富镁镍渣-粉煤灰基地质聚合物的制备及性能

doi:10.19964/j.issn.1006-4990.2023-0101

摘要/Abstract

摘要：

通过在富镁镍渣中引入MgO并重熔水淬，研究了活化处理过程对富镁镍渣活性的改善作用，并以水玻璃作为激发剂研究了活化处理后的富镁镍渣作为胶凝材料的工程性能和水化产物。结果表明：活化处理后的富镁镍渣基地质聚合物抗压强度可达35.60 MPa，较未活化处理的富镁镍渣基地质聚合物提升60.7%；影响地质聚合物抗压强度因素的主次顺序依次为水玻璃掺量、m（富镁镍渣）∶m（粉煤灰）、水玻璃模数；主要水化产物为钠镁铝硅酸盐凝胶（N-M-A-S-H），还有少部分铝硅酸盐及水化硅酸钙等组成的凝胶相和结晶相，未发现Mg（OH）₂；此外，大量的N-M-A-S-H胶凝相包裹着未反应的粉煤灰形成致密的凝胶-晶相结构。该研究为富镁镍渣作为原料制备地质聚合物的实际应用提供了一定的指导，并为提高矿渣的火山灰活性提供了一种新思路。

关键词: 富镁镍渣, 活化处理, 地质聚合物, 钠镁铝硅酸盐凝胶, 粉煤灰

Abstract:

The improvement of the activation treatment on the activity of high-magnesium nickel slag was investigated by introducing MgO in high-magnesium nickel slag and remelting it with water quenching，and the engineering performance and hydration products of activated high-magnesium nickel slag as cementitious material were studied using water glass as the activator.The results showed that the compressive strength of high-magnesium nickel slag based geopolymer after activation treatment could reach 35.60 MPa，which was 60.7% higher than that of untreated high-magnesium nickel slag-based geopolymer.The factors affecting the compressive strength of geopolymers in order of predominance were water glass dosing，m（high-magnesium nickel slag）∶m（fly ash），and water glass modulus.The main hydration products were sodium-magnesium-aluminum silicate gel（N-M-A-S-H），and a small portion of aluminosilicate and hydrated calcium silicate，etc，without Mg（OH）₂.A large number of gelling phases such as N-M-A-S-H wrapped around unreacted FA，etc.to form a dense gel-crystal phase structure.This study provided some guidance for the practical application of high-magnesium nickel slag as raw material for the preparation of geopolymers，and provided a new idea for improving the pozzolanic activity of slag.

Key words: high-magnesium nickel slag, activation treatment, geopolymer, N-M-A-S-H, fly ash

中图分类号:

TQ132.2

孙志高, 吴渊, 杨兴春, 张栋梁, 王觅堂. 富镁镍渣-粉煤灰基地质聚合物的制备及性能[J]. 无机盐工业, 2023, 55(11): 139-146.

SUN Zhigao, WU Yuan, YANG Xingchun, ZHANG Dongliang, WANG Mitang. Preparation and properties of high-magnesium nickel slag-fly ash based geopolymer[J]. Inorganic Chemicals Industry, 2023, 55(11): 139-146.

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参考文献 30

1	MARAGKOS I， GIANNOPOULOU I P， PANIAS D.Synthesis of ferronickel slag-based geopolymers［J］.Minerals Engineering，2009，22（2）：196-203.
2	WU Qisheng， WANG Shunxiang， YANG Tao，et al.Effect of high-ment［J］.Journal of Materials in Civil Engineering，2019，31（5）：04019051.
3	WANG Dengquan， WANG Qiang， ZHUANG Shiyu，et al.Evaluation of alkali-activated blast furnace ferronickel slag as a cementitious material：Reaction mechanism，engineering properties and leaching behaviors［J］.Construction and Building Materials，2018，188：860-873.
4	SUJIONO E H， SETIAWAN A， HUSAIN H，et al.The influence of nickel slag aggregate concentration to compressive and flexural strength on fly ash-based geopolymer composite［C］//International Conference on Advanced Materials Science & Technology. AIP Publishing LLC，2016.
5	RAHMAN M A， SARKER P K， SHAIKH F U A，et al.Soundness and compressive strength of Portland cement blended with ground granulated ferronickel slag［J］.Construction and Building Materials，2017，140：194-202.
6	HUA Sudong， ZHANG Lili， ZHANG Jian，et al.Study on physical and chemical properties of high magnesium nickel slag-phosphogysum composite cementitious materials in different particle sizes［J］.Journal of Advanced Concrete Technology，2020，18（3）：129-138.
7	YANG Tao， ZHANG Zuhua， ZHU Huajun，et al.Re-examining the suitability of high magnesium nickel slag as precursors for alkali-activated materials［J］.Construction and Building Materials，2019，213：109-120.
8	HUANG Yiduo， WANG Qiang， SHI Mengxiao.Characteristics and reactivity of ferronickel slag powder［J］.Construction and Building Materials，2017，156：773-789.
9	CHOI Y C， CHOI S.Alkali-silica reactivity of cementitious materials using ferro-nickel slag fine aggregates produced in different cooling conditions［J］.Construction and Building Materials，2015，99：279-287.
10	SCHÖLER A， WINNEFELD F， HAHA M BEN，et al.The effect of glass composition on the reactivity of synthetic glasses［J］.Journal of the American Ceramic Society，2017，100（6）：2553-2567.
11	WANG Mitang， FENG Chunfu， LIU Yun，et al.Enhancement of pozzolanic activity of high-magnesium nickel slag via phase separation by adding CaO［J］.Materials Today Communications，2023，34：105427.
12	MYSEN B O， VIRGO D， SEIFERT F A.The structure of silicate melts：Implications for chemical and physical properties of natural magma［J］.Reviews of Geophysics，1982，20（3）：353-383.
13	盛广宏，翟建平.镍工业冶金渣的资源化［J］.金属矿山，2005（10）：68-71.
	SHENG Guanghong， ZHAI Jianping.Making metallurgical slag from nickel industry a resource［J］.Metal Mine，2005（10）：68-71.
14	LUO Zhongqiu， MA Yue， MU Weihong，et al.Magnesium phosphate cement prepared with electric furnace ferronickel slag：Properties and its hydration mechanism［J］.Construction and Building Materials，2021，300：123991.
15	LI Jincheng， SUN Zhigao， WANG Lei，et al.Properties and mechanism of high-magnesium nickel slag-fly ash based geopolymer activated by phosphoric acid［J］.Construction and Building Materials，2022，345：128256.
16	刘洋，吴锦绣，封春甫，等.富镁镍渣-粉煤灰基地质聚合物的制备与性能表征［J］.硅酸盐通报，2021，40（3）：921-928.
	LIU Yang， WU Jinxiu， FENG Chunfu，et al.Preparation and performance characterization of magnesium-rich nickel slag-fly ash-based geopolymer［J］.Bulletin of the Chinese Ceramic Society，2021，40（3）：921-928.
17	WINNEFELD F， HAHA M BEN， LE SAOUT G，et al.Influence of slag composition on the hydration of alkali-activated slags［J］.Journal of Sustainable Cement-Based Materials，2015，4（2）：85-100.
18	DUXSON P， FERNÁNDEZ-JIMÉNEZ A， PROVIS J L，et al.Geopolymer technology：The current state of the art［J］.Journal of Materials Science，2007，42（9）：2917-2933.
19	PROVIS J L， LUKEY G C， VAN DEVENTER J S J.Do geopolymers actually contain nanocrystalline zeolites？A reexamination of existing results［J］.Chemistry of Materials，2005，17（12）：3075-3085.
20	XU Lingling， DENG Min.Dolomite used as raw material to produce MgO-based expansive agent［J］.Cement and Concrete Research，2005，35（8）：1480-1485.
21	AGUIAR H， SERRA J， GONZÁLEZ P，et al.Structural study of sol-gel silicate glasses by IR and Raman spectroscopies［J］.Journal of Non-Crystalline Solids，2009，355（8）：475-480.
22	LEE W K W， VAN DEVENTER J S J.Use of infrared spectroscopy to study geopolymerization of heterogeneous amorphous aluminosilicates［J］.Langmuir，2003，19（21）：8726-8734.
23	ZHANG Zuhua， WANG Hao， PROVIS J L.Quantitative study of the reactivity of fly ash in geopolymerization by FTIR［J］.Journal of Sustainable Cement-Based Materials，2012，1（4）：154-166.
24	ZHANG Z， ZHU Yingcan， YANG Tao，et al.Conversion of local industrial wastes into greener cement through geopolymer technology：A case study of high-magnesium nickel slag［J］.Journal of Cleaner Production，2017，141：463-471.
25	ISHIDA K， JENKINS D M， HAWTHORNE F C.Mid-IR bands of synthetic calcic amphiboles of tremolite-pargasite series and of natural calcic amphiboles［J］.American Mineralogist，2008，93（7）：1112-1118.
26	WANG Mitang， LIU Yun， FENG Chunfu，et al.Pozzolanic activity enhancement of magnesium-rich nickel slag and geopolymer preparation［J］.Journal of Material Cycles and Waste Management，2022，24（6）：2598-2607.
27	MIHAILOVA I， RADEV L， ALEKSANDROVA V，et al.Carbonate-apatite forming ability of polyphase glass-ceramics in the CaO-MgO-SiO₂ system［J］.Journal of Chemical Technology & Metallurgy，2015，50（4）：502-511.
28	BOUAISSI A， LI Longyuan， BAKRI ABDULLAH M M AL，et al.Mechanical properties and microstructure analysis of FA-GGBS-HMNS based geopolymer concrete［J］.Construction and Building Materials，2019，210：198-209.
29	MO Liwu， LV Liming， DENG Min，et al.Influence of fly ash and metakaolin on the microstructure and compressive strength of magnesium potassium phosphate cement paste［J］.Cement and Concrete Research，2018，111：116-129.
30	KIM M S， Yubin JUN， LEE Changha，et al.Use of CaO as an activator for producing a price-competitive non-cement structural binder using ground granulated blast furnace slag［J］.Cement and Concrete Research，2013，54：208-214.

水平	因素
水平	A ［m（W-HMNS）∶m（FA）］	B ［w（水玻璃）/%］	C （水玻璃模数）
1	8∶2	10	1.0
2	7∶3	15	1.2
3	6∶4	20	1.4

编号	A	B	C	水灰比
S1	1	1	1	0.24
S2	1	2	2	0.24
S3	1	3	3	0.24
S4	2	1	2	0.24
S5	2	2	3	0.24
S6	2	3	1	0.24
S7	3	1	3	0.24
S8	3	2	1	0.24
S9	3	3	2	0.24

编号	A	B	C	抗压强度/MPa
编号	A	B	C	3 d	7 d	28 d
S1	1	1	1	0.92	1.16	1.76
S2	1	2	2	3.36	5.32	8.00
S3	1	3	3	11.20	12.80	15.20
S4	2	1	2	1.40	1.64	1.92
S5	2	2	3	13.60	16.80	26.40
S6	2	3	1	2.56	4.08	8.00
S7	3	1	3	1.96	2.72	2.84
S8	3	2	1	2.56	4.58	5.20
S9	3	3	2	8.80	16.4	28.40

因素	K₁/MPa	K₂/MPa	K₃/MPa	R/MPa
A	8.32	12.11	12.08	3.79
B	2.17	13.20	17.13	14.96
C	4.99	12.71	14.81	9.82

编号	A	B	C	线性膨胀率/%
编号	A	B	C	3 d	7 d	28 d
S1	1	1	1	3.0	3.0	2.5
S2	1	2	2	5.5	5.0	3.0
S3	1	3	3	5.9	5.5	5.0
S4	2	1	2	3.9	4.0	4.0
S5	2	2	3	5.0	2.5	2.5
S6	2	3	1	5.6	3.0	4.0
S7	3	1	3	3.5	3.0	2.0
S8	3	2	1	2.5	5.0	3.0
S9	3	3	2	3.9	3.9	3.3

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