Analytical and Computer Modelling of Thermo-Mechanical Vapour Compression System
The use of traditional vapor compression systems for air conditioning in buildings is known for its high electrical power load and carbon footprint. TexGen addresses these challenges by offering an innovative thermo-mechanical vapour compression system that revolutionizes energy efficiency. Through analytical and computer modeling, TexGen's solution optimizes space air conditioning, providing indoor thermal comfort while significantly reducing energy consumption and environmental impact. This study paves the way for sustainable air conditioning practices in buildings.
Numerical Investigation into Thermal Interference of Slinky Ground Heat Exchangers
Understanding the thermal performance of ground heat exchangers is crucial for efficient heating and cooling systems. TexGen's numerical investigation delves into the thermal interference of slinky ground heat exchangers, offering insights into optimal trench separations, installation depths, and soil properties. By utilizing a validated transient 3D model, TexGen optimizes the operation of ground heat exchangers, enhancing energy efficiency in buildings. This study demonstrates TexGen's commitment to advancing sustainable heating solutions.
Innovative Solar-Driven Thermochemical Energy Storage Systems
TexGen's research focuses on modeling solar-driven thermochemical energy storage systems with heat recovery capabilities. By analyzing the integration of solar heat production with heating demand, TexGen enhances energy storage efficiency and promotes decarbonization in buildings. Through innovative approaches to typical salt hydrate TCES systems, TexGen pioneers sustainable energy technologies that align with global efforts towards a greener future. This study showcases TexGen's dedication to advancing renewable energy solutions.
Revolutionizing Natural Ventilation with Solar Chimney and Radiative Cooling Solutions
TexGen introduces a novel combination of solar chimney and radiative cooling cavity for natural ventilation enhancement in residential buildings. By parametrically studying this innovative approach, TexGen optimizes natural ventilation, promoting energy efficiency and indoor air quality. Leveraging radiative cooling for enhanced solar chimney ventilation, TexGen sets new standards for sustainable building designs. This study highlights TexGen's transformative impact on natural ventilation solutions.
Addressing Barriers to Electric Vehicle Adoption in Oil-Producing Nations
TexGen's research identifies potential barriers to electric vehicle adoption in oil-producing nations, focusing on the case of Saudi Arabia. By analyzing the unique challenges faced by EVs in such regions, TexGen sheds light on critical factors hindering their widespread adoption. Through this study, TexGen aims to facilitate the transition to electric mobility, offering valuable insights for policymakers, industry stakeholders, and environmental advocates. This research underscores TexGen's commitment to promoting sustainable transportation solutions.
Enhancing Demand-Controlled Ventilation Systems with Deep Learning and Computer Vision
TexGen explores the application of deep learning and computer vision for predicting occupancy CO2 levels in demand-controlled ventilation (DCV) systems. By integrating live occupancy detection, TexGen enhances the operational efficiency of DCV systems, ensuring optimal indoor thermal conditions and air quality. This study showcases TexGen's innovative approach to smart building technologies, revolutionizing ventilation systems for improved energy efficiency and occupant comfort.