Flexural strength

About: Flexural strength is a research topic. Over the lifetime, 52123 publications have been published within this topic receiving 846504 citations. The topic is also known as: bending strength & modulus of rupture.

Comparison of Polylactic Acid/Kenaf and Polylactic Acid/Rise Husk Composites: The Influence of the Natural Fibers on the Mechanical, Thermal and Biodegradability Properties

Abstract: This paper investigates and compares the performances of polylactic acid (PLA)/kenaf (PLA-K) and PLA/rice husk (PLA-RH) composites in terms of biodegradability, mechanical and thermal properties. Composites with natural fiber weight content of 20% with fiber sizes of less than 100 μm were produced for testing and characterization. A twin-screw extrusion was used to compound PLA and natural fibers, and extruded composites were injection molded to test samples. Flexural and Izod impact test, TGA, soil burial test and SEM were used to investigate properties. All results were compared to a pure PLA matrix sample. The flexural modulus of the PLA increased with the addition of natural fibers, while the flexural strength decreased. The highest impact strength (34 J m−1), flexural modulus (4.5 GPa) and flexural strength (90 MPa) were obtained for the composite made of PLA/kenaf (PLA-K), which means kenaf natural fibers are potential to be used as an alternative filler to enhance mechanical properties. On the other hand PLA-RH composite exhibits lower mechanical properties. The impact strength of PLA has decreased when filled with natural fibers; this decrease is more pronounced in the PLA-RH composite. In terms of thermal stability it has been found that the addition of natural fibers decreased the thermal stability of virgin PLA and the decrement was more prominent in the PLA-RH composite. Biodegradability of the composites slightly increased and reached 1.2 and 0.8% for PLA-K and PLA-RH respectively for a period of 90 days. SEM micrographs showed poor interfacial between the polymer matrix and natural fibers.

Assessment of fibre orientation in ultra high performance fibre reinforced concrete and its effect on flexural strength

Abstract: Fibre distribution and orientation in a series of round panel specimens of ultra high performance fibre reinforced concrete (UHPFRC) was investigated using electrical resistivity measurements and confirmed by X-ray CT imaging. By pouring specimens in different ways, the orientation of steel fibres was influenced and the sensitivity of the electrical resistivity technique was investigated. The round panels were tested in flexure and the results are discussed in relation to the observed orientation of fibres in the panels. It was found that the fibres tended to align perpendicular to the direction of flow. As a result, panels poured from the centre were significantly stronger than panels poured by other methods because the alignment of fibres led to more fibres bridging the radial cracks formed during mechanical testing.

Mechanical Properties of Ultra-High-Performance Concrete Enhanced with Graphite Nanoplatelets and Carbon Nanofibers

Abstract: Effects of graphite nanoplatelets (GNPs) and carbon nanofibers (CNFs) on mechanical properties of ultra-high-performance concrete (UHPC) are investigated. A non-proprietary UHPC mixture composed of 0.5% steel micro fibers, 5% silica fume, and 40% fly ash was used. The content of the nanomaterials ranged from 0 to 0.3% by weight of cementitious materials. The nanomaterials were dispersed using optimized surfactant content and ultra-sonification to ensure uniform dispersion in the UHPC mixture. As the content of nanomaterials is increased from 0 to 0.3%, the tensile strength and energy absorption capacity can be increased by 56% and 187%, respectively; the flexural strength and toughness can be increased by 59% and 276%, respectively. At 0.2% of GNPs, the UHPCs exhibited “strain-hardening” in tension and in flexure.

Alumina: Processing, Properties, and Applications

Abstract: 1 Introduction.- 1.1 Scope of the Book.- 1.2 General Remarks on the Use and the Behavior of Ceramic Materials.- 1.3 The History of Alumina.- 1.4 Preceding Summarizing Literature on Alumina.- 2 Physical Properties.- 2.1 Structure.- 2.2 Thermal Properties.- 2.3 Diffusion.- 2.3.1 General Remarks on Diffusion Phenomena in Ceramics.- 2.3.2 Intrinsic Diffusion and Disorder Mechanism.- 2.3.3 Extrinsic Diffusion.- 2.3.4 Problems in Determining the Diffusion Coefficient.- 2.3.5 Diffusion Data.- 2.4 Electrical Conductivity.- 2.5 Sintering and Grain Growth.- 2.5.1 Fundamental Sintering Mechanisms in Al2O3.- 2.5.2 Intermediate and Final-Stage Sintering.- 2.5.3 Influence of Additives.- 2.5.4 Effect of MgO.- 2.5.5 Influence of Atmospheres.- 2.5.6 Grain Growth.- 2.6 Hot Pressing.- 2.7 Segregation.- 3 Mechanical Properties.- 3.1 Elastic Properties.- 3.2 Fracture Strength.- 3.2.1 The Strength of Ceramics.- 3.2.2 Fracture Energy.- 3.2.3 Types of Flaws.- 3.2.4 Strength Data.- 3.2.5 Strength-Grain Size Relationships.- 3.3 Time-Dependent Strength and Subcritical Crack Growth.- 3.3.1 The Model of Time-Dependent Strength.- 3.3.2 Subcritical Crack Growth Data.- 3.3.3 Fatigue Data.- 3.3.4 Mechanisms of Slow Crack Growth in Alumina.- 3.4 Thermal and Mechanical Shock Resistance.- 3.4.1 Thermal Shock Properties.- 3.4.2 Mechanical Shock Properties.- 3.4.3 Crack Healing.- 3.5 Plastic Deformation.- 3.5.1 Slip.- 3.5.2 Twinning.- 3.5.3 Hardness.- 3.5.4 Abrasive Wear.- 3.6 Creep.- 3.6.1 Basic Creep Mechanisms.- 3.6.2 Creep of Pure and MgO-Doped Alumina.- 3.6.3 Effect of Other Dopants.- 3.6.4 High Temperature Failure Mechanisms.- 3.7 Strengthening Mechanisms.- 3.7.1 Second Phase Dispersions.- 3.7.2 Compressive Surface Stresses.- 3.7.3 Transformation Thoughening.- 4 Fabrication.- 4.1 Preparation of Powders.- 4.2 Forming.- 4.2.1 Dry Pressing.- 4.2.2 Hydrostatic Molding.- 4.2.3 Extrusion.- 4.2.4 Injection Molding.- 4.2.5 Hot Pressing.- 4.3 Sintering.- 4.4 Hard Machining.- 4.5 Quality Control.- 4.6 Manufacturing Tolerances.- 4.7 Principles of Design.- 5 Applications.- 5.1 Electronic Applications.- 5.1.1 Metal-to-Ceramic Bonding.- 5.1.2 Spark-Plug Insulators.- 5.1.3 Components and Housings for Electron Tubes.- 5.1.4 Discharge Lamps.- 5.1.5 Microelectronics.- 5.2 Mechanical Engineering Applications.- 5.2.1 Thread Guides for Textile Machines.- 5.2.2 Wire Drawing Step Cones.- 5.2.3 Paper Machine Covers.- 5.2.4 Bearings.- 5.2.5 Cutting Tools.- 5.3 Medical Applications.- 5.3.1 Artificial Joints.- 5.3.2 Dental Implants.- 5.3.3 Maxillary Reconstructions.- 5.4 Armor Applications.- 5.5 Other Applications.- References.