Determination of Physical Parameters of Lightweight Concrete Based on Pozzolana and Palm Nut Shells in Cameroon (Published)
This study is part of a sustainable innovation dynamic in the field of construction materials, focusing on the physical properties of lightweight concretes formulated with class II cement (42.5 MPa strength), natural pozzolan, and palm kernel shells. The main objective is to assess the balance between structural lightness and physical parameters, in order to identify the formulations best suited to sustainable construction requirements. In this context, several formulations were developed by partially substituting conventional lightweight aggregates with natural lightweight aggregates, namely pozzolan and palm kernel shells, used separately. Experimental results highlight a strong correlation between the type of lightweight aggregate and the overall performance of the concrete. The concrete containing 34% palm kernel shells achieved a dry density of 1850 kg/m³ and a bulk density of 2100 kg/m³. This opens concrete perspectives for integrating these sustainable concretes into smart construction systems.
Keywords: Physical parameter, Pozzolan, Shell, lightweight concrete
Study of the Compressive Strength and Thermal Behaviour of Lightweight Concrete in Cameroon (Published)
This thesis contributes to sustainable innovation in construction materials. The primary objective is to evaluate the balance between mechanical strength, thermal behavior, and structural lightness, with the goal of identifying formulations best suited to energy-efficient and environmentally friendly building applications. To this end, several lightweight concrete mixtures were developed by partially replacing conventional aggregates with natural lightweight ones pozzolan and PKS used independently. The Dreux-Gorise method guided the mix design, and a cement fixed dosage of CPJ 42.5 is adopted. cylindrical specimens are cast and subjected to standardized tests to assess fresh and dry density, compressive strength, porosity, and thermal behavior. The experimental results show a clear relationship between the type of lightweight aggregate and the overall concrete with 34% PKS achieved a dry density of 1850 kg/m3 and a compressive strength of 19.3 MPa at 28 days, while the formulation with 23% demonstrated a superior compressive strength of 24 MPa at 28 days with a density of 2100 kg/m3. In addition to experimental testing, a digital validation of the compressive strength was conducted exclusively through numerical simulations performed in ANSYS, using literature-based values of thermal conductivity, specific heat capacity, and density consistent with the concrete formulations developed in this study. The simulation aimed to analyzed transient heat transfer and to highlight the thermal insulation potential of lightweight concrete. This research provides a comparative insight into two rarely juxtaposed natural aggregates and reinforces the role of digital methods in evaluating thermal performance of materials
Keywords: Compressive Strength, digital simulation, lightweight concrete, palm kernel shell, thermal performance