| 1 |
Fin orientation effect on passive cooling of photovoltaic panels: An experimental study under extreme hot climate |
Future Technology |
2025 |
j9uy2lxnob7pg3k.pdf
|
| 2 |
Performance improvement of flat plate solar collector employing phase change material bags and hybrid nanofluid |
Results in Engineering |
2025 |
hzkpc_89obg6dws.pdf
|
| 3 |
Advanced Optimization Techniques Using Artificial Intelligence Algorithms for Thermal Efficiency Estimation of Photovoltaic Thermal Systems |
Process Integration and Optimization for Sustainability |
2025 |
yxvp4rhoaw5jc_d.pdf
|
| 4 |
Experimental examination of a boiler heat exchanger using nanofluids: Thermo-energetic and enviro-economic analysis |
Sustainable Energy Technologies and Assessments |
2025 |
8dpu5c1z07hjy64.pdf
|
| 5 |
Energy, exergy, and economic analysis of indirect solar dryer integrated phase change material cans |
Energy Conversion and Management: X |
2025 |
1c4lnvdxhawtk02.pdf
|
| 6 |
Effect of window-to-wall ratio and thermal insulation on building thermal energy in various Iraqi Cities |
Misan Journal of Engineering Sciences |
2024 |
jvq9nf4t8liygh1.pdf
|
| 7 |
Conjoint effect of nanofluids and baffles on a heat exchanger thermal performance: Numerical approachConjoint effect of nanofluids and baffles on a heat exchanger thermal performance: Numerical approach |
Misan Journal of Engineering Sciences |
2024 |
dfz306ov9gtxjmh.pdf
|
| 8 |
Advanced building envelope by integrating phase change material into a double-pane window at various orientations |
Energy and Buildings |
2025 |
ue9ln_vk0fd1zwa.pdf
|
| 9 |
Energy and exergy assessment of a photovoltaic-thermal (PVT) system cooled by single and hybrid nanofluids |
Energy Conversion and Management: X |
2024 |
7c4o5x6t_81ev2w.pdf
|
| 10 |
Metal fibers-enhanced PCM thermal energy storage unit: An experimental approach on a composite roof application |
International Journal of Thermofluids |
2024 |
43ca0ebpd6fmt5v.pdf
|
| 11 |
Experimental and numerical study of a photovoltaic/thermal system cooled by metal oxide nanofluids |
Alexandria Engineering Journal |
2024 |
3mk_syqjz8xugla.pdf
|
| 12 |
Experimental study of PCM-enhanced building envelope towards energy-saving and decarbonisation in a severe hot climate |
Energy and Buildings |
2023 |
ht679ri_4k2xou3.pdf
|
| 13 |
Numerical analysis of thin building envelope-integrated phase change material towards energy-efficient buildings in severe hot location |
Sustainable Cities and Society |
2023 |
3idw94p0_thybvx.pdf
|
| 14 |
Building envelope-combined phase change material and thermal insulation for energy-effective buildings during harsh summer: Simulation-based analysis |
Energy for Sustainable Development |
2023 |
kfra26yi8enlt9m.pdf
|
| 15 |
Thermal analysis of concrete bricks-embedded phase change material: A case study under hot weather conditions |
Case Studies in Construction Materials |
2023 |
_93tdweqfu7ab5h.pdf
|
| 16 |
Hourly analysis of temperature and heat gain reduction for building envelope-compacted phase change material in extremely hot conditions |
Journal of Energy Storage |
2023 |
ur0n83my_fhtziq.pdf
|
| 17 |
Building envelope-enhanced phase change material and night ventilation: Effect of window orientation and window-to-wall ratio on indoor temperature |
Renewable Energy |
2023 |
ymgn2e3tj4cq8ba.pdf
|
| 18 |
Building envelope integrated phase change material under hot climate towards efficient energy and CO2 emission saving |
IEEE Xplore |
2022 |
un437_8dyh9r1ls.pdf
|
| 19 |
Performance enhancement of photovoltaic module using finned phase change material panel: An experimental study under Iraq hot climate conditions |
Energy Sources, Part A: Recovery, Utilization, and Environmental Effects |
2022 |
gpws6nr2ulqdjz7.pdf
|
| 20 |
Phase change material coupled building envelope for thermal comfort and energy-saving: Effect of natural night ventilation under hot climate |
Journal of Cleaner Production |
2022 |
n4sgfzl8v_9j26b.pdf
|
| 21 |
Energetic and thermal comfort assessment of phase change material passively incorporated building envelope in severe hot climate: An experimental study |
Applied Energy |
2022 |
g_dvz781ola6krb.pdf
|
| 22 |
A review on solar-powered cooling and air-conditioning systems for building applications |
Energy Reports |
2022 |
69mnzx5ycwtrls3.pdf
|
| 23 |
A SHORT REVIEW ON PASSIVE STRATEGIES APPLIED TO MINIMISE THE BUILDING COOLING LOADS IN HOT LOCATIONS |
Analecta Technica Szegedinensia |
2021 |
m1j76ospcyr2f38.pdf
|
| 24 |
Selection of Phase Change Material Suitable for Building Heating Applications based on Qualitative Decision Matrix |
Energy Conversion and Management: X |
2021 |
7q158kuc0nx4ih6.pdf
|
| 25 |
Global Warming Potential: Causes and Consequences |
Academia Letters |
2021 |
9_83vb01zgwdf7q.pdf
|
| 26 |
Paraffin As a Phase Change Material to Improve Building Performance: An Overview of Applications and Thermal Conductivity Enhancement Techniques |
Renewable Energy and Environmental Sustainability |
2021 |
0xgt752srnhielm.pdf
|
| 27 |
Experimental investigation of phase change material (PCM) incorporated composite flat roof for energy-saving under Iraq hot climate conditions |
AIP Conference Proceedings |
2021 |
pti4gfk28usl6d0.pdf
|
| 28 |
Effect of encapsulation area on the thermal performance of PCM incorporated concrete bricks: A case study under Iraq summer conditions |
Case Studies in Construction Materials |
2021 |
x9dchlkus807_4t.pdf
|
| 29 |
Thermal performance of concrete bricks based phase change material encapsulated by various aluminium containers: An experimental study under Iraqi hot climate conditions |
Journal of Energy Storage |
2021 |
wjzt95qsa4de8u1.pdf
|
| 30 |
Single and Hybrid Nanofluids to Enhance Performance of Flat Plate Solar Collectors: Application and Obstacles |
Periodica Polytechnica Mechanical Engineering |
2021 |
e159dvr3qn2tp6g.pdf
|
| 31 |
Power output enhancement of grid-connected PV system using dual-axis tracking |
Renewable Energy and Environmental Sustainability |
2020 |
bx4it893szon1c6.pdf
|
| 32 |
Performance Assessment of Phase Change Materials Integrated with Building Envelope for Heating Application in Cold Locations |
European Journal of Energy Research |
2021 |
znmis7hfovtua1q.pdf
|
| 33 |
PCMs in building envelope: characteristics, applications, key parameters and energy contribution |
Mechanical Engineering Letters |
2021 |
8n365mwuvacjlro.pdf
|
| 34 |
Solar absorption cooling systems versus traditional air-conditioning in hot climate |
Mechanical Engineering Letters |
2016 |
yvx78emrhpqlasu.pdf
|
| 35 |
Incorporation of phase change materials into building envelope for thermal comfort and energy saving: A comprehensive analysis |
Journal of Building Engineering |
2021 |
gc16b3sjl2nauim.pdf
|
| 36 |
Improving the productivity of a single-slope solar still using Fresnel lenses under Iraq climatic conditions |
Desalination and Water Treatment |
2020 |
3kz12ebgj_54v6m.pdf
|
| 37 |
Influential aspects on melting and solidification of PCM energy storage containers in building envelope applications |
International Journal of Green Energy |
2021 |
9g4sxrq7yoj5wue.pdf
|
| 38 |
Experimental evaluation of the optimal position of a macroencapsulated phase change material incorporated composite roof under hot climate conditions |
Sustainable Energy Technologies and Assessments |
2021 |
0dhsa_w3cgeq7ml.pdf
|
| 39 |
Evaluation Of An Off-grid Photovoltaic Technology For Household Application In Iraq |
Journal of Al-Nisour University College |
2018 |
_43pfgw0chdq9xe.pdf
|
| 40 |
Consumption Profile Based Analysis of Solar Thermal System for DHW in Buildings |
Hungarian Agricultural Engineering |
2019 |
sz2qphevk_7lcmi.pdf
|
| 41 |
Comparative Study of Building Envelope Cooling Loads in Al-Amarah City, Iraq |
Journal of Engineering and Technological Sciences |
2019 |
8zqs9gy_n20cpm3.pdf
|
| 42 |
Case study on the optimal thickness of phase change material incorporated composite roof under hot climate conditions |
Case Studies in Construction Materials |
2021 |
3y8rf46whv_72sn.pdf
|
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