英国布里斯托复合材料研究所(Bristol Composites Institute)成 立于2017年3月,以ACCIS(先进复合材料创新与科学合作)的工作为基础。它把整个布里斯托尔大学的复合材料活动汇集在一起 ,工程学院与科学和医学院相连。
我们的愿景是成为世界领先的复合材料研究和教育机构,将尖端 的基础科学与强大的工业联系进行开发和技术转让。ACCIS 是内 部,国内和国际合作的重点。
布里斯托复合材料研究所(ACCIS)
主任Michael Wisnom
Recent publications
Professor Michael Wisnom
Wisnom, M. R. 2016. Mechanisms to create
high performance pseudo-ductile composites.
IOP Conference Series: Materials Science and
Engineering, 139, 012***
Wisnom, M. R., Czél, G., Swolfs, Y., Jalalvand, M.,
Gorbatikh, L. & Verpoest,
in thin ply carbon/glass unidirectional laminates:
Accurate experimental determination and
prediction. Composites Part A: Applied Science
and Manufacturing, 88, 131-***
Professor Ian Bond
Heath, C. J. C., Bond,
2016. Interlocking electro-bonded laminates.
Journal of Intelligent Material Systems ***
Structures, 28, 1524-1***
Luterbacher, R., Coope, T. S., Trask, R. S. &
Bond,
carbon fibre reinforced polymer stringer runout
configurations. Composites Science and
Technology, 136, 67***
Professor Steve Eichhorn
Wanasekara, N. D. & Eichhorn, S. J. 2***
Injectable Highly Loaded Cellulose Nanocrystal
Fibers and Composites. ACS Macro Letters,
1066-1***
Zhu, C., Richardson, R. M., Potter, K. D.,
Koutsomitopoulou, A. F., Van Duijneveldt,
J. S., Vincent, S. R., Wanasekara, N. D.,
Eichhorn, S. J. & Rahatekar, S. S. 2016. High
Modulus Regenerated Cellulose Fibers Spun
from a Low Molecular Weight Microcrystalline
Cellulose Solution. ACS Sustainable Chemistry &
Engineering, 4, 4545-4***
Professor Stephen Hallett
Nixon-Pearson, O. J., Belnoue, J.-H.,
Ivanov, D. S., Potter, K. D. & Hallett, S. R.
2016. An experimental investigation of the
consolidation behaviour of uncured prepregs
under processing conditions. Journal of
Composite Materials, 51, 1911-1***
Sun, X. C. & Hallett, S. R. 2017. Barely visible
impact damage in scaled composite laminates:
Experiments and numerical simulations.
International Journal of Impact Engineering, ***
178-***
Dr Ian Hamerton
Iredale, R. J., Ward, C. & Hamerton, I.
2017. Modern advances in bismaleimide resin
technology: A 21st century perspective on the
chemistry of addition polyimides. Progress in
Polymer Science, 69, 1***
Pozegic, T. R., Anguita, J. V., Hamerton, I.,
Jayawardena, K. D. G. I., Chen, J. S., Stolojan,
V., Ballocchi, P., Walsh, R. & Silva, S. R. P. 2***
Multi-Functional Carbon Fibre Composites using
Carbon Nanotubes as an Alternative to Polymer
Sizing. Scientific Reports, 6, 37***
Dr Dmitry Ivanov
Ariu, G., Hamerton, I. & Ivanov, D. 2***
Positioning and aligning CNTs by external
magnetic field to assist localised epoxy cure.
Open Physics, 14, ***
Turk, M., Hamerton, I. & Ivanov, D. S.
2017. Ductility potential of brittle epoxies:
Thermomechanical behaviour of plasticallydeformed
fully-cured composite resins. Polymer,
120, 43***
Dr Luiz Kawashita
Al-Azzawi, A. S. M., McCrory, J., Kawashita, L. F.,
Featherston, C. A., Pullin, R. & Holford, K. M.
2017. Buckling and postbuckling behaviour
of Glare laminates containing splices and
doublers. Part 1: Instrumented tests.
Composite Structures, 176, 1158-1***
Al-Azzawi, A. S. M., Kawashita, L. F.
& Featherston, C. A. 2017. Buckling and
postbuckling behaviour of Glare laminates
containing splices and doublers. Part 2:
Numerical modelling. Composite Structures,
176, 1170-1***
Dr Byung Chul Kim
Stodieck, O., Francois, G., Heathcote, D.,
Kim, B. C., Rhead, A., Cleaver, D. & Cooper, J.
2017. Experimental Validation of Tow-Steered
Composite Wings for Aeroelastic Design.
International Forum on Aeroelasticity and
Structural Dynamics, IFASD2017,
Veldenz, L., Di Francesco, M., Atwood, S.,
Giddings, P., Kim, B. C. & Potter, K. 2***
Assessment of Steering Capability of Automated
Dry Fibre Placement through a Quantitative
Methodology. International Symposium on
Automated Composites Manufacturing,
Dr James Kratz
Hubert, P., Centea, T., Grunefelder, L., Nutt, S.,
Kratz, J., Levy, A. 2018. 2.4 Out-of-Autoclave
Prepreg Processing. In:
Zweben, C.H. (eds.), Comprehensive Composite
Materials II. vol. 2, 63-94.
Press.
Kratz, J., Low, Y. S. & Fox, B. 2***
Resource-friendly carbon fiber composites:
combining production waste with virgin
feedstock. Advanced Manufacturing: Polymer
& Composites Science, ***
Dr Matthew O’Donnell
O’Donnell, M. P. & Weaver, P. M. 2017. RAPID
analysis of variable stiffness beams and plates:
Legendre polynomial triple-product formulation.
International Journal for Numerical Methods in
Engineering, 112, 86-***
O’Donnell, M. P., Weaver, P. M. & Pirrera, A.
2016. Can tailored non-linearity of hierarchical
structures inform future material development?
Extreme Mechanics Letters, 7, ***
Professor Ivana Partridge
Cui, H., Yasaee, M., Kalwak, G., Pellegrino,
A., Partridge,
& Petrinic, N. 2017. Bridging mechanisms of
through-thickness reinforcement in dynamic
mode I&II delamination. Composites Part A:
Applied Science and Manufacturing, 99, 198-***
Partridge,
Toughen Up! In: Beaumont, P. W. R., Soutis, C.
& Hodzic, A. (eds.) The Structural Integrity of
Carbon Fiber Composites: Fifty Years of Progress
and Achievement of the Science, Development,
and Applications. Cham: Springer International
Publishing.
Dr Alberto Pirrera
Arena, G., Groh, R. M. J., Brinkmeyer, A.,
Theunissen, R., Weaver, P. M. & Pirrera, A.
2017. Adaptive compliant structures for flow
regulation. Proceedings of the Royal Society A:
Mathematical, Physical and Engineering Science,
473, 2***
Scott, S., Capuzzi, M., Langston, D.,
Bossanyi, E., McCann, G., Weaver, P. M. &
Pirrera, A. 2017. Effects of aeroelastic tailoring
on performance characteristics of wind turbine
systems. Renewable Energy, 114, 887-***
Professor Kevin Potter
Di Francesco, M., Veldenz, L., Dell’Anno, G.
& Potter, K. 2017. Heater power control for
multi-material, variable speed Automated Fibre
Placement. Composites Part A: Applied Science
and Manufacturing, 101, 408-***
Longana, M. L., Ong, N., Yu, H. & Potter, K. D.
2016. Multiple closed loop recycling of carbon
fibre composites with the HiPerDiF (High
Performance Discontinuous Fibre) method.
Composite Structures, 153, 271-***
Professor Fabrizio Scarpa
Chen, Y., Li, T., Scarpa, F. & Wang, L. 2***
Lattice Metamaterials with Mechanically Tunable
Poisson’s Ratio for Vibration Control. Physical
Review Applied, 7, 024***
Wang, S., Huang, L. J., Geng, L., Scarpa, F.,
Jiao, Y. & Peng, H. X. 2017. Significantly
enhanced creep resistance of low volume fraction
in-situ TiBw/Ti6Al4V composites by architectured
network reinforcements. Scientific Reports***
40823.
Dr Mark Schenk
Filipov, E. T., Liu, K., Tachi, T., Schenk, M. &
Paulino, G. H. 2017. Bar and hinge models for
scalable analysis of origami. International Journal
of Solids and Structures, 124, 26***
Dr Valeska Ting
Doan, H. V., Fang, Y.,
Sartbaeva, A., Hintermair, U. & Ting, V. P.
2017. Controlled Formation of Hierarchical
Metal-Organic Frameworks Using CO2
-Expanded
Solvent Systems. ACS Sustainable Chemistry &
Engineering, 5, 7887-7***
Edler, K. J., Bowen, C. R., Mintova, S. &
Burrows, A. D. 2015. Gas sensing using porous
materials for automotive applications. Chemical
Society Reviews, 44, 4290-4***
Dr Carwyn Ward
Blok, L. G., Kratz, J., Lukaszewicz, D.,
Hesse, S., Ward, C. & Kassapoglou, C. 2***
Improvement of the in-plane crushing response
of CFRP sandwich panels by through-thickness
reinforcements. Composite Structures, 161, 15***
Hartley, J. W., Kratz, J., Ward, C. &
Partridge,
and loop length on the crushing behaviour of
tufted sandwich specimens. Composites Part B:
Engineering, 112, 49***
Professor Paul Weaver
Kordolemis, A. & Weaver, P. M. 2***
Geometric-material analogy for multiscale
modelling of twisted plates. International Journal
of Solids and Structures, 110, 24***
Wu, Z., Raju, G. & Weaver, P. M. 2***
Optimization of Postbuckling Behaviour of
Variable Thickness Composite Panels with
Variable Angle Tows: Towards “Buckle-Free”
Design Concept. International Journal of Solids
and Structures.
多功能复合材料和新型微结构
先进的复合材料提供了独特的机会来创造具有附加功能的结构材 料,例如用于感测,自修复以及结合新型纤维和纳米材料的新材 料结构。
设计,分析和失败
基础实验研究提供了物理和力学行为的理解,为分析方法预测性 能提供了基础,以及设计和制造最佳结构的工具。
智能结构
复合材料使材料科学,机械工程,计算机科学
电话:气工程,数值 建模和优化等传统学科的整合成为高性能的智能结构。
复合材料的加工和表征
材料微观结构和加工特性的知识使得能够开发用于制造复合部件 的增强和新颖的方法。
我们想向您介绍参与创新与科学先进复合材料博士培训中心的主 要人员。
CDT主任与管理委员会合作开展运营职责。该委员会包括研究和教 学协调员,项目经理,专职CDT讲师,CDT经理,研究生学生管理 员和当选学生代表。
我们的学生都是来自各个学科(如航空航天工程,生物化学,化 学,土木工程,材料科学,数学,机械工程,物理学和纺织工程)的学术天才毕业生。学生团体分成10至16名学生。
我们的表现,质量和战略方向每年都会通过外部咨询委员会的会 议进行审查,外部咨询委员会由外部学者和行业合作伙伴等主要 利益相 我们的咨询委员会为CDT和我们的学生的持续发展作出了 宝贵的贡献。
项目主管来自ACCIS内部以及大学内的其他合作部门,以及来自其 他大学和我们工业合作伙伴的合作者。
先进的复合材料科学中心(ACCIS)
http://www.**istol.ac.uk/composites/
composites-cdt**[ta]**stol.ac.uk
+44(0)117 33 1***
EPSRC创新与科学
先进复合材料博士培训中心先进复合材料创新与科学合作(ACCIS)
布里斯托大学
女王大学步行
布里斯托尔BS8 1TR
管理委员会
Michael Wisnom教授 ACCIS主任; 航空航天结构教授
+44(0)117 33 1***
m.wisnom**[ta]**stol.ac.uk
导向员
Paul Weaver教授 轻量结构教授
+44(0)117 33 1***
paul.weaver**[ta]**stol.ac.uk
学校的负责人
Ian Bond教授 女王工程学院院长; 航天工程教授
+44(0)117 33 1***
ipbond**[ta]**stol.ac.uk
副主任和研究协调员
Ian Hamerton博士 聚合物和复合材料阅读器
+44(0)117 33 1***
ian.hamerton**[ta]**stol.ac.uk
教学协调员
Ian Farrow博士 飞机结构设计高级讲师
+44(0)117 33 1***
ian.farrow**[ta]**stol.ac.uk
专门的CDT讲师
德米特里•伊万诺夫博士 复合材料制造讲师
+44(0)117 33 1***
dmitry.ivanov**[ta]**stol.ac.uk
Alberto Pirrera博士 复合结构讲师
+44(0)117 33 1***
alberto.pirrera**[ta]**stol.ac.uk
Valeska Ting博士 智能纳米材料阅读器
+44(0)117 33 1***
v.ting**[ta]**stol.ac.uk
行政
Sarah Hallworth女士 CDT经理
sarah.hallworth**[ta]**stol.ac.uk
Kathinka Watts夫人 研究生管理员(CDT)
+44(0)117 33 1***
kathinka.watts**[ta]**stol.ac.uk
凯蒂•德鲁里太太 ACCIS项目经理
+44(0)117 33 1***
katie.drury**[ta]**stol.ac.uk