铸造旧砂再生工艺及应用的研究
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摘要
我国每年要排放1000万吨以上的铸造旧砂,旧砂的大量排放,不但造成资源的浪费,而且对环境造成极大的污染,对旧砂的再生回用已成为铸造行业亟待解决的问题。
本文通过对混合型旧砂和水玻璃旧砂进行不同再生工艺的研究,然后利用再生砂制芯、造型,检验再生砂的可使用性,其目的是使再生砂能全部或部分取代新砂造型、制芯,减少旧砂的排放。
对混合型旧砂的实验结果表明,对混合型旧砂进行干法再生和低温加热+干法再生,再生砂仅能回用于造型。采用选择性再生,即将块状树脂旧砂从混合型旧砂中分离出来,对树脂旧砂进行再生,再生工艺采用干法再生和热气流再生+干法再生,再生砂质量得到极大的提高;其中热气流加热分为低温加热和中温加热,中温加热对比低温加热,再生砂质量提高不大。从经济方面考虑,生产中易采用干法再生和低温加热+干法再生。
对干法再生出来的树脂再生砂进行制芯的工艺实验,实验标准按照生产上的要求来实行。实验结果表明,再生砂只能以部分加入用于制芯;由于再生砂性质的变化,制芯工艺必须做一定的调整,其树脂与固化剂的比值要低于标准值4;在旧砂加入量为30%,树脂加入量树脂加入量2.5%(砂重),固化剂加入量0.7%(砂重),树脂与固化剂之比值为3.57,制得的型芯质量达到生产上的使用要求。
对低温加热+干法再生出来的树脂再生砂进行制芯的工艺实验,实验结果表明,再生砂也只能以部分加入用于制芯;再生砂加入量为5%时,制得的型芯质量达到生产上的使用要求;在再生砂加入量为30%时,制芯工艺要做一定的调整,在树脂加入量2.2%(砂重),固化剂加入量0.7%,树脂与固化剂之比值为3.14时,型芯质量合格。
对水玻璃旧砂的实验结果表明,干法再生和低温加热+干法再生均可生产出质量合格的再生砂,后者比前者更为有效,但经济性不如前者。
从经济性考虑,采用干法再生砂做造型、浇注实验。实验结果表明,采用50%再生砂造型,造型工艺不须调整并能生产出质量合格的铸件。
目前,旧砂再生在效益方面可能无利可图,但却是铸造行业发展的方向,是实现绿色铸造的一个重要环节。
In our country, more than ten millions used foundry sand is dumped into the nature every year. The great dumping of used sand is not only a great waste of resource, but also pollutant to environment. Reusing reclaimed sand has become a question that need to be resolved urgently in casting industry.
In this paper, different reclaiming technologies of used mixed sand and used sodium-silicate bounded sand are studied, and then reclaimed sand is used to make cores or moulds to test its usability. The purpose is to reduce the dumping of used sand by way of using reclaimed sand to make moulds or cores, totally or partly.
The experimental results of used mixed sand indicate that reclaimed sand, which is produced by way of dry reclamation and low thermal + dry reclamation, can be only used to make moulds. The selective reclamation is that used resin bonded sand is divided from used mixed sand, and then used resin bonded sand is reclaimed. Through dry reclamation and thermal + dry reclamation, the quality of reclaimed sand is greatly increased. Thermal reclamation comprises of low and high temperature. Compared with low thermal reclamation, the quality of reclaimed sand is increased a little by way of high thermal reclamation. From the point of economy, low thermal reclamation is preferred .
The technological experiment of reclaimed resin bounded sand produced through dry reclamation is made, the way of which is standard. The results indicate that reclaimed sand can be only used partly to make cores. Because of the changes of reclaimed sand s quality, the technology of making cores must be adopted, the specific value of resin and hardener is below the standard value, 4. When 30% reclaimed sand, 2.5%(sand weight) resin, 0.7%(sand weight) hardener are added to * make cores, at this time the specific value of resin and hardener is 3.57, the quality of cores can meet the demand of production.
The technological experiment of reclaimed resin bounded sand produced through low thermal + dry reclamation is made, and the results indicate that reclaimed sand can be only used partly to make cores too. When 5% reclaimed sand
is added to make cores, the quality of cores is up to standard; When 30% reclaimed
sand, 2.2%(sand weight) resin, 0.7%(sand weight) hardener are added to make cores, at this time the specific value of resin and hardener is 3.14, the quality of cores can meet the demand of production.
The experimental results of used sodium-silicate bounded sand indicate that the two ways, which are dry reclamation and low thermal + dry reclamation,can all produce eligible sand. The latter is better than the former in quality, but worse in economy.
From the point of economy, reclaimed sand which is made by way of dry reclamation is used to make moulds and cast.
At present, sand reclamation may not be lucrative, but this is the direction of development, and is a link of green casting.
本文通过对混合型旧砂和水玻璃旧砂进行不同再生工艺的研究,然后利用再生砂制芯、造型,检验再生砂的可使用性,其目的是使再生砂能全部或部分取代新砂造型、制芯,减少旧砂的排放。
对混合型旧砂的实验结果表明,对混合型旧砂进行干法再生和低温加热+干法再生,再生砂仅能回用于造型。采用选择性再生,即将块状树脂旧砂从混合型旧砂中分离出来,对树脂旧砂进行再生,再生工艺采用干法再生和热气流再生+干法再生,再生砂质量得到极大的提高;其中热气流加热分为低温加热和中温加热,中温加热对比低温加热,再生砂质量提高不大。从经济方面考虑,生产中易采用干法再生和低温加热+干法再生。
对干法再生出来的树脂再生砂进行制芯的工艺实验,实验标准按照生产上的要求来实行。实验结果表明,再生砂只能以部分加入用于制芯;由于再生砂性质的变化,制芯工艺必须做一定的调整,其树脂与固化剂的比值要低于标准值4;在旧砂加入量为30%,树脂加入量树脂加入量2.5%(砂重),固化剂加入量0.7%(砂重),树脂与固化剂之比值为3.57,制得的型芯质量达到生产上的使用要求。
对低温加热+干法再生出来的树脂再生砂进行制芯的工艺实验,实验结果表明,再生砂也只能以部分加入用于制芯;再生砂加入量为5%时,制得的型芯质量达到生产上的使用要求;在再生砂加入量为30%时,制芯工艺要做一定的调整,在树脂加入量2.2%(砂重),固化剂加入量0.7%,树脂与固化剂之比值为3.14时,型芯质量合格。
对水玻璃旧砂的实验结果表明,干法再生和低温加热+干法再生均可生产出质量合格的再生砂,后者比前者更为有效,但经济性不如前者。
从经济性考虑,采用干法再生砂做造型、浇注实验。实验结果表明,采用50%再生砂造型,造型工艺不须调整并能生产出质量合格的铸件。
目前,旧砂再生在效益方面可能无利可图,但却是铸造行业发展的方向,是实现绿色铸造的一个重要环节。
In our country, more than ten millions used foundry sand is dumped into the nature every year. The great dumping of used sand is not only a great waste of resource, but also pollutant to environment. Reusing reclaimed sand has become a question that need to be resolved urgently in casting industry.
In this paper, different reclaiming technologies of used mixed sand and used sodium-silicate bounded sand are studied, and then reclaimed sand is used to make cores or moulds to test its usability. The purpose is to reduce the dumping of used sand by way of using reclaimed sand to make moulds or cores, totally or partly.
The experimental results of used mixed sand indicate that reclaimed sand, which is produced by way of dry reclamation and low thermal + dry reclamation, can be only used to make moulds. The selective reclamation is that used resin bonded sand is divided from used mixed sand, and then used resin bonded sand is reclaimed. Through dry reclamation and thermal + dry reclamation, the quality of reclaimed sand is greatly increased. Thermal reclamation comprises of low and high temperature. Compared with low thermal reclamation, the quality of reclaimed sand is increased a little by way of high thermal reclamation. From the point of economy, low thermal reclamation is preferred .
The technological experiment of reclaimed resin bounded sand produced through dry reclamation is made, the way of which is standard. The results indicate that reclaimed sand can be only used partly to make cores. Because of the changes of reclaimed sand s quality, the technology of making cores must be adopted, the specific value of resin and hardener is below the standard value, 4. When 30% reclaimed sand, 2.5%(sand weight) resin, 0.7%(sand weight) hardener are added to * make cores, at this time the specific value of resin and hardener is 3.57, the quality of cores can meet the demand of production.
The technological experiment of reclaimed resin bounded sand produced through low thermal + dry reclamation is made, and the results indicate that reclaimed sand can be only used partly to make cores too. When 5% reclaimed sand
is added to make cores, the quality of cores is up to standard; When 30% reclaimed
sand, 2.2%(sand weight) resin, 0.7%(sand weight) hardener are added to make cores, at this time the specific value of resin and hardener is 3.14, the quality of cores can meet the demand of production.
The experimental results of used sodium-silicate bounded sand indicate that the two ways, which are dry reclamation and low thermal + dry reclamation,can all produce eligible sand. The latter is better than the former in quality, but worse in economy.
From the point of economy, reclaimed sand which is made by way of dry reclamation is used to make moulds and cast.
At present, sand reclamation may not be lucrative, but this is the direction of development, and is a link of green casting.
引文
[1] 郭景纯,郭思福.铸造旧砂再生利用及污染治理.广州:中山大学出版社,2001
[2] 胡彭生.型砂.上海:上海科学技术出版社,1994
[3] 郭景纯.旧砂的再生和综合利用.铸造设备研究,1997(1):52~54
[4] FAS Trans.1912 vol20:563
[5] C E Wenninger. "Developmen "Development of Foundry Sand Reclamation" AFS Trans,1953: 191
[6] 徐顺庆.国内外铸造机械概况和发展趋势.济南铸锻机械研究所,1979,9
[7] A Status Report of AFS Sand Recalamation & Reuse Committee (80-S). " Sand Reclamation" .Modern Casting, 1979(3):60
[8] First Report of Working Group P7. "Sand Reclamation" .British Foundryman, 1973(8): 45
[9] U Kleinheyer. "Sandaut Bereitung Sanlagen-Mschinen und -Zubekor auf der GIFA" .Giesserei, 1962(21):710
[10] M Gras. "NaBputzunlogen unter Besonderer Beerucksichfigung des Entkernens Von SlahlguB" .Giesserei, 1963(11):337
[11] Weiss R,Kleinheryer U.目前旧砂再生和废砂处理的发展趋势.(德)中文版,铸造设备与技术,1989(15)
[12] 今泉富士夫.日本旧砂再生的现状和未来.铸锻造热处理.1978(12):76
[13] 孙可伟.日本再生的现状和未来.中国铸机,1986(4):36
[14] ECJeter "Sand Reclamation for Ferrous Foundry" .Foundry,1946(8):86
[15] CIATF Report of Commission 1.4. "Reclamation of Foundry Sand from Moldingand Core Making Process" .British
[16] 用水力分级机选分原砂和再生旧砂.铸工,1958(1):23
[17] 济南铸锻机械研究所.国内外水力清砂湿法再生装置概述及对某些问题的探讨.济南铸锻机械研究所,1963
[18] 上海气轮机厂.水力旋游器-水力分级旧砂再生装置.铸造机械,1996(3):17
[19] 重庆钢铁设计院通风科.风力送砂、湿法再生,调查报告之一,之二.重庆
钢铁设计院,1973
[20] 郭寿恒.离心式搓撞旧砂再生器.铸造机械,1966(2):25
[21] 潍坊柴油机厂.废合脂砂焚烧再生.铸造机械,1969(1):36
[22] 郭景纯等.3t/h横吹式旧砂气流再生机的研制.铸造机械,1984(1):45
[23] 石光玉.全国旧砂再生经验交流会召开.中国铸机,1986(2):14
[24] 郭景纯等.水玻璃砂干法再生设备的开发研究.中国铸机,1990(5):27
[25] 铸造机械委员会旧砂再生专题组.全国第二届旧砂再生讨论会会议纪要.铸造设备研究,1994(1):42
[26] 蒋乃隆,周静一等.水玻璃砂学术研讨会论文集.中国铸造学会铸造工艺及造型材料技术委员会,1993:21
[27] 郭景纯,郭思福.各种旧砂的再生.铸造设备研究,1997(5):12
[28] 樊自田等.旧砂再生工艺方法及设备的选择.南昌大学学报(工科版),1996(1):12~19
[29] 樊自田.旧砂干法再生机理初探.江西工业大学学报,1993(1):21
[30] 樊自田等.酯硬化水玻璃砂的性能特征.铸造,1995,(3):38
[31] 樊自田等.酯硬化水玻璃砂旧砂湿法再生工艺试验研究.铸造技术,1993 (6):36
[32] The Possibilities of Reclamation Moulding Bonded with Sodium Silicate-Ester Binders and Practical Use of the Wet Process. 56th International Foundry Congress,CIATF, 1989.5:258
[33] Thermal Reclamation is Coming of Age,AFS.Transaction, 1993:457
[34] 石光玉.水玻璃干法再生工艺及其成套设备的研究.1990年全国铸造设备年会论文集
[35] 郭景纯.旧砂再生设备类型及新发展.铸造设备研究,1997(3):51~53
[36] 曹善堂等.铸造车间旧砂再生技术.机械工业出版社,1987
[37] Foundry 1961(1):2
[38] 蒋宗宇等.有机酯水玻璃砂再生线的实际应用.中国铸机,1995,(1):24
[39] 昆明工学院编.造型材料.昆明:云南人民出版社,1978
[40] M Granlund." Sand Reclamation Concept Definition Study Final Repot" .Gas Research Institute, 1990: 254
[41] 曹兴全等.旧砂再生机理的探讨.铸造设备研究,1991(3):35~38
[42] 张景德等.粘土旧砂的振动搓擦再生.铸造,1997(7):14
[43] 谢明师主编.铸造手册(造型材料).北京:机械工业出版社,1992
[44] 冀守勋等.树脂砂再生系统再生指标的探讨.热加工工艺,1994(6):26
[45] 吴殿杰.树脂自硬砂再生质量的控制.铸造设备研究,1993(5):54
[46] G Good et al. "Total Sand Reclamation" .AFS Special Report,1987 (7): 154
[47] 曹兴全等.含树脂芯砂的粘土砂再生方法试验研究.中国铸机,1995(1):39
[48] 李冀平等.水玻璃砂的化学.干法再生及应用.铸造装备与技术,2001(1):33
[49] 朱纯熙,卢晨等.水玻璃砂的化学再生.热加工工艺.1998(2):28
[50] 李明星等.用RCT改性剂组成的全系统水玻璃砂及其应用.铸造装备与技术,1998,(4):39
[51] Srinagesh Kchemistry of sodium silicate as a sand binder AFS International Cast Metal J, Mar. 1979:176~188
[52] American Foundrymen's Society.Molding Methods and Materials.AFS,1962
[53] AFS Sand Reclamation and Reuse Committee. " Sand Reclamation. Is it Profitable for your Foundry?" Modern Casting,1984(12): 134
[2] 胡彭生.型砂.上海:上海科学技术出版社,1994
[3] 郭景纯.旧砂的再生和综合利用.铸造设备研究,1997(1):52~54
[4] FAS Trans.1912 vol20:563
[5] C E Wenninger. "Developmen "Development of Foundry Sand Reclamation" AFS Trans,1953: 191
[6] 徐顺庆.国内外铸造机械概况和发展趋势.济南铸锻机械研究所,1979,9
[7] A Status Report of AFS Sand Recalamation & Reuse Committee (80-S). " Sand Reclamation" .Modern Casting, 1979(3):60
[8] First Report of Working Group P7. "Sand Reclamation" .British Foundryman, 1973(8): 45
[9] U Kleinheyer. "Sandaut Bereitung Sanlagen-Mschinen und -Zubekor auf der GIFA" .Giesserei, 1962(21):710
[10] M Gras. "NaBputzunlogen unter Besonderer Beerucksichfigung des Entkernens Von SlahlguB" .Giesserei, 1963(11):337
[11] Weiss R,Kleinheryer U.目前旧砂再生和废砂处理的发展趋势.(德)中文版,铸造设备与技术,1989(15)
[12] 今泉富士夫.日本旧砂再生的现状和未来.铸锻造热处理.1978(12):76
[13] 孙可伟.日本再生的现状和未来.中国铸机,1986(4):36
[14] ECJeter "Sand Reclamation for Ferrous Foundry" .Foundry,1946(8):86
[15] CIATF Report of Commission 1.4. "Reclamation of Foundry Sand from Moldingand Core Making Process" .British
[16] 用水力分级机选分原砂和再生旧砂.铸工,1958(1):23
[17] 济南铸锻机械研究所.国内外水力清砂湿法再生装置概述及对某些问题的探讨.济南铸锻机械研究所,1963
[18] 上海气轮机厂.水力旋游器-水力分级旧砂再生装置.铸造机械,1996(3):17
[19] 重庆钢铁设计院通风科.风力送砂、湿法再生,调查报告之一,之二.重庆
钢铁设计院,1973
[20] 郭寿恒.离心式搓撞旧砂再生器.铸造机械,1966(2):25
[21] 潍坊柴油机厂.废合脂砂焚烧再生.铸造机械,1969(1):36
[22] 郭景纯等.3t/h横吹式旧砂气流再生机的研制.铸造机械,1984(1):45
[23] 石光玉.全国旧砂再生经验交流会召开.中国铸机,1986(2):14
[24] 郭景纯等.水玻璃砂干法再生设备的开发研究.中国铸机,1990(5):27
[25] 铸造机械委员会旧砂再生专题组.全国第二届旧砂再生讨论会会议纪要.铸造设备研究,1994(1):42
[26] 蒋乃隆,周静一等.水玻璃砂学术研讨会论文集.中国铸造学会铸造工艺及造型材料技术委员会,1993:21
[27] 郭景纯,郭思福.各种旧砂的再生.铸造设备研究,1997(5):12
[28] 樊自田等.旧砂再生工艺方法及设备的选择.南昌大学学报(工科版),1996(1):12~19
[29] 樊自田.旧砂干法再生机理初探.江西工业大学学报,1993(1):21
[30] 樊自田等.酯硬化水玻璃砂的性能特征.铸造,1995,(3):38
[31] 樊自田等.酯硬化水玻璃砂旧砂湿法再生工艺试验研究.铸造技术,1993 (6):36
[32] The Possibilities of Reclamation Moulding Bonded with Sodium Silicate-Ester Binders and Practical Use of the Wet Process. 56th International Foundry Congress,CIATF, 1989.5:258
[33] Thermal Reclamation is Coming of Age,AFS.Transaction, 1993:457
[34] 石光玉.水玻璃干法再生工艺及其成套设备的研究.1990年全国铸造设备年会论文集
[35] 郭景纯.旧砂再生设备类型及新发展.铸造设备研究,1997(3):51~53
[36] 曹善堂等.铸造车间旧砂再生技术.机械工业出版社,1987
[37] Foundry 1961(1):2
[38] 蒋宗宇等.有机酯水玻璃砂再生线的实际应用.中国铸机,1995,(1):24
[39] 昆明工学院编.造型材料.昆明:云南人民出版社,1978
[40] M Granlund." Sand Reclamation Concept Definition Study Final Repot" .Gas Research Institute, 1990: 254
[41] 曹兴全等.旧砂再生机理的探讨.铸造设备研究,1991(3):35~38
[42] 张景德等.粘土旧砂的振动搓擦再生.铸造,1997(7):14
[43] 谢明师主编.铸造手册(造型材料).北京:机械工业出版社,1992
[44] 冀守勋等.树脂砂再生系统再生指标的探讨.热加工工艺,1994(6):26
[45] 吴殿杰.树脂自硬砂再生质量的控制.铸造设备研究,1993(5):54
[46] G Good et al. "Total Sand Reclamation" .AFS Special Report,1987 (7): 154
[47] 曹兴全等.含树脂芯砂的粘土砂再生方法试验研究.中国铸机,1995(1):39
[48] 李冀平等.水玻璃砂的化学.干法再生及应用.铸造装备与技术,2001(1):33
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