| 1. |
- Andersson, Petra, et al.
(författare)
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Innovativa elsystem i byggnader : konsekvenser för brandsäkerhet
- 2019
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Rapport (övrigt vetenskapligt/konstnärligt)abstract
- Det sker en snabb teknikutveckling i den elektriska miljön i byggnader, framförallt i våra bostäder. Ett exempel är lokal produktion av el, där solcellsinstallationer blir alltmer populära. Sådan elproduktion medför även förändringar i övriga delar av byggnaders elektriska infrastruktur, såsom DC-nät och i vissa fall energilagring i batterisystem. Utvecklingen sker till stor del som ett svar på behovet av mer hållbara lösningar, ur ett växthuseffektperspektiv, för vår elförsörjning, och förstärks bland annat av statligt stöd och ökad tillgänglighet på marknaden.Ny elektrisk teknologi kan leda till ökad brandrisk och denna förstudie har haft som mål att undersöka denna problematik. Metoden har varit workshops med intressenter och experter inom området, intervjuer, samt litteraturstudier.Av de studerade områdena förefaller solcellsanläggningar skapa störst utmaningar i framtiden om inget görs. Detta beror dels på bristfälligt regelverk men även på att dessa system är distribuerade i byggnaderna med flera delar som kan orsaka brand och att delar är exponerade för utomhusklimat vilket får stora konsekvenser vad gäller uppkomst av fel.Brandsäkerheten i samhället har sett ur ett långt tidsperspektiv väsentligt förbättrats. Detta har huvudsakligen drivits fram med hjälp av ett förbättrat regelverk, som ofta inkluderat förbättrade provnings- och kvalificeringsmetoder. En generell observation i detta projekt är att regelverket inte hinner utvecklas i samma takt som tekniken. Detta är en ofta återkommande utmaning inom brandsäkerhet, men gäller speciellt för de teknikområden som behandlas i denna rapport där utvecklingen går mycket snabbt, och de ingående komponenterna nästan uteslutande har stor inneboende brandpotential. Rapporten konstaterar att för att skapa ett relevant regelverk behövs tillämpad forskning, så kallad prenormativ forskning, inom prioriterade områden för att besvara de frågor som ställs vid formulerandet av nya regler och standarder. Exempel på områden som bör prioriteras är 1) komplettering av det än så länge magra statistiska underlaget för bränder i solcellsinstallationer med olycksutredningar, och studier av redan befintliga olycksutredningar, 2) studier av branddynamiken i solcellsinstallationer, såväl byggnadsapplicerade som integrerade, och såväl tak- som fasadmonterade sådana, 3) studier av ljusbågars uppkomst och hur dessa kan undvikas, alternativt hur det kan undvikas att de ger upphov till bränder, 4) skapa underlag för säker installation av batterilager, samt 5) kvalitetssäkring av så kallade second-life batterier, dvs. begagnade batterier, som används i batterilager.
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| 2. |
- Fjellgaard Mikalsen, Ragni, et al.
(författare)
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Branner i avfallsanlegg
- 2019
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Rapport (övrigt vetenskapligt/konstnärligt)abstract
- Waste facilities represent a vital function in society, but fires occur regularly. The aim of this study is to provide a knowledge base on risks associated with fires in waste facilities, and to identify measures that can prevent fire and limit the extent of fire damage and environmental impact.Information was obtained through meetings with the waste industry, two inspections at waste facilities, a survey, a literature review and a review of the events registered in the fire and rescue services' reporting solution BRIS, as well as communication with other stakeholders. The project included land-based waste management; facilities for the reception and storage of waste (N=661), reception and storage of hazardous waste (N=250), and treatment facilities for hazardous waste (N=38). Waste treatment plants (such as biogas- or incinerator plants) as well as landfills are not included.High-risk waste types have been found to be general, residual waste, batteries (especially batteries not correctly sorted), electrical and electronic (EE) waste, as well as paper, paperboard and cardboard. General, residual waste stands out as an important focus area for reducing the overall fire risk at Norwegian waste facilities, both based on reported frequency of fire ignition and potential consequences with regard to equipment, downtime, environment and health. Waste categorized as "Hazardous Waste" doesnot stand out, and is not ranked in the highest risk category in this study, since many preventive and damage reducing measures have been implemented, and appear to work. Chapter 9 provides details on rating of fire risk.In the period January 2016 - May 2019, 141 fires were reported in waste facilities in Norway in BRIS. The total number of fires (including small, medium and large fires) is unknown, but is believed to be far higher. Common sources of ignition have been found to be composting (self-ignition), thermal runaway in batteries, heat friction by grinding, human activity and unknown cause.Regularly occurring fires outdoors, increased use of indoor storage and new types of waste such as lithium batteries lead to a risk that is difficult to manage, which can be a challenge with regard to insurance of waste facilities. Increased use of indoor storage is motivated by consideration for the environment and neighbours, but it may conflict with fire safety, especially because it restricts the access for the fire fighters and because of possible high heat stress on the load-bearing structure of the building housing the waste.Any major fire, regardless of the type of waste burned, could potentially lead to the release of pollutants into the air, water or soil. All smoke from fires can be harmful to humans and exposure to it must be taken seriously. There is a need for more knowledge and expertise in assessing emissions and environmental consequences in connection with firefighting. The use of extinguishing foam can reduce the consumption of extinguishing water, but the foam itself can contribute to contamination if discharged into water. A more detailed list of chemical content in the foam product data sheet is needed in order to be able to assess environmental concerns during use.2© RISE Research Institutes of SwedenMeasures have been proposed for the design of more firesafe facilities, for waste management and for limiting the environmental impact during and after a fire. Key measures that should be prioritized are detection and monitoring, limiting the amounts of waste, tidiness, sufficient training, reception control, available and properly dimensioned fire extinguishing equipment, as well as solutions to collect extinguishing water in order to prevent the release of environmental toxins. It has not been possible to verify the effect of individual measures based on available data and statistics. The industry’s own overall assessment has been found to be consistent with experience-based observations found in other studies, and this has been found to be the best available information on effective measures. The responsibility for most of the measures lies with the owner of the facility or the business, and the focus should be on the use of documented technical solutions and the assessment of whether measures are appropriate and practicable at each facility. A fire risk assessment, locally adapted to the respective facility is important, as there are large variations in the types of waste handled, the size and the design of facilities, as well as other local conditions that differ between waste facilities in Norway. The fire service should strive to achieve a close dialogue and cooperation with the waste facilities. The authorities should facilitate better knowledge transfer and learning after fires, between different fire departments. The authorities should also, in collaboration with the industry, develop a national attitude campaign to avoid faulty battery sorting.Further work should study extinguishing techniques and extinguishing tactics that can limit the amount of water needed and that can be used during large-scale fires. Various detection and extinguishing solutions for use at waste facilities should be surveyed, assessed with regards to suitability and documented in cases where documentation is lacking. This should be made available on an openly accessible platform. There is also a need for further studies on the chemical composition of smoke from different types of waste fires, as well as studies on the extent and spread of fire smoke and environmental impacts from fires on water recipients.Increased fire safety at waste facilities could facilitate a better dialogue between industry and insurance providers by reducing potential financial losses. Good handling of fire risk in waste facilities will not only affect the plants themselves, but will also limit potential societal costs and consequences for health and the environment.
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| 3. |
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| 4. |
- Fjellgaard Mikalsen, Ragni, et al.
(författare)
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Extinguishing Smoldering Fires in Wood Pellets with Water Cooling : An Experimental Study
- 2019
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Ingår i: Fire technology. - : Springer Science and Business Media LLC. - 0015-2684 .- 1572-8099. ; 25:1, s. 257-284
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Tidskriftsartikel (refereegranskat)abstract
- Smoldering fires in stored or transported solid biofuels are very difficult to extinguish. The current study has explored heat extraction from the combustion zone as a method for extinguishing such flameless fires. Heat extraction from the sample was made feasible using water flowing through a metal pipe located inside the sample. The fuel container was a steel cylinder with insulated side walls, open at the top and heated from below. Wood pellets (1.25 kg, 1.8 l) was used as fuel. Results from small-scale experiments provide proof-of-concept of cooling as a new extinguishing method for smoldering fires. During self-sustained smoldering with heat production in the range 0 W to 60 W, the heat loss to the cooling unit was in the range 5 W to 20 W. There were only marginal differences between non-extinguished and extinguished cases. Up-scaling is discussed, cooling could be feasible for preventing smoldering fires in silos.
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| 5. |
- Fjellgaard Mikalsen, Ragni, et al.
(författare)
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Jet fires and cryogenic spills: How to document extreme industrial incidents
- 2019
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Ingår i: <em>Sixth Magdeburg Fire and Explosion Days (MBE2019) conference proceedings, </em>.
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Konferensbidrag (refereegranskat)abstract
- In industrial plants, such as oil platforms, refineries or onboard vessels carrying fuel, a rupture event of a pipeline could have dramatic consequences, as was demonstrated both in the Piper Alpha and Deepwater Horizon accidents. If surfaces are exposed to extreme conditions, both extreme cold (cryogenic spills) and extreme heat (jet fires), this can affect exposed surfaces, and can cause a domino effect of severe events.
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| 6. |
- Reitan, Nina Kristine, et al.
(författare)
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Brannsikkerhet ved bruk av krysslaminert massivtre i bygninger – en litteraturstudie
- 2019
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Rapport (övrigt vetenskapligt/konstnärligt)abstract
- This literature study presents recent research on fire safety in cross laminated timber (CLT) buildings. Results from large fire experiments and other studies in the period 2010 - 2018 are summarized, with focus on the following research questions:• How do constructions consisting of protected or exposed CLT contribute to the fire development in a room?• How can contribution to the fire development from detailing of CLT be avoided?There is an increasing desire to use wooden structures in tall buildings, as a substitute for more traditional construction materials. However, the use of combustible construc-tions in buildings in Norwegian Fire Class 3 (usually five floors or more) is not pre-accepted in the guideline to Regulations on technical requirements for construction works (TEK17), and fire safety must therefore be documented by analysis in such structures. When designing tall and complex timber buildings, it must be taken into account that a fire involving a timber construction may have more severe consequences than in buildings with constructions of steel or concrete, if the fire design of the construction and detail solutions is insufficient. Several studies show that fire exposed CLT, or CLT with insufficient protection, can cause a fire to develop faster, be more intense and last longer than a fire where the only fuel is the furniture and fixtures in the fire room. It is shown that the amount of fire exposed timber in a room may have impact on the extent and duration of a fire, but the knowledge has not yet been sufficient enough to be used in fire modeling, design and analysis.Research on charring rates, delamination and auto-extinction, all of which are factors that can have major impact on fire development and the fire resistance of the construction, takes place in Europe, Australia and North America. Although extensive research has been carried out, it is based on few large fire experiments, and the literature is still pointing to several knowledge gaps. However, the research projects have increased the knowledge of fire in timber buildings, and have contributed to the design of detail solutions, guidelines and development of models for function-based design. Revision of EN 1995-1-2 is under preparation and expected to apply from 2022. A knowledge base for the audit can be found in the network COST Action FP1404 Fire Safety Use of Bio-Based Building Products (COST FP1404) Working Group 2 (WG2). They have published several guidelines relevant for the fire design of CLT, including e.g. calculation methods for the prediction of charring rates and depths, determination of reduced CLT cross-section, design of CLT detailing and a suggested test method for evaluating adhesive performance.Based on the literature review, the following conclusions and recommendations are given for CLT constructions:• The design phase must sufficiently consider protection of the construction and con-tribution of the construction to the fire energy, and to a greater extent include the assessment of detailing and ventilation conditions. It should be considered whether analytic fire engineering design also should be required for buildings in the Norwegian Fire Classes 1 and 2 where more than one CLT wall is exposed.• By protecting all CLT surfaces of the structure with cladding, the construction may retain the stability and the load bearing capacity during the required time of fire resistance.• In buildings with only one exposed CLT wall in each fire cell, it may also be appropriate to use solutions that satisfy the pre-accepted performances, but one must consider whether a somewhat longer and more intense heat radiation and flame exposure on the facade outside window openings will require measures beyond the pre-accepted performances given in the guideline to TEK17.• Rooms where two or more CLT walls in addition to the ceiling are exposed, are configurations that should be avoided.• The risk of delamination can be reduced by using heat-resistant glue.• There is generally a need for relevant documentation for fire-resistant solutions for joints between CLT walls and floors and service penetrations in CLT constructions.• Test methods for testing of joints and penetrations in CLT constructions should be standardized. For example, there exists no standardized test for corner joints. Tests of penetration seals for CLT constructions are scarce, although they can be tested according to EN 1366-3. However, CLT is not a standard supporting construction according to EN 1366-3, and this must be taken into consideration when the test results are evaluated. Joints in glulam constructions should also be tested because they are often used in conjunction with CLT elements.
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| 7. |
- Storesund, Karolina, et al.
(författare)
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Brannsikkerhet i lek- og aktivitetssenter
- 2019
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Rapport (övrigt vetenskapligt/konstnärligt)abstract
- Fire safety in buildings used for play and recreational activityThis project has been carried out on behalf of the Norwegian Building Authority (DiBK) and the Norwegian Directorate for Civil Protection (DSB) as part of the research agreement between DSB and RISE Fire Research.The aim of the project has been to determine whether activity centres (offering indoor activities for different age groups, e.g. indoor playgrounds, trampoline parks and gymnastics halls) are well equipped to reduce the risk of ignition, spread of fire, and smoke production, and for high heat release as well as to handle escape in case of fire. All with regard to the particular combination of the number and type of visitors, type of activity in the premises, as well as the large amount of combustible and potentially highly flammable furnishings present in the building.In this report we have described fire engineering issues specifically related to the activity centres, partly based on a study of technical reports from the buildings’ planning phase and monitoring reports from the operational phase.Our main findings are related to• Lacking overall fire safety evaluation regarding the building and the safety plans of the responsible business owner with respect to:- The significance of the furnishing and use of material for personal safety.- Distribution of responsibility to evaluate the furnishing in a risk perspective.• Ignition and early fire development:- There is not enough focus on ignition sources in the design and planning phase.- The fire performance of materials is not sufficiently taken into account during the design and planning phase and the requirements for documentation are insufficient and not relevant enough.• Escape:- Children's behaviour during escape is not taken into account when planning.- The activity in activity centres is not taken into account during the planning phase.- The effect of the interior (both material properties, physical position in the room and geometry) on the escape routes and escape time is not taken into account when planning.- Deviations from the requirement for low-placed way guidance systems are made on an uncertain basis.• Organizational measures:- Organizational measures are hardly mentioned in the fire concepts.- Deviations regarding organizational measures during the operational phase is the responsibility of business owners. This indicates uncertainty or lack of competence of regulations
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| 8. |
- Storesund, Karolina, et al.
(författare)
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Evaluating particle and gas transmission through firefighters’ clothing
- 2019
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Ingår i: Interflam 2019.
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Konferensbidrag (refereegranskat)abstract
- The goal of this project has been to establish new knowledge and methods for testing the penetration of hazardous soot and smoke particles into fire clothing. The aim has been to provide the basis for the development of new fire-fighter clothing with better protection against particle penetration. In cooperation with fire services, authorities and protection clothing producers, needs, requirements and recommendations have been investigated. For the documentation and relevant classification of protective clothing, test set-ups in small and larger scale have been developed. The aim has been to be able to achieve representative and repeatable fire- and smoke exposure for accurate measurement of the particle penetration into clothing and trough clothing layers for screening materials and design solutions. With regard to the performance of the clothing, the small-scale tests give indications of the textiles’ ability to block gases and particles from penetrating into the clothing. The large-scale tests give indications to how the design of the clothing as a whole is able to prevent intrusion of gases and particles.
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