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1. Circuit Connection Reconfiguration of Partially Shaded BIPV Systems, a Solution for Power Loss Reduction

   Hosseiniirani, Seyedehhamideh; Kim, Kyoung-Hee (December 2023, ACSA Annual Meeting In Common)

   Integrating PV panels as a source of clean energy has been a widely established method to achieve net-zero energy (NZE) buildings. The exterior envelope of the high-rise buildings can serve as the best place to integrate PV panels for utilizing solar energy. The taller the building, the higher the potential to utilize solar energy by PV panels. However, shadows casting on the BIPV façade systems are unavoidable as they are often subject to partial shades from panels self-shading as well as building walls. Partial shading or ununiform solar radiation on the PV surface causes a dramatic decrease in the current output of the circuit. For that reason, in BIPV facades the default circuit connection of manufactured PV panels does not output maximum power under partial shading conditions. This paper investigates the different circuit connections in BIPV façade system to achieve higher energy yields while addressing design requirements. To this end, PV power production in different circuit connection reconfiguration scenarios was explored in two levels of BIPV components: 1) PV cells, and 2) strings of PV cells. Experimental tests conducted to validate the simulation results. The results of this study indicated that the maximum power generation occurred when the circuit connection between cells within a string is series, and the circuit connection between the strings within a PV panel is parallel. Results of the experimental tests shown that the series-parallel circuit connection increases the energy yields of the BIPV facades 71 times in real-world applications. The comparison analysis of the Ladybug energy simulations and the proposed analysis Grasshopper analysis recipe power output showed that the developed Grasshopper script will increase the BIPVs energy yields by 90% in simulations. 

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2. Understanding the Impact of Climate Change on Building Façade-integrated Photovoltaic Durability Testing: A Review

   Zhang, Enhe; Tenent, Robert; Wang, Julian (January 2025, American Solar Energy Society)

   Building-integrated photovoltaic (BIPV) systems blend energy generation with traditional architectural facade functions, promoting the development of zero-energy buildings by reducing energy consumption, lowering greenhouse gas emissions, and enhancing aesthetic value. Despite these benefits, the integration of photovoltaic technology into building materials introduces challenges, notably in ensuring structural integrity, maintaining thermal performance, and securing long-term durability under diverse environmental conditions. This review examines current standards and building codes relevant to BIPV windows, highlighting the necessity for testing protocols that encompass combined stressors from extreme weather events exacerbated by climate change. Through a case study focused on Singapore, the review underscores the rising frequency of combined heat and wind events, advocating for robust standards and adaptive policies. The paper identifies critical research gaps and proposes future directions to enhance the reliability and performance of BIPV systems, aiming to solidify their role in sustainable building practices. 

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3. Toward Net-Zero Energy Retrofitting: Building-Integrated Photovoltaic Curtainwalls

   Kim, Kyoung Hee Im (March 2021, International journal of highrise buildings)

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   With the rapid urbanization and growing energy use intensity in the built environment, the glazed curtainwall has become ever more important in the architectural practice and environmental stewardship. Besides its energy efficiency roles, window has been an important transparent component for daylight penetration and a view-out for occupant satisfaction. In response to the climate crisis caused by the built environment, this research focuses on the study of net-zero energy retrofitting by using a new building integrated photovoltaic (BIPV) curtainwall as a sustainable alternative to conventional window systems. Design variables such as building orientations, climate zones, energy attributes of BIPV curtainwalls, and glazed area were studied, to minimize energy consumption and discomfort hours for three cities representing hot (Miami, FL), mixed (Charlotte, NC), and cold (Minneapolis, MN). Parametric analysis and Pareto solutions are presented to provide a comprehensive explanation of the correlation between design variables and performance objectives for net-zero energy retrofitting applications. 

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4. Comprehensive analysis of energy and visual performance of building-integrated photovoltaics in all ASHRAE climate zones

   Hossei, Hamideh; Kim, Kyoung Hee (June 2024, Energy and buildings)

   Integrating PV panels into building facades (BIPV) necessitates a comprehensive understanding of the PV system’s impact on building energy consumption within the site’s climate zone. Maximizing PV power output depends on factors such as location, climate type, and latitude. However, minimizing total electricity consumption, which includes cooling, heating, and lighting loads, is significantly influenced by the design of the PV system and the climate region. This study conducted a thorough evaluation of the impact of south-facing PV-integrated louvers on both PV power generation and building energy performance, as well as occupants’ visual comfort, across 17 ASHRAE climate regions in the U.S. The results indicated that south-facing PV-integrated louvers significantly reduced building energy consumption in climate zones 1 to 3, as well as 4B and 5B. Wider louvers with longer spacing (S-3 typology) were particularly effective in zones with moderate cooling needs (climate zone 4). However, in colder climates (6–8) with significant heating demands, roof-mounted systems provided a better balance between power generation and solar heat gain for the building. The PV-louver designs effectively reduced sunlight penetration and maintained illuminance levels within the desired range across most of the floor area. Conversely, roof typologies exhibited lower lighting loads but resulted in significantly high mean illuminance levels on the working surface, leading to disturbing glare for occupants across a large portion of the floor area. The findings of this research offer practical implications for architects, engineers, and policymakers seeking sustainable building solutions. 

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5. Energy Use Sensitivity Analysis of Sensor Placement in Small Office Buildings with Dynamic Shading and Lighting

   Dong, Hao; Vanage, Soham; Cetin, Kristen (January 2022, ASHRAE Annual Conference 2022)

   The main energy end uses in commercial buildings include cooling, heating, and lighting. These energy consuming systems, however, can be substantially impacted by environmental parameters and sensor inputs when a building is being dynamically controlled. This study aims to conduct a sensitivity analysis on the energy consumption of a small commercial office building with an integrated control system, including automated shade devices and dimmable lighting. Previous studies have focused on sensitivity of automated shades energy impacts, based on glare level, solar irradiation, available daylighting and solar penetration; others have assessed the sensitivity of dimmable lighting on energy use. The focus of this study is to assess the impact of adjusting illuminance sensor location, and sensor rotation (towards or away from the exterior windows), for small office buildings with integrated shading and lighting controls in different ASHRAE climate zones. 

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