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Student Number 92322052
Author Chung-Yo Mar(馬宗佑)
Author's Email Address okwap1234@yahoo.com.tw
Statistics This thesis had been viewed 6311 times. Download 2572 times.
Department Civil Engineering
Year 2004
Semester 2
Degree Master
Type of Document Master's Thesis
Language zh-TW.Big5 Chinese
Title 探討磁化水之霍爾效應對於砂漿抗壓強度之關係
Date of Defense 2005-07-06
Page Count 201
Keyword
  • Compressive strength of mortar
  • Hall voltage
  • Magnetic water
  • Abstract Abstract
    Due to the instability of the use of mixing magnetic water with concrete and the lack of any equipment or device for measuring the level of magnetization of magnetic water, the quality and level of magnetization of magnetic water remains unknown, and it is therefore hard to control the quality of concrete. Therefore, this study utilizes Hall voltage produced in the process of magnetization as the indication of reacting to the changes of compressive strength, and is devoted to investigating the principle of Hall voltage of magnetic water and stabilizing it. Also, the relation between compressive strength of mortar and Hall voltage is analyzed by applying the electrode principle of MHD generator in the process of the experiment so as to acquire stable Hall voltage and investigate the impact of level of electrode on compressive strength. 
      The result of the study indicates that stable Hall voltage can be measured by a 1cm electrode made of copper foil. Moreover, a stable compressive strength curve of compressive strength of mortar mixed by the magnetic water magnetized by the electrode (1cm) can be acquired. The compressive strength increases as the magnetic-field intensity increases according to the experiment data. The compressive strengths of magnetic field: 0.96T>0.84T>0.65T>0.46T. In terms of the relation between compressive strength and Hall voltage, both of them are in a direct proportion as the flow velocity of magnetic water is less than 200m/min. On the contrary, they are in inverse proportion as the velocity is more than 200m/min. Among magnetized electrodes in various lengths and compressive strengths of mortar, based on the observations of the figures, it can be concluded whether Hall Effect has been employed to the utmost will influence the stability of compressive strength of mortar improved by magnetic water.
    Table of Content 第一章緒論1
    1.1研究源起1
    1.2研究目的2
    1.3研究的內容2
    第二章 文獻回顧4
    2.1水的性質與行為4
    2.1.1水分子架構4
    2.1.2水分子的極性與偶極矩5
    2.1.3分子間的吸引力5
    2.1.4氫鍵5
    2.1.5水的動態結構6
    2.1.6水的溶解度、表面張力與粘度8
    2.2水在通過磁場時的反應9
    2.3 物質的磁性反應9
    2.3.1水的磁化11
    2.3.2核磁共振13
    2.3.3 磁共振影像掃描14
    2.4磁化水的電磁效應15
    2.4.1法拉第電磁感應16
    2.4.2佛來明右手定則16
    2.4.3勞倫茲力17
    2.4.4勞倫茲力與磁化水的關係17
    2.4.5霍爾效應18
    2.4.6霍爾電壓與磁化水22
    2.4.7磁化水的電磁效應25
    2.4.8磁流動力發電器29
    2.4.9電磁式流量計測流33
    2.4.10分割電極與磁化水35
    2.5 磁化設備40
    2.5.1磁的基本概念41
    2.5.2磁鐵位置42
    2.5.3磁極配置44
    2.5.4水流與磁場夾角46
    2.5.5磁鐵的設置47
    2.5.6管線材質的影響48
    2.5.7電極材質的影響50
    2.5.8電磁鐵與永久磁鐵的差異52
    2.6磁化水之成效53
    2.6.1水垢的抑制53
    2.6.2水質的改變58
    2.6.3電雙層及界面電位的改變62
    2.6.4水分子鍵結角度67
    2.6.5水的記憶性68
    2.6.6水分子團大小的改變70
    2.7磁化水對水泥混凝土之影響74
    2.7.1 台灣之研究現況75
    2.7.2 大陸之使用現況77
    2.7.4磁化水改變水泥砂漿抗壓強度的機理79
    2.7.3水中加入物質通過磁場後拌和水泥砂漿80
    第三章 試驗器材與研究方法83
    3.1 實驗材料83
    3.2 實驗設備84
    3.2.1磁化裝置-磁鐵84
    3.2.2磁化裝置-電極93
    3.2.3電極製作材料102
    3.2.4磁化裝置系統103
    3.2.5量測用器材儀器105
    3.2.6抗壓試體拌合設備108
    3.3 研究流程與方法109
    3.3.1研究流程圖109
    3.3.2增強階段111
    3.3.3穩定階段113
    3.3.4整合階段119
    3.3.5水泥砂漿抗壓試體製作階段121
    第四章 結果與分析129
    4.1穩定霍爾電壓129
    4.1.1電子式穩定電壓129
    4.1.2循環法穩定電壓131
    4.1.3改變電極型式及材料來穩定霍爾電壓132
    4.2水泥砂漿試體抗壓試驗136
    4.2.1階段性試驗136
    4.2.2決定管子型式138
    4.2.3探討各電極型式140
    4.2.4 抗壓強度與霍爾電壓之關係158
    4.2.5探討磁化效應殘留時間167
    4.2.6探討流速與流量168
    4.2.7探討磁場間距170
    4.2.8探討水中物質171
    第五章 結論與建議176
    5.1結論176
    5.2 建議177
    參考文獻179
    Reference 參考文獻
    外文部份:
    Al-Qahtani, Haitham, ”Effect of Magnetic Treatment on Gulf Seawater,” Desalination, Vol.107, pp75-81(1996).
    Baker, John S. and Judd, Simon J., ”Magnetic Amelioration of Scale Formation,” review paper, Water Research, Vol.30, No.2, pp.247-260 (1996).
    Barrett, Rebecca A. and Parsons, Simon A.,” Influence of Magnetic Fields on Calcium Carbonate Precipitation,” Water Research, Vol.32, No.3, pp.609-612(1998).
    Basu, A., ”Dynamo Mechanism: Effects of Correlation And Viscosities,” The European Physical Journal B, Vol. 38, pp. 117-126 (2004).
    Benson, Robert F., Lubosco, Ronald and Martin, Dean F.,”Magnetic Treatment of Solid Carbonates, Sulfates, And Phosphates of Calcium,” Journal of Environmental Science and Health, Part A: Toxic/Hazardous Substances and Environmental Engineering, Vol.35, No.9, pp.1527-1524(2000).
    Botello-Zubiate, M.E., Alvarez, A., Martinez-Villafane, A., Almeraya-Calderon, F. and Matutes-Aquino, J.A., “Influence of Magnetic Water Treatment on The Calcium Carbonate Phase Formation and The Electrochemical Corrosion Behavior of Carbon Steel,” Journal of Alloys and Compounds, Vol.369, No.1-2, pp.256-259(2004).
    Busch, K. W., Busch, M. A., Parker, D. H., Darling, R. E. and McAtee, J. L. Jr., ”Studies of A Water Treatment Device That Uses Magnetic Fields,” Corrosion , Vol.42, No.9, pp.211-221(1986).
    Busch, Kenneth W. and Busch, Marianna A., ”Laboratory Studies on Magnetic Water Treatment And Their Relationship to A Possible Mechanism For Scale Reduction,” DESALINATION, Vol.109, pp.131-148(1997).
    Chibowski, E., Holysz, L., Szczes, A. and Chibowski, M., ”Some Magnetic Field Effects on in Situ Precipitated Calcium Carbonate,” Water Science and Technology, Vol.49, No.2, pp.169-176 (2004).
    Coey, J.M.D. and Cass, Stephen, ”Magnetic Water Treatment”, Journal of Magnetism and Magnetic Materials, Vol.209, pp.71-74(2000).
    Colic, Miroslav and Morse, Dwain, ”The Elusive Mechanism of The Magnetic 'Memory' of Water,” Colloids And Surfaces A: Physicochemical And Engineering Aspects, Vol.154, pp.167-174(1999).
    Cristofolini, Andrea and Borghi, Carlo A., “A Difference Method For The Solution of The Electrodynamic Problem In a Magnetohydrodynamic Field,” IEEE Transactions on Magnetics, Vol. 31, No. 3(1995).
    DODEL G, “Experimental Investigation of Current Density Distributions in an Argon-Potassium Plasma Streaming Through a Channel With Segmented Electrodes,” Plasma Phys, Vol. 12, No.4, pp.273-292(1970).
    Gabrielli, C., Jaouhari, R., Maurin, G. and Keddam, M., ”Magnetic Water Treatment For Scale Prevention,” water research, Vol.35, No.13, pp.3249-3259(2001).
    Gehr, Ronald, Zhai, Ziqi A., Finch, James A. and Rao, S. Ram, ” Reduction Of Soluble Mineral Concentrations In CaSO4 Saturated Water Using A Magnetic Field,” Water Research, Vol.29, No.3, pp.933-940(1995).
    Goforth, R.C., Kruger, H.C., “Investigation of Secondary Flows in Magnetohydrodynamic Channels”, Journal Of Propulsion And Power, Vol.9, No.6, pp.889-897(1993).
    Higashitani, Ko, Oshitani, Jun and Ohmura, Norio, “Effects of Magnetic Field on Water Investigated With Fluorescent Probes,” Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol.109, pp. 167-173(1996).
    Hollysz, L., Chibowski, M. and Chibowski, E., ”Time-Dependent Changes of Zeta Potential And Other Parameters of In Situ Calcium Carbonate Due to Magnetic Field,” Colloids and Surfaces A: Physicochemical and Engineering Aspects, Vol. 208, No.1-3 , pp. 231-240(2002).
    Holysz, Lucyna, Chibowski, Emil and Szczes, Aleksandra, ”Influence of Impurity Ions and Magnetic Field on The Properties of Freshly Precipitated Calcium Carbonate,” water research, Vol.37, No. 14, pp.3351-3360(2003).
    Inoue, I., Ishikawa, M. and Umoto, J., “Numerical Study of Arc Phenomena in Boundary Layer On MHD Generator,” Energy Conversion and Management,Vol.33, No.9, pp.873-884(1992).
    Iwasaka, M. and Ueno, S., “Structure of Water Molecules Under 14 T Magnetic Field,” Journal of Applied Physics, Vol.83, No.11, pp.6459-6461(1998).
    Jang, Jaesung and Lee,Seung S.,“Theoretical And Experimental Study of MHD (Magnetohydrodynamic) Micropump,” Sensors and Actuators, A: Physical, Vol. 80, No.1, pp.84-89(2000).
    Kitazawa, Koichi, Ikezoe, Yasuhiro, Uetake, Hiromichi and Hirota, Noriyuki, ” Magnetic Field Effects on Water, Air And Powders,” Physica B, 294-295, pp.709-714(2001).
    Kobe, S., Drazic, G., McGuiness, P.J. and Strazisar, J.,”The Influence of The Magnetic Field on The Crystallisation Form of Calcium Carbonate And The Testing of a Magnetic Water-Treatment Device,” Journal Of Magnetism And Magnetic Materials, Vol.236, pp.71-76(2001).
    Kobe, S., Drazic, G., Cefalas, A.C., Sarantopoulou, E. and Strazisar, J., ” Nucleation And Crystallization of CaCO3 in Applied Magnetic Fields,” Crystal Engineering, Vol.5, pp.243-253(2002).
    Kochmarsky, V., “Magnetic Treatment of Water:Possible Mechanisms And Conditions For Applications,” Magnetic and Electrical Separation, Vol.7, pp.77-107(1996).
    Kozic, V. and Lipus, L.C.,”Magnetic Water Treatment For a Less Tenacious Scale,” Journal of Chemical Information and Computer Sciences, Vol.43, pp.1815-1819(2003).
    Lipus, L.C., Krope, J. and Crepinsek, L., ” Dispersion Destabilization in Magnetic Water Treatment,” Journal of Colloid and Interface Science, Vol.236, No.1, pp.60-66(2001).
    London South Bank University , ”Water Structure And Behavior- Magnetic And Electric Effects on Water,” http://www.sbu.ac.uk/water/magnetic.html
    Mindess, Sidney, J.Francis Young and Darwin David, Concrete, second edition, Prentice-Hall Inc.Upper Saddle River, N.J.07458(2003).
    Mitchner M. and Kruger, Jr. Charles H., Partially Ionized Gases:Chapter Ⅳ,9.magnetohydrodynamic(MHD)power generation, Department of Mechanical Engineering, Stanford University, http://navier.stanford.edu/PIG/C4_S9.pdf, pp.214-230(1992).
    Murray, Robert C., Zaidi, Sohail H., Carraro, Mario R., Vasilyak, Leonid, Macheret, Sergey O., Shneider, Mikhail N. and Miles, Richard B., ”Investigation of a Mach 3 Cold Air Mhd Channel”, 34th AIAA Plasmadynamics and Lasers Conference(2003).
    Non Chemical Technologies for Scale and Hardness Control, U.S. Department of Energy(1998).
    Nyce, David S., Linear Position Sensors:Theory and Application, Hoboken, NY John Wiley & Sons, Inc. (US)(2004)
    Parsons, Simon A.,Wang, Bao-Lung; Judd, Simon J., Stephenson, Tom, ” Magnetic Treatment of Calcium Carbonate Scale-Effect of pH Control,” Water Research, Vol.31, No.2, pp.339-342(1997).
    Quinn, C. Jack, Molden, T. Craig and Sanderson, Charles H., “Magnetic Treatment of Water Prevents Mineral Build-Up,” Iron and steel Engineer, Vol.74, No.7, pp.47-52(1997).
    Rai, Subas, Singh, N.N. and Mishra, R.N., ”Magnetic Restructuring of Water,” Medical& Biological Engineering& Computing, Vol.3, No.4, pp.614-617(1995).
    Sawaya, Elie, Ghaddar, Nesreen and Chaaban, Farid, “Evaluation of The Hall Parameter of Electrolyte Solutions in Thermosyphonic MHD Flow,” International Journal of Engineering Science, Vol. 40, No.18, pp. 2041-2056(2002).
    Strazisar, Janez, Knez, Sergej and Kobe, Spomenka, “The Influence Of The Magnetic Field On The Zeta Potential Of Precipitated Calcium Carbonate,” Particle and Particle Systems Characterization, Vol. 18, No.5-6, pp. 278-285(2001).
    Su, Nan and Wu, Chea-Fang, ”Effect Of Magnetic Field Treated Water On Mortar And Concrete Containing Fly Ash,” Cement and Concrete Composites, Vol.25, No.7, pp.681-688(2003)
    Su, Nan, Wu, Yeong-Hwa and Mar, Chung-Yo, “Effect Of Magnetic Water On The Engineering Properties Of Concrete Containing Granulated Blast-Furnace Slag,” Cement And Concrete Research, Vol.30, pp.599-605(2000)
    Szkatula, A., Balanda, M. and Kopec, M., ”Magnetic Treatment Of Industrial Water. Silica Activation,” The European Physical Journal Applied Physics, Vol. 18, No. 1, pp. 41-49(2002)
    Takeda, Minoru, Tomomori, Naotaka;, Akazawa, Teruhiko, Nishigaki, Kazu and Iwata, Akira,”Flow Control of Seawater With a Diverging Duct by MHD Separation Method,” IEEE Transactions on Applied Superconductivity, Vol.14, No.2, pp.1543-1546(2004).
    Tillack M.S. and Morley N.B., “Magnetohydrodynamics,” McGraw Hill: Standard Handbook for Electrical Engineers, 14th Edition(1998)
    Ueno, Shoogo and Iwasaka, Masakazu, “Parting of Water by Magnetic Fields,” IEEE Transactions on Magnetics, Vol.30, No.6, PP. 4698-4770 (1994).
    Wang, Y., Babchin, A.J., Chernyi, L.T., Chow, R.S. and Sawatzky, R.P., ”Rapid Onset of Calcium Carbonate Crystallization Under The Influence of A Magnetic Field,” Water Research, Vol.31, No.2, pp.346-350(1997).
    Yang, M., Neubauer, C.M. and Jennings, H.M., “Interparticle Potential And Sedimentation Behavior of Cement Suspensions Review And Results From Paste,” Advanced Cement Based Materials, Vol.5, No.1, pp.1-7(1997).
    Yu, Q., Sugita, S.;, Sawayama, K. and Isojima, Y.,” Effect of Electron Water Curing And Electron Charging Curing on Concrete Strength,” Cement and Concrete Research, Vol.28, No.9, pp. 1201-1208(1998).
    中文部份:
    Halliddy D.著,單溥譯,基本物理學,曉園出版社(1991)。
    Hill John W., Baum Stuart J., Feigl Dorothy M. 著,董有蘭譯,化學與生命,國立編譯館,P238-263(1999)。
    Shaw Duncan J.,著張有義、郭蘭生譯,膠體及界面化學入門,高立圖書有限公司(1999)。
    Dickson T.R.著,黃芳裕,尹淑萍,廖金閱譯,普通化學,五南圖書出版股份有限公司,P317-321(2002)
    上平垣,「水的本質」,中華水電冷凍空調,第165,期第81-83頁 (1997)
    方江華、張景鈺、江玉松,「磁化水混凝土應用的幾個技術問題的研究」,安徽理工大學學報(自然科學版),第24卷,第2期,第18-22頁(2004)。
    日本電器計測器工會編、鄭振東譯,流量計的正確使用方法,中國生產力中心(1992)。
    左卷健男編著、余秋華譯,水與空氣的100個秘密,稻田出版有限公司(1999)。
    石中信編譯,能源應用,文笙書局,pp.271-275(1986)。
    朱元保、顏流水、曹祉祥、文陵飛、陳宗璋,「磁化水的物理化學性能」,湖南大學學報(自然科學版),Vol.26,No.1,第21-32頁(1999)。
    安文漢,「磁化水混凝土的試驗研究」,鐵道建築技術,第3期,第21-24頁(1996)。
    安燕、劉雲,「磁化水及其溶液表面性質的研究」,中科院化學所,貴州大學學報,29卷,第24期,第103-106頁(1998)。
    向可華譯,先進能源系統-MHD動力發電系統,能源季刊,第22卷,第三期(1982)。
    吳劍秋,基礎電磁學,全華科技圖書(2004)。
    吳志高,「磁場對碳酸鈣晶體成長速率之影響」,碩士論文,國立台灣大學,(2002)。
    吳忠、秦本東、羅運軍,「磁化水對混凝土強度的影響及其作用機理試驗研究」,建井技術,第25卷,第1期,第28-32頁(2004)。
    沈永年,「高性能混泥土水化作用機理之研究」,博士論文,台灣科技大學(1997)。
    屈志中,「前蘇聯利用磁化水拌製混凝土技術的現狀和問題」,建築技術,第23卷,第50-52頁(1996)。
    林英智著郭懿純策劃編輯,核磁共振儀專輯,行政院國家科學委員會精密儀器發展中心,1988
    苑金生,「水泥與磁化水」,中國建材,第7期,第37-38頁(2003)。
    姚慶釗、熊瑞生、何偉,「磁化水對水泥混凝土的增強效應分析」,上海建材,第1期,第26-27頁(2003)。
    哈爾濱市大禹磁處理開發有限公司,http://www.hrbdayu.com。
    郭松年、張自太,「磁化水拌和混凝土提高強度試驗」,甘肅農業大學學報,第30卷,第2期,第169~172頁(1995)。
    高向陽,「磁化水拌和混凝土的實分析」,彭城職業大學學報,第17卷,第4期,第52-56頁,(2002)。
    張啟陽,電磁學,東華書局,(1989)。
    魚崎浩平及喜多英明著黃忠良譯,基本電化學,復漢出版社(1993)。
    陳主福,「磁性水處理器概論」,中華水電冷凍空調,第142期,第117-123頁(1995)。
    游意雯,「磁場對二氧化矽粒子在(有機溶液-水)中zeta電位的影響」,碩士論文,國立台灣大學(2000)。
    許桂銘,「磁化水對水泥混凝土性能影響之探討」,鋪面工程學術研討會,第16屆(2001)。
    黃俊達、吳昌崙編著,電子學,全華科技圖書股份有限公司(1988)。
    張庭瑋,「強塑劑與水的磁化對水泥漿體性質的影響」,雲林科技大學,碩士論文(1999)。
    揚昌林、廖振方、陳德淑,「強極性活化水增強混凝土力學性能的機理研究」,新型建築材料,第2-4頁(2004)。
    曾憲煊、孫永振、肖恩與、孫國堂,「磁化水拌制水泥試驗研究」,河南交通科技,第5期,第18-23頁(1994)。
    曾國輝編著,化學,藝軒圖書出版社(2002)。
    湯如山、陳謝軍、姜玉松、徐穎,「磁化混凝土的試驗研究與應用分析」,建井技術,第20卷,第5期,第28-30頁(1999)。
    葉海坤,「工業節水新妙方-磁能處理器」,節約用水季刊24期(2001)。
    詹舒斐、陳仁仲、王今方/工研院能資所節水團,「電解水基礎研究」,節約用水季刊21期(2001)http://www.wcis.itri.org.tw/library/pdf/21-7.pdf。
    楊喬宇,「探討哈耳電壓與水磁化變數之關係及其對水泥砂漿抗壓強度之影響」,碩士論文,國立中央大學(2004)。
    劉占金、王恩松、余大全,「永磁式磁水器在混凝土工程中的應用技術」,混凝土,第43-47頁(1994)。
    謝榮忠,「商用磁能防垢器對碳酸鈣結晶之影響」,碩士論文,國立台灣大學(2003)。
    陳維方、鐘明吉 著,電機學,全華科技圖書股份有限公司(1996)。
    潘友鴻,「外加電場磁場對陶瓷懸浮液中微粉粒泳動行為的影響」,碩士論文,逢甲大學材料科學研究所,台中(1991)
    賴耿陽著,電能原理概論,復漢出版社,pp.90-95(1988)。
    量水設備技術規範草案第二篇,封閉管路量水設備技術規範,第三章 電磁式流量計測流,經濟部水利署,910128。
    蘇彥勳、李金海編,流量計量,中國計量出版社(1994)。
    蘇南、吳啟芳,「磁化水對飛灰混凝土工程性質之影響」,中國土木水利學刊,第十二卷,第四期,第839-846頁(2000)。
    蘇南、呂坤宗,「磁化水對混凝土力學性質及微結構之影響」,中國土木水利學刊,第十一卷,第三期,第473-483頁(1999)。
    Advisor
  • Chau Lee(李釗)
  • Files
  • 92322052.pdf
  • approve in 2 years
    Date of Submission 2005-07-12

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