磁化处理对铸造无机材料(水、水玻璃)性能的影响
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摘要
本文利用强磁场设备系统研究了不同磁场条件(0-10T)对铸造用无机材料(水、水玻璃)及水玻璃砂性能的影响。
本文研究了水经过磁化处理后,各种物理化学性质的变化。研究结果表明磁化处理后,水的电导率和PH值呈下降的趋势,虽然表面张力也有下降,但不是线性的关系,与磁感应强度的关系是一条多极值曲线。为了更进一步的研究,本文通过分子动力学模拟的方法计算了磁场条件下水的内能,得到了水的内能和磁感应强度之间也呈多极值特征,曲线走向与实验结果一致,说明方法合理可信。
水玻璃经磁场处理可以降低粘度,提高水玻璃砂的粘结强度,不同磁场强度下的磁化效果不同。试验发现0.9~1T条件下,型砂的粘结强度升幅最大,效果最好,可提高46%,水玻璃的“老化”程度影响着磁化处理的效果,存放久的老化水玻璃磁化效果明显。由于磁化处理可提高水玻璃砂的粘结强度,从而降低型砂中水玻璃的加入量,改善水玻璃砂的溃散性,有很好的经济和社会效益。
The paper is mainly studied the effects on properties of silicate bonded sand and inorganic material for foundry (water, sodium silicate) of different magnetic fields (0~1T) by ultra-strong magnetic device.
The paper studied the change of physical and chemical properties of water after magnetization. Experiment results point that the electric conductivity and PH value are in a reducing trend. Although surface tension reduces too, but in a nonlinear way, the relation between surface tension and magnetic conduction intensity is multi-extreme num relation. In order to further study, the paper calculated the internal energy of water molecules by molecular dynamics simulations. The results point that the relation between the internal energy of water and magnetic conduction intensity is also multi-extreme num relation, the trend agrees with the experiment result, it proves that the simulation method is reasonable and comparable.
The viscosity of sodium silicate may be reduced, thus the bond strength may be increased by magnetization. The magnetization result differs in different magnetic fields. The results point that the bond strength of foundry sand may be maximum increased by 46% in magnetic field of 0.9-IT. The aging level of sodium silicate will impact the effects of magnetization. The magnetization result of aged sodium silicate rested for long time is obvious. As the bond strength of silicate bonded sand will be increased by magnetization, the additional level of silicate bonded sand may be reduced, thus improving the collapsibility of the silicate bonded sand, yielding better economic and social returns.
本文研究了水经过磁化处理后,各种物理化学性质的变化。研究结果表明磁化处理后,水的电导率和PH值呈下降的趋势,虽然表面张力也有下降,但不是线性的关系,与磁感应强度的关系是一条多极值曲线。为了更进一步的研究,本文通过分子动力学模拟的方法计算了磁场条件下水的内能,得到了水的内能和磁感应强度之间也呈多极值特征,曲线走向与实验结果一致,说明方法合理可信。
水玻璃经磁场处理可以降低粘度,提高水玻璃砂的粘结强度,不同磁场强度下的磁化效果不同。试验发现0.9~1T条件下,型砂的粘结强度升幅最大,效果最好,可提高46%,水玻璃的“老化”程度影响着磁化处理的效果,存放久的老化水玻璃磁化效果明显。由于磁化处理可提高水玻璃砂的粘结强度,从而降低型砂中水玻璃的加入量,改善水玻璃砂的溃散性,有很好的经济和社会效益。
The paper is mainly studied the effects on properties of silicate bonded sand and inorganic material for foundry (water, sodium silicate) of different magnetic fields (0~1T) by ultra-strong magnetic device.
The paper studied the change of physical and chemical properties of water after magnetization. Experiment results point that the electric conductivity and PH value are in a reducing trend. Although surface tension reduces too, but in a nonlinear way, the relation between surface tension and magnetic conduction intensity is multi-extreme num relation. In order to further study, the paper calculated the internal energy of water molecules by molecular dynamics simulations. The results point that the relation between the internal energy of water and magnetic conduction intensity is also multi-extreme num relation, the trend agrees with the experiment result, it proves that the simulation method is reasonable and comparable.
The viscosity of sodium silicate may be reduced, thus the bond strength may be increased by magnetization. The magnetization result differs in different magnetic fields. The results point that the bond strength of foundry sand may be maximum increased by 46% in magnetic field of 0.9-IT. The aging level of sodium silicate will impact the effects of magnetization. The magnetization result of aged sodium silicate rested for long time is obvious. As the bond strength of silicate bonded sand will be increased by magnetization, the additional level of silicate bonded sand may be reduced, thus improving the collapsibility of the silicate bonded sand, yielding better economic and social returns.
引文
1.松本真治,和田仁.应用见开发.新磁气科学,日本东北大学,2000:1~7
2. F. debray, E.Mossang, W. Joss. Energy Conversion and Management. 2002(43):427~432
3.曹昌年.进入水处理的物理方法.物理,22(1993):361
4.克拉辛著,毛钜凡译.磁化水.北京,计量出版社,1982
5. K. Higashitani er al.. J. Colloid and Interface Science. 1992, 152 (1): 125
6.陈子瑜.磁场对共聚反应影响研究.兰州大学学报,1995,31(2),160
7.孙东宁,吴望一.低频交变磁场对刚性直圆管中脉动流的影响.应用数学和力学,1997,18(2):113~118
8. K. Higashitani er al.. J. Colloid and Interface Science. 1993, 156 (1): 90
9.常恩明.强磁防蜡技术在江汉油田抽油中的应用.磁能应用技术,1990,1:36~39
10.程子健.大庆油田磁技术的综合应用和研究.磁能应用技术,1993,4:13~21
11.朱林.磁处理对原油脱水和油气分离影响的观测.磁能应用技术,1991,2:15~17
12.丁昭.磁化防垢机理及适用界限研究.科技通报,1997,13(6):378~382
13.赵丹亚,郭平.磁化处理水防垢除垢极力探讨.云南工学院学报,1994,10(1):83~87
14.罗大兵.水的磁法处理技术—缚挪威考察见闻.工业水处理,1999,19(2):43~44
15.王瑞金.PMWP强磁水处理器的阻垢试验.水处理技术,2001,27(4):239~241
16.罗漫、陆柱.磁场处理水的阻垢研究.水处理技术,2000,26(4):218~221
17.高阳.谈谈磁处理水技术及其在热水供暖锅炉中的应用.工业水处理,1999,19(5):140~141
18.刘茉娥,朱常乐.高梯度磁分离技术在环保中的应用.化学工程,1987,2:57~63
19.1971:316
20.张维新,张轶.磁化技术在含酚废水处理中的应用.环境工程,1995,13(5):7~9
21.苏胜.磁化水影响水泥性能的研究.河北建筑科技学院学报,2000,17(1):21~22
22.徐安起,丁学厚,姜滢.磁场处理种子对作物生长的影响.山东大学学报(自然科学版)1998,33(1):58~62
23.周万松.第三届全国生物磁学会议资料.磁性材料及器件,1990,7:52~64
24.陈大睿.土壤改良方法.环境保护,1996,9:28~30
25.于玲娜,田立健,武晓华.磁场对健康人血红细胞的影响.中华理疗杂志,1994,17:19~21
26.周万松.磁场对微循环影响的国内外研究概况.中华理疗杂志,1994,17:167~169
27.高谦.强磁场处理水治疗泌尿系统结石.磁能应用技术,1989,1:40~43
28.梁应权.静磁场对慢性小腿溃疡的疗效及组织病理观察.中华理疗杂志,1994,17:24
29.王兴林,宫克强,贾天敏.水玻璃粘结剂的磁场处理.铸造,1990,6:18~22
30.刘芳玲,蒋佩琳.磁场处理条件与水的表面张力关系的研究.四川师范大学学报,
1997,5(20):127~131
31.李光林,杨亚玲.脉冲磁场对水结构影响的研究.激光生物学报,1999,8(1):39~42
32.吴敦虎,任崇,季孝轩,霍权等.内燃机冷却液的磁化处理.内燃机车,1995,4:25~28
33. P. Jelinek, R. Petrikova, U. Hthnel. E. Flemming, Mglichkeiten der Mdifizierung von Wasserglaslsungen durch Magnetfeld~und Ultraschallbehandlung und praktische Erfahrungen bei der Anwendung von magnetbehandelten Wasserglaslsungen in der CSSR(Teit Ⅰ). Gieβereitechnik.27. Jahrgang. 1981 (12): 370~373
34. 1971(1):25
35. 1976(2):29
36. 1975(10):21
37.胡彭生,罗和平.水玻璃磁性改性研究.上海工业大学学报,1987:8(4):363~375
38.朱纯熙,朱建飞.水玻璃的老化和物理改性.化学通报,1991;(11):32~33
39.王兴林,贾天敏.水玻璃粘结剂的磁场处理.铸造,1990:(6):21~22
40.杨湘杰,李东南,危仁杰等.水玻璃磁化改性对水玻璃砂性能的影响.1997,5:20~23
41.李东南,戴莉莉.水玻璃的磁化改性对水玻璃砂性能的影响.材料开发与应用,1996,14(3):29~31
42.傅廷亮.计算机模拟技术.合肥,中国科学技术大学出版社,2001
43. Mihaly Mezei and David L. Beveridge Further quasicom ponent distribution function analysis of liquid water Temperature dependence of the results[J]. Chem. Phys. 1982, 76(1): 593~600
44. Hideki Tanaka. Koichiro Nakanishi and Noduatsu Watanabe Constant temperature molecular dynamics calculation on Lennard~Jones fluid and its application to water J. chem. Phys. 1983, 78(5): 2626~2634
45.(德)宾得.赫尔曼著,秦克诚译.统计物理学中的蒙特卡罗模拟方法.北京,北京大学出版社,1994
46.(德)D.W.Heermann著,秦克诚译.理论物理学中的计算机模拟方法.北京,北京大学出版社,1996
47.李春喜.纯液体表面张力的统计热力学模型.化工学报,1996,47(3):362~366
48. Zhou K. X., Lu G. W., Zhou Q. C. and Hua S. A. Monte Carlo simualation of liquid water in a magnetic field[J]. Journal of Applied Physics. 2000, 88(4): 1802~1805
49. Owicki J C, Scherage H A. Monte Carlo Calculations in the Isothermal-Isobaric Ensemble. Journal of American Chemical Society. 1997, 99(23): 7403~7413
50.杨小震.分子模拟与高分子材料.科学出版社,2002
51.朱纯熙,卢晨,季敦生.水玻璃砂基础理论.上海,上海交通大学出版社,2000
52.朱纯熙,卢晨,季敦生.水玻璃砂基础理论研究的最新进展.中国机械工程,1992,
10(2):220~223
53.刘伟华,关健,朱纯熙,卢晨,戴跃.水玻璃砂的发展.铸造,2001,50(3):125~128
54.肖波,徐正达,王秀萍,张俊德,黄乃瑜,程金生.水玻璃砂—未来化学粘结刘的主力军,中国机械工程,1996,7(6):70~72
55.朱纯熙,陈荣三,朱建飞.水玻璃的老化和物理改性.化学通报,1991,11,32~35
1.张岩,高波,周继扬.超强磁场对水玻璃砂性能的影响.现代铸铁,2003,1
2.高波,周继扬,宋刚,张岩.磁化处理在液体材料领域应用及研究现状.博士学术动态.2002
3. Bo Gao, Yan Zhang, Jiyang Zhou. Influence of High Magnetic Field on Properties of Sodium Silicate-bonded Sand. Submitted to Material Science & Technology.
2. F. debray, E.Mossang, W. Joss. Energy Conversion and Management. 2002(43):427~432
3.曹昌年.进入水处理的物理方法.物理,22(1993):361
4.克拉辛著,毛钜凡译.磁化水.北京,计量出版社,1982
5. K. Higashitani er al.. J. Colloid and Interface Science. 1992, 152 (1): 125
6.陈子瑜.磁场对共聚反应影响研究.兰州大学学报,1995,31(2),160
7.孙东宁,吴望一.低频交变磁场对刚性直圆管中脉动流的影响.应用数学和力学,1997,18(2):113~118
8. K. Higashitani er al.. J. Colloid and Interface Science. 1993, 156 (1): 90
9.常恩明.强磁防蜡技术在江汉油田抽油中的应用.磁能应用技术,1990,1:36~39
10.程子健.大庆油田磁技术的综合应用和研究.磁能应用技术,1993,4:13~21
11.朱林.磁处理对原油脱水和油气分离影响的观测.磁能应用技术,1991,2:15~17
12.丁昭.磁化防垢机理及适用界限研究.科技通报,1997,13(6):378~382
13.赵丹亚,郭平.磁化处理水防垢除垢极力探讨.云南工学院学报,1994,10(1):83~87
14.罗大兵.水的磁法处理技术—缚挪威考察见闻.工业水处理,1999,19(2):43~44
15.王瑞金.PMWP强磁水处理器的阻垢试验.水处理技术,2001,27(4):239~241
16.罗漫、陆柱.磁场处理水的阻垢研究.水处理技术,2000,26(4):218~221
17.高阳.谈谈磁处理水技术及其在热水供暖锅炉中的应用.工业水处理,1999,19(5):140~141
18.刘茉娥,朱常乐.高梯度磁分离技术在环保中的应用.化学工程,1987,2:57~63
19.1971:316
20.张维新,张轶.磁化技术在含酚废水处理中的应用.环境工程,1995,13(5):7~9
21.苏胜.磁化水影响水泥性能的研究.河北建筑科技学院学报,2000,17(1):21~22
22.徐安起,丁学厚,姜滢.磁场处理种子对作物生长的影响.山东大学学报(自然科学版)1998,33(1):58~62
23.周万松.第三届全国生物磁学会议资料.磁性材料及器件,1990,7:52~64
24.陈大睿.土壤改良方法.环境保护,1996,9:28~30
25.于玲娜,田立健,武晓华.磁场对健康人血红细胞的影响.中华理疗杂志,1994,17:19~21
26.周万松.磁场对微循环影响的国内外研究概况.中华理疗杂志,1994,17:167~169
27.高谦.强磁场处理水治疗泌尿系统结石.磁能应用技术,1989,1:40~43
28.梁应权.静磁场对慢性小腿溃疡的疗效及组织病理观察.中华理疗杂志,1994,17:24
29.王兴林,宫克强,贾天敏.水玻璃粘结剂的磁场处理.铸造,1990,6:18~22
30.刘芳玲,蒋佩琳.磁场处理条件与水的表面张力关系的研究.四川师范大学学报,
1997,5(20):127~131
31.李光林,杨亚玲.脉冲磁场对水结构影响的研究.激光生物学报,1999,8(1):39~42
32.吴敦虎,任崇,季孝轩,霍权等.内燃机冷却液的磁化处理.内燃机车,1995,4:25~28
33. P. Jelinek, R. Petrikova, U. Hthnel. E. Flemming, Mglichkeiten der Mdifizierung von Wasserglaslsungen durch Magnetfeld~und Ultraschallbehandlung und praktische Erfahrungen bei der Anwendung von magnetbehandelten Wasserglaslsungen in der CSSR(Teit Ⅰ). Gieβereitechnik.27. Jahrgang. 1981 (12): 370~373
34. 1971(1):25
35. 1976(2):29
36. 1975(10):21
37.胡彭生,罗和平.水玻璃磁性改性研究.上海工业大学学报,1987:8(4):363~375
38.朱纯熙,朱建飞.水玻璃的老化和物理改性.化学通报,1991;(11):32~33
39.王兴林,贾天敏.水玻璃粘结剂的磁场处理.铸造,1990:(6):21~22
40.杨湘杰,李东南,危仁杰等.水玻璃磁化改性对水玻璃砂性能的影响.1997,5:20~23
41.李东南,戴莉莉.水玻璃的磁化改性对水玻璃砂性能的影响.材料开发与应用,1996,14(3):29~31
42.傅廷亮.计算机模拟技术.合肥,中国科学技术大学出版社,2001
43. Mihaly Mezei and David L. Beveridge Further quasicom ponent distribution function analysis of liquid water Temperature dependence of the results[J]. Chem. Phys. 1982, 76(1): 593~600
44. Hideki Tanaka. Koichiro Nakanishi and Noduatsu Watanabe Constant temperature molecular dynamics calculation on Lennard~Jones fluid and its application to water J. chem. Phys. 1983, 78(5): 2626~2634
45.(德)宾得.赫尔曼著,秦克诚译.统计物理学中的蒙特卡罗模拟方法.北京,北京大学出版社,1994
46.(德)D.W.Heermann著,秦克诚译.理论物理学中的计算机模拟方法.北京,北京大学出版社,1996
47.李春喜.纯液体表面张力的统计热力学模型.化工学报,1996,47(3):362~366
48. Zhou K. X., Lu G. W., Zhou Q. C. and Hua S. A. Monte Carlo simualation of liquid water in a magnetic field[J]. Journal of Applied Physics. 2000, 88(4): 1802~1805
49. Owicki J C, Scherage H A. Monte Carlo Calculations in the Isothermal-Isobaric Ensemble. Journal of American Chemical Society. 1997, 99(23): 7403~7413
50.杨小震.分子模拟与高分子材料.科学出版社,2002
51.朱纯熙,卢晨,季敦生.水玻璃砂基础理论.上海,上海交通大学出版社,2000
52.朱纯熙,卢晨,季敦生.水玻璃砂基础理论研究的最新进展.中国机械工程,1992,
10(2):220~223
53.刘伟华,关健,朱纯熙,卢晨,戴跃.水玻璃砂的发展.铸造,2001,50(3):125~128
54.肖波,徐正达,王秀萍,张俊德,黄乃瑜,程金生.水玻璃砂—未来化学粘结刘的主力军,中国机械工程,1996,7(6):70~72
55.朱纯熙,陈荣三,朱建飞.水玻璃的老化和物理改性.化学通报,1991,11,32~35
1.张岩,高波,周继扬.超强磁场对水玻璃砂性能的影响.现代铸铁,2003,1
2.高波,周继扬,宋刚,张岩.磁化处理在液体材料领域应用及研究现状.博士学术动态.2002
3. Bo Gao, Yan Zhang, Jiyang Zhou. Influence of High Magnetic Field on Properties of Sodium Silicate-bonded Sand. Submitted to Material Science & Technology.