E-Book, Englisch, 83 Seiten
Salvo Wearable technologies for sweat rate and conductivity sensors: design and principles
1. Auflage 2013
ISBN: 978-3-95489-537-3
Verlag: Anchor Academic Publishing
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
E-Book, Englisch, 83 Seiten
ISBN: 978-3-95489-537-3
Verlag: Anchor Academic Publishing
Format: PDF
Kopierschutz: Adobe DRM (»Systemvoraussetzungen)
Wearable sensors present a new frontier in the development of monitoring techniques. They are of great importance in sectors such as sports and healthcare, as they permit the continuous monitoring of physiological and biological elements, such as ECG and human sweat. Until recently, this could only be carried out in specialized laboratories in the presence of cumbersome, and usually, expensive devices. Sweat monitoring sensors integrated onto textile substrates are not only part of a new field of work but, they also represent the first attempt to implement such an innovative idea on a system which will be worn directly on the body. The objective of this book is to present possible designs and technologies of low cost wearable sweat rate and conductivity sensors integrated onto a textile. The first chapter deals with a preliminary introduction on sweat production and composition, and the applications of wearable devices. Further, the second chapter describes the conductivity sensor, i.e. the geometry, materials and the coupling which includes a temperature sensor for precise measurements are discussed. This is followed by a chapter on the sweat rate sensor, and the technologies employed to fabricate it. Sensors that are based on a) conductive yarns coated with hydrophilic polymers, b) conductive polymer fibres, c) hydrophilic polymers between conductive fabrics and d) humidity sensors are described in detail. Finally, the last chapter provides a study of sweat production in different body areas, the calibration procedure, and summarizes the results which arise from the tests on volunteers.
Biography Pietro Salvo received the M.Sc. degree in Electronic Engineering in 2004, specialization in biomedical applications, with the thesis "Realization of low-power analogue SC-CMOS filter which implements the wavelet algorithm to analyse ECG signals in pacemakers." During his M.Sc. thesis, he was at the Delft University of Technology, Electronics Research Laboratory, Faculty of Electrical Engineering, Mathematics and Computer Science, Mekelweg 4, Delft (The Netherlands). He received the Ph.D. degree in "Automation, Robotics and Bioengineering" from University of Pisa, Italy, in 2009 with the thesis "Development of wearable sensors for the measurement of sweat conductivity and rate." From 2008 until 2009, he was at the Institute for the Conservation and Promotion of Cultural Heritage, National Council of Research, Florence (Italy) where he was involved in the development of models and protocols for the monitoring of monumental buildings and paintings. In 2009-2013, he was at the Centre for Microsystems Technology (CMST), Ghent University, Ghent (Belgium), where he was responsible of the development of sensors, electronic devices and microfluidic systems for bioengineering platforms. From 2013 to 2016, he was at the Department of Chemistry and Industrial Chemistry, University of Pisa, Pisa (Italy) where he worked on sensors and biosensors for the monitoring of human fluids and physiological parameters. From September 2016, he is at the Institute of Clinical Physiology, National Council of Research, Pisa (Italy), where he is currently working on bioengineering applications such as a human breath sampling system, sensors for monitoring food quality and wearable sensors for wound monitoring. His scientific areas of interest include sensors and biosensors, non-invasive or minimal invasive monitoring tools, wireless sensors networks, smart materials and nanomaterials, hybrid systems, data analysis and signal processing.
Autoren/Hrsg.
Weitere Infos & Material
1;Wearable technologies for sweat rate and conductivity sensors: design and principles;1
1.1;Contents;3
1.2;Acknowledgements;4
1.3;Preface;5
1.4;Introduction;6
1.5;Chapter 1 – Wearable sensors;7
1.5.1;1.1 BIOTEX project;7
1.5.2;1.2 Sweat;8
1.5.3;1.3 Applications and sensors requirements;11
1.5.4;1.4 Market innovation analysis and level of innovation;16
1.5.5;References;18
1.6;Chapter 2 – Sweat conductivity and temperature sensors;20
1.6.1;2.1 Definition and preliminary tests;20
1.6.2;2.2 Geometry and substrate of electrodes;24
1.6.3;2.3 Temperature sensor;29
1.6.4;2.4 Conductivity and temperature sensors;34
1.6.5;References;37
1.7;Chapter 3 - Sweat rate sensor;38
1.7.1;3.1 Measurement of flow;38
1.7.2;3.2 Humidity sensors;39
1.7.2.1;3.2.1 Resistive humidity sensors;39
1.7.2.2;3.2.2 Thermal conductivity humidity sensors;40
1.7.2.3;3.2.3 Capacitive humidity sensors;41
1.7.3;3.3 Wearable humidity sensors;41
1.7.3.1;3.3.1 Test system;42
1.7.4;3.4 Sensors based on conductive yarns coated with hydrophilic polymers;43
1.7.5;3.5 Sensors based on conductive polymer fibres;47
1.7.6;3.6 Sensors based on a layer of hydrophilic polymer between conductive fabrics;54
1.7.7;3.7 Test of the sweat rate sensor;57
1.7.8;References;61
1.8;Chapter 4 - Calibration of the sensors and results;62
1.8.1;4.1 Choice of body area for sweat sampling;62
1.8.2;4.2 Calibration of the sensors;66
1.8.3;4.3 Results;72
1.8.4;4.4 Conclusions;82
1.8.5;References;83
Text Sample: Chapter 1.4, Market innovation analysis and level of innovation. The market is not only ready for the diffusion of wearable sensors but demand is also increasing. Smart fabrics and interactive textiles (SFITs) are likely to exceed $ 640 US million by the end of 2008. Moreover, the compound annual growth rate (CAGR) was about 27% in the period 2004-2008. According to BCC Research in 2007, the US market for smart textiles alone was worth about $ 79 million. Sales of conductive fabric products are expected to more than double each year through 2012, when the market is expected to reach $ 392 million. BCC expects rapid growth in military, health care, vehicle safety and comfort applications, thus leading to a greater impact of wearable sensors in the global market for sensors. Very few products that were designed to monitor health have reached the market, but significant amounts of money are being invested in this technology. Most of the products already available were designed for use by athletes. Lifeshirt, manufactured by Vivometrics, was designed for respiratory monitoring and other physiological signals, such as heart rate, EEG, EOG. Users have to wear a cap and a thimble in order to have their EEG/EOG and blood oxygen saturation monitored, respectively. Lifeshirt correlates and makes indirect measurements to obtain blood pressure, body temperature, periodic leg movement, and end tidal CO2. In any case, its use is limited to research and military centres. Sensatex, a U.S. company, is working on a Smart Textile Technology and on the SmartShirt System, which should be able to measure and/or monitor heart rate, respiration rate, body temperature, caloric burn, body fat, and UV exposure. Wealthy is a system by Smartex, an Italian company, able to acquire physiological parameters like ECG, posture and temperature. The most common products available are for heart monitoring by Polar, Reebok or Mio?, pedometers and pulse meters manufacture by, for example, Oregon Scientific and for diabetes monitoring such as GlucoWatch®, which shows glucose levels in blood. The development of a wearable sensor, which can be integrated into textiles, for sweat analysis is a complete breakthrough. This book is, in fact, one of the first attempts to correlate electrophysiological data with biochemical information. The results should provide lead to a more effective system than any other currently on the market. At present, to the best of our knowledge there is no product on the market that can perform multiple physiological measurements using a portable wireless system. Furthermore, although there are some devices that can monitor some physiological parameters, there are no chemical wearable sensors currently available. This point needs emphasizing since it represents the most important strength of the project, providing a new useful non-invasive instrument and technique for trainers, doctors, patients and users. Protection, safety, health and also fashion are sectors which will be greatly influenced by wearable sensors and it is certainly not farfetched to imagine a future where our life will be regulated by these new sensors.
