CN111393053A - Special composite cementing material for preparing low-shrinkage ultra-high-performance concrete - Google Patents

Abstract

The invention relates to a special composite cementing material for preparing low-shrinkage ultrahigh-performance concrete, which is prepared by uniformly mixing the following raw materials in parts by weight: 75-85 parts of portland cement clinker powder; 10-20 parts of expansive high belite sulphoaluminate cement clinker powder; 5-10 parts of anhydrite powder. The high-expansibility belite sulphoaluminate cement clinker has the following batching parameters: the alkalinity coefficient Cm is 1.4-1.6, fCaO is 5-8%, fSO₃7-10%; the mineral composition in percentage by weight is as follows: c₂S is 40-50%, C₄A₃S is 25-35%, C₁₂A₇4-5% of CaSO₄10-15%, fCaO 4-8%, C₄AF is 1 to 2%. According to the special composite cementing material, the 3d self-shrinkage value of the neat paste is 350-380ppm, and the compressive strength of each age is improved by 2-4 MPa; can not only reduce UHPC shrinkage value, but also improve the strength and stability.

Description

Special composite cementing material for preparing low-shrinkage ultra-high-performance concrete

Technical Field

The invention belongs to the technical field of concrete, and particularly relates to a special composite cementing material for preparing low-shrinkage ultrahigh-performance concrete.

Background

Ultra-high performance concrete (UHPC for short) is the most innovative technology in the field of concrete materials in recent years. The composite material has the advantages of ultrahigh strength (more than 120 MPa), high corrosion resistance and durability, capability of reducing the structure size, lightening the structure dead weight, saving the space, reducing the energy consumption, reducing the structure maintenance cost and the reconstruction cost and the like. At present, UHPC is applied to building decoration and structure integration, wet joint connection of large-span bridge structures and assembled building components, erosion and abrasion resistant hydraulic engineering, offshore oil production platform engineering and maintenance, reinforcement and repair of some major engineering, and the outstanding performance advantages are reflected.

Because of large usage amount of cementing material and low water-to-gel ratio, UHPC is usually mixed with superfine admixture of silica fume, so that the shrinkage, especially the early shrinkage, is large. The early shrinkage cracking of UHPC is more serious than that of common concrete, so that the early stress concentration of the member is caused, the member is easy to crack in the later period, and the UHPC product is influenced by the bending deformation of some light and thin members. The defect of large shrinkage of UHPC greatly restricts the development and application of UHPC. Therefore, it is of great importance to reduce the shrinkage, especially the early shrinkage, of UHPC.

In the prior art of reducing HUPC shrinkage, Chinese patent publication No. CN109369118A discloses a preparation method of low-shrinkage UHPC, which adopts super absorbent resin (SAP) admixture to improve the water absorption and water retention functions of UHPC internal materials, enhances internal curing conditions and effectively inhibits concrete self-shrinkage, and emphasizes the importance of the addition mode and uniform dispersion of the super absorbent resin. Chinese patent publication No. CN109721306A discloses a preparation method for reducing the self-shrinkage value of a UHPC system by adopting heavy calcium carbonate powder as an admixture instead of silica fume in a powder material, and simultaneously, the fluidity of the UHPC composition can be effectively improved by adopting glass beads to realize self-leveling. Chinese patent publication No. CN110407529A discloses a preparation technology of low-shrinkage UHPC by adopting calcium sulphoaluminate-calcium oxide expansion agent to perform expansion compensation on the shrinkage of a gelled material.

The technical means related to the reduction of UHPC material is mainly improved and optimized by the aspects of adding an internal curing chemical admixture (SAP), using a mineral expanding agent or changing the variety of mineral admixtures, however, the most main cementing material uses silicate cement without any change. Each of these prior art approaches has certain problems, such as the use of internal curing chemical admixtures (SAP) significantly reduces the compressive strength of UHPC, the use of calcium sulfoaluminate-calcium oxide type expanding agents causes the bulk stability of UHPC materials to deteriorate, and the strength to also decrease.

Disclosure of Invention

Aiming at the problems of the existing preparation technology for reducing UHPC shrinkage and the existing problems, the invention provides a special composite cementing material for preparing low-shrinkage ultrahigh-performance concrete. The special composite gelled material can reduce the shrinkage value of UHPC and can also improve the strength and stability of the UHPC, a large amount of cement and gelled material are used for the UHPC material, and the shrinkage performance, the setting and hardening characteristics and the strength development law of the cement and the gelled material play a role in determining the performance of the UHPC. The special UHPC composite cementing material with the characteristics of low shrinkage and high strength is prepared by optimizing and improving the performances of cement and cementing materials, and the shrinkage performance and the adaptability to mineral admixtures are obviously reduced, so that the shrinkage of the UHPC can be directly reduced, the shrinkage value can be indirectly reduced by reducing the using amount of ultrafine admixtures such as silica fume and the like in the UHPC, the preparation process of the UHPC is simplified, and the reduction of the preparation cost of the UHPC is promoted.

The invention is realized in such a way that the special composite cementing material for preparing the low-shrinkage ultra-high performance concrete is obtained by dry mixing the following raw materials in parts by weight: 75-85 parts of portland cement clinker powder; 10-20 parts of expansive high belite sulphoaluminate cement clinker powder; 5-10 parts of anhydrite powder.

In the above technical scheme, preferably, the expansive high belite sulphoaluminate cement clinker powder is prepared by grinding expansive high belite sulphoaluminate cement clinker until the specific surface area is 400-500 m²Obtained in kg.

In the above technical solution, it is further preferable that the expansive high belite sulphoaluminate cement clinker has the following compounding parameters: the alkalinity coefficient Cm is 1.4-1.6, fCaO is 5-8%, fSO₃7-10%; the expansive high belite sulphoaluminate cement clinker has the following mineral composition in percentage by weight: c₂40-50% of S mineral content and C₄A₃S mineral content of 25-35%, C₁₂A₇Mineral content of 4-5%, CaSO₄Mineral content of 10-15%, fCaO mineral content of 4-8%, C₄The content of AF mineral is 1-2%.

In the above-described technical solution, it is preferable that,the portland cement clinker powder is prepared by grinding common portland cement clinker until the specific surface area is 350-380 m²Obtained as a/kg.

In the above technical scheme, preferably, the anhydrite powder is prepared by grinding natural anhydrite until the specific surface area is 380-400m²/kg of SO in the anhydrite powder₃The content is more than 50 percent.

When UHPC is prepared, the special composite cementing material is adopted to replace single portland cement and is used as a cementing material of the UHPC. The special composite cementing material provided by the invention is obtained by taking portland cement as a main body and adding a proper amount of expansive high belite sulphoaluminate cement clinker and anhydrite with the free expansion rate of about 0.25% in 1d to modify the portland cement. The special composite cementing material has the performance characteristics of low shrinkage and high strength, the 3d self-shrinkage value of the net slurry is only 350-380ppm, the net slurry is only 1/3 of Portland cement, and the compressive strength of each age is improved by 2-4MPa compared with that of the Portland cement. The special composite gelled material is used as a base material, and other auxiliary materials are optimally designed according to the requirements of compact stacking and compact filling of the total material, so that the technical aim of preparing the UHPC with low shrinkage, high early strength, excellent mechanical property and durability is fulfilled.

The special composite gelled material can reduce the shrinkage performance of UHPC, and the mechanism that the UHPC has excellent mechanical property and durability is as follows: the special composite cementing material is based on portland cement, and is modified by introducing a proper amount of expansive high belite sulphoaluminate cement and gypsum. The shrinkage of the portland cement is effectively compensated by the double micro-expansion effect of the high-expansibility belite sulphoaluminate cement and the gypsum, so that the special composite cementing material system has lower hydration volume shrinkage compared with the traditional portland cement, and the shrinkage of UHPC is fundamentally reduced. Meanwhile, the modification of portland cement by the high-expansibility belite sulphoaluminate cement and gypsum is shown in that the setting and hardening process is promoted, the strength and the long-term strength increase rate are improved, so that compared with the UHPC (Portland cement), under the condition of the same cement (cementing material) dosage, the UHPC adopting the special composite cementing material can reduce the dosage of expensive superfine mineral admixture of silica fume, thereby indirectly reducing the shrinkage and preparation cost of the UHPC.

The invention has the advantages and positive effects that:

1) compared with the common Portland cement, the 3d self-shrinkage of the clean slurry is 380ppm, which is about 1/3 of the Portland cement, the compressive strength of each age is improved by 2-4Mpa, and the specific surface area is 380-400m²The strength can reach 52.5 grades at the time of/kg.

2) The invention carries on the specific setting of the batching rate value and mineral composition to calcine the high belite sulphoaluminate cement clinker, it has the obvious early expansion performance, the 1d free expansion rate is about 0.25%, it has very high strength of each age, the setting and hardening speed is fast, and the adaptability of the ordinary portland cement is greatly enhanced, it can increase the mixing amount, after mixing, it can improve the strength while compensating the shrinkage of the cementing material which uses the portland cement as the main body.

3) The UHPC prepared by the special composite cementing material has a small self-shrinkage value, the 7d self-shrinkage value is 300-350 ppm, which is far lower than that of part of commercial UHPC products with the self-shrinkage value of 1100-1300 ppm, and the post-cracking risk of the UHPC material and the deformation of components can be obviously reduced.

4) The UHPC material system prepared by the special composite cementing material has high compactness and ultrahigh strength and durability, the 1d compressive strength can reach 60-70MPa, the 28d compressive strength can reach 160-180MPa, and the 28d flexural strength can reach 30-40 MPa.

5) The UHPC prepared by the special composite cementing material has good fluidity, can be self-leveled, has the fluidity of 260-270mm, can be effectively filled in a mold with a complex configuration, and only needs slight vibration.

6) Compared with the products in the current market, the silica fume mixing amount of the UHPC prepared by the special composite cementing material is reduced by more than 70 percent, so that the preparation cost of the HUPC is reduced by about 10 percent.

7) The UHPC prepared by the special composite cementing material has higher cost performance and market competitiveness, can be used for building decoration and structure integration, large-span bridge structures, wet joint connection of assembled building components, abrasion-resistant hydraulic engineering, offshore oil extraction platform engineering, maintenance, reinforcement and repair of some major projects, and the like, and has wide application.

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.

Example 1 preparation of expansive high belite sulphoaluminate cement clinker powder

Grinding according to the raw material weight proportion and the material proportion value shown in the table 1 to obtain 1.0 ton of raw material with the fineness of 0.08mm and the screen residue of less than 6 percent, calcining the raw material in a rotary kiln at 1300 ℃ to obtain 0.70 ton (the loss of the raw material on ignition is 30 percent) of expansive high belite sulphoaluminate cement clinker, and grinding to obtain the expansive high belite sulphoaluminate cement clinker with the specific surface area of 400-500 m²Perkg of expansive high belite sulphoaluminate cement clinker powder.

TABLE 1 raw mix ratio and batch rate values

The mineral composition of the expansive high belite sulphoaluminate cement clinker is shown in table 2.

TABLE 2 mineral composition of expansive high belite sulphoaluminate cement clinker

The physical properties of the expansive high belite sulphoaluminate cement clinker measured according to standards GB17671-1999 method for testing cement mortar strength (ISO method), GB/T1346-2011 method for testing water consumption, setting time and stability of standard cement consistency and TC/T313-2009 method for testing expansion rate of expansive cement are shown in Table 3.

TABLE 3 physical Properties of expansive high belite sulphoaluminate cement clinker

As can be seen from Table 3, the clinker fired by setting the batching ratio and the mineral composition of the high-expansibility belite sulphoaluminate cement clinker has remarkable early expansion performance, the free expansion rate of 1d is about 0.25 percent, and simultaneously has high strength of each age, the setting and hardening speed is high, so that the adaptability with common Portland cement is greatly enhanced, and the strength can be improved while the shrinkage of a cementing material taking the Portland cement as a main body is compensated after the clinker is doped.

The high belite sulphoaluminate cement clinker calcined according to the common batching technology has poor compatibility with the portland cement, can be doped in a low amount (not more than 10 percent), is easy to cause the great reduction of the strength of a special composite cementing material system, and can not effectively compensate the shrinkage of the portland cement.

EXAMPLE 2 preparation of the specialized composite cementitious Material

The components are sequentially added into a dry powder mixer according to the weight ratio shown in Table 4, and are fully and uniformly mixed to obtain the low-shrinkage UHPC special composite gelled material.

TABLE 4 weight ratio of the special composite cementing material

The physical properties of the special composite cementing materials are measured by using standard GB17671-1999 method for testing strength of cement mortar (ISO method) and GB/T1346-2011 method for testing water consumption, setting time and stability of standard consistency of cement, and the 3d self-shrinkage value of a cementing material net slurry sample (water-cement ratio of 0.3) is measured by a bellows method according to ASTM C1698 standard, and the results are shown in Table 5.

TABLE 5 physical Properties of the specialized composite cementitious Material

As can be seen from Table 5, the special composite cementitious material obtained by modifying portland cement by adding appropriate amounts of high-expansion belite sulphoaluminate cement clinker and anhydrite with a free expansion rate of about 0.25% in 1d to the portland cement mainly comprises portland cement, the 3d self-shrinkage value of the neat paste is only 350-380ppm, the neat paste is only 1/3 ppm of the portland cement, and the compressive strength of each age is improved by about 2-4MPa compared with the portland cement.

EXAMPLE 3 preparation of Low-shrinkage UHPC

In the embodiment, the quartz sand is water-washed drying sand with the maximum grain diameter less than or equal to 1.5 mm; SiO in silica fume₂The content is more than 95 percent, and the specific surface area is not less than 20000m²Per kg; the water demand ratio of the class I fly ash is not more than 90 percent, and the specific surface area is 450-500m²Per kg; the water reducing agent is a polycarboxylic acid high-efficiency water reducing agent, and the water reducing rate is more than 30 percent; the length of the copper-plated steel fiber is 10mm-15mm, and the diameter is 0.15mm-0.2 mm.

Group number 1:

weighing the following raw material components in parts by weight: 800g of special composite cementing material; 80g of silica fume; 200g of I-grade fly ash; 140g of copper-plated steel fibers; 15g of water reducing agent; 1100g of quartz sand; 180g of water.

The preparation method comprises the following steps: pouring the special composite cementing material, silica fume, I-grade fly ash and quartz sand into a planetary mortar stirrer, and stirring for 3 minutes to be uniform; mixing the water reducing agent into water, fully dissolving and uniformly mixing the water reducing agent and the water, and then pouring the mixture into the mixture to continue stirring for 3 minutes; and pouring the copper-plated steel fibers into the mixture, and continuously stirring for 2 minutes to obtain the UHPC mixture.

Group number 2:

weighing the following raw material components in parts by weight: 850g of special composite cementing material; 65g of silica fume; 220g of I-grade fly ash; 145g of copper-plated steel fiber; 17g of water reducing agent; 1050g of quartz sand; 175g of water.

The preparation method comprises the following steps: pouring the special composite cementing material, silica fume, I-grade fly ash and quartz sand into a planetary mortar stirrer, and stirring for 3 minutes to be uniform; mixing the water reducing agent into water, fully dissolving and uniformly mixing the water reducing agent and the water, and then pouring the mixture into the mixture to continue stirring for 3 minutes; and pouring the copper-plated steel fibers into the mixture, and continuously stirring for 2 minutes to obtain the UHPC mixture.

Group number 3:

weighing the following raw material components in parts by weight: 850g of special composite cementing material; 70g of silica fume; 230g of I-grade fly ash; 150g of copper-plated steel fiber; 16g of water reducing agent; 1030g of quartz sand; 165g of water.

The preparation method comprises the following steps: pouring the special composite cementing material, silica fume, I-grade fly ash and quartz sand into a planetary mortar stirrer, and stirring for 3 minutes to be uniform; mixing the water reducing agent into water, fully dissolving and uniformly mixing the water reducing agent and the water, and then pouring the mixture into the mixture to continue stirring for 3 minutes; and pouring the copper-plated steel fibers into the mixture, and continuously stirring for 2 minutes to obtain the UHPC mixture.

Group number 4:

weighing the following raw material components in parts by weight: 900g of special composite cementing material; 50g of silica fume; 250g of I-grade fly ash; 160g of copper-plated steel fiber; 20g of water reducing agent; 1000g of quartz sand; 160g of water.

The preparation method comprises the following steps: pouring the special composite cementing material, silica fume, I-grade fly ash and quartz sand into a planetary mortar stirrer, and stirring for 3 minutes to be uniform; mixing the water reducing agent into water, fully dissolving and uniformly mixing the water reducing agent and the water, and then pouring the mixture into the mixture to continue stirring for 3 minutes; and pouring the copper-plated steel fibers into the mixture, and continuously stirring for 2 minutes to obtain the UHPC mixture.

Group number 5:

weighing the following raw material components in parts by weight: 820g of special composite cementing material; 60g of silica fume; 210g of I-grade fly ash; 150g of copper-plated steel fiber; 20g of water reducing agent; 1100g of quartz sand; 170g of water.

The preparation method comprises the following steps: pouring the special composite cementing material, silica fume, I-grade fly ash and quartz sand into a planetary mortar stirrer, and stirring for 3 minutes to be uniform; mixing the water reducing agent into water, fully dissolving and uniformly mixing the water reducing agent and the water, and then pouring the mixture into the mixture to continue stirring for 3 minutes; and pouring the copper-plated steel fibers into the mixture, and continuously stirring for 2 minutes to obtain the UHPC mixture.

Comparison 1:

weighing the following raw material components in parts by weight: 900g of Portland cement; 150g of silica fume; 50g of I-grade fly ash; 160g of copper-plated steel fiber; 21.5g of water reducing agent; 1005g of quartz sand; 175g of water.

The preparation method comprises the following steps: pouring portland cement, silica fume, I-grade fly ash and quartz sand into a planetary mortar stirrer, and stirring for 3 minutes to be uniform; mixing the water reducing agent into water, fully dissolving and uniformly mixing the water reducing agent and the water, and then pouring the mixture into the mixture to continue stirring for 3 minutes; and pouring the copper-plated steel fibers into the mixture, and continuously stirring for 2 minutes to obtain the UHPC mixture.

Comparison 2:

weighing the following raw material components in parts by weight: 850g of Portland cement; 250g of silica fume; 50g of I-grade fly ash; 156g of copper-plated steel fiber; 21.5g of water reducing agent; 1005g of quartz sand; 181.5g of water.

The preparation method comprises the following steps: pouring portland cement, silica fume, I-grade fly ash and quartz sand into a planetary mortar stirrer, and stirring for 3 minutes to be uniform; mixing the water reducing agent into water, fully dissolving and uniformly mixing the water reducing agent and the water, and then pouring the mixture into the mixture to continue stirring for 3 minutes; and pouring the copper-plated steel fibers into the mixture, and continuously stirring for 2 minutes to obtain the UHPC mixture.

The flow rate is measured by a static mortar flow rate method, the stirred UHPC mixture is filled into a cement mortar flow rate truncated cone round die (the height is 60 +/-0.5 mm, the inner diameter of an upper opening is 70 +/-0.5 mm, the inner diameter of a lower opening is 100 +/-0.5 mm, the outer diameter of a lower opening is 120mm, and an instrument is designated by a GB/T2419-2016 cement mortar flow rate measuring method), after the stirred UHPC mixture is scraped, the die is lifted, the average value of the longitudinal and transverse diameters of the mixture is taken as the flow rate, the compressive strength and the flexural strength are measured according to the standard GB17671-1999 cement mortar strength test method, a test block is 40mm × 40mm × 160mm prism, and various properties of the ultra-high performance concrete with the group numbers of 1-5 and the comparison numbers of 1-2 are measured, and the results are shown in Table 6.

TABLE 6 physical Properties of Low shrinkage UHPC for each group number

As can be seen from Table 6, the HUPC prepared by the special composite cementing material has remarkable low shrinkage performance compared with the products (comparison 1 and comparison 2) in the prior art, the 7d self-shrinkage value is only 300-350 ppm, the 7d self-shrinkage value can be reduced by about 70%, and the HUPC has ultrahigh strength and durability under the condition of basically same flow, wherein the 1d compressive strength can reach more than 60MPa, the 1d compressive strength is improved by about 50%, the 28d compressive strength can reach more than 170MPa, the 28d compressive strength is improved by about 10%, the 28d flexural strength can reach 30-40 MPa, and the performance is more excellent.

Finally, it should be noted that: the above examples are only intended to illustrate the technical solution of the present invention, but not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: it is to be understood that modifications may be made to the technical solutions described in the foregoing embodiments, or some or all of the technical features may be equivalently replaced, and the modifications or the replacements may not make the essence of the corresponding technical solutions depart from the scope of the technical solutions of the embodiments of the present invention.

Claims (5)

1. A special composite cementing material for preparing low-shrinkage ultra-high performance concrete is characterized in that: the material is prepared by dry-mixing the following raw materials in parts by weight uniformly: 75-85 parts of portland cement clinker powder; 10-20 parts of expansive high belite sulphoaluminate cement clinker powder; 5-10 parts of anhydrite powder.

2. The special composite cementitious material for preparing low-shrinkage ultra-high performance concrete according to claim 1, characterized in thatIn the following steps: the expansive high belite sulphoaluminate cement clinker powder is prepared by grinding expansive high belite sulphoaluminate cement clinker until the specific surface area is 400-500 m²Obtained in kg.

3. The special composite cementing material for preparing low-shrinkage ultra-high performance concrete according to claim 2, wherein: the high-expansibility belite sulphoaluminate cement clinker has the following batching parameters: the alkalinity coefficient Cm is 1.4-1.6, fCaO is 5-8%, fSO₃7-10%; the expansive high belite sulphoaluminate cement clinker has the following mineral composition in percentage by weight: c₂The content of S mineral is 40-50%,

mineral content of 25-35%, C₁₂A₇Mineral content of 4-5%, CaSO₄Mineral content of 10-15%, fCaO mineral content of 4-8%, C₄The content of AF mineral is 1-2%.

4. The special composite cementing material for preparing low-shrinkage ultra-high performance concrete according to claim 1, wherein: the portland cement clinker powder is prepared by grinding common portland cement clinker until the specific surface area is 350-380 m²Obtained as a/kg.

5. The special composite cementing material for preparing low-shrinkage ultra-high performance concrete according to claim 1, wherein: the anhydrite powder is prepared by grinding natural anhydrite until the specific surface area is 380-400m²/kg of SO in the anhydrite powder₃The content is more than 50 percent.