CN114524640A - Concrete with high-performance impermeability, preparation method and equipment thereof - Google Patents

Abstract

The invention relates to the technical field of concrete processing, and particularly discloses a concrete with high-performance impermeability, a preparation method and equipment thereof, wherein the concrete comprises, by weight, 300-400 parts of broken stone, 220-320 parts of cement, 80-120 parts of fly ash, 60-80 parts of quartz sand, 10-15 parts of titanium nitride powder, 50-60 parts of calcium carbonate powder, 10-13 parts of alumina fiber, 8-12 parts of hydroxypropyl starch ether, 8-10 parts of a water reducing agent, 0.5-1 part of an air entraining material, 3-8 parts of microporous sintered particles, 5-8 parts of magnesium oxide, 1-5 parts of zinc stearate and 110-150 parts of water. The invention has the characteristics of higher automation degree, better use convenience and higher processing efficiency.

Description

Concrete with high-performance impermeability, preparation method and equipment thereof

Technical Field

The invention relates to the technical field of concrete processing, in particular to concrete with high-performance impermeability, a preparation method and equipment thereof.

Background

The impervious concrete is concrete with impervious grade equal to or more than P6 grade, the impervious concrete is divided into 5 grades of P6, P8, P10, P12 and more than P12 according to different impervious pressure, and the impervious concrete improves the compactness of the concrete and improves the pore structure, thereby reducing the permeation channel and improving the impervious property.

The common method is to mix the air-entraining admixture to generate unconnected bubbles in the concrete, cut off the capillary channel and change the pore structure, so as to improve the impermeability of the concrete; in addition, the construction quality can be ensured by reducing the water cement ratio and selecting cement with proper variety and strength grade, and particularly, the important effect on improving the impermeability is realized by paying attention to compaction vibration, sufficient maintenance and the like.

Because need smash and weigh various raw materialss in the course of working of concrete, lead to the great reduction of efficiency of work, all need smash earlier then in the inside of adding the agitator tank body in proper order to various materials, need be according to certain order at the in-process that adds, traditional equipment can not satisfy the demand of using, leads to the great reduction of efficiency of processing.

Disclosure of Invention

The invention aims to solve the technical problems in the processing process of the existing concrete, and provides the concrete with high automation degree, good use convenience, high processing efficiency and high performance impermeability, a preparation method and equipment thereof.

The first technical scheme of the invention is as follows: a concrete with high-performance impermeability comprises the following components in parts by weight,

300-400 parts of broken stone, 220-320 parts of cement, 80-120 parts of fly ash, 60-80 parts of quartz sand, 10-15 parts of titanium nitride powder, 50-60 parts of calcium carbonate powder, 10-13 parts of alumina fiber, 8-12 parts of hydroxypropyl starch ether, 8-10 parts of a water reducing agent, 0.5-1 part of an air entraining material, 3-8 parts of micropore sintering particles, 5-8 parts of magnesium oxide, 1-5 parts of zinc stearate and 110-150 parts of water. According to the invention, a proper amount of air entraining material is added into the traditional concrete raw material, so that the plasticity of the concrete can be improved, and the prepared concrete has good durability; according to the invention, the proper amount of the microporous sintered particles are added, and the loose and porous microporous sintered particles have the effect of activated carbon, so that redundant air can be absorbed, the air in the concrete is reduced, and the impermeability of the concrete is improved; the microporous sintered particles can also effectively adsorb water, and the water can be slowly released in the concrete solidification process, so that the internal humidity of the concrete can be maintained to facilitate the solidification of the concrete, the impermeability of the concrete can be improved, and the problems of concrete collapse, flowability and the like can be effectively solved; in the invention, a proper amount of substances are cooperatively matched and mutually supplemented in performance, so that the finally prepared concrete finished product has good durability and impermeability.

Preferably, the composition comprises the following components in parts by weight,

330-370 parts of broken stone, 250-300 parts of cement, 90-110 parts of fly ash, 65-75 parts of quartz sand, 11-14 parts of titanium nitride powder, 53-68 parts of calcium carbonate powder, 11-12 parts of alumina fiber, 9-11 parts of hydroxypropyl starch ether, 8.5-9.5 parts of a water reducing agent, 0.6-0.8 part of an air entraining material, 4-7 parts of micropore sintering particles, 6-7 parts of magnesium oxide, 2-4 parts of zinc stearate and 120-140 parts of water.

Preferably, the composition comprises the following components in parts by weight,

350 parts of broken stone, 280 parts of cement, 100 parts of fly ash, 70 parts of quartz sand, 13 parts of titanium nitride powder, 60 parts of calcium carbonate powder, 11.5 parts of alumina fiber, 10 parts of hydroxypropyl starch ether, 9 parts of water reducing agent, 0.7 part of air entraining material, 5 parts of microporous sintered particles, 6.5 parts of magnesium oxide, 3 parts of zinc stearate and 130 parts of water. The proportion is further adjusted in the original ingredients, the prepared concrete is dried, the durability is better, the adsorbability of the micropore sintering particles is stronger, the air in the concrete can be better reduced, and the impermeability of the concrete is improved.

Preferably, the water reducing agent consists of the following raw materials in parts by weight,

2-6 parts of a polycarboxylic acid water reducing agent, 4-5 parts of potassium sulfite and 1-3 parts of polyacrylamide. The water reducing agent formed by reasonably proportioning various substances can promote the toughness of the micropore sintering particles to be further enhanced, and the bending resistance degree of the concrete finished product is improved.

Preferably, the water reducing agent consists of the following raw materials in parts by weight,

3-5 parts of polycarboxylic acid water reducing agent, 4.2-4.8 parts of potassium sulfite and 1.5-2.5 parts of polyacrylamide.

Preferably, the water reducing agent consists of the following raw materials in parts by weight,

4 parts of polycarboxylic acid water reducing agent, 4.5 parts of potassium sulfite and 2 parts of polyacrylamide.

Preferably, the microporous sintered particles are composed of the following raw materials in parts by weight,

1-1.5 parts of bentonite, 2.5-4.5 parts of nano silicon dioxide powder and 0.5-0.8 part of starch. In the preparation process of the microporous sintered particles, the mass ratio of the bentonite, the nano silicon dioxide and the starch can influence the impermeability and the mechanical property of the concrete, and the impermeability of the concrete can be effectively improved; the microporous sintered particles prepared from the bentonite, the nano silicon dioxide and the starch in proper parts can also effectively adsorb water, the water can be slowly released in the concrete solidification process, and the humidity in the concrete is kept so as to be beneficial to the solidification of the concrete.

Preferably, the microporous sintered particles are composed of the following raw materials in parts by weight,

1.3 parts of bentonite, 3 parts of nano silicon dioxide powder and 0.6 part of starch. The microporous sintered particles prepared from the bentonite, the nano silicon dioxide and the starch in limited parts can better improve the impermeability and the durability of concrete.

Preferably, the preparation of the microporous sintered particles comprises the steps of,

(a) weighing appropriate parts of bentonite, nano silicon dioxide powder and starch, and placing the bentonite, the nano silicon dioxide powder and the starch in a sintering container;

(b) mixing the materials in the sintering container in the step (a), and sintering at the temperature of 1000-1200 ℃ to obtain a sintered body with a microporous structure;

(c) and (c) crushing the sintered body with the micropore structure in the step (b) to obtain micropore sintered particles.

The loose and porous microporous sintered particles prepared by the method have better active carbon effect, and can absorb redundant air so as to reduce the air in concrete and improve the impermeability of the concrete; the microporous sintered particles prepared by the invention can effectively adsorb moisture, and the moisture can be slowly released in the concrete solidification process, so that the internal humidity of the concrete can be kept to facilitate the solidification of the concrete, and the impermeability of the concrete can be improved.

The second technical scheme of the invention is as follows: a method for preparing concrete with high-performance impermeability comprises the following steps,

(S01) placing the microporous sintered pellets in a pulverizing box on a supporting arm of the pulverizing box;

(S02) starting a crushing mechanism in the crushing box to further crush the microporous sintered particles in the crushing box;

(S03) weighing the further crushed microporous sintered particles by pressure and transferring the weighed microporous sintered particles into a stirring box body;

(S04) adding acid into the stirring box body through a water feeding mechanism, and soaking the microporous sintered particles;

(S05) taking a proper amount of crushed stone, cement, fly ash, quartz sand, titanium nitride powder, calcium carbonate powder, alumina fiber, hydroxypropyl starch ether, a water reducing agent, an air entraining material, microporous sintered particles, magnesium oxide and zinc stearate, respectively adding the materials into corresponding crushing boxes, and starting a crushing mechanism to crush the added corresponding materials;

(S06) weighing the crushed corresponding materials in the step (S05) by pressure weighing, and transferring the weighed materials into the stirring box in the step (S04);

(S07) the T-shaped stirring pushing teeth on the stirring piece and the cross-shaped stirring piece are transmitted to stir the mixture in the stirring box body in the step (S06), a proper amount of water is added through the water feeding mechanism in the stirring process, and the concrete with high impermeability is obtained after the stirring is finished. The method can quickly prepare the concrete with high performance and impermeability, has the characteristics of short construction period, high quality and saving of a large amount of manpower and material resources, has high plasticity and better durability of the prepared concrete, can keep the humidity in the concrete to be beneficial to curing of the concrete, and can improve the impermeability of the concrete.

The third technical scheme of the invention is as follows: a concrete manufacturing device with high-performance impermeability comprises a crushing box supporting arm and a stirring box body arranged on one side of the crushing box supporting arm, wherein a plurality of crushing boxes are arranged on the crushing box supporting arm, a crushing mechanism is arranged inside each crushing box and is used for crushing raw materials, a conveying stirring piece is rotatably arranged inside each stirring box and comprises a conveying roller and a stirring roller, and the conveying stirring piece is used for mixing and stirring the raw materials;

the stirring roller is provided with a plurality of T-shaped stirring pushing teeth, the T-shaped stirring pushing teeth are provided with material passing ports, a cross-shaped stirring piece is fixedly arranged between every two T-shaped stirring pushing teeth, and a plurality of stirring rods are arranged on the cross-shaped stirring piece;

the crushing mechanism comprises a crushing motor and a grinding hammer, the crushing motor is fixedly arranged on the upper side surface of the crushing box, an output end of the crushing motor is provided with a special-shaped cam, the special-shaped cam is rotatably connected with the upper side surface of the grinding hammer through a grinding hammer connecting rod, the crushing motor is used for pushing the grinding hammer to move downwards, and the grinding hammer is fixedly provided with grinding teeth;

a crushing bin is arranged in the crushing box, a crushing box inlet is arranged on the upper side surface of the crushing box, the crushing box inlet is communicated with the crushing bin, and the grinding hammer is arranged in the crushing bin;

a feeding plate is arranged below the crushing bin, a positioning pushing piece is fixedly arranged on one side of the feeding plate, and a pressure scale is fixedly arranged on the upper side face of the feeding plate.

In the processing process of the concrete, various raw materials are not required to be crushed and weighed in advance, the raw materials are directly added into the corresponding crushing box and are automatically and simultaneously crushed by the crushing mechanism in the crushing box, so that the crushing efficiency is greatly improved; according to the invention, different raw materials are respectively placed into different crushing boxes, the grinding hammer on the crushing mechanism crushes various materials, the crushed raw materials are weighed through the pressure scale, the crushed raw materials can be directly discharged into the stirring box body for stirring, the automation degree is very high, and the use convenience and the processing efficiency are greatly improved; the supporting arm of the crushing box rotates through the supporting column of the feeding machine, the crushing box is further arranged on the supporting arm of the crushing box, the crushing mechanism is arranged inside the crushing box, various materials are sequentially placed into the crushing bin through the inlet of the crushing box, then the raw materials are crushed through the grinding hammer on the crushing mechanism, the crushed materials are transmitted into the stirring box body through the conveying roller, and the concrete is stirred by the stirring roller, so that the structure is simple, the automation degree is high, the adding sequence of the materials is not influenced, and the processing efficiency of the concrete can be greatly improved; according to the invention, the required materials can be directly weighed, additional measurement is not needed, the convenience of operation and the production efficiency are greatly improved, after the raw materials are placed in the crushing bin, the crushing motor on the crushing mechanism is started to drive the special-shaped cam to rotate, the special-shaped cam drives the grinding hammer to move up and down through the grinding hammer connecting rod, and the grinding teeth on the grinding hammer can crush various materials, so that the raw materials are not needed to be added into the stirring box body after being crushed, and the processing efficiency is greatly improved; simultaneously, raw and other materials can directly be arranged into the stirring box after smashing in the inside of smashing the storehouse, and degree of automation is very high, promotes the convenience of using greatly.

As preferred, smash the case support arm and be connected with a feeder brace table through the support arm driving medium, the upper end of a feeder brace table is connected with the feeder support column, the upper end of feeder support column through the support arm rotate the motor with the support arm driving medium rotates to be connected, the inside of a feeder brace table is equipped with first agitator motor, the fixed second agitator motor that is provided with in inside of first agitator motor, the output of second agitator motor with transfer roller fixed connection. Simple structure drives the rotation that can drive the stirring roller again when the transfer roller through second agitator motor, promotes the utilization ratio of resource greatly.

Preferably, the positioning pushing piece comprises a positioning base and an electric telescopic rod, the electric telescopic rod is fixedly arranged on one side of the feeding plate, the output end of the electric telescopic rod is connected with a material pushing plate, the material pushing plate is arranged on the upper side surface of the feeding plate in a sliding mode, and a waterproof cushion pad is fixedly arranged on one side surface, away from the electric telescopic rod, of the material pushing plate;

the fixed setting of location base is in the side of going up of feeder brace table, the location base is close to one side of agitator tank is provided with infrared emitter, electric telescopic handle is close to a fixed infrared receiver that is provided with in a side of feeder brace table, infrared emitter with infrared receiver is corresponding. The crushing box can rotate around a supporting arm transmission part on a supporting arm of the crushing box in the process of crushing raw materials, namely, the crushed raw materials can be rotated to an inlet of the stirring box body through the rotation of the crushing box, after the raw materials in the crushing bin are crushed, the crushed raw materials can directly slide onto the feeding plate and can be weighed through a pressure scale on the feeding plate, so that the raw materials do not need to be weighed additionally, and the use convenience is greatly improved; after weighing is finished, raw materials on the feeding plate of the feeding plate are pushed to the port of the stirring box body through the material pushing plate on the electric telescopic rod, manual addition is not needed, and the use convenience and the processing efficiency are improved; infrared emitter on the location base is corresponding with the infrared receiver on the electric telescopic handle, in case infrared receiver receives infrared emitter information, just makes electric telescopic handle promote the scraping wings, with the port department that stirring box was carried to raw and other materials propelling movement on the feeding plate, degree of automation is high, promotes the convenience of using greatly.

Preferably, the upper end of the supporting platform of the feeder is provided with a water feeding mechanism, and the water feeding mechanism comprises a water feeding pump and a water spraying head;

the water supply device comprises a water supply tank, a stirring tank body, a water supply pump, a water supply tank, a water passing bottom plate, a stirring wheel, a filtering plate and a plurality of filtering holes, wherein the water feeding pump is connected with the input end of the water supply pump;

the stirring tank is characterized in that a water filling port is formed in the upper side face of the interior of the stirring tank body, the water spraying head is fixedly arranged in the water filling port, the water feeding pump is communicated with the water spraying head through a liquid conveying pipe, and a heating ring is fixedly arranged on the liquid conveying pipe and used for heating the liquid conveying pipe. Liquid such as water, acid and the like is absorbed by a water feeding pump on the water feeding mechanism and is uniformly sprayed on the mixed raw materials through a plurality of water spraying heads, so that the stirring is more uniform, and the quality of concrete is improved; the stirring wheel can stir the material, and filter mantle, filter and filtration pore can prevent effectively that impurity from entering into the inside of water pump, the security that hoisting device used.

Preferably, a bearing is fixedly arranged at the joint of the stirring roller and the stirring box body, a plurality of air pressure holes are formed in the stirring box body above the bearing, and a discharge door body is rotatably arranged below the bearing;

the below of stirring roller is in the inside of agitator tank is provided with transport mechanism, transport mechanism includes straight section of thick bamboo motor and rotates the setting and is in conveyer belt on the straight section of thick bamboo motor, the inside of agitator tank is provided with a plurality of guided ways, the guided way sets up the inside of conveyer belt, the fixed waterproof layer that is provided with of lateral surface of conveyer belt. The waterproof layer can prevent that the material gathering from condensing, and the atmospheric pressure hole is convenient for balance stirring box and outside atmospheric pressure, and the concrete discharge after the material door body is convenient to mix is arranged, and transport mechanism can pass through the conveyer belt with the concrete that the stirring was ended and transmit to row material door body department, discharges after the stirring, and simple structure promotes the convenience of using.

The invention has the following beneficial effects:

(1) the air entraining material with a proper amount of parts is added into the traditional concrete raw material, so that the plasticity of the concrete can be improved, and the prepared concrete has better durability;

(2) by adding a proper amount of microporous sintered particles, the loose and porous microporous sintered particles have the effect of activated carbon, and can absorb redundant air so as to reduce the air in the concrete and improve the impermeability of the concrete; the microporous sintered particles can also effectively adsorb water, and the water can be slowly released in the concrete solidification process, so that the internal humidity of the concrete can be maintained to facilitate the solidification of the concrete, the impermeability of the concrete can be improved, and the problems of concrete collapse, flowability and the like can be effectively solved;

(3) the substances in proper parts are cooperated and supplemented with each other in performance, so that the finally prepared concrete finished product has good durability and impermeability;

(4) the method can quickly prepare the concrete with high performance and impermeability, has the characteristics of short construction period, high quality and saving of a large amount of manpower and material resources, has high plasticity and better durability of the prepared concrete, can maintain the humidity in the concrete to be beneficial to the solidification of the concrete, and can improve the impermeability of the concrete;

(5) as various raw materials are not required to be crushed and weighed in advance in the processing process of the concrete, the raw materials are directly added into the corresponding crushing box and are automatically and simultaneously crushed by the crushing mechanism in the crushing box, so that the crushing efficiency is greatly improved;

(6) after different raw materials are respectively placed into different crushing boxes, a grinding hammer on a crushing mechanism crushes various materials, the crushed raw materials are weighed through a pressure scale, the crushed raw materials can be directly discharged into a stirring box body to be stirred, the automation degree is high, and the use convenience and the processing efficiency are greatly improved;

(7) the supporting arm of the crushing box rotates through the supporting column of the feeding machine, the crushing box is also arranged on the supporting arm of the crushing box, the crushing mechanism is arranged in the crushing box, various materials are sequentially placed into the crushing bin through the inlet of the crushing box, then the raw materials are crushed through a grinding hammer on the crushing mechanism, the crushed materials are transmitted into the stirring box body through the conveying roller, and the concrete is stirred by the stirring roller, so that the structure is simple, the automation degree is high, the adding sequence of the materials is not influenced, and the efficiency of concrete processing can be greatly improved;

(8) the required materials can be directly weighed, additional measurement is not needed, the convenience of operation and the production efficiency are greatly improved, after the raw materials are placed in the crushing bin, the crushing motor on the crushing mechanism is started to drive the special-shaped cam to rotate, the special-shaped cam drives the grinding hammer to move up and down through the grinding hammer connecting rod, and the grinding teeth on the grinding hammer can crush various materials, so that the raw materials are not needed to be added into the stirring box body after being crushed, and the processing efficiency is greatly improved; simultaneously, raw and other materials can directly be arranged into the stirring box after smashing in the inside of smashing the storehouse, and degree of automation is very high, promotes the convenience of using greatly.

Drawings

FIG. 1 is a cross-sectional view of the present invention;

FIG. 2 is a drive diagram of the shredder mechanism of the present invention;

FIG. 3 is an enlarged view taken at A in FIG. 1;

FIG. 4 is a top plan view of the crush box support arms of the present invention;

FIG. 5 is a perspective view of a stirring roller of the present invention;

FIG. 6 is a cross-sectional view of a stirring roller of the present invention;

FIG. 7 is a schematic view of a positioning pusher of the present invention;

FIG. 8 is a schematic view of a positioning pusher of the present invention;

fig. 9 is a cross-sectional view of a filter cage of the present invention.

The labels in the figures are: 1-a feeder support table; 101-feeder support column; 102-a first stirring motor; 2-stirring the tank body; 202-a discharge door body; 203-water injection port; 204-air pressure hole; 3-crushing box supporting arms; 301-a support arm transmission; 4-crushing box; 401-crush box inlet; 402-a crushing bin; 403-a feeding plate; 5-a crushing mechanism; 501-a crushing motor; 502-a shaped cam; 503-grinding hammer connecting rod; 6-conveying the stirring piece; 601-a transfer roll; 602-a stirring roller; 603-a material passing port; 7-positioning the pushing member; 701-positioning a base; 702-an electric telescopic rod; 703-a pusher plate; 704-an infrared emitter; 705-infrared receiver; 8-a water feeding mechanism; 801-water pump; 802-sprinkler head; 803-an infusion tube; 9-a bearing; 10-grinding hammer; 11-grinding teeth; 12-weighing under pressure; 13-waterproof buffer pads; 14-a support arm rotation motor; 15-heating ring; 16-T type stirring pushing teeth; 17-cross stirring piece; 18-a stirring rod; 19-a second agitator motor; 20-a transport mechanism; 21-a straight barrel motor; 22-a conveyor belt; 23-a waterproof layer; 24-a guide rail; 25-a water supply tank; 26-a filter mantle; 27-water passing bottom plate; 28-stirring wheel; 29-a filter plate; 30-filtration pores.

Detailed Description

The present invention will be further described with reference to the following examples and drawings, but the present invention is not limited thereto.

A concrete with high-performance impermeability comprises the following components in parts by weight,

300-400 parts of broken stone, 220-320 parts of cement, 80-120 parts of fly ash, 60-80 parts of quartz sand, 10-15 parts of titanium nitride powder, 50-60 parts of calcium carbonate powder, 10-13 parts of alumina fiber, 8-12 parts of hydroxypropyl starch ether, 8-10 parts of a water reducing agent, 0.5-1 part of an air entraining material, 3-8 parts of micropore sintering particles, 5-8 parts of magnesium oxide, 1-5 parts of zinc stearate and 110-150 parts of water.

A concrete with high-performance impermeability comprises the following components in parts by weight,

330-370 parts of broken stone, 250-300 parts of cement, 90-110 parts of fly ash, 65-75 parts of quartz sand, 11-14 parts of titanium nitride powder, 53-68 parts of calcium carbonate powder, 11-12 parts of alumina fiber, 9-11 parts of hydroxypropyl starch ether, 8.5-9.5 parts of a water reducing agent, 0.6-0.8 part of an air entraining material, 4-7 parts of micropore sintering particles, 6-7 parts of magnesium oxide, 2-4 parts of zinc stearate and 120-140 parts of water.

A concrete with high-performance impermeability comprises the following components in parts by weight,

350 parts of broken stone, 280 parts of cement, 100 parts of fly ash, 70 parts of quartz sand, 13 parts of titanium nitride powder, 60 parts of calcium carbonate powder, 11.5 parts of alumina fiber, 10 parts of hydroxypropyl starch ether, 9 parts of water reducing agent, 0.7 part of air entraining material, 5 parts of microporous sintered particles, 6.5 parts of magnesium oxide, 3 parts of zinc stearate and 130 parts of water.

The water reducing agent is composed of the following raw materials in parts by weight,

2-6 parts of a polycarboxylic acid water reducing agent, 4-5 parts of potassium sulfite and 1-3 parts of polyacrylamide.

The water reducing agent is composed of the following raw materials in parts by weight,

3-5 parts of polycarboxylic acid water reducing agent, 4.2-4.8 parts of potassium sulfite and 1.5-2.5 parts of polyacrylamide.

The water reducing agent is composed of the following raw materials in parts by weight,

4 parts of polycarboxylic acid water reducing agent, 4.5 parts of potassium sulfite and 2 parts of polyacrylamide.

The microporous sintered particles are composed of the following raw materials in parts by weight,

1-1.5 parts of bentonite, 2.5-4.5 parts of nano silicon dioxide powder and 0.5-0.8 part of starch.

The microporous sintered particles are composed of the following raw materials in parts by weight,

1.3 parts of bentonite, 3 parts of nano silicon dioxide powder and 0.6 part of starch.

The preparation of the microporous sintered particles comprises the following steps,

(a) weighing appropriate parts of bentonite, nano silicon dioxide powder and starch, and placing the bentonite, the nano silicon dioxide powder and the starch in a sintering container;

(b) mixing the materials in the sintering container in the step (a), and sintering at the temperature of 1000-1200 ℃ to obtain a sintered body with a microporous structure;

(c) crushing the sintered body with the micropore structure in the step (b) to obtain micropore sintered particles;

a method for preparing concrete with high-performance impermeability comprises the following steps,

(S01) placing the microporous sintered pellets in the crush boxes 4 on the crush box support arms 3;

(S02) starting the pulverization mechanism 5 in the pulverization box 4 to further pulverize the microporous sintered particles in the pulverization box 4;

(S03) weighing the further crushed microporous sintered particles by a pressure scale 12, and transferring the weighed microporous sintered particles into a stirring box body 2;

(S04) adding acid into the stirring box body 2 through the water feeding mechanism 8, and soaking the microporous sintered particles;

(S05) taking a proper amount of crushed stone, cement, fly ash, quartz sand, titanium nitride powder, calcium carbonate powder, alumina fiber, hydroxypropyl starch ether, a water reducing agent, an air entraining material, microporous sintered particles, magnesium oxide and zinc stearate, respectively adding the materials into a crushing box 4, and starting a crushing mechanism 5 to crush the added corresponding materials;

(S06) weighing the crushed corresponding materials in the step (S05) by a pressure scale 12, and transferring the weighed materials into the stirring box body 2 in the step (S04);

(S07) the T-shaped stirring pushing teeth 16 and the cross-shaped stirring piece 17 on the stirring piece 6 are conveyed to stir the mixture in the stirring box body 2 in the step (S06), a proper amount of water is added through the water feeding mechanism 8 in the stirring process, and after the stirring is finished, the concrete with high impermeability is obtained.

A concrete manufacturing device with high-performance impermeability comprises a crushing box supporting arm 3 and a stirring box body 2 arranged on one side of the crushing box supporting arm 3, wherein a plurality of crushing boxes 4 are arranged on the crushing box supporting arm 3, a crushing mechanism 5 is arranged inside each crushing box 4, each crushing mechanism 5 is used for crushing raw materials, a conveying stirring piece 6 is rotatably arranged inside the stirring box body 2, each conveying stirring piece 6 comprises a conveying roller 601 and a stirring roller 602, and each conveying stirring piece 6 is used for mixing and stirring the raw materials;

the stirring roller 602 is provided with a plurality of T-shaped stirring pushing teeth 16, the T-shaped stirring pushing teeth 16 are provided with a material passing port 603, a cross-shaped stirring part 17 is fixedly arranged between every two T-shaped stirring pushing teeth 16, and the cross-shaped stirring part 17 is provided with a plurality of stirring rods 18.

Crushing case support arm 3 is connected with a feeder supporting table 1 through support arm driving medium 301, the upper end of a feeder supporting table 1 is connected with a feeder support column 101, the upper end of a feeder support column 101 is connected with support arm driving medium 301 through support arm rotation motor 14 in a rotating manner, the inside of a feeder supporting table 1 is equipped with first agitator motor 102, the inside of first agitator motor 102 is fixed and is provided with second agitator motor 19, the output and the transfer roller 601 fixed connection of second agitator motor 19.

The crushing mechanism 5 comprises a crushing motor 501 and a grinding hammer 10, the crushing motor 501 is fixedly arranged on the upper side surface of the crushing box 4, a special-shaped cam 502 is arranged at the output end of the crushing motor 501, the special-shaped cam 502 is rotatably connected with the upper side surface of the grinding hammer 10 through a grinding hammer connecting rod 503, the crushing motor 501 is used for pushing the grinding hammer 10 to move downwards, and grinding teeth 11 are fixedly arranged on the grinding hammer 10;

a crushing bin 402 is arranged in the crushing bin 4, a crushing bin inlet 401 is arranged on the upper side surface of the crushing bin 4, the crushing bin inlet 401 is communicated with the crushing bin 402, and the grinding hammer 10 is arranged in the crushing bin 402;

a feeding plate 403 is arranged below the crushing bin 402, a positioning pushing piece 7 is fixedly arranged on one side of the feeding plate 403, and a pressure scale 12 is fixedly arranged on the upper side surface of the feeding plate 403.

The positioning pushing piece 7 comprises a positioning base 701 and an electric telescopic rod 702, the electric telescopic rod 702 is fixedly arranged on one side of the feeding plate 403, the output end of the electric telescopic rod 702 is connected with a material pushing plate 703, the material pushing plate 703 is arranged on the upper side surface of the feeding plate 403 in a sliding manner, and a waterproof cushion pad 13 is fixedly arranged on one side surface of the material pushing plate 703 away from the electric telescopic rod 702;

the positioning base 701 is fixedly arranged on the upper side face of the feeder supporting table 1, an infrared emitter 704 is arranged on one side, close to the stirring tank body 2, of the positioning base 701, an infrared receiver 705 is fixedly arranged on one side face, close to the feeder supporting table 1, of the electric telescopic rod 702, and the infrared emitter 704 corresponds to the infrared receiver 705.

The upper end of the feeder supporting table 1 is provided with a water feeding mechanism 8, and the water feeding mechanism 8 comprises a water feeding pump 801 and a water spraying head 802;

the input end of the water feeding pump 801 is connected with a filter cover 26, the upper part of the stirring box body 2 is connected with a water feeding tank 25, the filter cover 26 is arranged inside the water feeding tank 25, the upper end of the filter cover 26 is provided with a water passing bottom plate 27, the water passing bottom plate 27 is communicated with the water feeding pump 801, a stirring wheel 28 is fixedly arranged on the water passing bottom plate 27 inside the filter cover 26, a filter plate 29 is arranged between the water passing bottom plate 27 and the stirring wheel 28, and a plurality of filter holes 30 are formed in the filter plate 29;

the upper side surface in the stirring box body 2 is provided with a water filling opening 203, a water spraying head 802 is fixedly arranged in the water filling opening 203, a water feeding pump 801 is communicated with the water spraying head 802 through a liquid conveying pipe 803, a heating ring 15 is fixedly arranged on the liquid conveying pipe 803, and the heating ring 15 is used for heating the liquid conveying pipe 803.

A bearing 9 is fixedly arranged at the joint of the stirring roller 602 and the stirring box body 2, a plurality of air pressure holes 204 are formed in the stirring box body 2 above the bearing 9, and a discharge door body 202 is rotatably arranged below the bearing 9;

the inside of agitator tank 2 is provided with transport mechanism 20 in the below of stirring roller 602, and transport mechanism 20 includes straight section of thick bamboo motor 21 and rotates the conveyer belt 22 that sets up on straight section of thick bamboo motor 21, and the inside of agitator tank 2 is provided with a plurality of guided ways 24, and guided way 24 sets up the inside at conveyer belt 22, and the lateral surface of conveyer belt 22 is fixed and is provided with waterproof layer 23.

A concrete manufacturing device with high-performance impermeability comprises a crushing box supporting arm 3 and a stirring box body 2 arranged on one side of the crushing box supporting arm 3, wherein a plurality of crushing boxes 4 which are centrosymmetric are arranged on the crushing box supporting arm 3, a crushing mechanism 5 is arranged inside each crushing box 4, each crushing mechanism 5 is used for crushing raw materials, a conveying stirring piece 6 is rotatably arranged inside each stirring box body 2, each conveying stirring piece 6 comprises a conveying roller 601 and a stirring roller 602, each conveying stirring piece 6 is used for mixing and stirring the raw materials, T-shaped stirring pushing teeth 16 which are symmetrically distributed are arranged on each stirring roller 602, a material passing port 603 is formed in each T-shaped stirring pushing tooth 16, a cross-shaped stirring piece 17 is fixedly arranged between every two T-shaped stirring pushing teeth 16, and stirring rods 18 which are centrosymmetric are arranged on each cross-shaped stirring piece 17;

various raw materials are required to be crushed and weighed in the processing process of the concrete, so that the working efficiency is greatly reduced, the various materials are required to be crushed firstly and then added into the stirring box body 2 in sequence, and a certain sequence is required in the adding process;

smash case support arm 3 and rotate through feeder support column 101, and still be provided with on smashing case support arm 3 and smash case 4, the inside of smashing case 4 is provided with rubbing crusher structure 5, loop through the inside that smashes case entry 401 and put into crushing storehouse 402 with various materials, then smash raw and other materials through grinding hammer 10 on rubbing crusher structure 5, transmit the inside to agitator tank 2 through transfer roller 601 after smashing, and utilize agitator roller 602 to stir the concrete, moreover, the steam generator is simple in structure, the automation degree is high, neither influence the joining order of material, can promote the efficiency of concrete processing again by a wide margin.

Crushing case support arm 3 is connected with a feeder supporting table 1 through support arm driving medium 301, the upper end that a feeder supporting table 1 is connected with feeder support column 101, the upper end of feeder support column 101 is passed through the support arm and is rotated motor 14 and support arm driving medium 301 and rotate and be connected, first agitator motor 102 has been seted up to a feeder supporting table 1's inside, the fixed second agitator motor 19 that is provided with in inside of first agitator motor 102, the output and the transfer roller 601 fixed connection of second agitator motor 19, moreover, the steam generator is simple in structure, can drive the rotation of stirring roller 602 again when driving transfer roller 601 through agitator motor 19, promote the utilization ratio of resource greatly.

The crushing mechanism 5 comprises a crushing motor 501 and a grinding hammer 10, the crushing motor 501 is fixedly arranged on the upper side surface of the crushing box 4, an output end of the crushing motor 501 is provided with a special-shaped cam 502, the special-shaped cam 502 is rotatably connected with the upper side surface of the grinding hammer 10 through a grinding hammer connecting rod 503, the crushing motor 501 is used for pushing the grinding hammer 10 to move downwards, the grinding hammer 10 is fixedly provided with grinding teeth 11, a crushing bin 402 is arranged in the crushing box 4, a crushing bin inlet 401 is arranged on the upper side surface of the crushing box 4, the crushing bin inlet 401 is communicated with the crushing bin 402, the grinding hammer 10 is arranged in the crushing bin 402, a feeding plate 403 is arranged below the crushing bin 402, one side of the feeding plate 403 is fixedly provided with a positioning pushing piece 7, and the upper side surface of the feeding plate 403 is fixedly provided with a pressure scale 403;

after raw materials are placed in the crushing bin 402, the crushing motor 501 on the crushing mechanism 5 is started to drive the special-shaped cam 502 to rotate, the special-shaped cam 502 drives the grinding hammer 10 to move up and down through the grinding hammer connecting rod 503, and the grinding teeth 11 on the grinding hammer 10 can crush various materials, so that the raw materials do not need to be crushed and then added into the stirring box body 2, and the processing efficiency is greatly improved;

raw and other materials can directly be arranged into agitator tank 2 after being smashed in the inside of smashing storehouse 402 inside, and degree of automation is very high, promotes the convenience of using greatly.

The positioning pushing piece 7 comprises a positioning base 701 and an electric telescopic rod 702, the electric telescopic rod 702 is fixedly arranged on one side of a feeding plate 403, the output end of the electric telescopic rod 702 is connected with a material pushing plate 703, the material pushing plate 703 is arranged on the upper side surface of the feeding plate 403 in a sliding manner, a waterproof buffer cushion 13 is fixedly arranged on one side surface of the material pushing plate 703 away from the electric telescopic rod 702, the positioning base 701 is fixedly arranged on the upper side surface of a feeding machine supporting table 1, an infrared emitter 704 is arranged on one side of the positioning base 701 close to a stirring box body 2, an infrared receiver 705 is fixedly arranged on one side surface of the electric telescopic rod 702 close to the feeding machine supporting table 1, and the infrared emitter 704 corresponds to the infrared receiver 705;

the crushing box 4 can rotate around the supporting arm transmission part 301 on the crushing box supporting arm 3 in the process of crushing raw materials, namely, the crushed raw materials can be rotated to an inlet of the stirring box body 2 through the rotation of the crushing box 4, after the raw materials in the crushing bin 402 are crushed, the crushed raw materials can directly slide onto the feeding plate 403, and the crushed raw materials can be weighed through the pressure scale 12 on the feeding plate 403, so that the raw materials do not need to be weighed additionally, and the use convenience is greatly improved;

after weighing is finished, raw materials on the feeding plate 403 are pushed to the port of the stirring box body 2 through the pushing plate 703 on the electric telescopic rod 702 without manual addition, so that the use convenience and the processing efficiency are improved;

the infrared emitter 704 on the positioning base 701 corresponds to the infrared receiver 705 on the electric telescopic rod 702, once the infrared receiver 705 receives the information of the infrared emitter 704, the electric telescopic rod 702 pushes the material pushing plate 703 to push the raw materials on the material feeding plate 403 to the port of the stirring box body 2, the automation degree is high, and the use convenience is greatly improved.

The upper end of the feeder supporting table 1 is provided with a water feeding mechanism 8, the water feeding mechanism 8 comprises a water feeding pump 801 and a water spray nozzle 802, the input end of the water feeding pump 801 is connected with a filter cover 26, the upper part of the stirring box body 2 is connected with a water feeding tank 25, the filter cover 26 is arranged inside the water feeding tank 25, the upper end of the filter cover 26 is provided with a water passing bottom plate 27, the water passing bottom plate 27 is communicated with the water feeding pump 801, a stirring wheel 28 is fixedly arranged on the water passing bottom plate 27 inside the filter cover 26, a filter plate 29 is arranged between the water passing bottom plate 27 and the stirring wheel 28, the filter plate 29 is provided with a plurality of filter holes 30 which are centrosymmetric, water can be stirred, medicines can be dissolved in the water as much as possible during the process, meanwhile, impurities can be prevented from entering the inside the water feeding pump 801, and the use safety of the device is improved;

the upper side surface in the stirring box body 2 is provided with a water filling opening 203, a water spraying head 802 is fixedly arranged in the water filling opening 203, a water feeding pump 801 is communicated with the water spraying head 802 through a liquid conveying pipe 803, a heating ring 15 is fixedly arranged on the liquid conveying pipe 803, and the heating ring 15 is used for heating the liquid conveying pipe 803.

Liquid such as water, acid and the like is absorbed by the water supply pump 801 on the water supply mechanism 8 and is uniformly sprayed on the mixed raw materials through the plurality of water spraying heads 802, so that the stirring is more uniform, and the quality of concrete is improved.

Fixed bearing 9 that is provided with in the junction of stirring roller 602 and agitator tank 2, a plurality of atmospheric pressure hole 204 has been seted up to bearing 9's top on agitator tank 2, bearing 9's below is rotated the below that is provided with row material door body 202 stirring roller 602 and is provided with transport mechanism 20 in agitator tank 2's inside, transport mechanism 20 includes straight section of thick bamboo motor 21 and rotates the conveyer belt 22 that sets up on straight section of thick bamboo motor 21, agitator tank 2's inside is provided with a plurality of guided way 24, guided way 24 sets up the inside at conveyer belt 22, the fixed waterproof layer 23 that is provided with of lateral surface of conveyer belt 22, atmospheric pressure hole 204 is convenient for balance agitator tank 2 and outside atmospheric pressure, it conveniently discharges the concrete after mixing to arrange material door body 202, transport mechanism 20 can transmit the concrete that the stirring was ended to row material door body 202 department through conveyer belt 22, discharge after the stirring, moreover, the steam generator is simple in structure, promote the convenience of use.

The working principle of the invention is as follows:

the crushing box supporting arm 3 is also provided with a crushing box 4, the crushing mechanism 5 is arranged in the crushing box 4, various materials are sequentially placed into the crushing bin 402 through the crushing box inlet 401, then the raw materials are crushed through the grinding hammer 10 on the crushing mechanism 5, the crushed raw materials are transmitted into the stirring box body 2 through the conveying roller 601, and the concrete is stirred through the stirring roller 602, so that the structure is simple, the automation degree is high, the adding sequence of the materials is not influenced, and the concrete processing efficiency can be greatly improved;

the raw and other materials after smashing can directly the landing to the flitch 403 on, and can weigh the raw and other materials after smashing through the pressure on the flitch 403 is called 12, after weighing, the port department that pushes away the raw and other materials on the flitch feed plate 403 to agitator tank 2 through flitch 703 on the electric telescopic handle 702, need not manual interpolation, infrared emitter 704 on the location base 701 is corresponding with infrared receiver 705 on the electric telescopic handle 702, in case infrared receiver 705 receives infrared emitter 704 information and just makes electric telescopic handle 702 promote the flitch 703 and push away the raw and other materials on the flitch 403 to the port department of agitator tank 2, degree of automation is high, promote the convenience of use greatly.

Example 1:

a concrete with high-performance impermeability comprises the following components in parts by weight,

300 parts of crushed stone, 220 parts of cement, 80 parts of fly ash, 60 parts of quartz sand, 10 parts of titanium nitride powder, 50 parts of calcium carbonate powder, 10 parts of alumina fiber, 8 parts of hydroxypropyl starch ether, 0.5 part of air entraining material, 5 parts of magnesium oxide, 1 part of zinc stearate and 110 parts of water; 2 parts of a polycarboxylic acid water reducing agent, 4 parts of potassium sulfite and 1 part of polyacrylamide; 4 parts of microporous sintered particles.

The preparation of the microporous sintered particles comprises the following steps,

(a) weighing 1 part of bentonite, 2.5 parts of nano silicon dioxide powder and 0.5 part of starch, and placing the materials in a sintering container;

(b) mixing the materials in the sintering container in the step (a), and sintering at 1100 ℃ to obtain a sintered body with a microporous structure;

(c) and (c) crushing the sintered body with the micropore structure in the step (b) to obtain micropore sintered particles.

A method for preparing concrete with high-performance impermeability comprises the following steps,

(S01) placing the microporous sintered pellets in the crush boxes 4 on the crush box support arms 3;

(S02) starting the pulverization mechanism 5 in the pulverization box 4 to further pulverize the microporous sintered particles in the pulverization box 4;

(S03) weighing the further crushed microporous sintered particles by a pressure scale 12, and transferring the weighed microporous sintered particles into a stirring box body 2;

(S04) adding acid into the stirring box body 2 through the water feeding mechanism 8, and soaking the microporous sintered particles;

(S05) taking a proper amount of crushed stone, cement, fly ash, quartz sand, titanium nitride powder, calcium carbonate powder, alumina fiber, hydroxypropyl starch ether, a water reducing agent, an air entraining material, microporous sintered particles, magnesium oxide and zinc stearate, respectively adding the materials into a crushing box 4, and starting a crushing mechanism 5 to crush the added corresponding materials;

(S06) weighing the crushed corresponding materials in the step (S05) by a pressure scale 12, and transferring the weighed materials into the stirring box body 2 in the step (S04);

(S07) the T-shaped stirring pushing teeth 16 and the cross-shaped stirring piece 17 on the stirring piece 6 are conveyed to stir the mixture in the stirring box body 2 in the step (S06), a proper amount of water is added through the water feeding mechanism 8 in the stirring process, and after the stirring is finished, the concrete with high impermeability is obtained.

Example 2:

this embodiment is substantially the same as embodiment 1 except that: the concrete with high-performance impermeability comprises, by weight, 330 parts of broken stone, 250 parts of cement, 90 parts of fly ash, 65 parts of quartz sand, 11 parts of titanium nitride powder, 53 parts of calcium carbonate powder, 11 parts of alumina fiber, 9 parts of hydroxypropyl starch ether, 0.6 part of air entraining material, 6 parts of magnesium oxide, 2 parts of zinc stearate and 120 parts of water; 3 parts of a polycarboxylic acid water reducing agent, 4.2 parts of potassium sulfite and 1.5 parts of polyacrylamide; 4 parts of microporous sintered particles.

Example 3:

this embodiment is substantially the same as embodiment 1 except that: the concrete with high-performance impermeability comprises, by weight, 400 parts of crushed stone, 320 parts of cement, 120 parts of fly ash, 80 parts of quartz sand, 15 parts of titanium nitride powder, 60 parts of calcium carbonate powder, 13 parts of alumina fiber, 12 parts of hydroxypropyl starch ether, 1 part of air entraining material, 8 parts of magnesium oxide, 5 parts of zinc stearate and 150 parts of water; 6 parts of a polycarboxylic acid water reducing agent, 5 parts of potassium sulfite and 3 parts of polyacrylamide; 6.8 parts of microporous sintered particles.

The preparation of the microporous sintered particles comprises the following steps,

(a) weighing 1.5 parts of bentonite, 4.5 parts of nano silicon dioxide powder and 0.8 part of starch, and placing the materials in a sintering container;

(b) mixing the materials in the sintering container in the step (a), and sintering at 1100 ℃ to obtain a sintered body with a microporous structure;

(c) and (c) crushing the sintered body with the micropore structure in the step (b) to obtain micropore sintered particles.

Example 4:

this embodiment is substantially the same as embodiment 1 except that: 370 parts of crushed stone, 300 parts of cement, 110 parts of fly ash, 75 parts of quartz sand, 14 parts of titanium nitride powder, 68 parts of calcium carbonate powder, 12 parts of alumina fiber, 11 parts of hydroxypropyl starch ether, 0.8 part of air entraining material, 7 parts of magnesium oxide, 4 parts of zinc stearate and 140 parts of water; 5 parts of polycarboxylic acid water reducing agent, 4.8 parts of potassium sulfite and 2.5 parts of polyacrylamide; 4.9 parts of microporous sintered particles.

The preparation of the microporous sintered particles comprises the following steps,

(a) weighing 1.3 parts of bentonite, 3 parts of nano silicon dioxide powder and 0.6 part of starch, and placing in a sintering container;

(b) mixing the materials in the sintering container in the step (a), and sintering at 1100 ℃ to obtain a sintered body with a microporous structure;

(c) and (c) crushing the sintered body with the micropore structure in the step (b) to obtain micropore sintered particles.

Example 5:

this embodiment is substantially the same as embodiment 1 except that: the concrete with high-performance impermeability comprises, by weight, 350 parts of crushed stone, 280 parts of cement, 100 parts of fly ash, 70 parts of quartz sand, 13 parts of titanium nitride powder, 60 parts of calcium carbonate powder, 11.5 parts of alumina fiber, 10 parts of hydroxypropyl starch ether, 0.7 part of air entraining material, 6.5 parts of magnesium oxide, 3 parts of zinc stearate, 130 parts of water, 4 parts of polycarboxylic acid water reducing agent, 4.5 parts of potassium sulfite, 2 parts of polyacrylamide and 4.9 parts of microporous sintered particles.

The preparation of the microporous sintered particles comprises the following steps,

(a) weighing 1.3 parts of bentonite, 3 parts of nano silicon dioxide powder and 0.6 part of starch, and placing the materials in a sintering container;

(b) mixing the materials in the sintering container in the step (a), and sintering at 1100 ℃ to obtain a sintered body with a microporous structure;

(c) and (c) crushing the sintered body with the micropore structure in the step (b) to obtain micropore sintered particles.

Comparative example 1:

this comparative example is essentially the same as example 1, except that: the concrete with high-performance impermeability comprises the following components, by weight, 300 parts of broken stone, 220 parts of cement, 80 parts of fly ash, 60 parts of quartz sand, 10 parts of titanium nitride powder, 50 parts of calcium carbonate powder, 10 parts of alumina fiber, 8 parts of hydroxypropyl starch ether, 5 parts of magnesium oxide, 1 part of zinc stearate and 110 parts of water; 2 parts of polycarboxylic acid water reducing agent, 4 parts of potassium sulfite and 1 part of polyacrylamide.

Comparative example 2:

this comparative example is essentially the same as example 2, except that: the concrete with high-performance impermeability comprises, by weight, 330 parts of broken stone, 250 parts of cement, 90 parts of fly ash, 65 parts of quartz sand, 11 parts of titanium nitride powder, 53 parts of calcium carbonate powder, 11 parts of alumina fiber, 9 parts of hydroxypropyl starch ether, 6 parts of magnesium oxide, 2 parts of zinc stearate and 120 parts of water; 3 parts of polycarboxylic acid water reducing agent, 4.2 parts of potassium sulfite and 1.5 parts of polyacrylamide.

Comparative example 3:

this comparative example is essentially the same as example 3, except that: the concrete with high-performance impermeability comprises, by weight, 400 parts of crushed stone, 320 parts of cement, 120 parts of fly ash, 80 parts of quartz sand, 15 parts of titanium nitride powder, 60 parts of calcium carbonate powder, 13 parts of alumina fiber, 12 parts of hydroxypropyl starch ether, 8 parts of magnesium oxide, 5 parts of zinc stearate and 150 parts of water; 6 parts of polycarboxylic acid water reducing agent, 5 parts of potassium sulfite and 3 parts of polyacrylamide.

Comparative example 4:

this comparative example is essentially the same as example 4, except that: 370 parts of crushed stone, 300 parts of cement, 110 parts of fly ash, 75 parts of quartz sand, 14 parts of titanium nitride powder, 68 parts of calcium carbonate powder, 12 parts of alumina fiber, 11 parts of hydroxypropyl starch ether, 7 parts of magnesium oxide, 4 parts of zinc stearate and 140 parts of water; 5 parts of polycarboxylic acid water reducing agent, 4.8 parts of potassium sulfite and 2.5 parts of polyacrylamide.

Comparative example 5:

this comparative example is essentially the same as example 5, except that: the concrete with high-performance impermeability comprises, by weight, 350 parts of broken stone, 280 parts of cement, 100 parts of fly ash, 70 parts of quartz sand, 13 parts of titanium nitride powder, 60 parts of calcium carbonate powder, 11.5 parts of alumina fiber, 10 parts of hydroxypropyl starch ether, 6.5 parts of magnesium oxide, 3 parts of zinc stearate, 130 parts of water, 4 parts of polycarboxylic acid water reducing agent, 4.5 parts of potassium sulfite and 2 parts of polyacrylamide.

Performance testing

1. Flexural strength

Adding the recycled concrete mixture into a test mould with the thickness of 150 multiplied by 500mm, covering a preservative film on the surface of the test piece after vibration to prepare a concrete test piece, standing the concrete test piece for 2 days, then removing the mould, putting the concrete test piece into a standard curing box for curing for 15 days to prepare a concrete test block, and testing the flexural strength of the concrete by adopting GB/T5008-2002. The test results are shown in table 1 below.

2. Permeability test

The method comprises the steps of manufacturing a concrete sample by adopting a GB/T50082-2009 medium water seepage height method, installing the concrete sample in an impermeability instrument for carrying out a penetration test, ensuring that the water pressure is constant within 24h at 1.15-1.25 MPa, splitting a test block after 24h, measuring the height of the water mark by using a steel ruler, repeating 6 groups, and calculating the average value of the height of the water mark. The test results are shown in table 1 below.

Table 1: performance test results of the recycled concrete obtained in examples 1 to 5 and comparative examples 1 to 5

	Flexural strength (MPa)	Penetration height (cm)	Compressive strength (MPa)
				Example 1	4.15	7.9	43.6
Example 2	4.21	8.2	43.1
				Example 3	4.18	8.5	42.8
Example 4	4.26	8.7	42.1
				Example 5	4.19	8.0	43.3
Comparative example 1	3.95	13.2	40.1
				Comparative example 2	3.99	12.9	40.4
Comparative example 3	4.05	13.5	39.5
				Comparative example 4	4.02	13.6	40.8
Comparative example 5	4.04	12.8	40.5

As can be seen from the detection results in Table 1, the concrete prepared by the method has good strength, good flexural strength and compressive strength, and low penetration height.

As used in the specification and in the claims, certain terms are used to refer to particular components. As one skilled in the art will appreciate, manufacturers may refer to a component by different names. This specification and claims do not intend to distinguish between components that differ in name but not function. In the following description and in the claims, the terms "include" and "comprise" are used in an open-ended fashion, and thus should be interpreted to mean "include, but not limited to. "substantially" means within an acceptable error range, and a person skilled in the art can solve the technical problem within a certain error range to achieve the technical effect basically.

It is noted that the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a good or system that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such good or system. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of additional like elements in the article or system in which the element is included.

The foregoing description shows and describes several preferred embodiments of the invention, but as aforementioned, it is to be understood that the invention is not limited to the forms disclosed herein, but is not to be construed as excluding other embodiments and is capable of use in various other combinations, modifications, and environments and is capable of changes within the scope of the inventive concept as expressed herein, commensurate with the above teachings, or the skill or knowledge of the relevant art. And that modifications and variations may be effected by those skilled in the art without departing from the spirit and scope of the invention as defined by the appended claims.

Claims (10)

1. A concrete with high-performance impermeability is characterized in that: comprises the following components in parts by weight,

300-400 parts of broken stone, 220-320 parts of cement, 80-120 parts of fly ash, 60-80 parts of quartz sand, 10-15 parts of titanium nitride powder, 50-60 parts of calcium carbonate powder, 10-13 parts of alumina fiber, 8-12 parts of hydroxypropyl starch ether, 8-10 parts of a water reducing agent, 0.5-1 part of an air entraining material, 3-8 parts of micropore sintering particles, 5-8 parts of magnesium oxide, 1-5 parts of zinc stearate and 110-150 parts of water.

2. The concrete of claim 1, wherein the concrete has a high barrier property, and is characterized in that: comprises the following components in parts by weight,

330-370 parts of broken stone, 250-300 parts of cement, 90-110 parts of fly ash, 65-75 parts of quartz sand, 11-14 parts of titanium nitride powder, 53-68 parts of calcium carbonate powder, 11-12 parts of alumina fiber, 9-11 parts of hydroxypropyl starch ether, 8.5-9.5 parts of a water reducing agent, 0.6-0.8 part of an air entraining material, 4-7 parts of micropore sintering particles, 6-7 parts of magnesium oxide, 2-4 parts of zinc stearate and 120-140 parts of water.

3. The concrete of claim 1, wherein the concrete has a high barrier property, and is characterized in that: the water reducing agent is composed of the following raw materials in parts by weight,

2-6 parts of a polycarboxylic acid water reducing agent, 4-5 parts of potassium sulfite and 1-3 parts of polyacrylamide.

4. The concrete of claim 1, wherein the concrete has a high barrier property, and is characterized in that: the microporous sintered particles are composed of the following raw materials in parts by weight,

1-1.5 parts of bentonite, 2.5-4.5 parts of nano silicon dioxide powder and 0.5-0.8 part of starch.

5. The concrete of claim 1, wherein the concrete has a high barrier property, and is characterized in that: the preparation of the microporous sintered particles comprises the following steps,

(a) weighing appropriate parts of bentonite, nano silicon dioxide powder and starch, and placing the bentonite, the nano silicon dioxide powder and the starch in a sintering container;

(b) mixing the materials in the sintering container in the step (a), and sintering at the temperature of 1000-1200 ℃ to obtain a sintered body with a microporous structure;

(c) and (c) crushing the sintered body with the micropore structure in the step (b) to obtain micropore sintered particles.

6. A preparation method of concrete with high-performance impermeability is characterized by comprising the following steps: comprises the following steps of (a) carrying out,

(S01) placing the microporous sintered pellets in a crush box (4) on a crush box support arm (3);

(S02) starting a crushing mechanism (5) in the crushing box (4) to further crush the microporous sintered particles in the crushing box (4);

(S03) weighing the further crushed microporous sintered particles by a pressure scale (12) and transferring the weighed microporous sintered particles into a stirring box body (2);

(S04) adding acid into the stirring box body (2) through the water feeding mechanism (8) to soak the microporous sintered particles;

(S05) taking a proper amount of crushed stone, cement, fly ash, quartz sand, titanium nitride powder, calcium carbonate powder, alumina fiber, hydroxypropyl starch ether, a water reducing agent, an air entraining material, microporous sintered particles, magnesium oxide and zinc stearate, respectively adding the materials in the proper amount into corresponding crushing boxes (4), and starting a crushing mechanism (5) to crush the added corresponding materials;

(S06) weighing the crushed corresponding materials in the step (S05) by a pressure scale (12), and transferring the weighed materials into the stirring box body (2) in the step (S04);

(S07) the T-shaped stirring pushing teeth (16) and the cross-shaped stirring piece (17) on the conveying stirring piece (6) stir the mixture in the stirring box body (2) in the step (S06), a proper amount of water is added through the water feeding mechanism (8) in the stirring process, and after the stirring is finished, the concrete with high impermeability is obtained.

7. A concrete manufacturing equipment with high-performance impermeability is characterized in that: the grinding device comprises a grinding box supporting arm (3) and a stirring box body (2) arranged on one side of the grinding box supporting arm (3), wherein a plurality of grinding boxes (4) are arranged on the grinding box supporting arm (3), a grinding mechanism (5) is arranged inside the grinding boxes (4), the grinding mechanism (5) is used for grinding raw materials, a conveying stirring piece (6) is rotatably arranged inside the stirring box body (2), the conveying stirring piece (6) comprises a conveying roller (601) and a stirring roller (602), and the conveying stirring piece (6) is used for mixing and stirring the raw materials;

the stirring roller (602) is provided with a plurality of T-shaped stirring pushing teeth (16), the T-shaped stirring pushing teeth (16) are provided with a material passing port (603), a cross-shaped stirring piece (17) is fixedly arranged between every two T-shaped stirring pushing teeth (16), and a plurality of stirring rods (18) are arranged on the cross-shaped stirring piece (17);

the crushing mechanism (5) comprises a crushing motor (501) and a grinding hammer (10), the crushing motor (501) is fixedly arranged on the upper side surface of the crushing box (4), an output end of the crushing motor (501) is provided with a special-shaped cam (502), the special-shaped cam (502) is rotatably connected with the upper side surface of the grinding hammer (10) through a grinding hammer connecting rod (503), the crushing motor (501) is used for pushing the grinding hammer (10) to move downwards, and the grinding hammer (10) is fixedly provided with grinding teeth (11);

a crushing bin (402) is arranged in the crushing bin (4), a crushing bin inlet (401) is arranged on the upper side surface of the crushing bin (4), the crushing bin inlet (401) is communicated with the crushing bin (402), and the grinding hammer (10) is arranged in the crushing bin (402);

a feeding plate (403) is arranged below the crushing bin (402), a positioning pushing piece (7) is fixedly arranged on one side of the feeding plate (403), and a pressure scale (12) is fixedly arranged on the upper side surface of the feeding plate (403).

8. The apparatus for manufacturing concrete with high-performance impermeability according to claim 7, wherein: the crushing box supporting arm (3) is connected with a feeder supporting table (1) through a supporting arm transmission piece (301), the upper end of the feeder supporting table (1) is connected with a feeder supporting column (101), the upper end of the feeder supporting column (101) is rotatably connected with the supporting arm transmission piece (301) through a supporting arm rotating motor (14), a first stirring motor (102) is arranged inside the feeder supporting table (1), a second stirring motor (19) is fixedly arranged inside the first stirring motor (102), and the output end of the second stirring motor (19) is fixedly connected with the conveying roller (601);

a bearing (9) is fixedly arranged at the joint of the stirring roller (602) and the stirring box body (2), a plurality of air pressure holes (204) are formed in the stirring box body (2) above the bearing (9), and a discharging door body (202) is rotatably arranged below the bearing (9);

the below of stirring roller (602) is in the inside of agitator tank (2) is provided with transport mechanism (20), transport mechanism (20) include straight drum motor (21) and rotate and set up conveyer belt (22) on straight drum motor (21), the inside of agitator tank (2) is provided with a plurality of guided ways (24), guided way (24) set up the inside of conveyer belt (22), the fixed waterproof layer (23) that is provided with of lateral surface of conveyer belt (22).

9. The apparatus for manufacturing concrete with high-performance impermeability according to claim 8, wherein: the positioning pushing piece (7) comprises a positioning base (701) and an electric telescopic rod (702), the electric telescopic rod (702) is fixedly arranged on one side of the feeding plate (403), the output end of the electric telescopic rod (702) is connected with a material pushing plate (703), the material pushing plate (703) is arranged on the upper side face of the feeding plate (403) in a sliding mode, and a waterproof cushion pad (13) is fixedly arranged on one side face, away from the electric telescopic rod (702), of the material pushing plate (703);

the fixed setting of location base (701) is in the side of going up of feeder brace table (1), location base (701) are close to one side of agitator tank body (2) is provided with infrared emitter (704), electric telescopic handle (702) are close to a fixed infrared receiver (705) that is provided with of a side of feeder brace table (1), infrared emitter (704) with infrared receiver (705) are corresponding.

10. The apparatus for manufacturing concrete with high-performance impermeability according to claim 8, wherein: the upper end of the feeder supporting table (1) is provided with a water feeding mechanism (8), and the water feeding mechanism (8) comprises a water feeding pump (801) and a water spraying head (802);

the water supply device is characterized in that the input end of the water supply pump (801) is connected with a filter cover (26), the upper part of the stirring box body (2) is connected with a water supply tank (25), the filter cover (26) is arranged inside the water supply tank (25), the upper end of the filter cover (26) is provided with a water passing bottom plate (27), the water passing bottom plate (27) is communicated with the water supply pump (801), a stirring wheel (28) is fixedly arranged on the water passing bottom plate (27) inside the filter cover (26), a filter plate (29) is arranged between the water passing bottom plate (27) and the stirring wheel (28), and a plurality of filter holes (30) are formed in the filter plate (29);

water filling port (203) have been seted up to the inside side of going up of agitator tank body (2), sprinkler bead (802) are fixed to be set up the inside of water filling port (203), water pump (801) pass through transfer line (803) with sprinkler bead (802) are linked together, fixed heating circle (15) that are provided with on transfer line (803), heating circle (15) are used for right transfer line (803) heat.

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