甘學(xué)輝教授

2002年進(jìn)入東華大學(xué)任教，2004年到日本作客座研究員1年，歷任機械工程學(xué)院教師、院長助理，東華大學(xué)科研處副處長，科研教學(xué)平臺聯(lián)合黨委書記?，F(xiàn)有主持參與國家、省部級及產(chǎn)學(xué)研項目近20項，發(fā)表SCI、EI檢索論文60余篇，申請和授權(quán)發(fā)明專利34項。

研究方向：

1、 智能檢測技術(shù)(激光多普勒測振、機器視覺與深度學(xué)習(xí))

2、 纖維介質(zhì)流體動力學(xué)建模與CFD技術(shù)

榮譽及獲獎情況：

1、 “界面摩擦調(diào)控及超滑”獲2022年上海市科學(xué)技術(shù)獎自然科學(xué)獎二等獎

2、 “全自動噴絲板微孔檢測儀”獲2010年紡織工業(yè)協(xié)會科技進(jìn)步二等獎

近年來承擔(dān)的主要科研項目：

1、 國家重點研發(fā)計劃項目，2021YFB3701600，面向月球基地用仿月海玄武巖纖維研制與模塊化裝備構(gòu)建-自動化上絲裝置，80萬元，2021.12-2025.11，在研，主持

2、 上海市軍民融合項目，XX纖維生產(chǎn)線研發(fā)及產(chǎn)業(yè)化，50萬元，2018.11-至今，在研，主持

3、 國家重點研發(fā)計劃項目，2016YFB0302901，聚酯高效柔性化制備關(guān)鍵技術(shù)，2016.07-2020.12，90萬元，已結(jié)題，主持

4、 橫向課題，高性能碳纖維原絲的成形動力學(xué)研究，2020.9-2023.9，20萬，在研，主持

5、 橫向課題，非接觸式聚酯FDY長絲的在線張力和結(jié)構(gòu)檢測系統(tǒng)構(gòu)建，2019.12-2022.12，196萬，已結(jié)題，主持

近年來發(fā)表的代表性論著、專利：

論文

[1] Time-delayed feedback bistable stochastic resonance system and its application in the estimation of the polyester filament yarn tension in the spinning process. Chaos, Solitons and Fractals. 2023, 168, 113133.(1區(qū))

[2] Diffusion-convection model for interphase formation and process simulation of bicomponent fiber[J]. Journal of Manufacturing Processes, 2023, 91: 89-98. (2區(qū))

[3] Real-time tension estimation in the spinning process based on the natural frequencies extraction of the Polyester Filament Yarn[J]. Measurement, 2022, 188: 110514. (2區(qū))

[4] Evolution of interfacial formation and configuration control of bicomponent fiber during full spinning process [J]. Textile Research Journal, 2022, 93: 3-4. (3區(qū))

[5] Non-contact detection of polyester filament yarn tension in the spinning process by the laser Doppler vibrometer method[J]. 

Textile Research Journal, 2021: 92(5): 919-928. (3區(qū))

[6] Ma Q*, Dong F, Gan X*, Zhou T. Effects of different interface conditions on energy absorption characteristics of Al/carbon fiber reinforced polymer hybrid structures for multiple loading conditions[J]. Polymer Composites, 2021. (IF=2.877, 3區(qū))

[7] Ma Q*, Sun J, Gan X*, Sun Z. Experiment and modified model for CFRP/steel hybrid tubes under the quasi-static transverse loading[J]. International Journal of Crashworthiness, 2021, 26(3): 343-353. (IF=2.157, 4區(qū))

[8] Ma Q*, Wang K, Gan X*, Tian Y. Optimization design in perforated AL-CFRP hybrid tubes under axial quasi-static loading[J]. International Journal of Crashworthiness, 2021(4):1-20. (IF=2.157, 4區(qū))

[9] Wang S, Ma Q*, Gan X*, Zhou T. Crashworthiness analysis and multi-objective optimization of Al/CFRP tubes with induced holes[J]. Polymer Composites, 2021, 42(10): 5280-5299. (IF=2.877, 3區(qū))

[10] Bai C, Ma Q*, Gan X*, Zhou T. Theoretical prediction model of mean crushing force of CFRP-Al hybrid circular tubes under axial compression[J]. Polymer Composites, 2021, 42(10): 5035-5050. (IF=2.877, 3區(qū))

[11] Dong F, Ma Q*, Gan X*, Zhou T. Crashworthiness analysis of perforated metal/composite thin-walled structures under axial and oblique loading[J]. Polymer Composites, 2021, 42(4): 2019-2036. (IF=2.877, 3區(qū))

[12] Zha Y, Ma Q*, Gan X*, Cai M, Zhou T. Deformation and energy absorption characters of Al-CFRP hybrid tubes under quasi-static radial compression[J]. Polymer Composites, 2020, 41(11): 4602-4618. (IF=2.877, 3區(qū))

[13] Ma Q*, Zha Y, Dong B, Gan X*. Structure design and multiobjective optimization of CFRP/aluminum hybrid crash box[J]. Polymer Composites, 2020, 41(10): 4202-4220. (IF=2.877, 3區(qū))

[14] Ma Q, Zhang D, Gan X*. Simulation of the flow field and the chemical reaction coupling of selective catalytic reduction (SCR) system using an orthogonal experiment[J]. Plos one, 2019, 14(7): e0216138. (IF=3.788, 3區(qū))

[15] Shi B, Gan X, Zhang C, et al. Investigating the effect of nanoscale triboelectrification on nanofriction in insulators[J]. Nano Energy, 2022, 91: 106620. (IF=17.631, 1區(qū))

[16] Ma Q, Wang S, Zhou Q, et al. Parallel optimization of design and manufacture for carbon fiber reinforced plastic oil pan based on the thickness distribution[J]. Polymer Composites, 2021. (IF=2.877, 3區(qū))

[17] Shi B, Gan X, Lang H, et al. Ultra-low friction and patterning on atomically thin MoS2 via electronic tight-binding[J]. Nanoscale, 2021, 13(40): 16860-16871. (IF=7.632, 2區(qū))

[18] Wu Z, Chen Z, Chen G, et al. An Improvement of Probabilistic Feasible Region Method for Reliability-Based Design Optimization[J]. International Journal of Computational Methods, 2021, 18(06): 2140004. (IF=1.861, 4區(qū))

[19] Wu Z, Chen Z, Chen G, et al. A probability feasible region enhanced important boundary sampling method for reliability-based design optimization[J]. Structural and Multidisciplinary Optimization, 2021, 63(1): 341-355. (IF=4.715, 2區(qū))

[20] Wang Y, Chen G, Li W, et al. Reflectance model for filament yarn composed of different color monofilaments[J]. The Journal of the Textile Institute, 2021, 112(12): 2039-2047. (IF=2.028, 3區(qū))

[21] Cao X, Gan X, Lang H, et al. Impact of the Surface and Microstructure on the Lubricative Properties of MoS2 Aging under Different Environments[J]. Langmuir, 2021, 37(9): 2928-2941. (IF=3.908, 2區(qū))

[22] Zhaolin LIU, Yang Y, Yuwen W, et al. Preparation and Properties of Opaque Polyethylene Terephthalate/TiO2 Filaments[J]. Materials Science, 2021, 27(3): 325-329. (IF=0.665, 4區(qū))

專利

1、 一種基于激光測振的化纖長絲張力在線檢測方法及裝置, 2021-8-24, 中國, ZL20201032616.5.

2、 一種噴絲板殘留雜質(zhì)光電檢測清洗平臺, 2019-12-31, 中國, ZL201911413044.6.

3、 一種低阻尼聚酯負(fù)壓熔融紡絲成形方法, 2018-10-23, 中國,ZL201611004381.6.

4、 一種高強度纖維正壓熔融紡絲成形方法, 2018-10-23, 中國,ZL201611004297.4.

主要學(xué)術(shù)兼職：

1、 中國紡織工程學(xué)會紡織機械器材專業(yè)委員會化纖機械學(xué)組副組長

2、 上海市、中國紡織協(xié)會科技獎勵評審專家

聯(lián)系電話：021-67792132           E-MAIL：xuehuig@dhu.edu.cn