Impact of flat roof–integrated solar photovoltaic installation mode on building fire safety

Ju, Xiaoyu; Zhou, Xiaodong; Gong, Junhui; Zhao, Kun; Peng, Yang; Zhang, Cong; Ren, Xingyu; Yang, Lizhong

doi:10.1002/fam.2755

Cited by 17 publications

(25 citation statements)

References 35 publications

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“…As the angle of inclination varies across different installations, a fundamental analysis of flame spread below a horizontal panel is essential before introducing the influence of inclinations. This is supported by previous research which revealed that the smallest gap distance is expected to be most critical from a fire safety point of view due to increased heat flux [10], [27]. Thus, the current experiments are configured to form an understanding on how a non-combustible panel affect the initial stages of flame spread and subsequently compare these results to the influence of a PV module.…”

Section: Introductionsupporting

confidence: 69%

Experimental study of flame spread underneath photovoltaic (PV) modules

Kristensen

Faudzi

Jomaas

2021

Fire Safety Journal

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The horizontal flame spread underneath a photovoltaic (PV) module (or a plate) was studied for various gap heights to understand the fundamental fire dynamics between it and a flat roof construction. In a number of experiments, an opaque black polymethyl methacrylate (PMMA) and a black stainless-steel plate were used as surrogate fuel and module, respectively. Additional experiments were conducted with actual PV modules to analyse the reproducibility of the surrogate results and to study the potential effect of the small fuel contribution from the PV modules. PMMA samples (70 cm long) of varying widths (20 cm, 30 cm and 40 cm) were ignited at one end, and flame spread rate, mass loss, radiative heat flux and temperatures were recorded. For the 30 cm wide samples, a reduction in gap height from 20 cm to 17 cm resulted in a significant increase in the flame spread rate (from 0.37 mm/s to 2.41 mm/s). A similar critical gap height (transition into a much faster flame spread rate) was identified for all widths. Thus, introducing gap height requirements into PV installation standards could offer an inexpensive and elegant design that could reduce the fire risk associated with PV modules on flat roofs significantly.

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Section: Introductionsupporting

confidence: 69%

Experimental study of flame spread underneath photovoltaic (PV) modules

Kristensen

Faudzi

Jomaas

2021

Fire Safety Journal

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“…They explain that electric shock risks may occur from vital electrical PV components coming into contact with workers. Since PV systems are challenging to de-energize once energized and exposed to sunlight (Levins, 1986; Wybo, (2) Utilizing fire-resistant material during installations (Cancelliere et al , Ju et al , 2019) (3) Ground or insulate dead metal parts, implement safety such as ground fault and bypass diodes (Levins, 1986) Design alleys in a PY system to aid circulation (Wu et al, 2020;Wybo , 2013) design frangible structures to make panel fol dab le in case of shock emergency (Wybo, 2013) (7) Increasing the PY tilt angle and panel-roof distance to reduce flame propagation (Ju et al , 2019;Kristensen et al , 2021) (8) Utilize refractory glass and Type II J-box design (Huang et al ,20 I 8) (9) PY module backsheet fire-resistant design (Cancelliere et al , 2014) ( I 0) Strategic placement of fire fighting equipment across the plant and in vehicles, clearing of fire breaks around site boundary (Guerin, 2017) ( 11) Arc Fault detection techniques and algorithms (Wu et al , 2020;Onrran et al , 2020;Lu et al , 2018) (I) Unacclimatized workers with a work intensity of 400 kcal/h (heavy work) need to rest for 75% of each hour.…”

Section: Electrical and Fire Hazardsmentioning

confidence: 99%

“…The remaining references focus on fire risks concerning rooftop PV installations. For example, multiple articles studied the effect of PV tilt angle and panel-roof distance on reducing the potential of fire outbreaks associated with PV installations (Ju et al, 2019;Kristensen et al, 2021;Kristensen & Jomaas, 2018). At the same time, other studies focused on improving the junction box design (Huang et al , 2018) or module backsheet design to reduce fire risks (Cancelliere et al, 2014).…”

Section: Electrical and Fire Hazardsmentioning

confidence: 99%

Solar Installations & Their Occupational Risks

Duroha

Macht

2021

Proceedings of the Human Factors and Ergonomics Society Annual

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With the solar industry’s rapid growth, it is crucial to continuously review and assess the occupational risks associated with photovoltaic (PV) installations. PV installers are exposed to severe occupational risks, including but not limited to electrocution, heat stress, fall accidents, and manual handling risks. However, it is unclear what research is being done to mitigate these risks and where more research is required. Therefore, this paper performs a systematic literature review using the Scopus database to comprehensively review and identify: (1) the current knowledge available regarding the occupational risks associated with PV installations, (2) the health and safety effects these risks have on PV installers, (3) the research being done to mitigate them, and (4) the knowledge gaps for future research. This research can guide areas for future research concerning occupational safety and health in the PV installation sector.

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“…The preventive actions include array recombination and detection algorithm research. The studies [40][41][42][43][44][45][46][47][48][49][50] illustrate the reconfiguration of PV modules or PV arrays, and the studies introduce algorithm to detect the faulty PV modules.…”

Section: Solutions To Prevent Pv Fire Accidentsmentioning

confidence: 99%

“…When the module is arranged horizontally, the purlins are arranged vertically as shown in Figure 11. In this case, due to the chimney effect, the fire spreads faster than arrays with vertically arranged components [43][44][45].…”

Section: Figure 10 Dust Deposition On a Pv Arraymentioning

confidence: 99%

A Review for Solar Panel Fire Accident Prevention in Large-Scale PV Applications

Wen

et al. 2020

IEEE Access

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Due to the wide applications of solar photovoltaic (PV) technology, safe operation and maintenance of the installed solar panels become more critical as there are potential menaces such as hot spot effects and DC arcs, which may cause fire accidents to the solar panels. In order to minimize the risks of fire accidents in large scale applications of solar panels, this review focuses on the latest techniques for reducing hot spot effects and DC arcs. The risk mitigation solutions mainly focus on two aspects: structure reconfiguration and faulty diagnosis algorithm. The first is to reduce the hot spot effect by adjusting the space between two PV modules in a PV array or relocate some PV modules. The second is to detect the DC arc fault before it causes fire. There are three types of arc detection techniques, including physical analysis, neural network analysis, and wavelet detection analysis. Through these detection methods, the faulty PV cells can be found in a timely manner thereby reducing the risk of PV fire. Based on the review, some precautions to prevent solar panel related fire accidents in large-scale solar PV plants that are located adjacent to residential and commercial areas.

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Impact of flat roof–integrated solar photovoltaic installation mode on building fire safety

Cited by 17 publications

References 35 publications

Experimental study of flame spread underneath photovoltaic (PV) modules

Experimental study of flame spread underneath photovoltaic (PV) modules

Solar Installations & Their Occupational Risks

A Review for Solar Panel Fire Accident Prevention in Large-Scale PV Applications

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