Your search keyword '"Eric Häntzsche"' showing total 28 results

1. Novel Weft-Knitted Strain Sensors for Motion Capture

Author

Susanne Fischer, Bahareh Abtahi, Mareen Warncke, Carola Böhmer, Hans Winger, Carmen Sachse, Johannes Mersch, Eric Häntzsche, Andreas Nocke, and Chokri Cherif

Subjects

weft-knitted strain sensor, textile-based strain sensor, functional electrical stimulation (FES), multiple sclerosis (MS), knee angle, functional leggings, Mechanical engineering and machinery, TJ1-1570

Abstract

Functional electrical stimulation (FES) aims to improve the gait pattern in cases of weak foot dorsiflexion (foot lifter weakness) and, therefore, increase the liveability of people suffering from chronic diseases of the central nervous system, e.g., multiple sclerosis. One important component of FES is the detection of the knee angle in order to enable the situational triggering of dorsiflexion in the right gait phase by electrical impulses. This paper presents an alternative approach to sensors for motion capture in the form of weft-knitted strain sensors. The use of textile-based strain sensors instead of conventional strain gauges offers the major advantage of direct integration during the knitting process and therefore a very discreet integration into garments. This in turn contributes to the fact that the FES system can be implemented in the form of functional leggings that are suitable for inconspicuous daily use without disturbing the wearer unnecessarily. Different designs of the weft-knitted strain sensor and the influence on its measurement behavior were investigated. The designs differed in terms of the integration direction of the sensor (wale- or course-wise) and the width of the sensor (number of loops) in a weft-knitted textile structure.

Published

2024

2. Advancing Smart Textiles: Structural Evolution of Knitted Piezoresistive Strain Sensors for Enabling Precise Motion Capture

Author

Mareen N. Warncke, Carola H. Böhmer, Carmen Sachse, Susanne Fischer, Eric Häntzsche, Andreas Nocke, Johannes Mersch, and Chokri Cherif

Subjects

wearables, smart textiles, textile strain sensor, motion monitoring, medical applications, Organic chemistry, QD241-441

Abstract

Recently, there has been remarkable progress in the development of smart textiles, especially knitted strain sensors, to achieve reliable sensor signals. Stable and reliable electro-mechanical properties of sensors are essential for using textile-based sensors in medical applications. However, the challenges associated with significant hysteresis and low gauge factor (GF) values remain for using strain sensors for motion capture. To evaluate these issues, a comprehensive investigation of the cyclic electro-mechanical properties of weft-knitted strain sensors was conducted in the present study to develop a drift-free elastic strain sensor with a robust sensor signal for motion capture for medical devices. Several variables are considered in the study, including the variation of the basic knit pattern, the incorporation of the electrically conductive yarn, and the size of the strain sensor. The effectiveness and feasibility of the developed knitted strain sensors are demonstrated through an experimental evaluation, by determining the gauge factor, its nonlinearity, hysteresis, and drift. The developed knitted piezoresistive strain sensors have a GF of 2.4, a calculated drift of 50%, 12.5% hysteresis, and 0.3% nonlinearity in parts.

Published

2023

3. Investigation of the Bonding Mechanism between Overlapping Textile Layers for FRP Repair Based on Dry Textile Patches

Author

David Rabe, Juan Daniel Ortega Arbulu, Eric Häntzsche, and Chokri Cherif

Subjects

FRP, novel method repair, dry textile patch, thermoset composites, UV-based depolymerization, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Lots of damaged fiber-reinforced plastic (FRP) components are replaced by new components instead of repairing. Furthermore, only very labor-intensive repair methods are available on the market to fully restore the integrity of the structure. This requires a high level of experience or, alternatively, very cost-intensive technology, such as the use of computer tomography and robotics. The high costs and CO2 emissions caused by the manufacture of FRP components then bear no relation to their service life. The research project IGF-21985 BR “FRP-Repair” aims to solve the named challenges. Using semiconductor oxide catalysts, the matrix can be locally depolymerized by ultraviolet (UV) radiation, and thus removed from the damaged area of the FRP component. Subsequently, the damaged fibers in this area can be detached. By using customized textile repair patches and local thermoset reinfiltration, the repair area is restored. With this process, the fiber structure can be repaired locally with new fibers on the textile level. The repair is similar to the original production of a fiber composite in an infusion process. No additional adhesive material is used. As a result, repaired FRP structures with restored mechanics and a near-original surface can be realized. This article provides an insight into the actual steps of the development of the FRP component repair process using dry textile patches. The empirical investigation of overlapped rovings and UD material showed the expected results. Residual fracture forces of up to 86% could be achieved. The most interesting approach on the roving level was splicing the overlapping fibers. The free ends of the fibers of the patch and part are mechanically bonded. This bond at the textile level is further strengthened by infusion with matrix.

Published

2023

4. Numerical modeling of the mechanical behavior of textile structures on the meso‐scale for forming process simulations of composite 3D preforms

Author

Minh Quang Pham, Ellen Wendt, Eric Häntzsche, Thomas Gereke, and Chokri Cherif

Subjects

3D preforms, FEM, mechanical behavior, meso‐scale, textile, Engineering (General). Civil engineering (General), TA1-2040, Electronic computers. Computer science, QA75.5-76.95

Abstract

Abstract The models for textile structures based on the Finite Element Method (FEM) are diverse. In general, they can be divided into three groups based on their length scale: macro‐, meso‐, and micro‐scale models. The macro‐scale models are the simplest approach and require the least computational cost. On the contrary, the micro‐scale models are the most realistic and complex, thus involving extremely high computational costs. The meso‐scale models stand in the middle with sufficient representation degree at a reasonable computational cost. Every group of models has its own advantageous application field. For the forming process of 3D preforms, macro‐scale models have been widely used. As computational costs drop over time, meso‐scale models become more and more favorable. Hence, research efforts increasingly focus on meso‐scale models. In this paper, the modeling methods of FEM meso‐scale models for plain woven fabric made of glass roving and biaxial reinforced weft‐knitted fabric made of carbon fiber/polyamide 6.6 hybrid yarns are introduced. The experimental tests are used to characterize the mechanical properties of the yarns and fabrics. Different modeling methods for the geometries of each type of fabric are described. The mechanical behavior of the models is calibrated and validated with the help of a series of test simulations. Examples for the usage of the introduced models are presented.

Published

2022

5. Novel Strain Sensor in Weft-Knitted Textile for Triggering of Functional Electrical Stimulation

Author

Bahareh Abtahi, Mareen Warncke, Hans Winger, Carmen Sachse, Eric Häntzsche, Andreas Nocke, and Chokri Cherif

Subjects

weft-knitted fabric, textile-based strain sensor, functional electrical stimulation, multiple sclerosis, FES, Engineering machinery, tools, and implements, TA213-215

Abstract

Functional electrical stimulation (FES) aims to improve the gait pattern in case of foot drop of people suffering chronic diseases, e.g., multiple sclerosis. The fibular nerve can be stimulated by electrical impulses sent through electrodes on the skin, which leads to the contraction of the corresponding muscles. One major disadvantage of commercial FES devices is their bulky design. The paper presents an alternative approach of weft-knitted strain sensors that are directly integrated into the knee area of a functional legging suitable for daily use. To initiate electrical impulses for FES at the right time, the textile strain sensors are used as soft triggers.

Published

2023

6. Recycling of Carbon Fibres and Subsequent Upcycling for the Production of 3D-CFRP Parts

Author

David Rabe, Eric Häntzsche, and Chokri Cherif

Subjects

recycling, weft knitting, hybrid yarn, thermoplast, end of Life-CFRP, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Carbon fibres (CF) are used in CF reinforced plastic (CFRP) components. However, waste from CF yarn trim, CFRP and the end of life (EOL) CFRP structures will cause a recycling challenge in the next decades because of strict environmental regulations. Currently, recycling is carried out almost entirely by the use of pyrolysis to regain CF as a valuable resource. This high temperature process is energy consuming, and the resulting fibres are brittle. Hence, they are not suitable for processing of textiles into yarns or new reinforcement structures. To enable grave to cradle processing, a new approach based on a solvolysis recovery of CF and subsequent yarn spinning to obtain hybrid yarns suitable for textile processing, especially by weft knitting, was the focus of the international research project IGF/CORNET 256EBR. For the first time, it was possible to process hybrid yarns made of rCF on a weft knitting machine to produce biaxial reinforced structures to form CFRP from recycled carbon fibres. Therefore, various modifications were done on the textile machinery. In this way, it was possible to process the rCF and to get out a reproducible textile structure for the production of 3D recycled CFRP (rCFRP) parts.

Published

2022

7. Hinged Adaptive Fiber-Rubber Composites Driven by Shape Memory Alloys—Development and Simulation

Author

Felix Lohse, Achyuth Ram Annadata, Eric Häntzsche, Thomas Gereke, Wolfgang Trümper, and Chokri Cherif

Subjects

shape memory alloy, fiber-rubber composite, simulation, hinge, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Adaptive structures based on fiber-rubber composites with integrated Shape Memory Alloys are promising candidates for active deformation tasks in the fields of soft robotics and human-machine interactions. Solid-body hinges improve the deformation behavior of such composite structures. Textile technology enables the user to develop reinforcement fabrics with tailored properties suited for hinged actuation mechanisms. In this work, flat knitting technology is used to create biaxially reinforced, multilayer knitted fabrics with hinge areas and integrated Shape Memory Alloy wires. The hinge areas are achieved by dividing the structures into sections and varying the configuration and number of reinforcement fibers from section to section. The fabrics are then infused with silicone, producing a fiber-rubber composite specimen. An existing simulation model is enhanced to account for the hinges present within the specimen. The active deformation behavior of the resulting structures is then tested experimentally, showing large deformations of the hinged specimens. Finally, the simulation results are compared to the experimental results, showing deformations deviating from the experiments due to the developmental stage of the specimens. Future work will benefit from the findings by improving the deformation behavior of the specimens and enabling further development for first applications.

Published

2022

8. Experimental and Numerical Analysis of the Deformation Behavior of Adaptive Fiber-Rubber Composites with Integrated Shape Memory Alloys

Author

Felix Lohse, Karl Kopelmann, Henriette Grellmann, Moniruddoza Ashir, Thomas Gereke, Eric Häntzsche, Cornelia Sennewald, and Chokri Cherif

Subjects

shape memory alloy, fiber-rubber composite, simulation, smart material, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Fiber-reinforced rubber composites with integrated shape memory alloy (SMA) actuator wires present a promising approach for the creation of soft and highly elastic structures with adaptive functionalities for usage in aerospace, robotic, or biomedical applications. In this work, the flat-knitting technology is used to develop glass-fiber-reinforced fabrics with tailored properties designed for active bending deformations. During the knitting process, the SMA wires are integrated into the textile and positioned with respect to their actuation task. Then, the fabrics are infiltrated with liquid silicone, thus creating actively deformable composites. For dimensioning such structures, a comprehensive understanding of the interactions of all components is required. Therefore, a simulation model is developed that captures the properties of the rubber matrix, fiber reinforcement, and the SMA actuators and that is capable of simulating the active bending deformations of the specimens. After model calibration with experimental four-point-bending data, the SMA-driven bending deformation is simulated. The model is validated with activation experiments of the actively deformable specimens. The simulation results show good agreement with the experimental tests, thus enabling further investigations into the deformation mechanisms of actively deformable fiber-reinforced rubbers.

Published

2022

9. Novel Repair Procedure for CFRP Components Instead of EOL

Author

David Rabe, Philippa Ruth Christine Böhnke, Iris Kruppke, Eric Häntzsche, and Chokri Cherif

Subjects

CFRP, repair, textile, patch, thermoset, novel method, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

Today, numerous carbon fiber (CF) reinforced plastic (CFRP) components are in continuous usage under harsh environmental conditions. New components often replace damaged structural parts in safety-critical applications. In addition to this, there is also no effective repair method to initially restore the mechanics of these structures using dry fiber material. The high costs of CFRP components are not in proportion to their lifetime. The research project IGF-19946 BR “CFRP-Repair” addresses this specific challenge. By using an oxide semiconductor that is activated by ultraviolet (UV) irradiation, the thermoset matrix can be depolymerized and thus locally removed from the damaged CFRP component. Afterward, the harmed fibers can be physically removed from the laminate in this certain area. A load-adjusted tailored fiber reinforcement patch is subsequently applied and consolidated by local thermoset re-infiltrating. Using this procedure, the structure can be locally repaired with new CF. As a result, repaired CFRP structures can be obtained with reduced mechanics and an approximately original surface. This article gives an insight into the developed repair procedure of CFRP components in an innovative and more efficient way than the state-of-the-art.

Published

2021

10. Matrix Decomposition of Carbon-Fiber-Reinforced Plastics via the Activation of Semiconductors

Author

Philippa Ruth Christine Böhnke, Iris Kruppke, David Hoffmann, Mirko Richter, Eric Häntzsche, Thomas Gereke, Benjamin Kruppke, and Chokri Cherif

Subjects

atomic force microscopy, CF, CFRP, depletion, recycling, repair, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

The present study proposed a novel process for the matrix decomposition of carbon-fiber-reinforced plastics (CFRPs). For this purpose, the influence of ultraviolet (UV) radiation paired with semiconductors on CFRP was analyzed. Then, suitable process parameters for superficial and in-depth matrix decomposition in CFRP were evaluated. The epoxy resin was decomposed most effectively without damaging the embedded carbon fiber by using a UV light-emitting diode (LED) spotlight (395 nm, Semray 4103 by Heraeus Noblelight) at a power level of 66% compared to the maximum power of the spotlight. Using a distance of 10 mm and a treatment duration of only 35–40 s achieved a depth of two layers with an area of 750 mm2, which is suitable for technological CFRP repair procedures. In addition to the characterization of the process, the treated CFRP samples were analyzed based on several analytical methods, namely, light microscopy (LM), scanning electron microscopy (SEM), and atomic force microscopy (AFM). Subsequently, the prepared carbon fibers (CFs) were tested using filament tensiometry, single filament tensile tests, and thermogravimetric measurements. All analyses showed the power level of 66% to be superior to the use of 96% power. The gentle (“fiber friendly”) matrix destruction reduced the damage to the surface of the fibers and maintained their properties, such as maximum elongation and maximum tensile strength, at the level of the reference materials.

Published

2020

11. Development of a Function-Integrative Sleeve for Medical Applications

Author

Moritz Neubauer, Eric Häntzsche, Christina Pamporaki, Graeme Eisenhofer, Martin Dannemann, Andreas Nocke, Niels Modler, and Angelos Filippatos

Subjects

smart textiles, warming device, blood flow, multi-material design, function integration, phaeochromocytomas/paragangliomas (PPGLs), medical engineering, Chemical technology, TP1-1185

Abstract

Function-integrative textiles bear the potential for a variety of applications in the medical field. Recent clinical investigations suggest that the application of a function-integrative fabric could have a positive impact on currently applied diagnostic procedures of a specific type of tumour. In this context, the fabric should enable local warming of a patient’s upper extremity as well as blood flow measurement. Existing solutions comprise a warming system but lack a measuring apparatus for blood flow determination. With regard to the quality of results of current diagnostic procedures, the local warming of the patients’ upper extremity and the simultaneous determination of the blood flow plateau are crucial. In the present paper, the development process of a function-integrative sleeve is introduced. Besides the development of an adaptable sleeve-design, the manufacturing process of an integrated warming system was also addressed. Furthermore, the identification of crucial physiological effects, using a Laser Doppler Perfusion Monitor, is introduced. During testing of the function-integrative sleeve, modulation of the desired physiological effects was observed. The results support the initial assumptions and dictate further investigations on increasing user-friendliness and cost-efficiency during adjusting and determining the physiological effects in the course of tumour diagnosis.

Published

2019

12. Investigation of the Bonding Mechanism between Overlapping Textile Layers for FRP Repair Based on Dry Textile Patches

Author

Cherif, David Rabe, Juan Daniel Ortega Arbulu, Eric Häntzsche, and Chokri

Subjects

FRP, novel method repair, dry textile patch, thermoset composites, UV-based depolymerization

Abstract

Lots of damaged fiber-reinforced plastic (FRP) components are replaced by new components instead of repairing. Furthermore, only very labor-intensive repair methods are available on the market to fully restore the integrity of the structure. This requires a high level of experience or, alternatively, very cost-intensive technology, such as the use of computer tomography and robotics. The high costs and CO2 emissions caused by the manufacture of FRP components then bear no relation to their service life. The research project IGF-21985 BR “FRP-Repair” aims to solve the named challenges. Using semiconductor oxide catalysts, the matrix can be locally depolymerized by ultraviolet (UV) radiation, and thus removed from the damaged area of the FRP component. Subsequently, the damaged fibers in this area can be detached. By using customized textile repair patches and local thermoset reinfiltration, the repair area is restored. With this process, the fiber structure can be repaired locally with new fibers on the textile level. The repair is similar to the original production of a fiber composite in an infusion process. No additional adhesive material is used. As a result, repaired FRP structures with restored mechanics and a near-original surface can be realized. This article provides an insight into the actual steps of the development of the FRP component repair process using dry textile patches. The empirical investigation of overlapped rovings and UD material showed the expected results. Residual fracture forces of up to 86% could be achieved. The most interesting approach on the roving level was splicing the overlapping fibers. The free ends of the fibers of the patch and part are mechanically bonded. This bond at the textile level is further strengthened by infusion with matrix.

Published

2023

13. Novel Knitting Vision - Modern Ways for Integral Knitting of Intelligent Gloves for Tactile Internet Applications

Author

Florian Wieczorek, Hans Winger, Philippa Ruth Christine Böhnke, Jens Wagner, Eric Häntzsche, Andreas Nocke, Iris Kruppke, and Chokri Cherif

Subjects

General Materials Science, Condensed Matter Physics, Atomic and Molecular Physics, and Optics

Abstract

The internet of things is a key driver for new developments in the fields of medicine, industry 4.0 and gaming. Consequently, the interaction of virtual and real world by smart interconnecting of devices in our everyday life is the basis idea of the Cluster of Excellence "Centre for Tactile Internet with Human-in-the-Loop" (CeTI) at TU Dresden. To enable a user-centric approach in CeTI innovative textile structures, mainly knitted smart gloves, and their functionalization by integration of sensors and sensory yarns are focus of research activities.

Published

2022

14. From Grave to Cradle - Development of Weft Knitted Fabrics Based on Hybrid Yarns from Recycled Carbon Fibre Reclaimed by Solvolytic Process from of EOL-Components

Author

David Rabe, Mir Mohammad Badrul Hasan, Eric Häntzsche, Chokri Cherif, Yasushi Murakami, Li Min Bao, and Kanji Kajiwara

Subjects

Mechanics of Materials, Mechanical Engineering, General Materials Science, Condensed Matter Physics

Abstract

Carbon fibre (CF) is widely used in CF reinforced plastic (CFRP) components. However, waste CF, CFRP and the end-of-life (EOL) CFRP structures will cause an even bigger problem in the next years because of strict environmental regulations. Currently, recycling is carried out almost entirely by the use of pyrolysis to regain CF as a valuable resource. This high temperature process is very energy consuming and the resulting fibres are brittle. Hence, not suitable for textile processing into yarns or fabrics. To enable a grave to cradle circle, a new approach based on a solvolytic recovery of CF and the subsequent spinning process to obtain a hybrid yarn suitable for weft knitting processing is the focus of the international research project IGF/CORNET 256EBR “3D-r-CFRP”.

Published

2022

15. Protective Coating for Electrically Conductive Yarns for the Implementation in Smart Textiles

Author

Philippa Ruth Christine Böhnke, Hans Winger, Florian Wieczorek, Mareen Warncke, Lisa Marie Lüneburg, Iris Kruppke, Andreas Nocke, Eric Häntzsche, and Chokri Cherif

Subjects

General Materials Science, Condensed Matter Physics, Atomic and Molecular Physics, and Optics

Abstract

The Cluster of Excellence “Centre for Tactile Internet with Human-in-the-Loop (CeTI)” deals with developments and inventions concerning smart devices used in many fields, e.g. industry 4.0, medicine and skill learning. These kind of applications require smart devices, sensors, actors and conductive structures. Textile structures address these applications by meeting requirements such of being flexible, adaptable and wearable. Within this paper, the development of a protective coating for electrically conductive (EC) yarns is captured. These EC yarns are nowadays often used for smart textile applications. One challenge in their application is the integration into textile structures. Often, the handling and use of EC yarns lead on the one hand to damages on the surface of the yarn and on the other hand to reduced electromechanically characteristics. This paper aims to characterize these EC yarns in regard to develop a suitable protective coating based on polypropylene (PP). To achieve this development, an extensive characterization of the EC yarns as well as the protective coating itself is important. The surface free energy (SFE), the topographical and the chemical characteristics are necessary for developing a suitable protective coating. However, the yarns are characterized before and after implementation into the textile structure and furthermore after the coating respectively with the developed finish.

Published

2022

16. Recycling von Kohlenstofffasern und anschließendes Upcycling für die Herstellung von 3D-CFK-Teilen

Author

Chokri Cherif, Mir Mohammad Badrul Hasan, Anwar Abdkader, Eric Häntzsche, and David Rabe

Subjects

Polymers and Plastics, General Business, Management and Accounting, Industrial and Manufacturing Engineering, General Environmental Science

Abstract

Kohlenstofffasern (CF) werden in Bauteilen aus CF-verstärktem Kunststoff (CFK) verwendet. CF-Produktionsabfälle, durch Unfälle zerstörte CFK-Strukturen und CFK-Strukturen am Ende ihrer Lebensdauer werden in den nächsten Jahrzehnten aufgrund strenger Umweltvorschriften eine Herausforderung für das Recycling darstellen. Derzeit erfolgt das Recycling fast ausschließlich durch den Einsatz von Pyrolyse, um CF als wertvolle Ressource zurückzugewinnen. Dieser Hochtemperaturprozess ist energieaufwendig und die entstehenden Fasern sind spröde. Daher eignen sie sich nicht für die textile Verarbeitung zu Garnen oder neuen Verstärkungsstrukturen. Um eine Verarbeitung „from grave to cradle“ zu ermöglichen, wurde im Rahmen eines internationalen Forschungsprojekts ein neuer Ansatz entwickelt, der auf der zweistufigen Solvolyse-Rückgewinnung von CF und dem anschließenden Spinnprozess basiert, um ein Hybridgarn zu erhalten, das sich für die textile Verarbeitung eignet.

Published

2022

17. Innovative Kompressionstextilien aus neuartigen Formgedächtnisgarnen

Author

Chokri Cherif, Dilbar Aibibu, Florian Wieczorek, Robert Tonndorf, Carmen Sachse, and Eric Häntzsche

Subjects

Polymers and Plastics, General Business, Management and Accounting, Industrial and Manufacturing Engineering, General Environmental Science

Abstract

Im Rahmen des IGF-Projekts gelang es am ITM, innovative Kompressionstextilien aus einem neuartigen Garn mit Formgedächtniseffekt (FG-Effekt) zu entwickeln und umzusetzen, die im Vergleich zu kommerziellen Produkten mit deutlich weniger Kraftaufwand angelegt werden können. Die Besonderheit liegt darin, dass sich das Kompressionstextil durch die integrierten FG-Garne erst durch Wärmeeinwirkung nach dem Anziehen zusammenzieht und damit den Kompressionsdruck sukzessive aufbaut. Dadurch wird die Anziehbarkeit signifikant erleichtert, was die Akzeptanz der Kompressionstherapie erhöht. Für die zeitnahe Überführung der Forschungsergebnisse in die industrielle Praxis und damit in kommerzielle Produkte wurden die in der deutschen Textilindustrie bereits etablierten Fertigungstechnologien adressiert. Daher erfolgte die Umsetzung geeigneter FG-Garne mittels Schmelzspinntechnik und der Kompressionstextilien durch Flachstricktechnik, wobei das dazu erforderliche technologische und produktvorbereitende Know-how insbesondere für KMU bereitgestellt wurde.

Published

2022

18. Meso-Scale Finite Element Model for Rib-Stiffened Composites with Biaxial Weft-Knitted Reinforcements

Author

Minh Quang Pham, Quentin Bollengier, David Rabe, Tobias Georg Lang, Eric Häntzsche, Wolfgang Trümper, Chokri Cherif, and Thomas Gereke

Subjects

Ceramics and Composites, biaxial weft-knitted fabrics (BWKF), fiber-reinforced polymer (FRP), meso-scale model, net shape composites, Engineering (miscellaneous)

Abstract

Shell-rib structures made of textile-reinforced composites are used in a wide range of applications to increase bending, buckling and torsional stiffness. Such composites are usually manufactured in differential construction at the preform level by assembling several textile structures or at the component level by the subsequent joining of separately manufactured shells and stiffening structures. Integral preform production is one way to overcome the disadvantages of the forenamed methods, such as high manual effort, failure during assembling or fiber distortion. Weft-knitting technology is excellent for achieving integral preforms for shell-rib components with a strong connection between the shell and the rib, especially while producing biaxial weft-knitted fabrics (BWKF) with reinforcing yarns in the warp and weft direction to improve its mechanical behavior. In this work, the possibilities of the knitting technique are investigated, and a finite element model for comparing different variants is developed and validated. A meso-scale Finite-Element-Method (FEM) model of the BWKF is used. The simulation results with the meso-scale model show a good correlation with experimental data by a description of bending strength and stiffness of different FRP configuration variations. The model can be used in further investigation of fiber-reinforced polymer (FRP) made from BWKF.

Published

2023

19. Bio-inspired semi-flexible joint based on fibre-reinforced composites with shape memory alloys

Author

Nils Bolk, Chokri Cherif, Rico Hickmann, Klaus-Dieter Klass, Carmen Wende, Eric Häntzsche, Moniruddoza Ashir, Quentin Bollengier, Rico Pöschel, Wolfgang Trümper, and Felix Lohse

Subjects

010302 applied physics, Materials science, Bionics, Mechanical Engineering, High activation, 02 engineering and technology, Shape-memory alloy, 021001 nanoscience & nanotechnology, SMA, 01 natural sciences, 0103 physical sciences, General Materials Science, Composite material, 0210 nano-technology, Joint (geology)

Abstract

Shape memory alloys (SMA) are a promising material class for active lightweight structure applications with movement functionality. Due to their high activation energy potential and good processability in wire shape, they are well suited for application in actively deformable, fibre-reinforced composite structures. In order to generate large deflections from the limited deformation potential of SMA, detailed analysis of the deformation mechanisms is required. In this work, a bionic approach is pursued, investigating the characteristics of locomotion systems of insects. A simplified joint concept is derived from the cockroach knee and implemented using flat knitting technology. A composite joint is manufactured with a resin infusion process and experimentally verified in regards to its motion behaviour. The presented results show good deformation behaviour with large deformation angles up to 60°, suggesting large potential for further development of the presented approach.

Published

2020

20. Electro-mechanical characterization of shape memory alloy hybrid yarn based adaptive fiber-reinforced plastics

Author

Eric Häntzsche, Moniruddoza Ashir, and Chokri Cherif

Subjects

Materials science, Polymers and Plastics, Materials Science (miscellaneous), Shape-memory alloy, Yarn, Fibre-reinforced plastic, SMA, Industrial and Manufacturing Engineering, Characterization (materials science), Barrier layer, visual_art, Thermal, visual_art.visual_art_medium, Fiber, Composite material, General Agricultural and Biological Sciences

Abstract

Shape memory alloys (SMA) are being used for the development of adaptive fiber-reinforced plastics (FRP) with high functional density. During the thermal induced activation of SMA, a barrier layer ...

Published

2020

21. Novel Repair Procedure for CFRP Components Instead of EOL

Author

Philippa Ruth Christine Böhnke, Eric Häntzsche, Chokri Cherif, Iris Kruppke, and David Rabe

Subjects

Fiber reinforcement, Technology, Materials science, Thermosetting polymer, 02 engineering and technology, 010501 environmental sciences, Repair method, 01 natural sciences, Article, UV-based depolymerization, Oxide semiconductor, thermoset, General Materials Science, patch, Fiber, Composite material, CFRP, 0105 earth and related environmental sciences, Microscopy, QC120-168.85, textile, QH201-278.5, CF, Fibre-reinforced plastic, 021001 nanoscience & nanotechnology, Engineering (General). Civil engineering (General), TK1-9971, repair, novel method, Descriptive and experimental mechanics, Electrical engineering. Electronics. Nuclear engineering, TA1-2040, 0210 nano-technology

Abstract

Today, numerous carbon fiber (CF) reinforced plastic (CFRP) components are in continuous usage under harsh environmental conditions. New components often replace damaged structural parts in safety-critical applications. In addition to this, there is also no effective repair method to initially restore the mechanics of these structures using dry fiber material. The high costs of CFRP components are not in proportion to their lifetime. The research project IGF-19946 BR “CFRP-Repair” addresses this specific challenge. By using an oxide semiconductor that is activated by ultraviolet (UV) irradiation, the thermoset matrix can be depolymerized and thus locally removed from the damaged CFRP component. Afterward, the harmed fibers can be physically removed from the laminate in this certain area. A load-adjusted tailored fiber reinforcement patch is subsequently applied and consolidated by local thermoset re-infiltrating. Using this procedure, the structure can be locally repaired with new CF. As a result, repaired CFRP structures can be obtained with reduced mechanics and an approximately original surface. This article gives an insight into the developed repair procedure of CFRP components in an innovative and more efficient way than the state-of-the-art.

Published

2021

22. Author response for 'Numerical modeling of the mechanical behavior of textile structures on the meso‐scale for forming process simulations of composite <scp>3D</scp> preforms'

Author

Eric Häntzsche, Minh Quang Pham, Chokri Cherif, Thomas Gereke, and Ellen Wendt

Subjects

Meso scale, Materials science, Textile, business.industry, Composite number, Numerical modeling, Forming processes, Composite material, business

Published

2020

23. B3.1 - Wireless Read-Out of Optical Fiber Sensors

Author

D. Plettemeier, Eric Häntzsche, N. Neumann, T. Schuster, and Andreas Nocke

Subjects

Materials science, Optical fiber, Fiber optic sensor, law, business.industry, Optical cross-connect, Wavelength-division multiplexing, Fiber optic splitter, Wireless, Optoelectronics, business, law.invention

Published

2017

24. C7.2 - Textile-based sensor systems for condition monitoring in composite and medical applications

Author

Eric Häntzsche, Chokri Cherif, Andreas Nocke, and Johannes Wendler

Subjects

Materials science, business.industry, Composite number, Condition monitoring, Textile (markup language), Process engineering, business

Published

2017

25. Characteristics of carbon fiber based strain sensors for structural-health monitoring of textile-reinforced thermoplastic composites depending on the textile technological integration process

Author

Andreas Nocke, Eric Häntzsche, A. Matthes, and Ch. Cherif

Subjects

chemistry.chemical_classification, Textile, Thermoplastic, Materials science, business.industry, Glass fiber, Metals and Alloys, Mechanical engineering, Yarn, Structural engineering, Condensed Matter Physics, Tailored fiber placement, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, chemistry, visual_art, visual_art.visual_art_medium, Structural health monitoring, Electrical and Electronic Engineering, Weaving, business, Instrumentation, Wireless sensor network

Abstract

The paper presents an effective online measurement technology for non-destructive and continuous monitoring of endless glass fiber reinforced thermoplastic (FRTP) composite structures using the numerous possibilities of textile process technologies for the design and one-step integration of one- and two-dimensional sensor structures based on piezo-resistive exPAN carbon filament yarn (CFY) in textile reinforced structures. The focus of this paper is directed at the analysis of such textile technological integrated sensors as an integral part of the textile reinforcement and their usability for in situ monitoring of local and/or global mechanical loading conditions in difficult or inaccessible areas within short distance of the structural load-bearing layers of FRTP's. If the adhesion of the carbon filament yarn sensor (CFYS) to the surrounding FRTP is sufficient enough, a change in geometry and thereby in resistivity of the carbon filaments can be measured by any mechanical load of the sensor-carrying FRTP component. The advantages and disadvantages of the tailored fiber placement (TFP), flat knitting and weaving textile processes for creating sensor structures will be shown, wherein the mentioned variety of interlacing techniques are used. The effects of the used textile manufacturing processes on the sensory properties are being compared. Furthermore, the effects of the integrated CFY on the mechanical properties of the basic structure are quantified. Sensor structures with minimal influence on the composite structure can be derived from it as well as sensors that enable a selective reinforcement of the composite structure. The textile integration provides a routing of one CFY through several layers of reinforcement. Thus, a damage-free and reproducible production of more complex, 3-dimensional, textile-based sensor networks is feasible in one step.

Published

2013

26. 6.4.2 - Multifunktionale Bauteile aus Carbonbeton - Integrierte textilbasierte Sensorlösungen zur In-Situ- Strukturüberwachung adaptiver Gebäudehüllen

Author

M. Gorges, M. Butler, N. Neumann, Eric Häntzsche, T. Schuster, G. Schönfelder, C. Cherif, Andreas Nocke, D. Plettemeier, and V. Mechtcherine

Abstract

Eric Hantzsche , Andreas Nocke , Chokri Cherif , Tobias Schuster , Niels Neumann , Dirk Plettemeier , Michaela Gorges , Marko Butler ,Viktor Mechtcherine , Gert Schonfelder 4 Technische Universitat Dresden, 01062 Dresden: …Institut fur Textilmaschinen und Textile Hochleistungswerkstofftechnik (ITM), …Institut fur Nachrichtentechnik Lehrstuhl Hochfrequenztechnik (IfN), …Institut fur Baustoffe (IfB). …Prignitz Mikrosystemtechnik GmbH, Margarethenstr. 61, 19322 Wittenberge

Published

2016

27. Multiple functional coating highly inert fiber surfaces of para-aramid filament yarn

Author

Eric Häntzsche, Ch. Cherif, Rolf-Dieter Hund, and Toty Onggar

Subjects

Inert, 021110 strategic, defence & security studies, Materials science, Polymers and Plastics, 0211 other engineering and technologies, Metals and Alloys, 02 engineering and technology, engineering.material, 021001 nanoscience & nanotechnology, Surfaces, Coatings and Films, Electronic, Optical and Magnetic Materials, Biomaterials, Aramid, Coating, Filament yarn, engineering, Fiber, Composite material, 0210 nano-technology

Published

2018

28. Sensor yarns for real-timein situdetection of damage behavior for the purpose of structural health monitoring of textile-reinforced thermoset composites: development of a continuous wet-chemical silvering process for high-performance filament yarn

Author

Andreas Nocke, Eric Häntzsche, Toty Onggar, Rolf-Dieter Hund, and Ch. Cherif

Subjects

Materials science, Scanning electron microscope, Fineness, Shear force, Thermosetting polymer, 02 engineering and technology, 010402 general chemistry, 021001 nanoscience & nanotechnology, Condensed Matter Physics, 01 natural sciences, Atomic and Molecular Physics, and Optics, Surface energy, 0104 chemical sciences, Mechanics of Materials, Signal Processing, Ultimate tensile strength, General Materials Science, Electrical and Electronic Engineering, Elasticity (economics), Composite material, 0210 nano-technology, Elastic modulus, Civil and Structural Engineering

Abstract

High-performance textile yarns such as glass filament (GF) yarn will be used as the base material for the development of sensor yarns because glass filament yarns offer both high tensile strengths and moduli of elasticity, as well as high melting temperatures and elongation. A new continuous wet-chemical metallization process has been developed for GF yarns on a laboratory scale to achieve special properties such as electrical conductivity. The aim of the work is to develop a continuous wet-chemical silver plating process for the GF-filament yarn in order to achieve electrical conductivity on the GF-surface. The process was carried out continuously in order to metallize the GF, which is sensitive to the shear force. A homogeneous, completely covered and adhered silver layer on the GF yarn surfaces was obtained by the application of this technology. The surface morphology was been determined by light and scanning electron microscopy to assess the silver layer properties such as structure, homogeneity, and cracking. The chemical structure of the surfaces was analyzed by means of energy dispersive x-ray spectroscopy. For structural analysis, GF yarns were investigated using a Fourier transform infrared spectrometer. The dispersive and polar component of the surface energy of the sized and silvered GF yarn was measured by using a single fiber Tensiometer K100. The silver layer thickness and the silver content were determined after the metallization. Textile physical tests of the tensile strength, elasticity modulus, elongation at break, and yarn fineness of the single GF yarns as well as GF bundle were carried out.

Published

2017