阅读说明：本技术 一种灌浆材料及其制备、应用 (Grouting material and preparation and application thereof ) 是由 罗健林 张纪刚 李秋义 高嵩 张鹏 滕飞 于 2021-07-08 设计创作，主要内容包括：本发明涉及灌浆材料及制备、应用,属于滨海装配结构连接件防腐技术领域。该灌浆料包括以下组分：凝胶材料、固废材料、粉煤灰、聚乙烯醇、氧化石墨烯、缓释型超塑化剂和水。加入缓释型超塑化剂可以降低膨胀性复配水泥与外加剂不兼容、塌落度损失过快的问题,加入可再分散聚合物胶乳可有效地提升灌浆料可灌流变性和抗冻融耐久性、柔韧性及防水性能；而在GO-PVA预聚体液的制备过程中,进一步采用离子交换处理,可建起GO-PVA预聚体有效屏障,减少GO-PVA预聚体之间的团聚。(The invention relates to a grouting material, preparation and application thereof, and belongs to the technical field of corrosion prevention of connectors of coastal assembly structures. The grouting material comprises the following components: gel material, solid waste material, fly ash, polyvinyl alcohol, graphene oxide, slow-release superplasticizer and water. The problems of incompatibility between expansive compound cement and an additive and over-quick slump loss can be reduced by adding the slow-release superplasticizer, and the perfusion degeneration, freeze-thaw resistance durability, flexibility and waterproof performance of the grouting material can be effectively improved by adding the redispersible polymer latex; and in the preparation process of the GO-PVA prepolymer body fluid, ion exchange treatment is further adopted, so that an effective barrier of the GO-PVA prepolymer can be built, and the agglomeration between the GO-PVA prepolymers is reduced.)

1. A grouting material, characterized by comprising: gel material, solid waste material, fly ash, polyvinyl alcohol, graphene oxide, slow-release superplasticizer and water.

2. The grouting material of claim 1, wherein the grouting material further comprises: a redispersible polymer latex.

3. The grouting material of claim 2, wherein the redispersible polymer latex is at least one of EVA, PS, or PAA.

4. The grouting material of claim 1, wherein the solid waste material comprises: slag sand and mineral admixture.

5. The grouting material of claim 1, wherein the grouting material further comprises: at least one of a water reducing agent, a coagulation regulator and a defoaming agent.

6. A method of preparing a grouting material, comprising:

mixing graphene oxide aqueous dispersion, an oxidant and polyvinyl alcohol aqueous solution, and carrying out in-situ polymerization intercalation to form prepolymer liquid;

mixing fly ash, a slow-release superplasticizer or water reducing agent and a catalyst with the prepolymer body fluid, and performing ultrasonic dispersion under a heating condition to form GO-PVAH @ FA;

adding the rest water reducing agent and tartaric acid into the GO-PVAH @ FA, and uniformly mixing to form GO-PVAH @ FA suspension;

mixing and grinding the gel material and the solid waste material to form dry mixed material;

and uniformly mixing the GO-PVAH @ FA suspension with the dry mixture and other auxiliaries to form the grouting material.

7. The method of claim 6, wherein GO-PVAH @ FA is subjected to an ion exchange treatment.

8. The slow release type superplasticizer is applied to reducing incompatibility of expansive compound cement and an additive and too fast slump loss.

9. The application of the redispersible polymer latex in improving perfusion denaturation and freeze-thaw resistance durability, flexibility and waterproof performance of the grouting material.

10. The application of ion exchange treatment in reducing the agglomeration of GO-PVA prepolymers.

Technical Field

The invention belongs to the field of corrosion prevention of coastal structure connecting pieces, and particularly relates to a grouting material and preparation and application thereof.

Background

The information in this background section is only for enhancement of understanding of the general background of the invention and is not necessarily to be construed as an admission or any form of suggestion that this information forms the prior art that is already known to a person of ordinary skill in the art.

The reinforced concrete structure is widely applied to the field of coastal structural engineering such as offshore buildings, bridge tunnels, wind energy nuclear power stations, oil well drilling platforms, harbor wharfs and the like. These coastal structures often fail prematurely due to high chloride, sulfate, and other marine corrosive environments. A highway bridge built in 1967 is in an offshore environment, ocean sulfides and chlorides cause steel bar corrosion, and in addition, the highway bridge is not good in maintenance, collapses suddenly in 2018 just after 40 years of service, and a large number of casualties are caused. The method comprises the following steps: in 2007, a certain sea-crossing bridge completed in 2002 in 12 months was found that the lower structure in the spray splash zone had severe concrete peeling and internal steel bars were exposed. In fact, as a porous, heterogeneous material, seawater and oxygen can reach the surface of the rebar along the gaps in the concrete, creating corrosive free electrons. The electrons are transmitted to the cathode region through the reinforcing steel bars, and negative ions in the solution are transmitted to the anode region through the pore solution, so that a large number of corrosion micro-batteries are easily formed.

With the development of modern industrial technology and assembly manufacturing industry, the restriction of climate conditions is small, labor force is saved, the building quality can be improved, the assembly building with low overall production cost is raised to the national level, and building industrialization is imperative. The grouting sleeve is a key component of an assembled building, so that the corresponding grouting material is required to have good perfusability and degeneration, and also has the requirements of quick setting, early strength, stable volume, good durability and the like, and various prefabricated components such as beams, plates, columns and supports are quickly connected to form an assembled integral structure. However, the inventor finds that: the cement-based grouting materials sold in markets and applied in engineering often have the problems of slow or over-fast setting time, large loss of fluidity with time, low early strength, shrinkage caused by later hardening and the like.

Meanwhile, when developing the coastal assembly work, the inventors found that the following problems existed:

(1) the grouting sleeve for connecting corresponding structures is also easy to form a corrosion micro-battery, and once the basic connection function is lost due to corrosion of the grouting sleeve, the direct economic loss is large, and the repair is more difficult and complicated.

(2) Because the inner cavity of the steel bar sleeve is narrow, the thickness of the concrete protective layer is increased, the steel bar rust inhibitor is doped (as described in the patent with the publication number of CN110015871A, the method of simultaneously doping the early strength agent and the rust inhibitor), the surface coating of the concrete, the electrochemical desalting, the cathode protection method and other conventional anti-permeability, rust-resistant and anti-corrosion measures cannot be used, or the use effect is poor, or no platform is developed.

(3) When the early-strength non-shrinkage cement-based grouting material sleeve is adopted to quickly connect a coastal structure, the requirement of having good fluidity, early strength, high strength, no shrinkage during expansion and enough corrosion resistance and durability is difficult to guarantee.

Disclosure of Invention

In order to overcome the problems, the invention provides a grouting material and preparation and application thereof. The anticorrosion concrete grouting material is grouted into the steel bar sleeve by a gravity grouting method or a pressure grouting method, then embedded into the connection part of the coastal prefabricated component, maintained and molded, and the obtained anticorrosion concrete grouting material-based sleeve is applied to the coastal structure to realize quick connection.

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

in a first aspect of the present invention, there is provided a grouting material comprising: gel material, solid waste material, fly ash, polyvinyl alcohol, graphene oxide, slow-release superplasticizer and water.

In a second aspect of the present invention, there is provided a method for preparing a grouting material, comprising:

mixing graphene oxide aqueous dispersion, an oxidant and polyvinyl alcohol aqueous solution, and carrying out in-situ polymerization intercalation to form prepolymer liquid;

mixing fly ash, a slow-release superplasticizer or water reducing agent and a catalyst with the prepolymer body fluid, and performing ultrasonic dispersion under a heating condition to form GO-PVAH @ FA;

adding the rest water reducing agent and tartaric acid into the GO-PVAH @ FA, and uniformly mixing to form GO-PVAH @ FA suspension;

mixing and grinding the gel material and the solid waste material to form dry mixed material;

and uniformly mixing the GO-PVAH @ FA suspension with the dry mixture and other auxiliaries to form the grouting material.

The invention has the beneficial effects that:

(1) the research finds that: the slow-release superplasticizer is added into the grouting material, so that the problems of incompatibility between expansive compound cement and an additive and over-quick slump loss can be reduced, and the addition of the redispersible polymer latex can effectively improve perfusion denaturation and freeze-thaw resistance durability, flexibility and waterproof performance of the grouting material; and in the preparation process of the GO-PVA prepolymer body fluid, ion exchange treatment is further adopted, so that an effective barrier of the GO-PVA prepolymer can be built, and the agglomeration between the GO-PVA prepolymers is reduced.

(2) By adopting the grouting material and the preparation process, not only can the complete grouting sleeve system of the coastal assembly structure be quickly connected, but also the corrosion resistance and durability can be effectively guaranteed. As can be seen from fig. 1 and 2, firstly, the stably dispersed GO-PVAH is innovatively passed through the FA medium surface wrapped outside, so that the GO-PVAH is long-acting uniformly distributed in a subsequent grouting material system, and the problem of greatly reducing the fluidity of the grouting material when GO is directly mixed with the grouting material can be effectively offset; meanwhile, the GO-combined PVA prepolymer containing hydrophilic groups is uniformly dispersed in the grouting material, so that the segregation resistance and the time-dependent rheological property of the grouting material are effectively improved; secondly, the expansive compound cement hydration product has a thicker hydration film and the ball lubrication characteristic of FA is beneficial to realizing the grouting flow and self-compaction functions of the corresponding grouting material; and thirdly, the adsorption effect of the water reducing agent, the coagulation regulating agent and other additives on the double electric layers of the grouting material can effectively ensure the realization of perfusion performance of the grouting material. The mechanism for realizing the mechanical impermeability of the hardened body of the grouting material is as follows: on one hand, the surface of GO contains a plurality of hydrophilic groups such as hydroxyl, epoxy, carboxyl and the like, which is beneficial to the compatibility of GO with a cement mortar system, and meanwhile, GO can fully exert the effects of nanocrystal cores and templates, improve the micro morphology of the corresponding grouting material hardened body, and further improve the mechanical strength and the anti-cracking and anti-permeability effects of the grouting material; on the other hand, the GO-PVAH hydrogel can serve as an internal curing component well in the grouting material forming process, subsequent water is slowly released, so that the thermal shrinkage stress generated when the expansive compound cement is rapidly hydrated is effectively offset, and the shrinkage reduction effect is realized; on the other hand, the quick setting and micro-expansion characteristics of the expansive compound cement and the self-lubricating shrinkage-reducing effect of FA effectively realize the early-strength non-shrinkage effect of the grouting material.

(3) According to the grouting material, firstly, the GO nano active template effect can effectively reduce the porosity of a hardened body of the grouting material, improve the compactness of the grouting material, reduce an ion permeation path and delay the time for a seawater corrosion medium to reach the surface of a sleeve reinforcing steel bar; and secondly, the GO containing functional groups such as hydroxyl, epoxy, carboxyl and the like and the PVA electrolyte containing hydroxyl are stably combined to form a large number of GO-PVAH micro-capacitors, and the GO-PVAH micro-capacitors uniformly dispersed in the grouting material through FA media can store a large number of grouting material hole solution electrolytes and capture ions migrated by seawater media, so that the formation of corrosion batteries in the reinforcing sleeve of the grouting material is avoided, the electrochemical corrosion of the reinforcing steel bar is effectively prevented, and the chlorine ion permeation resistance and seawater corrosion resistance of the grouting material are obviously improved.

In the grouting material, GO-PVAH is synthesized on the surface of FA, the time for adding GO-PVAH @ FA into the nano grouting material is effectively delayed by using an external additive aqueous solution medium, and the bottleneck problem of GO deoxidation in a strong alkaline environment is creatively avoided by combining low-alkalinity compound cement and FA and other admixtures with reduced alkalinity. The nanometer grouting material can realize the functions of grouting flow deformation and self-compaction through the GO-PVAH externally wrapped FA medium surface, the existence of a thicker hydration film in the compound cement slurry and the roll ball lubrication effect of FA; the continuous early strength, high strength, crack resistance and permeability resistance functions of the nano grouting material are realized by using the GO nano template and the compound cement effect; the non-shrinkage effect of the grouting material is realized through GO-PVAH internal curing, compound cement micro-expansion and FA shrinkage reduction effects; the energy storage effect of the GO-PVAH micro-capacitor is exerted to avoid the formation of a steel bar corrosion micro-battery in the grouting material sleeve, the steel bar corrosion self-immunity effect is realized, and the perfusability of the grouting material and the early strength non-shrinkage, anti-cracking, anti-permeability and corrosion self-immunity effects of a hardened body are innovatively and synchronously realized; the slag sand is utilized to effectively improve the seawater erosion resistance of the grouting material, and the solid waste recycling of the slag sand is synchronously widened.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate exemplary embodiments of the invention and together with the description serve to explain the invention and not to limit the invention.

FIG. 1 is a schematic diagram of GO-PVA polymeric intercalation and GO-PVAH @ FA coating processes in example 1 of the present invention. Wherein: 1-FA particles, 2-GO-PVA hydrogel layers, 21-GO sheet layers, 22-PVA polymers and 23-hydrogel; the GO-PVA hydrogel layer is coated on the surface of FA particles, and a PVA polymer is effectively inserted into a GO lamellar structure to form a micro-capacitor positive and negative electric double layer, so that the marine corrosion resistance of the grouting material is effectively improved. The GO-PVA intercalation structure is used for schematically reflecting the intercalation structure formed by a GO sheet layer and a PVA linear chain type polymer, and the SEM micro-morphology of FA is used for schematically reflecting the spherical hollow structure and the size specification of FA so as to be better understood by a person skilled in the art.

FIG. 2 is a scanning electron micrograph of a cured product after 7d curing of the grouting material of example 1 of the present invention.

Detailed Description

It is to be understood that the following detailed description is exemplary and is intended to provide further explanation of the invention as claimed. Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs.

In view of the above-mentioned disadvantages of the prior art, the present invention provides a grouting material, a method for preparing the same, and an application of the grouting material in the quick connection of a coastal assembly structure. GO-PVAH is synthesized on the surface of FA, the time for adding GO-PVAH @ FA into the nano grouting material is effectively delayed by using an external additive aqueous solution medium, and the bottleneck problem of GO deoxidation in a strong alkaline environment is creatively avoided by combining low-alkalinity compound cement and FA and other admixtures for reducing alkalinity. The nanometer grouting material can realize the functions of grouting flow deformation and self-compaction through the GO-PVAH externally wrapped FA medium surface, the existence of a thicker hydration film in the compound cement slurry and the roll ball lubrication effect of FA; the continuous early strength, high strength, crack resistance and permeability resistance functions of the nano grouting material are realized by using the GO nano template and the compound cement effect; the non-shrinkage effect of the grouting material is realized through GO-PVAH internal curing, compound cement micro-expansion and FA shrinkage reduction effects; the energy storage effect of the GO-PVAH micro-capacitor is exerted to avoid the formation of a steel bar corrosion micro-battery in the grouting material sleeve, the steel bar corrosion self-immunity effect is realized, and the perfusability of the grouting material and the early strength non-shrinkage, anti-cracking, anti-permeability and corrosion self-immunity effects of a hardened body are innovatively and synchronously realized; the seawater erosion resistance of the grouting material is effectively improved by utilizing the slag sand, the solid waste resource utilization of the slag sand is synchronously widened, and finally huge economic and environmental benefits are contained in the field of fast connection of coastal assembly structures.

A grouting material comprising: gel material, solid waste material, fly ash, polyvinyl alcohol, graphene oxide, slow-release superplasticizer and water.

In some embodiments, the grouting material further comprises: a redispersible polymer latex.

In some embodiments, the redispersible polymer latex is at least one of EVA, PS, or PAA.

In some embodiments, the solid waste material comprises: slag sand and mineral admixture.

In some embodiments, the grouting material further comprises: at least one of a water reducing agent, a coagulation regulator and a defoaming agent.

The method specifically comprises the following steps:

s1: dissolving the PVA in hot water to prepare a PVA aqueous solution; under the condition that the PVA oxidant exists, the GO powder or the water dispersion is mixed into a PVA aqueous solution, and a PVA prepolymer is intercalated in a GO lamellar structure by adopting an in-situ polymerization intercalation process to obtain GO-PVA prepolymer liquid;

s2: adding FA, part of the water reducing agent and the PVA catalyst into GO-PVA prepolymer liquid, further wrapping GO-PVA hydrogel (GO-PVAH) on the surface of FA particles by adopting a thermal ultrasonic process to obtain GO-PVAH @ FA, and sealing for later use;

s3: adding the GO-PVAH @ FA into an additive water solution formed by the rest water reducing agent and the coagulant, and stirring uniformly at a high speed to obtain a GO-PVAH @ FA suspension; simultaneously, mechanically mixing the expansive compound cement, the slag sand and the mineral admixture to form a grouting material dry blend;

s4: and adding the GO-PVAH @ FA suspension into the dry grouting material by grouting material stirring equipment, and mechanically stirring uniformly to obtain the grouting material.

In step S1, the PVA intercalation efficiency and GO dispersion effect in GO-PVA pre-polymerization fluid may be analyzed by combining an automatic titration method, a rotational viscometer, a UV-Vis spectrophotometry method, and a micro-topography method.

In step S2, GO-PVAH equilibrium swelling ratio, transmittance, structural crosslinking degree, micro-distribution morphology and density can be measured by combining with a freeze-drying method, a UV-Vis spectrophotometry, a TG-DSC integrated thermal analysis method and a micro-morphology method, respectively; and (3) measuring the overall density, water content and organic matter content, interface stripping resistance and wrapping layer thickness of GO-PVAH @ FA by combining an ethanol drainage method, a TG-DSC comprehensive thermal analysis method, a stripping strength method and a film thickness instrument method.

In step S4, the grouting material may be prepared by conventional grouting material preparation methods well known to those skilled in the art, and the types and mixing amounts of the corresponding water reducing agent, coagulation regulator and defoaming agent are preferably selected according to the rheological properties (viscosity coefficient, shear stress), setting time (consistency, rheology) of the grouting material, and the like. The performance characterization of the grouting material can be carried out by combining the methods of grouting material pourability, mechanical strength, expansion rate, water/oil permeability resistance and chloride ion permeability resistance, which are well known to those skilled in the art. The electrochemical parameters such as the corrosion potential, the polarization resistance, the corrosion current density, the electrochemical impedance spectrum and the like of the steel bar of the grouting material sleeve, the mechanical parameters such as the mechanical behavior (tensile strength, load-displacement curve), the deformation performance (residual deformation, maximum elongation) and the interface cohesive force (cohesive strength, failure characteristics) and the like can be developed by combining the grouting sleeve electrochemical parameter and tension-compression mechanical fatigue property characterization methods which are well known by the technical personnel in the field.

The rubber plugs familiar to the technicians in the field plug the grouting ports and the grout discharging ports of the steel bar sleeves, and the grouting construction quality can be evaluated by methods familiar to the technicians in the field, such as ultrasonic or radar wave nondestructive detection and the like.

A grouting material comprising the following components: the composite material comprises expansive compound cement, slag sand, coal ash (FA), polyvinyl alcohol (PVA) (containing corresponding oxidant and catalyst), Graphene Oxide (GO), a water reducing agent, a coagulation regulator, a defoaming agent, a mineral admixture and water, wherein the mass ratio of the components is 1: (1-2): (0.05-0.2): (0.005-0.05): (0.0002-0.002): (0.005-0.01): (0.005-0.01): (0.0001-0.001): (0-0.05): (0.25-0.55).

In some embodiments, the expansive compounded cement includes the following components: sulphoaluminate cement (SAC), portland cement and gypsum, wherein the mass ratio of the components is 1: (0.65-1.25): (0-0.15); the expansive compound cement hydration product has a thicker hydration film and the ball lubrication characteristic of FA is beneficial to realizing the grouting flow and self-compaction functions of the corresponding grouting material.

The specific type of the slag sand is not particularly limited in this application, and in some embodiments, the slag sand is one or a combination of several of blast furnace heavy slag sand, steel slag sand, titanium steel slag sand, copper-nickel slag sand and nickel-iron slag sand; and the good particle grading curve is realized by matching the following components: coarse sand with the fineness modulus of 3.7-3.1, the average grain diameter of more than 0.5mm, medium sand with the fineness modulus of 3.0-2.3, medium sand with the average grain diameter of 0.5-0.35 mm, fine sand with the fineness modulus of 2.2-1.6, fine sand with the average grain diameter of 0.35-0.25 mm, the fineness modulus of 1.5-0.7 and superfine sand with the average grain diameter of less than 0.25mm, wherein the mass ratio of the components is 1: (1.1-2.0): (1-1.5): (1-1.5), ensuring that the sand content is in the interval of 27% -33%; the slag sand is utilized to effectively improve the seawater erosion resistance of the grouting material, and the solid waste recycling of the slag sand is synchronously widened.

In some embodiments, the FA is class I FA with loss on ignition of less than or equal to 5% specified in GB/T1596-2017 standard, so as to obtain better ball lubrication effect.

In some embodiments, the PVA is an aqueous PVA solution with an average degree of polymerization of 500-600 and a degree of alcoholysis of 88%; dispersing GO in PVA water solution to form stable GO-PVA pre-polymer body fluid.

In some embodiments, the PVA oxidant and the PVA catalyst are respectively one of sodium periodate, potassium permanganate or potassium chlorate mentioned in chinese patent CN103450489 or CN105885064A, concentrated hydrochloric acid, diluted sulfuric acid, diluted nitric acid or boric acid, so as to intercalate the PVA prepolymer in the GO lamellar structure by an in-situ polymerization intercalation process.

In some embodiments, the GO is a GO powder with a single-layer rate of more than or equal to 90% and an oxygen content of 35-45% or an aqueous dispersion with a concentration of 0.05-10 mg/mL; when the GO water dispersion is used, the mass of GO in the water dispersion is calculated according to the concentration proportion, and the water content in the corresponding water dispersion is calculated to the total amount of water used by the grouting material.

The specific type of the water reducing agent is not particularly limited in the application, and in some embodiments, the water reducing agent is one or an optimized combination of polycarboxylic acid high-efficiency water reducing agent, naphthalene sodium sulfonate high-efficiency water reducing agent or melamine resin high-efficiency water reducing agent; the set retarder is one of gluconate retarder, citric acid, tartaric acid and salt retarder thereof or lignosulfonate water-reducing retarder; the defoaming agent is one of organosilicon defoaming agents, polyether defoaming agents and polyether modified polysiloxane defoaming agents. The adsorption effect of the external agents such as the water reducing agent, the coagulation regulator and the like on the double electric layers of the grouting material can effectively ensure the realization of the perfusion performance of the grouting material.

The specific source of the mineral admixture is not particularly limited in this application, and in some embodiments, the mineral admixture is one or a combination of ground slag, fly ash, volcanic ash, silica powder or zeolite powder; the mineral admixture is mechanically mixed with expansive compound cement and slag sand to form the grouting material dry blend.

In some embodiments, the water is one of distilled water, deionized water or tap water, and the person skilled in the art can select the water according to specific working conditions.

The invention also provides application of the grouting material in connection of coastal structure engineering. And (3) pouring the grouting material into the steel bar sleeve by a gravity grouting method or a pressure grouting method, then embedding the steel bar sleeve into the connection part of the coastal prefabricated components, and quickly forming to obtain the sleeve based on the grouting material, which is applied to the coastal structure, so as to realize quick connection of the coastal structure.

In some embodiments, the coastal precast elements in grouting material applications may be honeycomb beams, fabricated composite slabs, fabricated columns, fabricated pedestals, or the like.

In some embodiments, the sleeve of rebar in grouting material applications may be a half-grouted sleeve with grout ports, a full-grouted sleeve, or the like.

The present invention is described in further detail below with reference to specific examples, which are intended to be illustrative of the invention and not limiting.

Example 1

The preparation process of the grouting material of the embodiment comprises the following specific steps:

s1: dissolving 0.25kg of PVA in 5L of hot water at the temperature of 70 ℃ to prepare a PVA water solution with the concentration of 5%, the average polymerization degree of 500-600 and the alcoholysis degree of 88%; under the condition of containing 0.02kg of sodium periodate (PVA oxidant), 0.025kg of GO powder is mixed into the PVA aqueous solution, and a GO-PVA prepolymer is intercalated in a GO lamellar structure by adopting an in-situ polymerization intercalation process to obtain GO-PVA prepolymer liquid;

s2: adding 1.0kg of FA, 0.1kg of polycarboxylic acid high-efficiency water reducing agent and 0.01kg of concentrated hydrochloric acid (PVA catalyst) into the GO-PVA pre-polymerization body fluid, further adopting an oil bath pot thermal ultrasonic dispersion process (oil temperature 100 ℃, frequency 10kHz, power 50W and ultrasonic time 30min), wrapping GO-PVA hydrogel (GO-PVAH) on the surface of FA particles to obtain GO-PVAH @ FA, and sealing for later use;

s3: adding the GO-PVAH @ FA into an additive aqueous solution formed by the residual 0.15kg of PCA-I type polycarboxylic acid high-efficiency water reducing agent (purchased from Jiangsu Subo New materials Co., Ltd.) and 0.3kg of HN-B type gluconate retarder (purchased from Qingdao Dingchang New materials Co., Ltd.), and uniformly stirring at a high speed to obtain a GO-PVAH @ FA suspension; at the same time, 20kg of expansive combined cement (composed of 10kg of type 425 SAC, 9.5kg of P.I type 42.5 portland cement and 0.5kg of gypsum), 40kg of blast furnace heavy slag sand (taken from the group consisting of 2560kg/m apparent density)³The chemical composition of the blast furnace heavy slag of the steel is SiO₂＝32～38％，CaO＝40～42％，MgO＝8～11％,Al₂O₃5-8 percent (composed of 8kg of coarse sand, 12kg of medium sand, 10kg of fine sand and 10kg of superfine sand) and 0.5kg of ground slag powder (also taken from the group with the apparent density of 2560 kg/m)³The steel blast furnace heavy slag is obtained by ball milling), and the mixture is mechanically mixed to form corresponding grouting material dry blend;

s4: adding the GO-PVAH @ FA suspension into corresponding dry grouting material mixture by a JJ-5 type mortar stirrer, mechanically stirring uniformly (rotating speed of 120rpm for 4min), adding a 0.005kgACP1266 type organosilicon defoaming agent (purchased from Dow Corning (Shanghai) Co., Ltd.) to eliminate possible foams, and finally obtaining the grouting material.

The grouting material is poured into a full-grouting steel bar sleeve by a pressure grouting method (grouting pressure is 5MPa), and the electrochemical parameters and the mechanical fatigue behavior of the steel bar are tested; and trying to embed the prefabricated column into a connection node of the coastal prefabricated column, quickly forming to obtain the grouting material-based sleeve prefabricated column, and evaluating the quick connection and corrosion resistance and durability of the prefabricated column.

In step S1, the intercalation efficiency and the dispersing effect of the PVA in the GO-PVA pre-polymer fluid are shown in fig. 1. In step S2, the swelling ratio and the wrapping layer thickness of GO-PVAH @ FA are respectively 30% and 65 μm. In step S4, the hardened body micro-morphology of the grouting material is shown in fig. 2, and the related properties are shown in table 1.

Example 2

The preparation process of the grouting material of the embodiment comprises the following specific steps:

s1: dissolving 0.5kg of PVA in 5L of hot water at the temperature of 80 ℃ to prepare a PVA water solution with the concentration of 10%, the average polymerization degree of 500-600 and the alcoholysis degree of 88%; under the condition of containing 0.015kg of potassium permanganate (PVA oxidant), mixing 10mg/mL of 2L of GO water dispersion into the PVA aqueous solution, and intercalating a PVA prepolymer in a GO lamellar structure by adopting an in-situ polymerization intercalation process to obtain GO-PVA prepolymer body fluid;

s2: adding 1.5kg of FA, 0.2kg of FDN-O type sodium naphthalene sulfonate high-efficiency water reducing agent (purchased from Wuhanzhuozhen trade Co., Ltd.) and 0.01kg of dilute sulfuric acid (PVA catalyst) into the GO-PVA pre-polymerization body fluid, further adopting an oil bath pan thermal ultrasonic dispersion process (oil temperature 120 ℃, frequency 20kHz, power 50W and ultrasonic time 45min), wrapping GO-PVA hydrogel (GO-PVAH) on the surface of FA particles to obtain GO-PVAH @ FA, and sealing for later use;

s3: adding the GO-PVAH @ FA into an additive aqueous solution formed by the residual 0.1kg of naphthalene sodium sulfonate superplasticizer and 0.25kg of citric acid, and stirring uniformly at a high speed to obtain GO-PVAH @ FA suspension; at the same time, 25kg of expansive blended cement (composed of 12kg of SAC type 525, 12kg of Portland cement type P.II 52.5 and 1kg of gypsum), 35kg of steel slag sand (taken from the slag with apparent density of 3160 kg/m)³The steel slag sand comprises 35-38% of CaO and Fe₂O₃＝20～24％，SiO₂＝18～21％，Al₂O₃5-8% of MgO, 5-7% (consisting of 8kg of coarse sand, 12kg of medium sand, 8kg of fine sand and 7kg of superfine sand) and 1kg of fly ash, and mechanically mixing to form corresponding grouting material dry blend;

s4: adding the GO-PVAH @ FA suspension into corresponding dry grouting material mixture by an electric high-speed stirrer, mechanically stirring uniformly (rotating speed 500rpm for 3min), adding 0.008kgRK-1500 type polyether defoamer (purchased from Xiamen Raylen chemical engineering Co., Ltd.) to eliminate possible bubbles, and finally obtaining the grouting material.

Pouring the grouting material into a semi-grouting steel bar sleeve by a gravity grouting method, and testing the electrochemical parameters and the mechanical fatigue behavior of the steel bar; and trying to embed into a connection node of the coastal prefabricated lotus root beam, quickly forming, obtaining the quick connection of the grouting material-based sleeve lotus root beam, and evaluating the quick connection and corrosion resistance durability of the grouting material-based sleeve lotus root beam.

The swelling ratio and the wrapping thickness of GO-PVAH @ FA in the step S2 are respectively 40% and 50 μm. In step S4, the properties of the grouting material are shown in table 1.

Example 3

The preparation process of the grouting material of the embodiment comprises the following specific steps:

s1: dissolving 0.3kg of PVA in 5L of hot water at 65 ℃ to prepare a PVA aqueous solution with the concentration of 6%, the average polymerization degree of 500-600 and the alcoholysis degree of 88%; under the condition of containing 0.02kg of potassium chlorate (PVA oxidant), 5L of GO water dispersion with the concentration of 4mg/mL is mixed into the PVA water solution, and a PVA prepolymer is intercalated in a GO lamellar structure by adopting an in-situ polymerization intercalation process to obtain GO-PVA prepolymer body fluid;

s2: adding 1.2kg of FA, 0.15kg of SBTJM-9 type polycarboxylic acid and melamine resin combined high-efficiency water reducing agent (purchased from Jiangsu Subo New Material Co., Ltd.) and 0.01kg of boric acid (PVA catalyst) into the GO-PVA pre-polymerization body fluid, further adopting an oil bath pan thermal ultrasonic dispersion process (oil temperature 100 ℃, frequency 20kHz, power 50W and ultrasonic time 60min), wrapping GO-PVA hydrogel (GO-PVAH) on the surface of FA particles to obtain GO-PVAH @ FA, wherein the swelling rate and the wrapping layer thickness are respectively 50% and 100 mu m, and sealing for later use;

s3: adding the GO-PVAH @ FA into an additive aqueous solution formed by adding the residual 0.15kg of SBTJM-9 type polycarboxylic acids and melamine resin combined high-efficiency water reducing agent and 0.3kg of tartaric acid, and stirring at a high speed to obtain GO-PVAH @ FA suspension; at the same time, 25kg of expansive compounded cement (composed of 12kg of 625 type high belite SAC, 12kg of P.I type 62.5 portland cement and 1kg of gypsum), 40kg of copper-nickel slag sand (taken from the concrete having an apparent density of 2870 kg/m)³With SiO₂And copper-nickel slag sand (composed of 10kg coarse sand, 10kg medium sand, 10kg fine sand and 10kg ultra-fine sand) of Jinchuan group GmbH mainly containing MgO, and 1kg volcanic ash, and mechanically mixing to form corresponding dry grouting material;

s4: adding the GO-PVAH @ FA suspension into dry mixture of corresponding grouting material by a DE-500 type shearing emulsifying machine, mechanically stirring (the rotating speed is 2500rpm, the duration is 2min), adding a 0.004kgRK-1805S type polyether modified polysiloxane defoaming agent (purchased from Xiamen Raylen chemical technology Co., Ltd.) to eliminate bubbles possibly existing, and trying to further eliminate bubbles caused by high-speed stirring by vacuumizing to finally obtain the grouting material.

The grouting material is poured into a full-grouting steel bar sleeve through a pressure grouting method, and the electrochemical parameters and the mechanical fatigue behavior of the steel bar are tested; and trying to embed into a connecting node of the shore prefabricated column support, quickly forming, obtaining the quick connection based on the grouting material sleeve support, and evaluating the quick connection and corrosion resistance and durability of the quick connection based on the grouting material sleeve support.

The GO-PVAH @ FA swelling ratio and the wrapping layer thickness in the step S2 are respectively 40% and 50 μm. In step S4, the properties of the grouting material are shown in table 1.

Example 4

The manufacturing method of this example is the same as example 1, except that 20kg of expansive blended cement in the step S3 is composed of 10kg of SAC type 425 and 10kg of P.I type 42.5 portland cement, no gypsum is contained, and the corresponding mineral admixture is added in an amount of 0 kg.

In step S2, the swelling ratio and the wrapping layer thickness of GO-PVAH @ FA are respectively 30% and 65 μm. In step S4, the properties of the grouting material are shown in table 1.

Table 1 comparative results of performance tests of grouting materials in examples

Experimental example 1

On the basis of the embodiment 1, the preparation process and the formula of the grouting material are further optimized to improve the performance of the grouting material, and the preparation method comprises the following specific steps:

s1: dissolving 0.25kg of PVA in 5L of hot water at the temperature of 70 ℃ to prepare a PVA water solution with the concentration of 5%, the average polymerization degree of 500-600 and the alcoholysis degree of 88%; under the condition of containing 0.02kg of sodium periodate (PVA oxidant), 0.025kg of GO powder is mixed into the PVA aqueous solution, and a GO-PVA prepolymer is intercalated in a GO lamellar structure by adopting an in-situ polymerization intercalation process to obtain GO-PVA prepolymer liquid;

s2: adding 1.0kg of FA, 0.1kg of slow-release superplasticizer and 0.01kg of concentrated hydrochloric acid (PVA catalyst) into the GO-PVA pre-polymerization body fluid, further adopting an oil bath pan thermal ultrasonic dispersion process (oil temperature 100 ℃, frequency 10kHz, power 50W and ultrasonic time 30min), then carrying out ion exchange treatment, wrapping GO-PVA hydrogel (GO-PVAH) on the surface of FA particles, obtaining GO-PVAH @ FA, and sealing for later use;

s3: adding the GO-PVAH @ FA into an additive aqueous solution formed by the rest 0.15kg of slow-release superplasticizer and 0.3kg of HN-B type gluconate retarder (purchased from Qingdao Dingchang New materials Co., Ltd.), and uniformly stirring at a high speed to obtain GO-PVAH @ FA suspension; at the same time, 20kg of expansive combined cement (composed of 10kg of type 425 SAC, 9.5kg of P.I type 42.5 portland cement and 0.5kg of gypsum), 40kg of blast furnace heavy slag sand (taken from the group consisting of 2560kg/m apparent density)³The chemical composition of the blast furnace heavy slag of the steel is SiO₂＝32～38％，CaO＝40～42％，MgO＝8～11％,Al₂O₃5-8 percent (composed of 8kg of coarse sand, 12kg of medium sand, 10kg of fine sand and 10kg of superfine sand) and 0.5kg of ground slag powder (also taken from the group with the apparent density of 2560 kg/m)³The steel blast furnace heavy slag is obtained by ball milling), and the mixture is mechanically mixed to form corresponding grouting material dry blend;

s4: adding the GO-PVAH @ FA suspension into corresponding dry grouting material mixture by a JJ-5 type mortar stirrer, mechanically stirring uniformly (rotating speed of 120rpm for 4min), adding a 0.005kgACP1266 type silicone defoaming agent (purchased from Dow Corning (Shanghai) Co., Ltd.) to eliminate possible foams, and adding 0.005kg EVA to finally obtain the grouting material.

The grouting material is poured into a full-grouting steel bar sleeve by a pressure grouting method (grouting pressure is 5MPa), and the electrochemical parameters and the mechanical fatigue behavior of the steel bar are tested; and trying to embed the prefabricated column into a connection node of the coastal prefabricated column, quickly forming to obtain the grouting material-based sleeve prefabricated column, and evaluating the quick connection and corrosion resistance and durability of the prefabricated column.

The test result shows that: the slow-release superplasticizer is added into the grouting material, so that the problems of incompatibility between expansive compound cement and an additive and over-quick slump loss can be reduced, and the addition of the redispersible polymer latex can effectively improve perfusion denaturation and freeze-thaw resistance durability, flexibility and waterproof performance of the grouting material; and in the preparation process of the GO-PVA prepolymer body fluid, ion exchange treatment is further adopted, so that an effective barrier of the GO-PVA prepolymer can be built, and the agglomeration between the GO-PVA prepolymers is reduced.

It should be noted that the above-mentioned embodiments are only preferred embodiments of the present invention, and the present invention is not limited thereto, and although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications and equivalents can be made in the technical solutions described in the foregoing embodiments, or equivalents thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.