Your search keyword '"Curtis PT"' showing total 8 results

1. Self-Sensing Composites: In-Situ Detection of Fibre Fracture

Author

Malik, SA, Wang, L, Curtis, PT, and Fernando, GF

Subjects

Technology, Science & Technology, structural health monitoring, Pressure sensor, fibre fracture, Chemistry, Analytical, Aircraft composites, self-sensing, optical fibre sensors, lcsh:Chemical technology, Article, Strain, Analytical Chemistry, damage detection, Chemistry, Reinforced composites, Interferometry, Thermography, Physical Sciences, Electrical And Electronic Engineering, Electrochemistry, lcsh:TP1-1185, Instruments & Instrumentation

Abstract

The primary load-bearing component in a composite material is the reinforcing fibres. This paper reports on a technique to study the fracture of individual reinforcing fibres or filaments in real-time. Custom-made small-diameter optical fibres with a diameter of 12 (±2) micrometres were used to detect the fracture of individual filaments during tensile loading of unreinforced bundles and composites. The unimpregnated bundles were end-tabbed and tensile tested to failure. A simple technique based on resin-infusion was developed to manufacture composites with a negligible void content. In both cases, optical fibre connectors were attached to the ends of the small-diameter optical fibre bundles to enable light to be coupled into the bundle via one end whilst the opposite end was photographed using a high-speed camera. The feasibility of detecting the fracture of each of the filaments in the bundle and composite was demonstrated. The in-situ damage detection technique was also applied to E-glass bundles and composites; this will be reported in a subsequent publication.

Published

2016

2. The Development of a Satisfactory, Simple, Shear Fatigue Test for Unidirectional E-Glass Epoxy

Author

Butler, RJ, primary, Barnard, PM, additional, and Curtis, PT, additional

Published

1988

3. Compressive Failure of Laminated and Woven Composites

Author

Johnson, WS, primary, Masters, JE, additional, Fleck, NA, additional, Jelf, PM, additional, and Curtis, PT, additional

Published

1995

4. A new technique for tensile testing of engineering materials and composites at high strain rates.

Author

Zhou J, Pellegrino A, Heisserer U, Duke PW, Curtis PT, Morton J, Petrinic N, and Tagarielli VL

Abstract

A new test technique and bespoke apparatus to conduct high strain rate measurements of the tensile response of materials are presented. The new test method is applicable to brittle solids and composites as well as high-performance fibres, yarns and tapes used in composite construction. In this study, the dynamic response of monolithic poly(methyl methacrylate) and unidirectional composites based on Dyneema® tape, Dyneema® SK75 yarn and Kevlar® 49 yarn are explored. The technique allows early force equilibrium and yields valid tensile stress-strain curves, which include part of the elastic material response. The new method also enables investigation of size effects in tape and yarn materials, allowing testing of specimens of arbitrary length., Competing Interests: We declare we have no competing interests., (© 2019 The Author(s).)

Published

2019

5. Finite element simulation of the braiding process.

Author

Del Rosso S, Iannucci L, and Curtis PT

Abstract

Braiding is one of the most common technique employed for the manufacture of fabrics and ropes. It is also commonly used to produce near-net shaped preforms for advanced fibre reinforced composites. This paper presents an explicit finite element approach to create and simulate the braiding process for the virtual manufacture of 2D braids. The process starts from the definition of an analytical function which describes the movement of the carriers on a braiding track plate. Models of idealised Maypole-type braiding machines are built and used to shape virtual yarns into braids. This procedure can be used in a parameter control fashion, to optimise or to create virtual braided structures, which can serve as input for other structural analyses. It is emphasised that multiple cylinders are required for the modelling of a multifilament yarn to achieve better correlation with the experimental results. A parametric study is presented to investigate the effect of the number of virtual cylinders to represent a real yarn and the shape of the final braid. Excellent correlation was found between the virtual models and the experimental results when comparing the braid angle and yarn width., Competing Interests: The authors declare that they have no competing interests.Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Published

2019

6. Understanding the Thickness Effect on the Tensile Strength Property of Dyneema ® HB26 Laminates.

Author

Iannucci L, Del Rosso S, Curtis PT, Pope DJ, and Duke PW

Abstract

In this study, an experimental and numerical investigation is presented on the effect of thickness and test rate within the pseudo static regime on the tensile properties of Dyneema ® HB26 laminates. A detailed experimental presentation on the tensile testing of different thickness is presented and highlights the commonly seen observation that the tensile strength of a laminate reduces as a function of the specimen thickness. To understand these experimental observations, a constitutive material model of the individual macro fibril is developed and applied to modelling the fibre and upscaling to the laminate. The modelling strategy is implemented into ls-dyna and used to perform a parameter study on the specimen geometries used in the experimental study. The model assumes that the fibril strength is a function of the amorphous volume within the fibre and hence fibril. It can be observed that the experimental behaviour can be simulated by modelling the interface between laminate plies and the fibril, and hence fibre failure. The weak interfaces from the fibril to the laminate scale make the testing of fibres and laminates very difficult. Hence, it is proposed that the intrinsic fibril strength should be used as a measure of strength, and the fundamental strength is determined through numerical studies.

Published

2018

7. Joint moment-angle properties of the hip abductors and hip extensors.

Author

Kindel C Pt Mpt PhD and Challis J PhD

Subjects

Adolescent, Adult, Biomechanical Phenomena, Humans, Middle Aged, Pennsylvania, Range of Motion, Articular, Young Adult, Hip Joint physiology, Isometric Contraction, Knee Joint physiology, Muscle Strength, Muscle, Skeletal physiology

Abstract

Purpose: Strengthening of hip joint musculature is common in the rehabilitation of the lower extremity. However, strength curves for hip abduction and extension have not been assessed when varying the position of the knee. The force-length properties of the biarticular muscles can be affected when altering the position of the knee during the production of hip moments., Methods: Maximum isometric joint moments were measured at four different angles of hip abduction and hip extension, at the two knee positions (0° and 90°)., Results: The hip abduction and extension moments decreased as the hip moved from an adducted position and flexed position to an abducted position and extended position, respectively, resulting in a descending joint moment angle curve for each., Conclusion: The results indicate that position of the knee does not significantly change the normalized peak hip abduction joint moment, but the position of the knee does significantly change the normalized peak hip extension joint moment. This provides a baseline reference of hip joint moment production and can be utilized when assessing a population with a pathology or prescribing rehabilitative exercises.

Published

2017

8. Translating Genomic Advances to Physical Therapist Practice: A Closer Look at the Nature and Nurture of Common Diseases.

Author

Curtis CL, Goldberg A, Kleim JA, and Wolf SL

Subjects

Cardiovascular Diseases therapy, Genome-Wide Association Study, Humans, Motor Activity genetics, Osteoarthritis therapy, Pharmacogenetics, Physical Fitness, Polymorphism, Single Nucleotide, Precision Medicine, Cardiovascular Diseases genetics, Genetic Predisposition to Disease, Genomics, Osteoarthritis genetics, Physical Therapy Specialty

Abstract

The Human Genome Project and the International HapMap Project have yielded new understanding of the influence of the human genome on health and disease, advancing health care in significant ways. In personalized medicine, genetic factors are used to identify disease risk and tailor preventive and therapeutic regimens. Insight into the genetic bases of cellular processes is revealing the causes of disease and effects of exercise. Many diseases known to have a major lifestyle contribution are highly influenced by common genetic variants. Genetic variants are associated with increased risk for common diseases such as cardiovascular disease and osteoarthritis. Exercise response also is influenced by genetic factors. Knowledge of genetic factors can help clinicians better understand interindividual differences in disease presentation, pain experience, and exercise response. Family health history is an important genetic tool and encourages clinicians to consider the wider client-family unit. Clinicians in this new era need to be prepared to guide patients and their families on a variety of genomics-related concerns, including genetic testing and other ethical, legal, or social issues. Thus, it is essential that clinicians reconsider the role of genetics in the preservation of wellness and risk for disease to identify ways to best optimize fitness, health, or recovery. Clinicians with knowledge of the influence of genetic variants on health and disease will be uniquely positioned to institute individualized lifestyle interventions, thereby fulfilling roles in prevention and wellness. This article describes how discoveries in genomics are rapidly evolving the understanding of health and disease by highlighting 2 conditions: cardiovascular disease and osteoarthritis. Genetic factors related to exercise effects also are considered., (© 2016 American Physical Therapy Association.)

Published

2016