Olga Troynikov

Moisture management properties of wool/ polyester and wool/bamboo knitted fabrics for the sportswear base layer

This research seeks to investigate liquid moisture management properties of knitted fabrics of different wool/polyester and wool/bamboo blends of different ratios suitable for the base layer of sportswear. The fabrics were knitted in single jersey construction and their moisture management properties were assessed by using the Moisture Management Tester. Blending wool with polyester or wool with bamboo has improved moisture management properties of the fabrics in comparison to 100% wool and 100% bamboo fabrics. Out of nine fabrics studied, five fabrics were classified as moisture management fabrics that are suitable for the base layer of active sportswear.

Influence of cover factor on liquid moisture transport performance of bamboo knitted fabrics

The moisture transport responses to plain jersey fabrics produced from bamboo yarns were studied. The fabric responses included wetting times of top and bottom fabric surfaces, maximum moisture absorption rates of top and bottom surfaces, maximum wetted radii of top and bottom surfaces, spreading speeds of top and bottom surfaces, and cumulative one‐way transport capacity and overall moisture management capacity. The fabrics were produced from 100% bamboo yarns with 13 different fabric cover factors. The relationships between cover factors and moisture management properties were determined. It was observed that as the cover factor of the fabric increased, the wetting time increased, maximum wetted radius decreased, rate of absorption decreased, spreading speed decreased and overall moisture management capacity decreased.

Consumer behavior of generational cohorts for compression sportswear

Purpose – The purpose of this paper is to understand the difference in purchase decision behavior of compression sportswear by Baby Boomers and Generation Y. Design/methodology/approach – Two methods were used for data collection: a simulation study with 17 Baby Boomers and 23 Generation Y subjects using eye-tracking technology; and a questionnaire from a sample of 82 Baby Boomers and 84 Generation Y consumers. Findings – Generation Y are more inquisitive and focus greatly on technical information. Baby Boomers are more confident with their choices, taking a shorter time to reach a purchase decision; they are more concerned with aspects that protect the wearer. Research limitations/implications – Limited demographic information was collected from participants in the simulation study, further research is required in this area. Practical implications – This study provides important insights into the purchase decision behavior of Baby Boomers and Generation Y for compression sportswear. By providing better u...

Therapy gloves for patients with rheumatoid arthritis: a review

Rheumatoid arthritis is a chronic inflammatory disease that causes pain, joint stiffness and swelling leading to impaired hand function and difficulty with daily activities. Wearing therapy gloves has been recommended by occupational therapists as one of the alternative treatment methods for rheumatoid arthritis. This study aims to review the available literature on the effects of wearing therapy gloves on patients’ hand function and symptoms as well as to discuss the attributes of gloves that might influence the glove performance. An electronic databases search of MEDLINE, Physiotherapy Evidence Database, Occupational Therapy Systematic Evaluation of Evidence, Wiley Online Library, ScienceDirect and Cochrane Central Register of Controlled Trial was performed. Eight articles met the inclusion criteria, and covered seven clinical trials and one case study. Seven outcome measures were identified from the included studies and were then classified into two categories: hand function and hand symptoms. The hand symptoms such as pain, stiffness and swelling improve substantially when the therapy gloves are used. However, marginal or no improvement in hand function (with the exception of grip strength) linked to the use of therapy gloves is being reported. Further research is needed to quantify the effectiveness of therapy gloves, especially in improvement of hand function and in patients’ interest in wearing therapy gloves. Furthermore, future studies should include parameters which might influence therapy gloves’ performance, such as duration of trials, interface pressure generated by the gloves on the underlying skin and tissue, glove fit and construction, as well as thermophysiological comfort.

Evaluation and improvement of thermo-physiological comfort properties of firefighters’ protective clothing containing super absorbent materials

In this research, super absorbent materials were incorporated into the internal layer of the firefighters’ protective clothing with the aim of increasing absorption of sweat to improve the thermo-physiological comfort properties. The performance properties were evaluated following the standard test methods (ISO 6942:2002 and ISO 9151: 1995(E)) and the thermo-physiological comfort-related properties were evaluated by measuring the transport properties such as air permeability, water sorption and evaporation, thermal resistance and water vapour resistance of the fabric assemblies with super absorbent materials. The results indicated that it is possible to improve the comfort properties of the protective clothing by the incorporation of super absorbent materials into the internal layer. The use of super absorbent materials is likely to help in the absorption of sweat in higher amount and keeping the skin and internal microclimate dry, which in turn improves the comfort level. The performance properties of all the combinations satisfied the requirements for firefighter’s clothing as mentioned in AS/NZS 4967-2009.

Flexible Sensors for Pressure Therapy: Effect of Substrate Curvature and Stiffness on Sensor Performance

Flexible pressure sensors are increasingly being used in medical and non-medical applications, and particularly in innovative health monitoring. Their efficacy in medical applications such as compression therapy depends on the accuracy and repeatability of their output, which in turn depend on factors such as sensor type, shape, pressure range, and conformability of the sensor to the body surface. Numerous researchers have examined the effects of sensor type and shape, but little information is available on the effect of human body parameters such as support surfaces’ curvature and the stiffness of soft tissues on pressure sensing performance. We investigated the effects of body parameters on the performance of pressure sensors using a custom-made human-leg-like test setup. Pressure sensing parameters such as accuracy, drift and repeatability were determined in both static (eight hours continuous pressure) and dynamic (10 cycles of pressure application of 30 s duration) testing conditions. The testing was performed with a focus on compression therapy application for venous leg ulcer treatments, and was conducted in a low-pressure range of 20–70 mmHg. Commercially available sensors manufactured by Peratech and Sensitronics were used under various loading conditions to determine the influence of stiffness and curvature. Flat rigid, flat soft silicone and three cylindrical silicone surfaces of radii of curvature of 3.5 cm, 5.5 cm and 6.5 cm were used as substrates under the sensors. The Peratech sensor averaged 94% accuracy for both static and dynamic measurements on all substrates; the Sensitronics sensor averaged 88% accuracy. The Peratech sensor displayed moderate variations and the Sensitronics sensor large variations in output pressure readings depending on the underlying test surface, both of which were reduced markedly by individual pressure calibration for surface type. Sensor choice and need for calibration to surface type are important considerations for their application in healthcare monitoring.

Evaluation of Flexible Force Sensors for Pressure Monitoring in Treatment of Chronic Venous Disorders

The recent use of graduated compression therapy for treatment of chronic venous disorders such as leg ulcers and oedema has led to considerable research interest in flexible and low-cost force sensors. Properly applied low pressure during compression therapy can substantially improve the treatment of chronic venous disorders. However, achievement of the recommended low pressure levels and its accurate determination in real-life conditions is still a challenge. Several thin and flexible force sensors, which can also function as pressure sensors, are commercially available, but their real-life sensing performance has not been evaluated. Moreover, no researchers have reported information on sensor performance during static and dynamic loading within the realistic test conditions required for compression therapy. This research investigated the sensing performance of five low-cost commercial pressure sensors on a human-leg-like test apparatus and presents quantitative results on the accuracy and drift behaviour of these sensors in both static and dynamic conditions required for compression therapy. Extensive experimental work on this new human-leg-like test setup demonstrated its utility for evaluating the sensors. Results showed variation in static and dynamic sensing performance, including accuracy and drift characteristics. Only one commercially available pressure sensor was found to reliably deliver accuracy of 95% and above for all three test pressure points of 30, 50 and 70 mmHg.

3D body scanning method for close-fitting garments in sport and medical applications

Background: Close-fitting pressure garments and compression therapy are widely used for both sport and medical applications. These garments are constructed to have a negative fit where the size of the garment is smaller than the size of the body over which they are fitted. Due to this, these types of garments generate pressure on the underlying tissue of the human body. The degree and the distribution of the negative fit in such garments are of the utmost importance to ensure that the intended correct amount of pressure is generated by them. Aim: This research aims to develop a lower body 3D Body Scanning Measurement Method as applicable to garments with negative fit for sport and medical applications. Methods: New measuring methods both manual and with utilization of 3D Body scanning were developed with modifications to the Measurement Extraction Profile made to facilitate the body measurement at points of critical importance for the required application. Customised measurements were extracted and used for the evaluation of the garment performance or garment engineering. The developed method is validated on a representative sample of human subjects both male and female. Results and Conclusions: It is concluded that the Developed Method and 3D Scanning Protocol can be successfully used for lower body compression garments engineering and the calculation of the predictive pressure generated by these garments on the underlying human limbs. In addition, the protocol can be used for the generation of the true to scale body models and avatars.

Towards sustainable and safe apparel cleaning methods: A review

Perchloroethylene (PERC) is a compound commonly used as a solvent in dry cleaning, despite its severe health and environmental impacts. In recent times chemicals such as hydrocarbons, GreenEarth(®), acetal and liquid carbon dioxide have emerged as less damaging substitutes for PERC, and an even more sustainable water-based wet cleaning process has been developed. We employed a systematic review approach to provide a comprehensive overview of the existing research evidence in the area of sustainable and safe apparel cleaning methods and care. Our review describes traditional professional dry cleaning methods, as well as those that utilise solvents other than PERC, and their ecological attributes. In addition, the new professional wet cleaning process is discussed. Finally, we address the health hazards of the various solvents used in dry cleaning and state-of-the-art solvent residue trace analysis techniques.

Materials and Engineering Design for Human Performance and Protection in Extreme Hot Conditions

The level of protective material performance attributes are well defined and highly regulated, however the attributes related to the thermo physiological comfort of materials are not. In this chapter, the application of new materials to firefighting protective clothing systems used in extreme heat is addressed, with a focus on thermo physiological comfort. The new generation of protective textile materials and their structures are evaluated through use of both objective laboratory testing and mathematical modeling methods. In addition, 3D body imaging technology is utilized to demonstrate a method of assessing the fit of protective garments and its potential impact on the thermal status of the wearer. The proposed engineering approach could be used in other areas where the balance between clothing performance and wear comfort is critical, e.g. sport, work wear etc.