阅读说明：本技术 一种水泥熟料及其制备方法 (Cement clinker and preparation method thereof ) 是由 陈伟 李博 赵亮 于 2021-10-12 设计创作，主要内容包括：本发明提供一种水泥熟料及其制备方法。所述水泥熟料包括以下组分：磷尾矿40-70重量份,钢渣5-20重量份,铜尾矿5-20重量份,煤矸石5-10重量份,含镍工业固废10-30重量份。本发明全部利用工业固体废弃物生产高镁高铁相水泥熟料,生产成本降低且消纳工业固废,促进水泥工业可持续发。本发明具有显著的经济和社会效益。且烧成的高镁高铁相水泥熟料,后期安定性合格,且具有微膨胀、耐磨损和冲刷等优越性能。(The invention provides a cement clinker and a preparation method thereof. The cement clinker comprises the following components: 40-70 parts of phosphorus tailings, 5-20 parts of steel slag, 5-20 parts of copper tailings, 5-10 parts of coal gangue and 10-30 parts of nickel-containing industrial solid waste. The invention completely utilizes industrial solid wastes to produce the high-magnesium high-iron phase cement clinker, reduces the production cost, eliminates the industrial solid wastes and promotes the sustainable development of the cement industry. The invention has remarkable economic and social benefits. And the calcined high-magnesium high-iron phase cement clinker has qualified later-period stability and has the superior performances of micro-expansion, wear resistance, scouring resistance and the like.)

1. A cement clinker characterized in that it comprises the following components: 40-70 parts of phosphorus tailings, 5-20 parts of steel slag, 5-20 parts of copper tailings, 5-10 parts of coal gangue and 10-30 parts of nickel-containing industrial solid waste.

2. The cement clinker of claim 1, wherein the chemical composition of the cement clinker comprises the following components: CaO: 40 to 50 parts by weight of SiO₂: 10-20 parts by weight; al (Al)₂O₃: 3-10 parts by weight; fe₂O₃: 5-15 parts by weight; MgO: 7-15 parts by weight, NiO: 0.7-5 parts.

3. The cement clinker according to claim 2, wherein NiO is 10 to 50% of MgO.

4. The cement clinker of claim 1, wherein the nickel-containing industrial solid waste is nickel slag or stainless steel slag or nickel tailings.

5. The cement clinker of claim 1, wherein the nickel-containing industrial solid waste comprises 1-11% NiO and 1-10% Fe by weight₂O₃15 to 50 percent of CaO and 1 to 10 percent of MgO.

6. The cement clinker of claim 1, wherein the phosphate tailings comprise, by mass, 25% to 56% CaO and 10% to 20% MgO.

7. Such asThe cement clinker of claim 1, wherein the cement clinker phase composition comprises, in mass percent: tricalcium silicate: 35-50%; 15-25% of dicalcium silicate; tetracalcium aluminoferrite: 15-25%; tricalcium aluminate: 1-3%; MgNiO₂Or NiO-doped periclase: 10 to 20 percent.

8. The cement clinker of claim 1, wherein the coal gangue comprises, in mass percent: SiO 2₂And Al₂O₃The sum of which is 50% -70%, Fe₂O₃1 to 10 percent of MgO and 1 to 7 percent of MgO.

9. The method of manufacturing cement clinker according to claim 1, comprising the steps of:

all the raw materials are designed according to the proportion and ground together;

preheating raw materials in a pre-decomposition furnace, and then burning in a rotary kiln;

air cooling is adopted to rapidly cool the calcined clinker.

10. The method according to claim 9, wherein the firing temperature is 1300-1400 ℃, and the rotation speed of the rotary kiln is 0.2-1.2 rpm.

Technical Field

The invention belongs to the technical field of building materials, and particularly relates to high-magnesium high-iron phase cement clinker which is completely sintered by using solid industrial wastes and a preparation method thereof.

Background

The discharge amount of industrial solid wastes such as tailings, metallurgical slag and the like in China is more than 30 hundred million tons every year, the stockpiling amount is over one billion tons, a large amount of land is occupied, and the hidden danger of serious environmental pollution exists. The cement industry consumes billions of tons of natural resources such as limestone, natural clay and the like every year. The cement prepared by sintering industrial solid wastes in a large scale can not only consume a large amount of solid wastes, but also meet the urgent requirement of sustainable development of building material industry, and has great significance to the national important strategy of ecological civilization construction and resource safety supply.

The technical characteristics of industrial solid wastes such as tailings, metallurgical slag and the like are wide source, complex components and great component fluctuation, especially Fe₂O₃And enriching harmful elements such as MgO and a small amount of heavy metal.

High-magnesium high-iron phase cement (C4 AF)>18 percent) has the technical characteristics of micro-expansion, abrasion resistance, erosion resistance and the like, and is suitable for road engineering, airport runways, ocean engineering with complex and severe service environment and the like. The chemical composition and the sintering process are more suitable for industrial solid wastes Fe such as tailings, metallurgical slag and the like₂O₃And MgO enrichment.

The restriction of MgO content in cement specified in national standard of China is lower than 6%, and the MgO content in raw meal in cement production is controlled to be lower than 3%. Otherwise periclase hydrates to form Mg (OH)₂Swelling occurs, resulting in poor stability.

The mixing amount of industrial solid wastes such as tailings, metallurgical slag and the like in the production of cement clinker is lower than 30%, and a large amount of natural resources such as limestone, clay, iron ore and the like are consumed. The cement clinker prepared by using industrial solid wastes such as tailings, metallurgical slag and the like with large mixing amount is bound to cause that the MgO content in the cement clinker exceeds 6 percent, thereby generating the problem of unqualified cement stability. Therefore, the key technical bottleneck of preparing the high-magnesium high-iron phase cement by using industrial solid wastes such as tailings, metallurgical slag and the like in large mixing amount is how to stabilize the free MgO in the clinker and avoid the poor stability of the cement clinker. In the prior art, the cement is prepared by utilizing industrial solid wastes, the mixing amount of the industrial solid wastes is less than 30 percent so as to meet the standard that the MgO content in clinker is less than 6 percent, or additionally adding a stabilizer or processes such as acid leaching, steam pressing and the like is needed, so that the cost and the process complexity are increased.

Therefore, there is an urgent need to develop a cement clinker which can use all industrial solid wastes and does not cause poor stability.

Disclosure of Invention

The invention provides a high-magnesium high-iron phase cement clinker fired by solid wastes and a preparation method thereof for solving the technical problems. The cement clinker can solve the key technical bottlenecks of low utilization rate of solid wastes, unqualified later stability of cement and the like in the cement sintering process.

In order to achieve the purpose, the invention adopts the technical scheme that:

a cement clinker comprising the following components: 40-70 parts of phosphorus tailings, 5-20 parts of steel slag, 5-20 parts of copper tailings, 5-10 parts of coal gangue and 10-30 parts of nickel-containing industrial solid waste.

Preferably, the chemical composition of the cement clinker comprises the following components: CaO: 40 to 50 parts by weight of SiO₂: 10-20 parts by weight; al (Al)₂O₃: 3-10 parts by weight; fe₂O₃: 5-15 parts by weight; MgO: 7-15 parts by weight, NiO: 0.7-5 parts.

Preferably, NiO accounts for 10-50% of the MgO content.

Preferably, the nickel-containing industrial solid waste is nickel slag or stainless steel slag or nickel tailings. In the invention, the nickel-containing solid waste is solid waste before valuable metal recovery and refining.

Preferably, the nickel-containing industrial solid waste comprises 1-11% of NiO and 1% -10% of Fe in percentage by mass₂O₃15 to 50 percent of CaO and 1 to 10 percent of MgO.

Preferably, the phosphate tailings comprise 25-56% of CaO and 10-20% of MgO by mass percentage. The phosphate tailings are limestone or dolomite phosphate tailings and are large solid wastes generated after concentrate is extracted by mineral separation in the phosphorization industry, and the main components of the phosphate tailings are dolomite and limestone.

The steel slag is a bulk solid waste produced in the steel smelting process.

The copper tailings are bulk solid wastes generated by copper ore dressing, and the main components of the copper tailings are quartz and clay. In the invention, the copper tailings are high-silicon solid wastes, namely SiO₂60-80% of Al₂O₃10-30% by mass of Na₂O and K₂The sum of the mass percent of O is less than 7 percent.

Preferably, the cement clinker phase composition comprises, in mass percent: tricalcium silicate: 35-50%; 15-25% of dicalcium silicate; tetracalcium aluminoferrite: 15-25%; tricalcium aluminate: 1-3%; MgNiO₂Or NiO-doped periclase: 10 to 20 percent.

Preferably, the coal gangue comprises, by mass: SiO 2₂And Al₂O₃The sum of which is 50% -70%, Fe₂O₃1 to 10 percent of MgO and 1 to 7 percent of MgO. The coal gangue is a bulk solid waste generated in coal mining and coal washing processes, contains a large amount of combustible components such as carbon, sulfur and the like, and can replace part of fuel.

The preparation method of the cement clinker comprises the following steps:

all the raw materials are designed according to the mixture ratio and ground together, and the particle size is less than 80 mu m;

preheating raw materials in a pre-decomposition furnace, and then burning in a rotary kiln;

air cooling is adopted to rapidly cool the calcined clinker.

Preferably, the firing temperature is 1300-.

The reaction principle of the invention is as follows: the invention synergistically utilizes MgO and NiO components in the solid waste to obviously improve the content of MgO and NiO in the clinker, and the MgO and NiO components generate phase transition in the clinker sintering process to generate MgNiO₂Or NiO-doped MgO, stabilizes the crystal structure of MgO in the clinker, converts the MgO in the clinker into a hydration inert phase, and avoids generating Mg (OH) at the later stage of cement hydration₂The expansion is generated, and the stability of the high-magnesium high-iron phase cement is qualified.

Compared with the prior art, the invention has the beneficial effects that:

1) the invention completely utilizes industrial solid wastes to produce the high-magnesium high-iron phase cement clinker, reduces the production cost, eliminates the industrial solid wastes and promotes the sustainable development of the cement industry. The invention has remarkable economic and social benefits.

2) The high-magnesium high-iron phase cement clinker fired by industrial solid wastes is qualified in later-period stability, and has the superior performances of micro-expansion, wear resistance, scouring resistance and the like.

Drawings

FIG. 1 is the XRD pattern of the clinker in example 1;

FIG. 2 is the XRD pattern of the clinker in example 2;

FIG. 3 is the XRD pattern of the clinker in example 3;

FIG. 4 is the XRD pattern of the clinker in example 4;

FIG. 5 is the XRD pattern of the clinker in example 5;

FIG. 6 is the XRD pattern of the clinker in example 6;

FIG. 7 is a photograph of a Rayleigh clamp assay after a boiling stability test in example 1;

FIG. 8 is a photograph showing the measurement of the Leeb's clamp after the boiling test in the stable state in comparative example 1.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is further described in detail with reference to the following embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Examples 1-6 formulations for the preparation of high magnesium high iron phase cement clinker using total solid waste are shown in table 1 and their chemical compositions are shown in table 2.

The invention also provides a preparation method of the cement clinker, which comprises the following steps:

all the raw materials in the table 1 are designed according to the mixture ratio and are ground together, and the particle size is less than 80 mu m;

preheating the raw material in a predecomposition furnace, and then burning in a rotary kiln at 1380 ℃ at the rotary speed of 0.2-1.2 rpm;

air cooling is adopted to rapidly cool the calcined clinker.

The high-magnesium high-iron phase cement clinker sintered in the examples 1 to 6 is ball-milled for 1h and has a specific surface area of more than 400m²Kg, 45 mu m screen residue less than 5 percent and meets the national standardAnd (4) requiring.

The cement clinker and dihydrate gypsum which accounts for 3.5 percent of the mass of the cement clinker are ball-milled for 20min and are uniformly mixed to prepare the high-magnesium high-iron phase cement, and the test of the physical properties is shown in Table 5 by referring to the national standard GB/T1346-2011. The national standard GB/T1346 plus 2011 stipulates that the expansion value does not exceed 5mm in a boiling stability test of cement. In the comparative examples, the swelling values are all over 5mm, and the stability is not qualified.

Fig. 1 to 6 are XRD patterns of the clinkers of examples 1 to 6, respectively. According to this figure, the clinker contains tetracalcium aluminoferrite, tricalcium silicate, dicalcium silicate, NiO-doped magnesium oxide and MgNiO₂And (4) phases. In comparative examples 1 to 6, when the ratio of NiO/MgO is 0.10 to 0.31, NiO-doped magnesium oxide is contained in the clinker; when the ratio of NiO/MgO is 0.31-0.50, MgNiO is contained in the clinker₂。

TABLE 1 (unit: g)

	Steel slag	Copper tailings	Phosphorus tailings	Coal gangue	Stainless steel slag	Nickel slag
							Example 1	19.29	5.87	40.62	9.79	24.43	--
Example 2	5.44	5.00	68.79	5.11	--	15.66
							Example 3	10.26	18.98	54.13	6.50	10.13	--
Example 4	16.70	13.46	53.10	6.44	--	10.30
							Example 5	7.69	6.04	51.39	5.00	--	29.88
Example 6	11.32	11.87	49.62	5.16	--	22.03

TABLE 2 (unit: g)

	CaO	SiO2	Al2O3	Fe2O3	MgO	NiO	NiO/MgO(％)
								Example 1	48.03	18.23	8.19	14.13	7.91	3.51	44.37
Example 2	48.88	19.49	5.38	9.73	14.37	2.15	14.96
								Example 3	43.52	20.00	9.75	14.93	10.63	1.07	10.07
Example 4	46.79	18.37	3.46	12.32	14.66	4.40	30.01
								Example 5	42.12	16.11	8.22	14.26	14.43	4.86	33.68
Example 6	49.57	23.32	4.26	6.37	12.68	3.80	29.97

Comparative examples 1 to 4

In order to further illustrate the content of NiO in the added clinker, the NiO component stabilizes the crystal structure of free MgO in the clinker and eliminates the positive effect of unqualified stability. The NiO composition in the clinker of examples 1-3 was 0 as comparative examples 1, 2, 3, respectively. The chemical compositions of comparative examples 1, 2 and 3 are shown in table 3. The NiO component was removed and the amount of MgO was reduced as comparative example 4.

TABLE 3

	CaO	SiO2	Al2O3	Fe2O3	MgO
						Comparative example 1	48.03	18.23	8.19	14.13	7.91
Comparative example 2	48.88	19.49	5.38	9.73	14.37
						Comparative example 3	43.52	20.00	9.75	14.93	10.63
Comparative example 4	48.03	18.23	8.19	14.13	7.61

Comparative example 5

In order to further verify the proportional relation between NiO and MgO contents in the clinker, the clinker strength is greatly reduced by excessively adding NiO, so that the pure NiO is analyzed and added in example 1, the NiO content in the clinker is increased, and the NiO/MgO content reaches 77.24 percent, which is used as comparative example 5, and the ingredients are shown in Table 4.

TABLE 4 (Unit g)

	Steel slag	Copper tailings	Phosphorus tailings	Coal gangue	Stainless steel slag	Nickel slag	Nickel oxide
								Comparative example 5	19.29	5.87	40.62	9.79	24.43	--	2.59

TABLE 5

The above embodiments are merely examples for clearly illustrating the present invention and do not limit the present invention. Other variants and modifications of the invention, which are obvious to those skilled in the art and can be made on the basis of the above description, are not necessary or exhaustive for all embodiments, and are therefore within the scope of the invention.