1. Stewart Kidd, MA, MSc, FIFireE
Heritage Loss Prevention Consultant
�COST C 17�Vienna 8 December 2004�Schloß Schönbrunn�Fire Risk Improvement Project�
3. Structural Fire Protection �of Key Areas: Phase 3 Proposal to Utilise Low Pressure Water Mist
4. This project, which started in 1999 has been undertaken in three parts: 1. An overview of the main problems facing the Palace and how these could best be managed
2. A full risk assessment project and recommendations for ways in which the levels of risk can be reduced and other observations
3. Implementation
5. A Reminder:�Managing Fire Safety in Historic Buildings Based on recommendations in Heritage Under Fire
(2nd Edition)
6. Each building or institution must have a fire safety policy Managing Fire Safety in Heritage Buildings
7. The institution should appoint� a fire safety manager Managing Fire Safety in Heritage Buildings
8. In larger premises, the FSM should be assisted by a full or part-time �Fire Safety Officer Managing Fire Safety in Heritage Buildings
9. A fire risk assessment should be undertaken and updated regularly Managing Fire Safety in Heritage Buildings
10. A fire safety manual and a record book should be set up and maintained Managing Fire Safety in Heritage Buildings
11. Automatic fire detection systems of modern design and capability should be introduced Managing Fire Safety in Heritage Buildings
12. Following a full survey, the fire resisting elements of the building should be upgraded Managing Fire Safety in Heritage Buildings
13. Where particular legal requirements exist these must be complied with Managing Fire Safety in Heritage Buildings
14. All staff, including part-timers and volunteers must be trained in all aspects of their role in fire safety Managing Fire Safety in Heritage Buildings
15. Where individual residences or apartments form part of a heritage building, these must form part of the general survey and risk assessment Managing Fire Safety in Heritage Buildings
16. Special, detailed arrangements must be imposed to control and supervise all contractors Managing Fire Safety in Heritage Buildings
17. Managing Fire Safety in Heritage Buildings Special care must be taken when arranging or hosting special events, especially if these involve filming, fireworks or fashion The Risk Assessment will have to be repeated, taking into account the new risks and hazards
18. In larger premises a trained damage limitation team should be set up Managing Fire Safety in Heritage Buildings
19. Managing Fire Safety in Heritage Buildings� Regular liaison meetings and exercises with the local fire brigade should take place
20. Consideration should be given to the benefits of sprinkler systems, particularly if compartmentation and segregation of of the building proves difficult or costly Managing Fire Safety in Heritage Buildings
21. A full set of records, drawings, photographs and other information should be stored off-site for use in rebuilding in the event of a fire Managing Fire Safety in Heritage Buildings
22. Risk Assessment Findings
23. Hazards and Problems (1): Roof structures
27. Hazards and Problems (1): Roof structures
Voids and cavities
31. Hazards and Problems (1): Voids and cavities
Roof structures
Fire brigade access to roof spaces
33. Hazards and Problems (1): �• Voids and cavities�• Roof structures�• Fire brigade access to roof spaces Tenancies
Un-refurbished areas
Electrical wiring
Compartmentation
34. Hazards and Problems (2): High value heritage contents
37. Hazards and Problems (2): High value heritage contents
Chimneys and flues, wood burning
Control of contractors
Special functions
39. Impact of Fire (1): Small fire - quickly discovered and contained:
Minor damage to single apartment/room
Low probability of spread to other levels
Minor injury to occupants/visitors
Minimal cost/financial loss
Minimal smoke damage to neighbouring areas
Minor water damage
Minor publicity/financial loss
40. Impact of Fire (2): Large fire - delayed discovery; late containment:
Major damage to more than one room/contents
Probable spread to other levels
Loss of 30% of roof
Severe smoke damage
Significant water damage
Serious injury to occupants/firefighters
Negative publicity
Loss of revenue
41. Recommendations and Conclusions
42. Risk Assessment Findings: Premises are very large, have a complex, structure and are multi-tenanted
The location is of paramount importance - nationally and internationally
The risks of fire and from fire are high
Anything other than a minor incident cannot be tolerated for heritage,life safety and financial reasons
43. Compensating Factors: Highly professional and committed approach to fire safety by senior management ü
Staff support and enthusiasm ü
Very good housekeeping e.g: work on clearing roof spaces ü
Comprehensive structural survey ü
Initial work on re-wiring ü
High quality new fire detection system ü
Collaboration with Vienna fire brigade ü
Good on-site water supply ü
44. Conclusions (1): Even with best possible fire brigade response, effective intervention will take 15 - 20 minutes from time of discovery
Undiscovered small fires have high probability of spreading
High probability of smoke and water damage
High possibility of injury
45. Conclusions (2): The probability of losing 30% of the roof is high
Even a moderately small fire will do significant damage to heritage fabric
Heritage contents will suffer major loss from even a small fire
Negative publicity will have serious impact
Serious revenue losses will result from enforced closure of even part of the Palace
46. Conclusions (3) Given the presence of the hazards described, it is concluded that the Palace should be classified as:
“High Risk”
With the consideration of the compensating factors, this can be reduced to:
“Above Normal Risk”
47. Risk Reduction (1):� The risk can be further reduced by: 1.Upgrading/introducing structural fire barriers and introducing new fire stopping wherever possible
2.Extending the new fire detection systems to the whole Palace
3. Education of tenants, inspections of apartments and control of tenant activities
4. Re-wiring remainder of Palace
5 Installing sprinklers in most vulnerable areas
48. Conclusions Significant work has been done to reduce the risk from fire
If the recommendations made are carried out then:
1. The chances of a fire will be reduced
2. If a fire does take place, it will almost certainly be contained
3. If it is not quickly contained then its impact and consequential damage will be minimised
49. Work Done to Date Re-wiring
Compartmentation
New detection throughout
Extensive staff training
Improved security and surveillance
Formation of Damage Limitation Team
Fire Safety Management Policies
Control of hazards and good housekeeping
Phased introduction of sprinklers
50. Areas Outstanding Roof spaces
Tenanted areas in palace
Main state rooms (Showrooms)
Chapel
Other areas ( Wagonberg/Theatre)
51. Work Underway Changes to evacuation system
Voice evacuation
Further development of DLT
Development of internal first strike fire equipment
Control and monitoring
52. Priorities Roof Spaces in Palace
State Rooms
Rationale for fire protection
Choices
Sprinklers
Water Mist - High pressure
Water Mist - Low pressure
Gas systems
53. Slide 9
This slide illustrates the three key elements required for a fire to occur and develop. These are heat, fuel and oxygen. The removal of one or more of these elements will extinguish the fire.
Halon chemical agents extinguish a fire by causing a chemical interference that affects all three elements.
Slide 9
This slide illustrates the three key elements required for a fire to occur and develop. These are heat, fuel and oxygen. The removal of one or more of these elements will extinguish the fire.
Halon chemical agents extinguish a fire by causing a chemical interference that affects all three elements.
54. Slide 10
This slide illustrates how sprinklers remove the heat element of the triangle by cooling. Slide 10
This slide illustrates how sprinklers remove the heat element of the triangle by cooling.
55. Slide 11
This slide illustrates how CO2 removes the oxygen element of the triangle. Slide 11
This slide illustrates how CO2 removes the oxygen element of the triangle.
56. Slide 12
This slide illustrates how inert gaseous fire suppression systems reduce the amount of oxygen to a level that will not sustain combustion but will sustain life.
Slide 12
This slide illustrates how inert gaseous fire suppression systems reduce the amount of oxygen to a level that will not sustain combustion but will sustain life.
57. Slide 13
This slide illustrates how watermist acts to remove heat by cooling and reduce the oxygen level at the flame front by converting the fine watermist droplets to steam.
Slide 13
This slide illustrates how watermist acts to remove heat by cooling and reduce the oxygen level at the flame front by converting the fine watermist droplets to steam.
58. What Do We Know About Water? specific heat = 4.18 Kjoules/kg/oC�
latent heat of vapourisation = 2240 Kjoules/kg�
expansion on vapourisation = 1620:1 Slide 14
Water is a unique fire fighting media. It is plentiful, cheap and environmentally friendly. It has the ability to absorb high levels of heat and expand 1620 : 1 on vapourisation. These factors rapidly cool surface areas and create a tremendous amount of steam, The steam produced significantly reduces the level of oxygen present in the atmosphere at the flame front.Slide 14
Water is a unique fire fighting media. It is plentiful, cheap and environmentally friendly. It has the ability to absorb high levels of heat and expand 1620 : 1 on vapourisation. These factors rapidly cool surface areas and create a tremendous amount of steam, The steam produced significantly reduces the level of oxygen present in the atmosphere at the flame front.
59. Evaporation (heat extraction) is a function of surface area of droplets
Reducing droplet size increases surface area
Increase in surface area allows for larger cooling effect for a given flow Slide 15
This slide illustrates how the reduced droplet size of watermist increases the rate of evaporation that in turn speeds up the process of heat extraction.
Watermist provides a much wider surface area than conventional sprinklers.
The larger the surface area of the droplets the more efficient the watermist becomes in controlling or extinguishing a fire. Slide 15
This slide illustrates how the reduced droplet size of watermist increases the rate of evaporation that in turn speeds up the process of heat extraction.
Watermist provides a much wider surface area than conventional sprinklers.
The larger the surface area of the droplets the more efficient the watermist becomes in controlling or extinguishing a fire.
60. Volume = Equivalent volume
Diameter ‘D’ = 8 x D/2
Surface area ‘S’ = S x 2 � (twice surface area) Slide 16
This slide illustrates the formula of volume X diameter of the water droplet X the surface area. This formula demonstrates how the surface area of watermist droplets increases in comparison to the same volume of water from the larger droplets of a sprinkler system. Slide 16
This slide illustrates the formula of volume X diameter of the water droplet X the surface area. This formula demonstrates how the surface area of watermist droplets increases in comparison to the same volume of water from the larger droplets of a sprinkler system.
61. It seems that the smaller the droplet
the better
But:
Droplets need momentum to penetrate
the fire plume Slide 17
Science has established that the smaller a droplet is the more efficient it is at controlling fire. However, water droplets need momentum to penetrate the fire plume.
Low pressure watermist solves this problem with the addition of some larger water droplets that carry the smaller ones directly to the seat of the fire.Slide 17
Science has established that the smaller a droplet is the more efficient it is at controlling fire. However, water droplets need momentum to penetrate the fire plume.
Low pressure watermist solves this problem with the addition of some larger water droplets that carry the smaller ones directly to the seat of the fire.
62. Why Low Pressure ? Low pressure systems deliver a mix of�large and small droplets at a lower velocity
The few larger drops act as carriers for the smaller droplets
Less water volume (and weight !) in roof space for given time
Low pressure system can utilise existing tanks and pumps
Slide 18
Experience tells us that fire extinguishment improves with direct contact of water droplets
Larger droplets are an important part of the operation if ventilation is a factor and class “A” combustibles are present Slide 18
Experience tells us that fire extinguishment improves with direct contact of water droplets
Larger droplets are an important part of the operation if ventilation is a factor and class “A” combustibles are present
63. Droplets with high momentum penetrate �the fire plume
Some larger droplets help to deliver fine droplets to the fire
A range of droplet sizes maximises extinguishing efficiency Slide 19
This slide illustrates how the combination of different droplet sizes work together to maximise extinguishing efficiency. The process produces a two and a half dimensional effect that enables the mist to reach and penetrate areas that is beyond the capability of sprinklers which are only one dimensional.Slide 19
This slide illustrates how the combination of different droplet sizes work together to maximise extinguishing efficiency. The process produces a two and a half dimensional effect that enables the mist to reach and penetrate areas that is beyond the capability of sprinklers which are only one dimensional.
64. Minimum operational pressures 7- 8 bar.
Temperature ratings for detection:
57°c orange
68°c red
79°c yellow
93°c green Using detector nozzles Slide 23
This slide illustrates the different temperature ratings available for sealed detector nozzles for volume protection. Slide 23
This slide illustrates the different temperature ratings available for sealed detector nozzles for volume protection.
65. Slide 21
This slide illustrates two typical sealed detector nozzles used for volume protection. The mist generator determines the pattern of watermist discharge and the droplet size combination delivered.Slide 21
This slide illustrates two typical sealed detector nozzles used for volume protection. The mist generator determines the pattern of watermist discharge and the droplet size combination delivered.
66. The little nozzles will prevent…
70. Stewart Kidd, MA, MSc, FIFireE
Heritage Loss Prevention Consultant
�COST C 17�Vienna 8 December 2004�Schloß Schönbrunn�Fire Risk Improvement Project�
