Dynamic Modeling and Simulation of a Facade Integrated Adsorption System for Solar Cooling of Lightweight Buildings. MPDI-Energies, 2024. [PUMA: Adsorption Buildings Cooling Dynamic Facade Integrated Lightweight Modeling Simulation Solar System a and for of]
Systematic screening and evaluation for an optimal adsorbent in a facade-integrated adsorption-based solar cooling system for high-rise buildings. Elservier-Energy, 2024. [PUMA: Systematic a adsorbent adsorption-based an and buildings cooling evaluation facade for high in integrated optimal rise screening solar system]
Facade-integrated adsorption system for solar cooling of lightweight buildings. 2021. [PUMA: Facade-integrated adsorption buildings cooling for lightweight of solar system]
Low Order Hybrid Model for Control Design of an Adsorption Facade System for Solar Cooling. 2022. [PUMA: Adsorption Control Cooling Design Facade Hybrid Low Model Order Solar System an for of]
Modeling and simulation of a facade-integrated adsorption system for solar cooling of lightweight buildings. 2022. [PUMA: Modeling a adsorption and buildings cooling facade-integrated for lightweight of simulation solar system]
CoolSkin - A novel facade design for sustainable solar cooling by adsorption. 2023. [PUMA: - A CoolSkin adsorption by cooling design facade for novel solar sustainable]
Material Study for a Facade-Integrated Adsorption System for Solar Cooling of Buildings. 2023. [PUMA: Adsorption Buildings Cooling Facade-Integrated Material Solar Study System a for of]
Alternating operation of a facade-integrated adsorption chiller for continous cooling of lightweigth buildings. 2023. [PUMA: Alternating a adsorption buildings chiller continous cooling facade-integrated for lightweigth of operation]
Simulation-based determination of system size and energy savings for a life cycle assessment of a facade-integrated adsorption system for solar cooling of buildings. 2021. [PUMA: Simulation-based a adsorption and assessment buildings cooling cycle determination energy facade-integrated for life of savings size solar system]
Operation Optimization of a Facade Integrated Adsorption Based Solar Cooling System for Lightweight High-rise Buildings. 2024. [PUMA: Adsorption Based Buildings Cooling Facade High-rise Integrated Lightweight Operation Optimization Solar System a for of]
Modeling and simulation of a facade-integrated thermochemical energy storage system for solar cooling of buildings. 2024. [PUMA: Modeling a and buildings cooling energy facade-integrated for of simulation solar storage system thermochemical]
First experimental investigations of a facade-integrated adsorption system for solar cooling. 2024. [PUMA: First a adsorption cooling experimental facade-integrated for investigations of solar system]
Low Order Hybrid Model for Control Design of an Adsorption Facade System for Solar Cooling. 2022. [PUMA: Adsorption Control Cooling Design Facade Hybrid Low Model Order Solar System an for of]
Material Study for a Facade-Integrated Adsorption System for Solar Cooling of Buildings. 2023. [PUMA: Adsorption Buildings Cooling Facade-Integrated Material Solar Study System a for of]
First experimental investigations of a facade-integrated adsorption system for solar cooling. 2024. [PUMA: First a adsorption cooling experimental facade-integrated for investigations of solar system]
Modeling and simulation of a facade-integrated thermochemical energy storage system for solar cooling of buildings. 2024. [PUMA: Modeling a and buildings cooling energy facade-integrated for of simulation solar storage system thermochemical]
Simulation-based determination of system size and energy savings for a life cycle assessment of a facade-integrated adsorption system for solar cooling of buildings. 2024. [PUMA: Simulation-based a adsorption and assessment buildings cooling cycle determination energy facade-integrated for life of savings size solar system]
One-dimensional model of a closed low-pressure adsorber for thermal energy storage. Elsevier, 2017. [PUMA: One-dimensional a adsorber closed energy for low-pressure model of storage thermal]
Simulation of a closed low-pressure honeycomb adsorber for thermal energy storage. International Journal of Heat and Mass Transfer, Elsevier, 2018, 2018. [PUMA: Simulation a adsorber closed energy for honeycomb low of pressure storage thermal]
Modeling and simulation of closed low-pressure zeolite adsorbers for thermal energy storage. International Journal of Heat and Mass Transfer, Elsevier, 2019,, 2019. [PUMA: Modeling adsorbers and closed energy for low-pressure of simulation storage thermal zeolite]