signs, smoke
absorber.
3. Isolate fire cause element and material.
4. Fire retardant building materials have also developed such as paints and chemical
used to coat and impregnate combustible material such as wood and fabric.
5. Height and width of window should be small.
6. Use of exhaust fan in corridor.
7 .The distances for human evacuation should be less (not greater than 10-15m).
8. Elevator must have emergency exit.
9. Use of smoke vents inside a room so that all the smoke must be thrown out of the
room.

8. The physics of fire development has not changedover long time.
Factors including home size, geometry, positionof doors, size of
window and constructionmaterial have changedsignificantly over
past few years.
Each of these factors will be examined in detail as they concern to the
safety of occupants and the fire service.
Windows-
Windows play an important role in fire safety of buildings. As the size of
window increases the flow of air (oxygen entering in the room) also increases in the
room, which causes more fire in the room. In modern architecture the window size is
large for more attractive and aesthetic looks.
Windows may be of following types:
1. Wood Frame: The frame of the window is made up of wood. Wood is more likely
to cause fire, so there is more chance of the breakage of the glass window.
2. Vinyl Frame: The frame of this type of windows is generally made up of PVC
(Poly Vinyl Chloride) which has more chances of melting at low temperature. The
melting point of PVC is about 413 Kelvin and the minimum temperature of fire inside
a room goes up to 800 kelvin. So it will also cause the breakage of the glass window.
3. Double glazed designs: It consist of double glass separated by a vacuum or gas
filled between to glass pane of single window. It reduce the heat transfer across the
room. The thickness of a glass 3 to 10 mm. Due to double glass pane the temperature
difference of about 343k between heated glass and edge glass temperature is created
which decrease the chances of breakage of glass pane at high temperature.
*3 mm normal window glass will break at 360 degrees Celsius
*4 - 6 mm normal window glass will break at 460 degrees Celsius
*Double glazed window of thickness 6 mm will break at 600 degrees Celsius.
*Tempered glass will break after the room flashover has reached.
OUR RECOMANDATION:
Use double glazed tempered glass window design.

9. Fire safetyequipment-
Sprinkler system–According to 2009 American housing survey automatic
sprinklers are the most effective and reliable elements for protection from fire
in buildings.
There are four types of sprinkler system-
1 Pre Action-
Pre action fire sprinkler systems are filled with water and air. Which allowed to
pass through when the smoke alarm or detector detects smoke.
Use- This type of sprinkler system are use in location where accidental activation is
undesired. For eg –historic libraries, data center for computer protection from
accidental water discharge .These sprinklers have double interlock system.
2. Dry pipe-
Dry pipe sprinkler use pressurized air in the pipe which exits before water
discharge. Which is ideal for buildings with low temperature ,so the pipe do not
freeze.
Ex-warehouses located in north are good example of dry pipe sprinkler system.
3. Wet pipe-
Modern high buildings or more than 10 floors building uses the wet pipe system.
As name suggest wet pipe fire sprinkler system contained water constantly. These
allow for a quick action to a fire and are the most common sprinkler installed in
buildings.
4. Deluge -
A deluge fire sprinkler system is similar to pre action system except the sprinkler
heads are open and the pipe is not pressurized. The system is operated by the
operation of smoke or heat detection system .This system use in places such as
aircraft hangers, power plant and chemical storage
(Fire sprinkler systems are extensively used worldwide over 40
million sprinkler heads fitted eachyearover 96% of fire are
controlled by fire sprinkler alone).

10. Smoke vents:
Smoke vents are situated at the roof top of any building or hall, so that the smoke
which is produced due to the fire caused in the building, is released from the vents,
which in turn is hazardous for humans inside that building or hall. Smoke has the
property of flowing upward therefore most of the smoke vents are located at the roof
top. Smoke is an unwanted byproduct of fire which contains various toxic particles,
which if inhaled by any human, can be hazardous to their health and may even cause
their death, if inhaled in larger amount.
Such kind of smoke should be thrown outside the building or hall as soon as possible.
Therefore, smoke vents are necessary in such cases as they throw the smoke out to the
surroundings thus preventing the damage caused due to fire.
Types of smoke vents:
Smoke vents are generally categorized in two type -
1. Mechanically opening vent: These types of vents open mechanically, with the
use of motors, springs to bring back to their original position, hydraulic or
pneumatic actuators.
2. Drop out vent : These type of vents are made up of plastic, which shrinks
when heated and allow the smoke to pass through them.
Our recommendation-
There is no any type of fire sprinkler systemin the building, this is
really a big mistake which not avoidable. According to above
explanation of fire sprinkler system, the most suitable and
economicalfire sprinkler systemis dry pipe sprinkler systemfor our
building.
Smoke vents are also not use in constructionof building which is
againdangerous for building.
So we recommend that also.

12. Problem statement-
We are working on a model of TECHNICAL UNIVERSITY OF SOFIA,
BULGARIA. We have chosen 2nd block of the university. The 2nd block
consists of 5 floors. We have given the source of fire at the
Hydrodynamic Laboratory, which is located on the 1st floor. Since the
laboratory is not in use now, it has been used as a storeroom, to keep
books inside it. Also there are machines inside the room. There are
various furniture like the wooden chair, table and bookshelves. These
furniture as well as the cables of the machines and electrical switch
boards which are in open condition will cause the fire to increase rapidly.
Pictorial top view of our model is as shown below.
Dimensions of room are as follows-
Roomis (12m*12m*3.5 m) in length .Dooris (
There are 5 windows in which W1, W2 & W3 are (3.3m*0.3m*2.5 m) in
length and W4 &W5 are (5.3m*0.3m*2.5 m) in length
No. of columns: 6 each of (0.7m*0.7m*3.5m)

13. LABORATORY (Source of fire in our model):
( Img-1. Fire source room)
This room is the source of fire. There are lots of books piled up on each other,
which will cause the fire to ignite more. Also there is furniture, electric supply
board which will contribute more to the fire.
The area of the room is 144 m2, and the height is 3.5 m so there is sufficient
amount of oxygen which will cause dangerous fire in the room.
Also the room is so congested that there is not enough space to enter or exit the
room. The way to enter and exit is too narrow.
If someone is trapped inside this room when it has caught fire, there will be a
trouble for that person to exit the room due to the above mentioned reason.

15. ( Img-2 Full view of fire source room )
OUR RECOMMENDATION:
The books should not be spread on the floor; it should be properly arranged and
kept inside a book shelf. Also, the book shelf must be of metal instead of wood,
which catches fire easily.
The electric switch boards should be properly covered, so that they are not
exposed to fire.

16. (Img-3 corridor)
In front of the laboratory, there is a corridor. The smoke arising from the fire will
spread to this whole corridor. There need to be proper arrangements made in the
corridor to exit the smoke from the building.
OUR RECOMMENDATION:
There should be a door in the entrance of this corridor so that the smoke will not
be spread along the corridor, as there are people inside the room, who need to be
evacuated safely from the building.

17. (Img-4 Door )
There is a door at the end of the corridor, which will be of no use to exit the
smoke as the smoke has to travel along the length of the corridor, which will
create a trouble for the people inside the rooms. Therefore, there should be a door
at the entrance as suggested earlier.
If there is a door at the entrance of the corridor, then the people can be evacuated
from this door safely as long as the door at the entrance will not break.
Also since this door closes automatically, there will be a trouble for the evacuation
of the people.

18. Automatic Door Closing:
The doorshown in Img. 4 has an automatic closing system shown
above. Due to this it will create a trouble for the people inside the
building to evacuate safely outside the building.
If there are more people, there will be a rush at the exit, causing more
trouble for the people to exit.

20. Our recommendation-
The arrangement of the room is shown below, which is safe from fire

22. Img. 5
Simulationof fire using software:
In order to reduce the number of deaths occurring due to fire, we have to predict its
nature.
We have various software available to simulate the fire, which will be of great help
for the firefighters to extinguish the fire. These include;
1. PYROSIM
2. EXTENDSIM
3. FLAMESIM
4. FLUENT
We are using PYROSIM for the simulation of fire.

23. I mg. 6
The model of Technical University of Sofia block 1 which we are
analyzing and simulating using Pyrosim

24. Img. 7 Back view Img. 8 Front view

25. Img. 9 Fire Source(Red) Img. 10 Side view
By using Pyrosim, we created a model of the block 2 of Technical
University of Sofia. We measured the dimensions of the laboratory as
well as the corridorand built an exact replica of the block 2 in
Pyrosim. The material used for building the walls and pillars of the
block is Concrete.
Inside the room we have 2 bookshelves which are made up of wood.
So the material used for building the shelves in Pyrosim was Yellow
pine wood.
We choosethe fire source to be near the shelf. The material used is
Burner, which is the fire source.
Different views of the block are shown in Img.7, Img.8, Img.9 and
Img.10.

26. For New Model-
Run PyroSim.
1. on the File menu, click New.
2. Also check View menu, click Units and select SI to display values in
SI system.
3.Save the model. On the File menu, click Save and choosea folder.
Name the file building-fire.psm.
4.Click OK to save the model
Create the Mesh
1.On the Model menu, click Edit Meshes .
2.Click New, Figure 1.
3.In the Min X box, type -2 and in the Max X box, type 12.
4.In the Min Y box, type -2and in the Max Y box, type 55.
5.In the Min Z box, type 0 and in the Max Z box, type 18.
6.In the X Cells box, type 24.
7.In the Y Cells box, type 110.
8.In the Z Cells box, type 36.
9.Click OK to save changes and close the Edit Meshes dialog.

27. How to give Reaction-
Reaction –A reaction assumes a fuel vapor that reacts with oxygen to
deliver energy and form ignition products.
First we define the reaction for this simulation.
1.On the Model menu, Edit Reactions.
2.Click the Add From Library button, select POLYURETHANE
reaction,and shift it to the Current Model. Click Close.
3.Click OK to close the dialog.

29. ( Img 1- creating the mesh )
TO ADD MATERIAL-
To add material see the figure shown below
In our model we select two material,1.concrete for wall,and yellow pine
for furniture in lab.

32. Figure -3 Shift of materials from the library into the current model.
Create the Burner Surface
Surfaces are used to define the properties of objects.
In this example, we define a burner surface that releases heat at a rate of
1000 kW/m2.

33. 1.On the Model menu, click Edit Surfaces .
2.Click New.
3.In the Surface Name box, type burner, Figure 2.
( Figure 4-creating new burner surface )
4.In the Surface Type list, select Burner.
5.Click OK to create the new default burner surface.

34. Figure 5- Defining parameters for the burner surface
1.In the Description box, type 1000 kW/m2 burner, Figure 3.
2.Click the Color button to open the Surface Color
dialog, then select a good color (e.g.red) and click OK.
3.In the Heat Release Rate (HRR)box, type 1000
4.Click OK to save changes and close the Edit Surfaces dialog.
Create the Burner Vent

35. In this example, we use a vent and the previously created
Burner surface to define the fire.
1.On the Model menu, click New Vent....
2.In the Description box, type burner vent, Figure 4.
3.In the Type list, select burner. This specifies that the previously created
burner surface will define the properties of the vent.

36. Figure 6-. Creating the burner vent
4.in the Plane list, select Z and type 0.3.
5.In the Min X box, type 2 and in the Max X box, type 3.
6.In the Min Y box, type 2 and in the Max Y box, type 3.
7.Click OK to create the new burner vent
Add the Wall
In FDS obstructions are used to define solid object in the model. In this
example, we will use an obstructionto define a wall.
1.On the Model menu, click New Obstruction.
2.In the Description box, type wall, Figure 5.
3.In the Min X boxtype 0.0 and in the Max X boxtype 0.3.
4.In the Min Y boxtype 0.0 and in the Max Y box,type17.4
5.In the Min Z boxtype 0.0 and in the Max Z box type 3.5.
6.Click OK to create the wall obstruction.

37. Figure-7 side wall
Similarly draw the wall by using the dimension's as shown in figure
below

38. Figure-8 back side wall
Figure-9 side wall
Figure-10 front wall
Figure-11 top ceiling /roof

39. Figure -12 floor
we created the room,nowwe have to create the column which support
the roof.
First we create one column and then copythat column.
First we have to create first column
Click on the draw block obstruction in the task bar, drag it anywhere and
give dimensions as shown in figure
Right click on the obstruction select
copy/move. Select the copyoption in the
translate box type no of copies 2
And in the x box type4.
x y z
min 0 0 0
max 0.7 0.7 3.5

40. Figure-13 window hole
Similarly by using copy/moveoption create two windows, spacing
between two windows are 0.7 m .
Add the Door
In FDS holes are used to define openings through solid objects. In this
example, we will use a hole to define a door.
1.On the Model menu, click New Hole....
2.In the Description box, type door.
3.In the Min X box, type 4.65 and in the Max X box, type7.35.
4.In the Min Y box, type 11.7 and in the Max Y box, type 12.
5.In the Min Z box, type 0.3 and in the Max Z box, type2.35.
6.Click OK to create the door.

41. `
TO GIVE ACTIVATION CONTROL-
Click on the device menu,then click on the edit activation control.
Click on the new in activation control box.Do the procedure as shown in the figure below.
Figure-14 activation controlfor doorand window

42. `

43. `
Img. 11 Fire taking place inside the laboratory
The image shows the room is lit with fire. The fire sourcesituated near the shelf has started
burning. After a certain period of time, the shelf will also catch fire as well as the another
shelf and the books, furniture will also start to ignite, making the fire more aggressive.
Img. 12 Smoke view
This image shows the smoke view of the block. The fire inside the Laboratory has started
spreading along the length of the corridor.

44. `
Img. 13 Wall Temperature.
This image shows the wall temperature of the block after 470 seconds ofstarting fire. The
minimum temperature is 20 degrees Celsius, which is shown by blue color and the
maximum temperature shown is 170 degrees Celsius.Jj kbjhjhbhhjbhbhbh
Img. 14 Pressure Slice
This image shows the pressure slice at z=2m. The maximum pressure attained inside the
room is approx.3 bar shown by red color and the minimum pressure is approx. 2 bar
shown by blue color

45. `
Img. 15 Temperature slice
This image shows the temperature at a certain plane inside the building. The maximum
temperature attained is 220 degrees Celsius and is shown with red color. The minimum
temperature is the room temperature which is 20 degrees Celsius and is shown by blue
color.
Img. 16 Velocity slice
This image shows the velocity of the flame or the smoke flowing along the building. The
maximum velocity of the smoke is 2 m/s and is shown by red color.