Prof. Pan of KUAS

潘煌鍟教授

E-mail: pam [at] nkust.edu.tw

電話: 07-3814526轉15231

研究方向 (Research Interests)

	結構健康監測 (Structural Health Monitoring)

	智慧壓電水泥和壓電感測器 (Smart Piezoelectric Cement and Piezoelectric Sensors)

	超高性能混凝土 (Ultra High Performance Concrete, UHPC)

	水泥基結構超級電容器 (Cement-based structural supercapacitors)

發表著作 (Publications)

	Paper/[Book]	Year	Citation
[221].	Determination of Interfacial Transition Zone of Cementitious Materials by ESPI.
[220].	Empirical Formulation for Age-Dependent Piezoelectric and Dielectric Properties of PZT/Cement Composites.
[219].	Monitoring the Concrete Strength Using Piezoelectric Cement Sensor-Based Electromechanical Impedance.
[218].	Effect of Alkali Equivalent on the Electrochemical Properties of Alkali-Activated Supercapacitors.	(2027)
[217].	Research on the Engineering Properties of Biomineralized Waste Tire Rubber Fine Aggregate Concrete.	(2026)
[216].	壓電陶瓷感測器用於混凝土中性化監測.	(2026)
[215].	Characteristics of PZT/Alkali-Activated Composites for Piezoelectric Sensors.	(2026)
[214].	Effect of Seawater Curing on the Engineering Properties of Alkali-Activated BFS Mortar.	(2026)
[213].	An Initial Analysis of Improvement Measures (IMs) for CCE Industry's Female Labour Participation in Taiwan.	(2026)	優秀論文2026-ICEIB
[212].	Dynamic Tensile Behavior of Ultra-High Performance Concrete Reinforced with Steel Fibers Under Quasistatic to High Strain Rates.	(2026)
[211].	Effect of CO2 Curing on the Engineering Properties of Moratr Incorporating Recycled Aggregate.	(2026)
[210].	海水養護對鹼激發砂漿抗壓強度之影響.	(2025)
[209].	以爐石與飛灰為膠結材料之配比參數對鹼激發砂漿抗壓強度之影響.	(2025)
[208].	鹼激發輕質砂漿工程性質之研究.	(2025)
[207].	養護濕度對水泥基壓電複合材料性質影響.	(2025)
[206].	鋯鈦酸鉛陶瓷感測器應用於鹼激發砂漿強度監測.	(2025)
[205].	Effect of Free Water on Polarization and Piezoelectric Coefficients of Cement-Based Piezoelectric Composites During Manufacturing Process. [https://doi.org/10.4028/p-5qsFns]	(2025)
[204].	The Factors of Gender Inequity in Employment in the A/E/C Industry in Taiwan: Report-Reflexive Evidences from a Survey.	(2025)
[203].	Feasibility Study of Precoated Binder Type Electric Arc Furnace Oxidizing Slags as Aggregates for Cement Mortar. [DOI: 10.1007/978-3-031-69626-8_11]	(2025)
[202].	玻璃粉對水泥基壓電複合材料壓電性質影響. [DOI:10.6652/JoCICHE.202412_36(8).0006]	(2024)
[201].	Piezoelectric Properties and Electromechanical Impedance of Piezoelectric Cement as a Sensing Material.	(2024)
[200].	基於快速氯離子滲透試驗之硬固混凝土游離性氯離子含量評估.	(2024)
[199].	國軍內部緊急應變體制及措施精進作為.	(2024)
[198].	電信公司人孔局限空間作業導入科技防災作為.	(2024)
[197].	建築工程地梁鋼筋組立施工風險評估.	(2024)
[196].	Two-Phase Three-Median (2P3M): The 2P3M Approach and Its Application.	(2024)
[195].	Rebar Corrosion Monitoring in Concrete Using Piezoelectric Cement Sensors. [DOI:10.1007/9783031533891_100]	(2024)	1次
[194].	Effect of Steam Curing on the Compressive Strength of Concrete with Blast Furnace Slag. [https://doi.org/10.1007/978-981-99-9227-0_38]	(2024)
[193].	以鋯鈦酸鉛感測器監測三維列印混凝土列印性質.	(2023)
[192].	超高性能混凝土動態拉伸力學行為研究.	(2023)
[191].	AI與傳統門禁對營造業職場安全管理.	(2023)
[190].	沉箱、基礎深開挖施工風險評估之實施-以台20線78K+500寶來一橋改建工程為例.	(2023)
[189].	Effect of Epoxy Resin and Barium Zirconate Titanate Contents on Piezoelectric Properties of 0-3 Barium Zirconate Titanate-Portland Cement Composite with Epoxy Resin Addition. [DOI:10.1016/j.ceramint.2023.02.188]	(2023)	7次
[188].	Piezoelectric Cement Sensor-Based Electromechanical Impedance Technique for the Chloride Ion Content Monitoring of Hardened Concrete. [https://doi.org/10.1117/12.2658308]	(2023)
[187].	Effect of Water to Cement Ratio on Acoustic Impedance, Microstructure, and Piezoelectric Properties of 0-3 Barium Zirconate Titanate-Portland Cement Composite with Epoxy Resin Addition. [DOI:10.1016/j.materresbull.2022.112078]	(2023)	8次
[186].	[橋梁工程施工實務]	(2022)
[185].	Effect of Graphene on Piezoelectric Properties of Cement-Based Piezoelectric Composites. [DOI:10.1016/j.sna.2022.113882]	(2022)	27次
[184].	Durability of Lightweight Aggregate Concrete Incorporating High Volume Fly Ash.	(2022)
[183].	壓電水泥監測三維列印混凝土的列印性質和有效監測頻率.	(2022)
[182].	壓電水泥感測器應用在混凝土結構之氯離子含量監測技術.	(2022)
[181].	逆打工法地下室開挖施工安全評估-以臺北市某大樓新建工程為例.	(2022)
[180].	TCI優質學術期刊研究分享.	(2022)
[179].	Stress and Strain Behavior Monitoring of Concrete Through Electromechanical Impedance Using Piezoelectric Cement Sensor and PZT Sensor. [DOI:10.1016/j.conbuildmat.2022.126685]	(2022)	81次
[178].	2021台灣混凝土學會暨混凝土工程研討會11/18舉行.	(2022)
[177].	微鋼纖維對超高性能混凝土拉力行為之研究.	(2021)
[176].	熱處理對添加飛灰壓電水泥之壓電性質影響.	(2021)
[175].	添加爐石對經熱處理0-3型水泥壓電複合材料之性質影響.	(2021)
[174].	使用直接拉伸及雙向壓孔試驗對UHPC張力行為之比較.	(2021)
[173].	監造單位以編碼表單在模板工程的安全衛生查核.	(2021)
[172].	應用構件預鑄化降低營造業職災風險之探討.	(2021)
[171].	台灣營造業男性從人力斷層及薪資低下之因應對策.	(2021)
[170].	Rudder Profiles of Power-Free Underwater Vehicle for Kuroshio Power Generation. [DOI:10.14455/ISEC.2020.7(2).ENR-02]	(2020)	3次
[169].	Piezoelectric Properties of Cement Piezoelectric Composites Containing Nano-Quartz Powders. [DOI:10.14455/ISEC.2020.7(2).SUS-02]	(2020)	4次
[168].	紊流效應對黑潮無動力載具舵片水平配置影響之探討.	(2020)
[167].	[結構分析] /譯 [---ISBN 9789863782575] (高立圖書)	(2020)
[166].	壓電水泥感測器應用於RC結構物鋼筋腐蝕監測.	(2020)
[165].	壓電水泥感測器監測硬固混凝土氯離子濃度技術.	(2020)
[164].	Piezoelectric Cement Sensor-Based Electromechanical Impedance Technique for the Strength Monitoring of Cement Mortar. [DOI:10.1016/j.conbuildmat.2020.119307]	(2020)	97次
[163].	Influence of Water-to-Cement Ratio on Piezoelectric Properties of Cement-Based Composites Containing PZT Particles. [DOI:10.1016/j.conbuildmat.2019.117858]	(2020)	42次
[162].	添加氧化石墨烯對水泥壓電複合材料壓電性質的影響.	(2019)
[161].	探討水泥基壓電複合材料微觀結構特性與壓電性質之研究.	(2019)
[160].	A Case Study of Urban Road Subsidence Induced By the Underground Connection of the Shield Tunneling Method.	(2019)	2次
[159].	使用壓電水泥與機電阻抗技術監測砂漿和混凝土強度.	(2019)	論文獎2020-土木水利工程學刊
[158].	Composite Approach for Strain-Rate Sensitivity of Reactive Powder Concrete with Steel Fibers.	(2019)
[157].	Performance Evaluation of a Rocking Steel Column Base Equipped With Asymmetrical Resistance Friction Damper.	(2019)	14次
[156].	施工架作業安全管理與案例探討.	(2019)
[155].	Piezoelectric Cement Sensor and Impedance Analysis for Concrete Health Monitoring.	(2019)	9次
[154].	The Assessment of Temperatures Dissipation During the Hot Mix Asphalt Concrete Construction in Conjunction with a Multilayered Pavement Temperature Monitoring Stations.	(2019)
[153].	機電阻抗法應用於水泥砂漿強度預測.	(2018)
[152].	使用壓電水泥感測器監測水泥砂漿應力-應變關係.	(2018)
[151].	石墨烯分散對水泥壓電複合材料壓電性質的影響.	(2018)
[150].	使用壓電水泥感測器監測不同水灰比水泥砂漿強度.	(2018)
[149].	The Evaluation of Skid Resistance with Various Film Thickness of Moisture in Dense-Graded Asphalt Mixture.	(2018)
[148].	The Pilot Study in Processing and Piezoelectric Properties of Asphalt-Based PZT Composites.	(2018)
[147].	Seismic Performance Evaluation of the Steel Column Base with an Asymmetrical Friction Damper.	(2018)
[146].	奈米石英粉對0-3型水泥壓電複合材料壓電性質的影響.	(2017)
[145].	PZT級配對0-3型水泥壓電複合材料的性質影響.	(2017)
[144].	壓電水泥感測器製作與力電性質.	(2017)
[143].	矽藻土含量對水泥壓電複合材料壓電性質的影響.	(2017)
[142].	Strength Analysis for the Rudder of Power-Free Underwater Vehicle in Kuroshio Subjected to Typhoon Waves.	(2017)	1次
[141].	壓電水泥感測器監測水泥砂漿強度發展.	(2017)
[140].	房地產投資報酬評估-以高雄仁武為例.	(2017)
[139].	Curing Time and Heating Conditions for Piezoelectric Properties of Cement-Based Composites Containing PZT.	(2016)	34次
[138].	High Piezoelectric and Dielectric Properties of 0-3 PZT/Cement Composites by Temperature Treatment.	(2016)	56次
[137].	應用形狀記憶合金之自復位鋼構梁柱接頭開發.	(2016)
[136].	壓電陶瓷含量對水泥壓電複合材料壓電與力電性質的影響.	(2016)
[135].	級配PZT對0-3型水泥壓電複合材料壓電性質的影響.	(2016)
[134].	非對稱摩擦系統之開發性能評估.	(2016)
[133].	淺談滑動模板工程-以火力發電廠筒式煤倉工程為例.	(2016)
[132].	以CFRP束制鋼梁局部挫曲行為之效能評估.	(2016)
[131].	The Nondestructive Evaluation of High-Temperature Conditioned Concrete in conjunction with Acoustic Emission and X-ray Computed Tomography.	(2016)	6次
[130].	Causes of Explosion in Section C of the Diversion Tunnel Under Construction at Zengwen Reservoir.	(2016)
[129].	水灰比對0-3型水泥壓電複合材料壓電性質的影響.	(2015)
[128].	水泥壓電感測器的力電性質.	(2015)	優秀論文2015-TCI
[127].	矽藻土水泥壓電材料壓電性質.	(2015)
[126].	點石成金-2015臺灣創意混凝土競賽活動.	(2015)
[125].	隧道開挖爆炸之主動式預防-以「曾文水庫越域引水工程計畫」職災為例.	(2015)
[124].	High Piezoelectric Properties of Cement-Based Piezoelectric Composites Containing Kaolin.	(2015)	10次
[123].	[彈性力學] [---ISBN 9789868558373] (太普公關)	(2014)
[122].	顯微結構與水泥壓電複合材料壓電性質.	(2014)
[121].	水灰比對0-3型矽灰/水泥壓電複合材料壓電性質的影響.	(2014)
[120].	含水狀態爐石活性粉混凝土磨耗和力學性質.	(2014)
[119].	Piezoelectric Properties of Cement-Based Piezoelectric Composites Containing Fly Ash.	(2014)	6次
[118].	台灣土石流防救災策略與機制探討.	(2014)
[117].	Effect of Aged Binder on Piezoelectric Properties of Cement-Based Piezoelectric Composites.	(2014)	19次
[116].	卜作嵐材料對混凝土阻尼係數的影響.	(2013)
[115].	0-3型矽灰水泥壓電複合材料壓電性質.	(2013)
[114].	Age Effect on Piezoelectric Properties of Cement-Based Piezoelectric Composites Containing Slag.	(2013)	4次
[113].	Attack Angle and Strength of Rudders for Power-Free Underwater Vehicle in Kuroshio.	(2013)	2次
[112].	New Waterwheel Blades for Power Generation in Kuroshio.	(2013)	2次
[111].	Influence of Pozzolanic Materials on 0-3 Cement-Based Piezoelectric Composites.	(2013)	11次
[110].	適用在黑潮洋流發電之水渦輪機葉片.	(2012)
[109].	洋流發電防止水下海生物附著塗料比較.	(2012)
[108].	Rudder Controlling of Underwater Vehicle Using in Kuroshio.	(2012)	5次
[107].	Effect of Pozzolanic Materials and Poling Field on Electromechanical Coupling Coefficient of Cement-Based Piezoelectric Composites.	(2012)	3次
[106].	洋流發電水下海生物附著分析.	(2012)
[105].	核能反應爐搬運作業安全研究.	(2012)
[104].	Investigation on the Age-Dependent Constitutive Relations of Mortar.	(2012)	15次
[103].	學生就應善盡認真學習的學生本份. [高雄應用科技大學頂尖高手5~專訪]	(2011)
[102].	添加爐石對0-3型水泥壓電複合材料壓電與介電性質影響.	(2011)
[101].	活性粉混凝土界面過渡區位移與耐久性.	(2011)
[100].	爐石活性粉混凝土的動態力學性質與耐久性.	(2011)
[99].	Properties of Coconut Fiber/Rubber Cement Board for Building Partitions.	(2011)	3次
[98].	Mechanical Properties of Steel Fiber Reinforced Reactive Powder Concrete Following Exposure to High Temperature Reaching 800 oC.	(2011)	388次
[97].	Static-Dynamic Properties of Reactive Powder Concrete with Blast Furnace Slag.	(2011)	10次
[96].	Comparison of Various Electrode Instrumentations for Electrical Measurement of Cement-Based Materials.	(2011)
[95].	Determination of Interfacial Transition Zone in Cementitious Materials by Dynamic Displacement.	(2011)
[94].	0-3型PZT水泥基壓電複合材料製程與極化行為(Manufacturing and Polarization Process of 0-3 Cement-Based PZT Composites).	(2011)	10次
[93].	輕鋼構低層住宅施工與危害因子.	(2010)
[92].	養護溫度對 0-3型PZT矽灰水泥壓電性質的影響.	(2010)
[91].	爐石活性粉混凝土韌性性質.	(2010)
[90].	Composite Approach to High Strain-Rate Stress-Strain Curve of Reactive Powder Concrete. [ACF 2010, Proceedings of the 4th ACF International Conference]	(2010)	1次
[89].	Desulfurization Slag/Granulated Blast Furnace Slag Binder and Mortar without Portland Cement.	(2010)
[88].	Electrical Resistivity Measurement of Cement-Based Binders Using Embedded Four-Terminal Probe Method.	(2010)	6次
[87].	ESPI Measurement to Determine Interfacial Transition Zone in Cementitious Materials under Temperatures.	(2010)
[86].	Study on the Strain-Rate Sensitivity of Cementitious Composites.	(2010)	20次
[85].	Effect of Temperature to Micro-Displacement of Interfacial Transition Zone in Cementitious Materials by ESPI Measurement.	(2010)	2次
[84].	建築節能分析與視覺化模擬之研究.	(2010)	1次
[83].	鋼纖維含量對RPC彎曲強度與韌性之比較.	(2010)
[82].	高溫作用後鋼纖維活性粉混凝土殘留強度與變形性能.(Residual Strength and Deformation of Steel Fiber Reinforced Reactive Powder Concrete After Elevated Temperature)	(2010)	5次
[81].	0-3型鋯鈦酸鉛水泥基材料極化行為.	(2009)
[80].	應用類神經網路模式預測鋼筋混凝土深樑之剪力強度.	(2009)
[79].	高溫作用後鋼纖維活性粉混凝土應力-應變行為-理論模擬.	(2009)
[78].	高溫作用後鋼纖維活性粉混凝土應力-應變行為-試驗研究.	(2009)
[77].	Properties of natural fiber cement boards for building partitions.	(2009)	5次
[76].	Effect of Micro and Nano-Cracks for the Mechanical Properties of Cementitious Materials.	(2009)	2次
[75].	活性粉混凝土高溫作用後動態力學行為與破壞模式.	(2009)
[74].	Micromechanics-Based Predictions on the Overall Stress-Strain Relations of Cement-Matrix Composites.	(2008)	16次
[73].	Composite-Based Approach for Strain-Rate Sensitivity of Stress-Strain Curves of Cement-Matrix Composites. [The 3rd ACF International Conference-ACF/VCA 2008]	(2008)
[72].	熱熔塑膠輕質混凝土配比對工程性質之影響.	(2008)
[71].	使用ESPI量測加溫材料的微變位.	(2008)
[70].	微奈米裂縫對水泥系材料韌性的影響.	(2008)
[69].	活性粉混凝土在不同應變速率動態下的應力-應變行為.	(2008)
[68].	輕量安全帶掛鉤研發.	(2008)
[67].	模擬鋼筋混凝土腐蝕殘留應力.	(2008)
[66].	The Accelerated Method for Estimating Corrosion of Reinforced Concrete Structure in Seawater.	(2008)	4次
[65].	雨水下水道鑄鐵清掃孔蓋替代材料分析與評估.	(2008)
[64].	回憶金門技術學院規劃及開發. [金門大學建校十年紀念集]	(2007)
[63].	[施工安全與環境管理] [---ISBN 9789572159965] (全華圖書)	(2007)
[62].	[工程數學] [---ISBN 9789572999936] (太普公關)	(2007)
[61].	模擬水泥壓電複合材料的壓電應變常數.	(2007)
[60].	水泥系材料含孔隙和裂縫的微觀與力學行為.	(2007)
[59].	Determination of Representative Crack Density of Cementitious Materials.	(2007)	1次
[58].	黏土基添加奈米級氧化鋯的力學性質.	(2007)
[57].	Use of Waste Bricks and Tiles as a Pozzolan-like Material in Concrete. (DOI:10.14359/18733)	(2007)	1次
[56].	應用影像分析量測輕質多孔混凝土孔隙率之探討. [第二屆海峽兩岸輕骨料混凝土產製與應用技術研討會, pp. 215-226]	(2006)	優秀論文獎-張朝順
[55].	Micromechanics Approach for Long-Term Stress-Strain Relationships of Cement-Matrix Composites.	(2006)
[54].	Solid-Particle Abrasion of Hydraulic Concrete.	(2006)	1次
[53].	微觀力學法模擬水泥基複合材料長期應力應變行為.	(2006)
[52].	驗證高性能水泥基複合材料微裂縫密度計算方法.	(2006)
[51].	Increasing the Compressive Strength of High Performance Concrete by Adding Nano-Silica Powder.	(2006)
[50].	[Mechanics of Composite Materials]	(2006)
[49].	Effect of Nano-Silica Powder on the Durability Properties of High Performance Concrete.	(2005)
[48].	Zirconia Strengthened High Performance Concrete.	(2005)
[47].	[Elasticity].	(2005)
[46].	氧化鋯對高性能水泥基之韌性研究.	(2004)
[45].	Long-Term Stress-Strain Relations of the Cement-Matrix Composite.	(2004)
[44].	氧化鋯混凝土韌性強化之研究--微裂縫機制.	(2004)
[43].	石膏含量與型式對含強塑劑水泥漿流動性質之影響.	(2004)
[42].	氧化鋯強化高性能混凝土樑韌性.	(2004)
[41].	氧化鋯強化高性能混凝土.	(2004)
[40].	水泥中鹼當量對含強塑劑水泥漿流變行為之影響.	(2004)
[39].	[工程數學].	(2004)
[38].	認識奈米世界. [進修學院專刊]	(2003)
[37].	水泥基複合材料應力-應變曲線力學模式.	(2003)
[36].	Stress-Strain Relationship of Damaged Solids Containing Elliptic Cracks.	(2003)
[35].	Influence of the Constituents on the Elastic Moduli and the Strength of Concrete.	(2003)
[34].	Transformation Toughening of a Two-Phase, Transversely Isotropic Solid.	(2003)	2次
[33].	輸氣混凝土的韌性及彈性模數.	(2002)
[32].	氧化鋯混凝土韌性強化之研究.	(2002)
[31].	Effective Toughness of Damaged Solids Containing Ribbon Cracks.	(2002)	1次
[30].	孔隙對高性能混凝土彈性模數之影響.	(2002)
[29].	強塑劑對C3A水化行為之影響.	(2002)
[28].	A Micromechanical Theory for the Determination of the Stress-Strain Relation of Cement-Matrix Composites.	(2002)
[27].	氧化鋯混凝土可行性之研究.	(2002)
[26].	A Micromechanics Theory for the Transformation Toughening of Two-Phase Ceramics. [10.1007/BF01188741]	(2002)	6次
[25].	The Toughness and Elastic Moduli of Rigid-Reinforced Composites.	(2001)
[24].	Residual Stress on Toughening with Spherical Inclusions Accompanying Phase Transformation.	(2000)
[23].	A Theory for Elastic Potential Energy Change and Applied Stresses Accompanying Phase Transformation.[https://doi.org/10.1017/S1727719100001829]	(2000)
[22].	材料溫度對高性能混凝土工作性及抗壓強度之影響.	(2000)
[21].	[量測系統].	(2000)
[20].	鋼構件製造施工品保/品管自動化系統之開發. [中華民國第一屆營建管理學術研討會, pp. I-105~112]	(1999)
[19].	An Overall Approach for Microcrack and Inhomogeneity Toughening in Brittle Solids.	(1999)	6次 (論文獎2000-力學期刊)
[18].	[預力混凝土工程].	(1999)
[17].	On the Application of Willis' Bounds Involving Ellipsoidal Inclusions.	(1998)
[16].	[分包及安全管理].	(1998)
[15].	混凝土材料韌性加強機構.	(1997)
[14].	量測系統教學架構. [營建自動化教學成果研討會]	(1995)
[13].	Elastic Moduli of Heterogeneous Solids with Ellipsoidal Inclusions and Elliptic Cracks.	(1995)	48次
[12].	HPC筒形試驗品質分析.	(1994)
[11].	T & C Tower HPC 品質保證實務.	(1994)
[10].	工程估價課程架構與教學. [營建自動化課程成果研討會, pp. 165-173]	(1994)
[9].	Thermal Stress Relief by Plastic Deformation in Aligned Two-Phase Composites.	(1993)	9次
[8].	Determination of Transient and Steady-State Creep of Metal-Matrix Composites by a Secant-Moduli Method.	(1993)	9次
[7].	裂縫形狀對等向性脆性材料性質的影響.	(1993)
[6].	Thermal Stress and Volume Change During a Cooling Process Involving Phase Transformation.	(1992)	18次
[5].	Energy Approach to the High-Temperature Creep of Fiber-Reinforced Metal-Matrix Composites. [ASME Winter Annual Meeting]	(1992)	4次
[4].	Thermal Stress and Phase Transformation Strain in Dual-Phase Metals During a Cooling Process. [ASME Winter Annual Meeting]	(1991)	4次
[3].	[工程材料] [---正元圖書公司 (正文書局)]	(1987)
[2].	[土木建築工程概要] . [---正元圖書公司 (正文書局)]	(1987)
[1].	混凝土模型試驗可靠性之研究.	(1984)

潘煌鍟 教授

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潘煌鍟教授