Predictive Numerical Analysis to Optimize Ventilation Performance in a Hydropower Surge Chamber for H2S Removal

Rahman, Mohammad Nurizat; Aris, Mohd Shiraz; Ujir, Mohd. Haffis; Boosroh, M.H.; Pillai, Dinishkaran Pillai a/l Velayutham

doi:10.37934/cfdl.13.10.6980

Cited by 4 publications

(3 citation statements)

References 18 publications

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“…Menter et al, [16,17] provide detailed information on the formulations and constants used in the SST k -ω model. The use of RANS simulations has been shown to produce results that are comparable to air dispersion experimental data, as seen in Kumar et al, [15] and Rahman et al, [18].…”

Section: In-situ Measurements and Numerical Simulationsmentioning

confidence: 55%

Coal Dust Severity in a Power Plant: In-Situ, Analytical, and Numerical Assessments

Mohammad Nurizat Rahman

2023

ARNHT

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One of the most serious occupational hazards in the coal industry is coal dust. Previous research revealed that the vast majority of coal dust assessments were conducted in coal mines, resulting in a lack of understanding of the severity of coal dust during coal handling activities in power plants. Therefore, the severity of combustible coal dust in one of Malaysia's power plants was assessed using a comprehensive analysis that included qualitative observations, in-situ measurements, numerical simulations, laboratory tests, and data analysis. The designated locations include the coal conveyor hall (Zone 1, 2A, and 2B), milling (Zone 3), and bunkering areas (Zone 4). Relevant safety limits, as recommended in National Fire Protection Association (NFPA) 654, were used as guidelines where comparisons with the site data were made. The high coal dust accumulation rate in Zone 1 was revealed to be largely the result of inefficient ventilation performance, as confirmed by in-situ measurement and numerical simulation. Direct referencing to the relevant NFPA 654 guidelines finds the zones encompassing the coal conveyor hall are at “high risk” of fire and explosion. Further laboratory assessments on the dust samples in Zone 1 however reduces the earlier assessment to “medium risk” with the potential of “low risk” with regular housekeeping. Zones 3 and 4 were found to be “low risk” areas due to insignificant accumulation and good air flow management. Overall, the evaluation of the severity of combustible coal dust was successful in establishing the risk mapping for all zones. Cleaning frequencies were also proposed based on the coal dust accumulation rates and the risk mapping.

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Section: In-situ Measurements and Numerical Simulationsmentioning

confidence: 55%

Coal Dust Severity in a Power Plant: In-Situ, Analytical, and Numerical Assessments

Mohammad Nurizat Rahman

2023

ARNHT

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“…As a result, it can help with combustion tuning for actual H 2 -NG co-firing in power plants. CFD has been used extensively to investigate flow dynamics, heat transmission, and combustion qualities [17][18][19][20][21]. As a result, a detailed Large Eddy Simulation (LES) was used in this study to investigate the effects of H 2 -NG co-firing on CRZs, combustion properties, and CIVB flashback risks in a pilot-scale swirl burner facility.…”

Section: Introductionmentioning

confidence: 99%

Large Eddy Simulation of Hydrogen/Natural Gas/Air Premixed Swirling Flames and CIVB Flashback Risks

Mohammad Nurizat Rahman,

Suzana Yusup

2023

CFDL

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The desire to develop gas turbines (GTs) that can utilise natural gas (NG) blended with hydrogen (H2) often encounters operability challenges related to combustion-induced vortex breakdown (CIVB) flashback issues. Hence, a detailed Large Eddy Simulation (LES) was employed in this study to examine the impact of H2-NG co-firing on central recirculation zones (CRZs), combustion properties, and the risk of CIVB flashback in a pilot-scale swirl burner facility. The LES model successfully replicated the swirling component of the flame observed in the experiment with reasonable accuracy. The findings revealed that the introduction of H2 into the burner increased the velocity and temperature of the burned gases. The higher reactivity of H2 resulted in faster burning rates and a shift in the reaction zone, indicating that NG-H2 firing burns more rapidly than pure NG firing. Additionally, H2 was found to enhance the velocity gradient, pushing the CRZ upstream. Changes in the location of the CRZ can disrupt density and velocity gradients, affecting the generation of vorticity by the baroclinic torque and potentially increasing negative axial velocity, thereby increasing the risk of CIVB flashback. Further research is necessary to comprehensively assess the CIVB flashback risk, particularly when the proportion of H2 exceeds 30 %.

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“…Another approach that has the potential to be a dependable and cost-effective strategy in the investigation of OPWs co-firing is numerical modelling (computational fluid dynamics). Numerical modelling has been shown to be an effective technique for diagnosing and resolving flow and combustion issues [24,[26][27][28][29][30][31]. As it can provide insights into the combustion properties of unfamiliar solid fuel blends [6,24], such as OPWs co-firing, it has been widely used to examine the combustion performance of a single coal and multiple solid fuel blends in bench-pilots and full-scale utility furnaces.…”

Section: Introductionmentioning

confidence: 99%

Oil Palm Wastes Co-firing in an Opposed Firing 500 MW Utility Boiler: A Numerical Analysis

Rahman

Yusup

Chin

et al. 2023

CFDL

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Malaysia is rich in palm oil plantations, where oil palm wastes (OPWs) are one of the readily accessible biomass resources. OPWs has the potential to be used as a fuel for electricity generation. Hence, the evaluation of OPWs co-firing for one of Malaysia's 500 MW utility boilers was executed numerically. Three types of OPWs were tested including empty fruit bunches (EFB), palm kernel shell (PKS), and palm mesocarp fibres (PMF). The predicted furnace exit gas temperature (FEGT) from the numerical model was validated against the actual FEGT from the power plant where the current boiler is situated, revealing a difference of less than 10%. The nose area temperature was predicted to exceed the cap of 1200°C in OPWs co-firing cases due to higher volatile matter (VM) in OPWs than the baseline of pure coal case, leading to higher levels of volatile release. When co-firing with OPWs, the predicted unburned carbon (UBC) at the boiler's outlet is lower because OPWs-coal blends contain less fixed carbon (FC) than the pure coal blend. UBC levels were anticipated to be lower than the loss of ignition (LOI) limit in all cases, highlighting its positive impact on carbon reduction. Slightly lowered mill performance was observed as a result of the calculated OPWs fuel flow surpassing the normal operation in the power plant to make up for the low gross calorific value (GCV) of OPWs while meeting the required load from the boiler. OPWs co-firing was predicted to emit lower carbon monoxide (CO) and carbon dioxide (CO2) than baseline coal due to lower FC. Nonetheless, higher thermal nitrogen oxides (NOx) were predicted due to the higher flame temperature created by OPWs co-firing. Even so, it is recommended that the ash mineral composition be included in future numerical studies since the ash minerals may have an effect on the emitted NOx.

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Predictive Numerical Analysis to Optimize Ventilation Performance in a Hydropower Surge Chamber for H2S Removal

Cited by 4 publications

References 18 publications

Coal Dust Severity in a Power Plant: In-Situ, Analytical, and Numerical Assessments

Coal Dust Severity in a Power Plant: In-Situ, Analytical, and Numerical Assessments

Large Eddy Simulation of Hydrogen/Natural Gas/Air Premixed Swirling Flames and CIVB Flashback Risks

Oil Palm Wastes Co-firing in an Opposed Firing 500 MW Utility Boiler: A Numerical Analysis

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