CN111189768B

CN111189768B - Corrosion-driven intelligent fiber and preparation method and application thereof

Info

Publication number: CN111189768B
Application number: CN201811354857.8A
Authority: CN
Inventors: 孙宇雁; 王子国; 程淑珍
Original assignee: Qingdao University of Technology
Current assignee: Qingdao University of Technology
Priority date: 2018-11-14
Filing date: 2018-11-14
Publication date: 2023-03-10
Anticipated expiration: 2038-11-14
Also published as: CN111189768A; JP2022502339A; AU2019284139A1; JP7029866B2; AU2019284139B2; WO2020098271A1

Abstract

The invention relates to a corrosion-driven intelligent fiber and a preparation method and application thereof. The corrosion-driven intelligent fiber consists of a core fiber and/or a core fiber with a corrosion-resistant coating and a corrosion-prone coating; the core fiber and/or the core fiber with the corrosion-resistant coating is in a tensile stress state along the length direction of the fiber; the corrosion-prone coating is in a compressive stress state along the length direction of the fiber; and the core fiber and/or the core fiber with the corrosion-resistant coating and the corrosion-prone coating are in a tension-compression balance state along the length direction of the fiber; the corrosion-susceptible coating is coated outside the core fiber and/or the core fiber with the corrosion-resistant coating. The preparation method comprises the following steps: applying a tensile force to the core fiber or the core fiber with the corrosion-resistant coating; then preparing a corrosion-prone coating in a set area on the surface of the coating; and (5) removing the tensile force to obtain a sample. Applications include their use in concrete. The invention firstly provides that the core fiber with the corrosion-prone coating is added into the concrete to obtain a product with excellent performance.

Description

Corrosion-driven intelligent fiber and preparation method and application thereof

Technical Field

The invention relates to a corrosion-driven intelligent fiber and a preparation method and application thereof; belongs to the technical field of civil engineering.

Background

The concrete material is the most widely used artificial building material in the world at present, but due to the defects of brittle nature, low tensile strength, low ultimate elongation and the like of the material, cracks and local damage are easily generated in the using process and under the influence of the surrounding environment, corrosive media such as air, water, chloride ions and the like invade into the inside of the structure along the cracks to corrode the reinforcing steel bars, the service life of the engineering structure is shortened, and the structure safety is endangered. With the continuous innovation of engineering construction technology, hydraulic dams, railway engineering, highway bridges, ports and ocean engineering, tunnels and mine engineering, pipeline engineering, nuclear power engineering and the like put higher requirements on the performance of concrete, so that the fiber reinforced concrete is produced at the right moment, and the formation and development of cracks are prevented and inhibited by adding fibers, so that the performances of the concrete, such as crack resistance, toughness, impermeability and the like, are improved.

However, due to the defects of low elongation and low strength of concrete, the brittle fracture problem is difficult to solve even if high-strength and high-elasticity modulus fibers such as carbon fibers and steel fibers are adopted, and the problem is difficult to solve by the low-modulus organic fibers. Mainly because the fiber generates smaller stress when the concrete structure is cracked under the action of temperature and humidity change, uneven settlement and external load, the fiber still does not reach the strength of the fiber, and the microcracks are further increased and widened along with the increase of the cracking stress. Therefore, the fiber is only put into the concrete within a small cracking stress range to improve the crack resistance of the concrete and reduce the width of cracks, once the cracks appear, the fibers cannot repair and heal the cracks, if the cracks cannot heal in time, the original micro cracks develop into macrocracks, and corrosive media enter the interior of the building through the cracks to corrode the reinforcing steel bars quickly, so that the safety and the service life of the building are influenced.

The repair of concrete cracks is always a focus of attention and research in academic and engineering circles, once a crack occurs in concrete, the concrete is simply checked and repaired manually, so that the technical requirement is high, the implementation is difficult, and the operation is complicated. Therefore, self-repairing concrete is produced at the same time, and the reports of the self-repairing methods of the cement concrete on relevant documents at home and abroad are mainly classified into three categories:

1.1 crystallization deposition method;

the method is divided into a mineral crystallization precipitation method, a cement-based infiltration crystallization method and a microbial crystallization method according to a restoration mechanism.

(1) Mineral crystallization precipitation method

The mechanism is as follows: one of the fracture repair factors in the crystal precipitation method is the fracture water together with unhydrated cement particles and other mineral additives (e.g., C) ₃ S、C ₂ S, etc.) continue to hydrate and generate hydration product deposit to repair the crack, the repair effect has little influence, but the dominant factor is water-soluble CO ₂ Slightly soluble Ca (OH) ₂ CaCO3 crystal precipitation is generated, and cracks are blocked and healed.

The mineral crystallization precipitation method has the following problems: the healing function of the method is greatly influenced by the age, the size, the quantity and the distribution of cracks and specific environment of the concrete, the healing period is long, the healing function of the concrete in later age is basically lost, and the cracks with the width of more than 0.15mm are basically difficult to heal.

(2) Cement based osmotic crystallization process

The mechanism is as follows: the cement-based permeable crystalline material consists of ordinary portland cement, quartz sand and a chemical compound with active functional groups, and when concrete doped with the permeable crystalline material is dried, the active functional groups are in a dormant state, and when the concrete cracks and water permeates into the concrete, ca is in gaps ²⁺ When the concentration is reduced to a certain degree, the active functional groups generate polycondensation reaction to generate new crystals, and the cracks are quickly and automatically filled and repaired.

The cement-based infiltration crystallization method has problems that: the self-repairing width of the crack is limited, and the repairing effect on the crack with the width exceeding 0.4mm is not good enough.

(3) Microbial crystallization method

The mechanism is as follows: the microbial repairing technology is that specific harmless bacteria (aerobic alkalophilic bacillus) are put into a concrete material, the interior of the undamaged concrete is in a high-alkali anoxic environment, and the bacteria are in a dormant state. When the concrete structure is damaged and cracked, the permeation of oxygen and water activates bacterial spores, and CO is generated in the metabolic process ₂ With Ca in the concrete material ²⁺ Calcium carbonate crystals are generated by reaction, and cracks are sealed and repaired.

The problems of the microbial crystallization method are as follows: the width range of the self-healing crack is limited, and only cracks smaller than 0.5mm can be repaired; the bacteria have certain requirements on working environment and temperature, and have short service time and service life (about one year).

1.2 repair agent filling method

The method is an intelligent bionic self-healing concrete and is divided into a microcapsule method and a hollow fiber (hollow optical fiber or hollow fiber) method according to the type of a repairing agent carrier.

Both have similar repair mechanisms: the microcapsule/hollow fiber loaded with the repairing adhesive is implanted into concrete, when damage and microcracks occur in the service and use processes of a concrete structure, the part where the cracks pass is broken, the repairing agent flows out of the cracks to infiltrate into the cracks and contacts with a catalyst dispersed in the concrete, and the curing and hardening are performed to quickly block the cracks, so that the self-repairing is realized.

The repairing agent filling method has the following problems: the method is a very complex repairing system, the repairing agent covers organic synthesis, polymer chemistry, fine chemical engineering, microcapsule/hollow fiber technology, embedding technology and the like, the method still stays in the experimental research stage, and a lot of problems to be solved exist, mainly comprising the following steps: (1) the number of the carriers is large, the strength of the concrete is affected by too much carriers, and the number of the carriers is too small to fill gaps; (2) the problem of fracture strain of the carrier is that the carrier is too large, the carrier is not easy to tear, the glue solution cannot flow out in time, and the carrier is easy to break during stirring due to too small strain, so that the glue solution flows out in advance; (3) compatibility among a concrete matrix, a repairing agent carrier and an adhesive, long-term stability of the repairing agent, fluidity in cracks, curing timeliness and the like;

1.3 shape memory alloy actuated closure method (SMA method)

The method is a method matched with a repairing agent filling method, and in order to obtain the ideal self-repairing effect, the crack width of the concrete must be controlled, otherwise, a large number of repairing carriers are needed, and the performance of the concrete is influenced. In addition, when the crack of the concrete is too wide, the capillary suction force is reduced, the crack above the fiber tube is difficult to absorb and store glue, the glue flows downwards along the crack under the action of gravity, little glue is remained on the crack surface, and the repairing effect is poor, so that the crack width of the concrete needs to be controlled to achieve the ideal self-repairing effect. The existing intelligent material which can sense external stimulation active deformation and provide driving force, namely the shape memory material, mainly comprises shape memory alloy and shape memory polymer, but the memory polymer has small deformation restoring force and is not suitable for self-healing driving, and the shape memory alloy can be used for self-healing driving due to high strength and large restoring force.

The mechanism is as follows: the SMA method provides driving force for closing cracks by electrifying, heating and exciting the shape memory alloy wires embedded in the concrete to contract and deform. This method actively adjusts the crack width by applying pre-stress to the structure, which is not accessible by the above-mentioned methods.

The shape memory alloy driven closing method has the following problems: because the shape memory alloy is a thermal deformation material, the alloy wire needs to be electrified and heated to be stimulated to shrink, a series of matched equipment is needed for driving the crack to close, and the whole driving and controlling system is complex and tedious. Because the SMA material has low resistance, the electric heating needs large current, and the requirements on a power supply and a lead are high. The heating temperature has great influence on the shape recovery of the SMA and the mechanical property of the concrete, the temperature regulation and control of the SMA have technical difficulty due to the heat conduction of the concrete, the SMA is difficult to drive due to low temperature, and the concrete is cracked due to high temperature and uneven temperature rise. In addition, the crack closure is driven to realize self-repairing, a large amount of SMA is required to be put into the crack closure, and the price of the SMA is high and is 700 times that of common steel, so that the application of the SMA method in concrete can be killed.

In order to reduce economic loss and safety threat of a concrete structure caused by crack defects and repair crack defect hazards of concrete, the conventional repair method has the advantages that a cement-based permeable crystallization material is a relatively successful intelligent repair material, but the repair effect is limited by the width of cracks, and other methods basically stay in an experimental exploration stage or have poor repair effect due to too complicated repair mechanisms. Therefore, to achieve the desired self-repairing effect, it is very important to control the crack width of the concrete.

Disclosure of Invention

Aiming at the defects of the prior art, the invention provides a corrosion-driven intelligent fiber and a preparation method and application thereof.

The invention relates to a corrosion-driven intelligent fiber; the corrosion-driven intelligent fiber consists of a core fiber and/or a core fiber with a corrosion-resistant coating and a corrosion-prone coating; the core fiber and/or the core fiber with the corrosion-resistant coating is in a tensile stress state along the length direction of the fiber; the corrosion-prone coating is in a compressive stress state along the length direction of the fiber; and the core fiber and/or the core fiber with the corrosion-resistant coating and the corrosion-prone coating are in a tension-compression balance state along the length direction of the fiber; the corrosion-susceptible coating is coated outside the core fiber and/or the core fiber with the corrosion-resistant coating.

Preferably, the corrosion-susceptible coating has a corrosion rate greater than that of the core fiber under equivalent corrosion conditions; and/or, the corrosion rate of the corrosion-susceptible coating is greater than the corrosion rate of the core fiber with the corrosion-resistant coating under equivalent corrosion environments.

As a preferred solution, the present invention is a corrosion-driven smart fiber;

the corrosion-driven intelligent fiber comprises a core fiber and a corrosion-prone coating, and the corrosion-prone coating is coated on part or all of the positions outside the core fiber;

or

The corrosion-driven intelligent fiber comprises a corrosion-resistant coating, a core fiber and a corrosion-prone coating; part or all of the positions outside the core fiber are coated with corrosion-resistant coatings; when part or all of the positions outside the core fiber are coated with the corrosion-resistant coating, the obtained material is defined as A; coating a corrosion-prone coating on part of or all of the surface A,

or

The corrosion-driven intelligent fiber comprises a core fiber, an easily-corroded coating and a corrosion-resistant coating; the core fiber is coated with a corrosion-prone coating; a corrosion-resistant coating is coated on part of the position of the corrosion-prone coating;

or

The corrosion-driven intelligent fiber comprises a core fiber and a corrosion-prone coating, and the corrosion-prone coating is coated on part or all of the positions outside the core fiber; the portion of the location outside of the core fiber comprises an end of the core fiber; when the end part of the core fiber is coated with the corrosion-prone coating, the corrosion-prone coating at the end part is also coated with the corrosion-resistant coating;

or

The corrosion-driven intelligent fiber comprises a corrosion-resistant coating, a core fiber and a corrosion-prone coating; a corrosion-resistant coating is coated on part or all of the positions outside the core fiber; when part or all of the positions outside the core fiber are coated with the corrosion-resistant coating, the obtained material is defined as A; the surface A is coated with an easily-corroded coating at part or all of the surface A, and when the end part of the surface A is coated with the easily-corroded coating, the end part of the surface A is also coated with a corrosion-resistant coating;

wherein the core fiber and/or the core fiber with the corrosion-resistant coating is in a tensile stress state along the length direction of the fiber; the corrosion-prone coating is in a compressive stress state along the length direction of the fiber;

the corrosion rate of the corrosion-prone coating is greater than that of the core fiber under the same corrosion environment; and/or, the corrosion rate of the corrosion-susceptible coating is greater than the corrosion rate of the core fiber with the corrosion-resistant coating under equivalent corrosion environments.

The invention relates to a corrosion-driven intelligent fiber; the core fiber is at least one of inorganic fiber and polymer fiber; the equivalent diameter of the core fiber is 20mm or less, preferably 5mm or less. The equivalent diameter is the diameter of the fiber cross-sectional area converted into a circular cross-section.

The invention relates to a corrosion-driven intelligent fiber; the inorganic fiber is selected from at least one of C fiber, glass fiber, mineral fiber, basalt fiber, ceramic fiber and metal fiber; the metal fiber is selected from at least one of steel fiber, M-plated steel fiber, stainless steel fiber, copper alloy fiber, titanium alloy fiber and nickel alloy fiber; the M is selected from at least one of copper, nickel, chromium, tin, cadmium and silver.

The polymer fiber is selected from at least one of polypropylene fiber, polyacrylonitrile fiber, polyvinyl alcohol fiber, polyethylene fiber, aramid fiber, polyester fiber and polyamide fiber.

The invention relates to a corrosion-driven intelligent fiber; the corrosion-resistant coating is made of at least one of copper, nickel, chromium, cadmium, silver and gold. When the core fiber is steel fiber, the material of the corrosion-resistant coating is selected from at least one of copper, nickel, chromium, cadmium, silver and gold elements. When the core fiber is a steel fiber, the corrosion-resistant coating is prepared by plating or coating.

The invention relates to a preparation method of corrosion-driven intelligent fiber; applying a tensile force to the core fiber or the core fiber with the corrosion-resistant coating; then preparing a corrosion-prone coating in a set area on the surface of the coating; removing the tensile force to obtain a sample; the applied tensile force is 10% to 90% of the load-bearing capacity of the core fiber or the core fiber with the corrosion resistant coating. The core fiber with the corrosion-resistant coating in the preparation method comprises at least two conditions, namely, the corrosion-resistant coating uniformly covers the surface of the core fiber in the first condition, and the corrosion-resistant coating is coated on the set area of the surface of the core fiber in the second condition. In industrial applications, if necessary, the end is provided with a corrosion-resistant coating; the ends of the resulting sample were then coated with a corrosion-resistant coating.

When the corrosion-resistant coating is required to be coated at the local position of the corrosion-resistant coating, the corrosion-resistant coating is directly prepared at the set position of the surface of the sample.

The invention relates to a preparation method of corrosion-driven intelligent fiber; in the whole corrosion-driven intelligent fiber, in order to maximize the prestress applied by the intelligent fiber to the outside, the optimal acquisition method comprises the following steps:

under the condition that the cross section area of the corrosion-driven intelligent fiber is certain,

magnitude of pre-stress storage of smart fiber and volume fraction V of core fiber _f Closely related, the axial force F stored by the core fiber is:

when F reaches the maximum, the prestress action of the intelligent fiber on the outside is maximized;

the maximum value of the axial force of the core fiber is obtained, and F is firstly differentiated to obtain:

namely:

let F' =0, then:

(E _c -E _f )V _f ² -2E _c V _f +E _c ＝0

(14)

when E is _c ＝E _f Then, get

At the moment, F can be the maximum value, namely Fmax is obtained;

when E is _c ≠E _f For equation of time

Order to

Due to E _c ＞0，E _f > 0, then a < 0 or a > 1, then Δ =4a ² 4a > 0, the original equation has two different real roots, namely:

and because 0 < V _f < 1, and when E _c ＜E _f When it is, then

When E is _c ＞E _f When the temperature of the water is higher than the set temperature,

root of immature bitter orange

Not satisfying 0 < V _f The condition < 1 should be left off; when in

V _f And (3) satisfying the condition of the formula 16, and enabling F to be the maximum value, namely obtaining Fmax.

The invention discloses application of corrosion-driven intelligent fiber, which comprises the following steps: including use in concrete or fiber reinforced resin composites.

The invention discloses application of corrosion-driven intelligent fiber, which comprises the following steps: when the corrosion-driven intelligent fiber is used for concrete, the corrosion-driven condition is the use environment of the concrete. In the environment of use of the concrete, H ₂ O/O ₂ 、Cl ^- 、SO ₄ ^-2 And the like, or acidic corrosive substances. These corrosive media are one of the prerequisites for driving corrosion-driven smart fibers to exhibit intelligence. When the intelligent fiber is applied to industry or engineering, the core fiber material, the corrosion-resistant coating material and the easily-corroded coating material of the intelligent fiber are further adjusted according to the service environment of concrete.

The invention discloses application of corrosion-driven intelligent fiber, which comprises the following steps: the corrosion drives the smart fiber anchoring in the concrete. The anchoring means may be at least one of adhesive anchoring and/or mechanical anchoring.

The invention discloses application of corrosion-driven intelligent fiber, which comprises the following steps: when the corrosion-driven intelligent fiber is used in concrete, the consumption of the corrosion-driven intelligent fiber is 0.01-20 v%.

The invention discloses application of corrosion-driven intelligent fiber, which comprises the following steps: the material of the corrosion-prone coating is preferably a corrosion-prone iron metal material (such as elemental iron, low-carbon iron, iron alloy and the like), an iron-based metal material doped with harmful substances (such as harmful trace elements of carbon, nitrogen, phosphorus, silicon and the like) and prone to form electrochemical corrosion, or an alloy prone to form intergranular corrosion.

The corrosion-prone coating can be formed by a single-layer material, a multi-layer material or a functional gradient material.

The cross section of the corrosion-driving intelligent fiber can be circular, polygonal or irregular (including groove, cross, groined, trilobal, quincunx or star), the axial line can be wavy, and the surface can be indentation or ribbed.

The corrosion-driven intelligent fiber can be formed by a single fiber or a stranded wire formed by twisting and stranding a plurality of fibers.

The core fiber in the corrosion-driven intelligent fiber can be formed by a single fiber or a stranded wire formed by twisting and stranding a plurality of fibers.

The corrosion-driven intelligent fiber forms an anchoring end form in a target body, and the corrosion-driven intelligent fiber comprises a fully-plated end hook type, an exposed end straight hook type, an exposed end bent hook type, an end pier head anchor type and an end flat head anchor type.

The shape of the corrosion-driven intelligent fiber is flat, straight, prism-shaped, wave-shaped, hook-shaped, big-head-shaped, double-tip-shaped or cluster-shaped.

In the present invention, all or part of the coating layer may be a multilayer or a composite coating layer.

In order to prevent the core fiber and the concrete from losing anchoring force transfer points when the corrosion-prone coating is completely corroded, and the force exerted by the core fiber on the concrete is ineffective, in order to ensure that the acting force of the core fiber is effective permanently, an anchoring end is preferably arranged at the end part of the fiber, or a plurality of anchoring points are arranged on a longer intelligent fiber, as shown in fig. 7.

The invention relates to the application of corrosion-driven intelligent fiber; when the corrosion-driven intelligent fiber is used in concrete, the construction and maintenance modes of the corrosion-driven intelligent fiber are completely consistent with those of the existing concrete.

Principles and advantages

The invention firstly provides that core fiber with a corrosion coating is added into concrete; by the anchoring effect of the concrete, the corrosion resistance and cracking resistance at the early stage are equivalent to those of the existing concrete in the using process; as soon as the corrosion-coated core fiber starts to corrode, it exhibits the function of gradually repairing the already developed cracks until they are completely closed; this greatly prolongs the service life of the concrete. Meanwhile, the core fiber with the corrosion coating is added into the concrete, so that the premature cracking probability of the concrete can be reduced, the mechanical property, the durability and the use safety of a concrete structure are improved, and the improvement of the crack resistance of the low-modulus polymer fiber concrete member is greatly facilitated.

The invention provides a corrosion-driven intelligent fiber and self-healing concrete, which are based on the principle that an intelligent fiber (wherein the core fiber is not easy to corrode, and the corrosion-prone coating is easy to corrode) is prepared from a corrosion-prone coating coated on the surface of a pre-tensioned core fiber, the shape recovery of the intelligent fiber is excited through the corrosion of a corrosive medium in the environment, pre-pressure is applied to the concrete to provide power for the closing of cracks of the concrete, and when the corrosion of the corrosion-prone coating is more serious, the applied pre-stress is larger, and when the pre-stress is large enough, the cracks are healed. The application of the prestress can improve the mechanical property, the durability and the use safety of a concrete structure, provides a brand new design idea for the shape memory material, and provides a brand new idea for the self-repairing and the self-healing of composite materials such as concrete and the like.

The invention provides a fiber with a corrosion-driven shape memory function, which drives an intelligent fiber to shrink and deform by corrosive media entering concrete in the environment, applies prestress to the concrete, mechanically closes concrete cracks, provides a brand new method for intelligent self-healing of the concrete, and provides a brand new thought for applying prestress at any position and in any direction in a concrete material.

The invention relates to a preparation method of corrosion-driven intelligent fibers and a basic principle of self-healing concrete of the corrosion-driven intelligent fibers

Preparation method

The corrosion-driven intelligent fiber (the intelligent fiber is called intelligent fiber for short) is composed of a core fiber and a corrosion-prone coating, wherein the core fiber is composed of a corrosion-resistant material or a material coated with the corrosion-resistant coating, and the corrosion-prone coating is composed of a material which is easily corroded by a corrosive medium in the environment. The preparation method of the intelligent fiber is shown in figure 1, and the preparation steps are carried out from a to d in sequence.

In fig. 1, a indicates that the core fiber is in an unstressed state; b represents the pretensioning of the core fiber in the elastic range with a tensile stress of σ _o (ii) a c denotes the core fiber tensile stress σ _o Uniformly coating the surface of the substrate by deposition, spraying or electroplating under the constant conditionCoating the easy-to-corrode coating, wherein the easy-to-corrode coating is in a stress-free state; d represents that after the coating is coated, the tensile force is removed, and if the core fiber is well combined with the corrosion-prone coating, the corrosion-prone coating retracts along the axial direction under the action of the elastic restoring force of the core fiber in the removing process, and the generated compressive stress is

Finally, tension and pressure balance is established between the fiber and the fiber, the corrosion prone coating stores the pre-stress and the corresponding pre-stress strain, and the core fiber stores the pre-stress and the corresponding pre-stress strain.

Mechanism of shape recovery

The intelligent fiber shape recovery mechanism is shown in fig. 2, and under the corrosive medium environment, when the corrosion-prone coating is corroded and the cross section is lost, the intelligent fiber starts to recover, and the recovery process is carried out from a to c in sequence. FIG. a shows the smart fiber in an un-corroded state with the core fiber and the erodible coating in an original equilibrium state; the graph b shows that under the corrosive medium environment, the easy corrosion coating is firstly contacted with the corrosive medium and is corroded to generate a corrosion product which is difficult to bear load, the core fiber has strong corrosion resistance, the cross section and the strength cannot be lost, and as the effective stressed cross section of the easy corrosion coating becomes smaller in thickness after being corroded, the compressive stress and the compressive deformation of the residual easy corrosion coating are continuously increased under the action of the elastic restoring force of the core fiber, and the core fiber is continuously shrunk and gradually approaches to the initial length; as shown in fig. c, when the corrosion-susceptible coating is completely corroded, the core fiber returns to the original length, completing the one-way memory effect, and the core fiber is in an unstressed state.

Therefore, the corrosion-driven intelligent fiber with the shape memory function needs to satisfy two basic conditions:

1. the core fiber is stored with pre-stress strain along the axial direction, the corrosion prone coating is stored with pre-stress strain, and the core fiber and the corrosion prone coating are in a tension-compression balance state;

2. the corrosion-susceptible coating material needs to be composed of a material that is easily corroded by the corrosive medium in the environment, while the core fiber is composed of a corrosion-resistant material or a material coated with a corrosion-resistant coating.

Fundamental principle of self-healing concrete

Basic conditions and principles of prestressing intelligent fiber

The concrete structure is cracked by the factors of temperature, humidity, external force and the like, the intelligent fibers at the crack defect are corroded by corrosive media in the environment, the shape recovery is excited, pre-pressure is applied to the concrete, and power is provided for the closing of the crack. The corrosion-driven smart fiber self-healing principle is shown in fig. 3, and the self-healing process is performed in order from a to c. Figure a shows the concrete cracked, but the smart fibers have not corroded yet and are in a stable state. And the graph b shows that the corrosion-prone coating at the crack is subjected to chemical or electrochemical reaction with a corrosive medium, the intelligent fiber is stimulated to retract, a load is transmitted through a bonding area (a bonding and anchoring interface between the corrosion-prone coating which is not corroded temporarily and the concrete), pre-pressure is applied to the concrete, and the higher the corrosion degree of the corrosion-prone coating is, the larger the closing force is, and the smaller the crack width is. As shown in the figure c, when the closing force acting on the crack surface is large enough after the corrosion-prone coating corrodes to a certain degree, the crack is closed, the corrosive medium inlet channel is cut off, the corrosion stops, and the self-healing protection function is realized, at this time, the retraction force and the pre-pressure of the core fiber stop increasing.

However, if defects such as holes exist, corrosive media can still enter the material to continuously corrode the intelligent fibers, the bonding anchoring interface of the corrosion-prone coating and the concrete is continuously reduced, the pre-stress and pre-stress area of the concrete is continuously increased, and when the anchoring interface is insufficient to bear the drawing force caused by retraction of the intelligent fibers, the intelligent fibers are pulled out, and the pre-stress application fails. Or when the crack is close to the end part of the intelligent fiber, the surface of the corrosion-prone coating in the end part area is corroded, the anchoring of the end part fails, the intelligent fiber cannot effectively apply prestress on concrete, and the crack is opened again.

In order to make the intelligent fiber more effective in prestressing the concrete, it is preferable to leave a reliable anchoring end at the end of the intelligent fiber, as shown in fig. 3, leaving an uncoated bare end at both ends of the core fiber, or leaving an end hook at both ends, to ensure the reliability of the anchoring end. Whether cracks are distributed at the end of the fiber or the corrosion-prone coating is totally corroded, but the reliable anchoring end can make the fiber difficult to pull out, so that the prestress effectiveness is guaranteed, and the crack resistance of the concrete is improved.

Theoretical calculation of internal force of intelligent fiber and concrete

Theoretical calculation of internal force of intelligent fiber

Basic assumptions

Because the intelligent fiber is a unidirectional composite material with a sufficient slenderness ratio, in order to simplify the calculation of the internal force of the intelligent fiber, the following assumptions can be made:

1) The corrosion-prone coating is uniformly coated on the core fiber;

2) The interface of the core fiber and the corrosion-prone coating is well combined, and the core fiber and the corrosion-prone coating have good chemical compatibility;

3) Neglecting the influence of the transverse strain of the core fiber and the easily corroded coating, and not counting the Poisson ratio in the formula derivation;

4) The stress of the core fiber and the corrosion-prone coating is in a linear elastic state;

5) The structural units are positively tensioned and negatively pressurized.

Intelligent fiber internal force formula derivation

Referring to FIG. 4, the core fiber is stretched with the original length of the core fiber being l, and the tensile stress is σ _o Elongation of Deltax ₁ . The length of the coating after deposition is l + Deltax ₁ Removing the tension of the core fiber, and the compression deformation of the coating is Deltax due to the restoring force of the core fiber ₂ The two reach the balance of force and coordinate deformation, according to Hooke's law:

tensile force of core fiber:

pressure of the corrosion-susceptible coating:

by balance of forces, F _f +F _c If not =0, then

Namely, it is

And because:

substituting formula (4) into formula (5) to obtain:

let the cross-sectional area of the intelligent fiber A = A _c +A _f To do so

The right numerator denominator of formula (6) is divided by Al

And also

Substitution formula (7), compressive stress of the corrosion-susceptible coating:

due to sigma _o Is much smaller than E _f Therefore:

at this time, the core fiber stores the prestress expression:

in all formulas of the invention:

σ _o is the initial tensile stress value of the core fiber;

is the pre-stress value of the corrosion-susceptible coating;

E ₁ ＝E _f V _f +E _c V _c is the elastic modulus (composite elastic modulus) of the smart fiber.

E _c ，E _f The elastic modulus of the corrosion-prone coating and the elastic modulus of the core fiber (when the corrosion-resistant coating is attached to the core fiber, the elastic modulus is calculated according to a composite elastic modulus calculation formula);

V _c ，V _f volume fractions, V, of the corrosion-susceptible coating and core fiber, respectively _c +V _f ＝1；

A _c ，A _f Cross-sectional areas of the corrosion-susceptible coating and the core fiber, respectively, A _c +A _f ＝A；

ε _c Strain after equilibration for the corrosion susceptible coating; epsilon _f Is the initial tensile strain of the core fiber.

Intelligent fiber pre-stress storage optimization

For intelligent fibers with the same cross-sectional area, the pre-stress storage size of the intelligent fibers and the volume fraction V of the core fibers _f Closely related, the axial force F stored by the core fiber is:

when F reaches a maximum, the pre-stressing of the smart fiber to the outside will be maximized.

namely:

let F' =0, then:

(E _c -E _f )V _f ² -2E _c V _f +E _c ＝0 (14)

when E is _c ＝E _f Then, get

Where F may take the most value.

When E is _c ≠E _f For equation of time

Order to

and because 0 < V _f < 1, and when E _c ＜E _f When it is, then

then the root is grown

Not satisfying 0 < V _f The condition < 1 should be left off; when in

V _f The condition of expression 16 is satisfied, so that F may take a maximum value, i.e., fmax.

In engineering applications, if the calculated value of equation 16 is not in the range of 5V% to 95V%, it is preferable to set the volume fraction V of the core fiber _f The concentration is adjusted to 5-95 v%.

Intelligent calculation of internal force of fiber concrete

In order to ensure that the intelligent fibers can continuously play a role under complex working conditions, the intelligent fibers with the permanent anchoring ends are doped into the concrete, and the prestress applied to the concrete is predicted when the intelligent fibers recover in shape. The permanent anchoring end has two conditions:

case one the corrosion-driven smart fiber is comprised of a core fiber and a corrosion-susceptible coating; the surface part of the core fiber is not coated with the corrosion-prone coating, the core fiber is positioned in concrete, the part of the core fiber which is not coated with the corrosion-prone coating is a permanent anchoring end, and the length of any permanent anchoring end is defined as l';

in the second case, the corrosion-driven intelligent fiber consists of a core fiber, a corrosion-prone coating and a corrosion-resistant coating; the permanent anchoring end is a part of the surface of the core fiber, which is coated with the corrosion-prone coating and coated with the corrosion-resistant coating; meanwhile, the core fiber is positioned in concrete, wherein the length of any one permanent anchoring end is defined as l;

to simplify the calculation, the influence of the poisson ratio on the magnitude of the axial stress is not considered.

Basic assumptions

To simplify the calculation of the interaction force in the smart fiber and concrete, the following assumptions were made:

1) The intelligent fibers are uniformly arranged in the concrete member in a unidirectional mode;

1) The influence of the poisson ratio on the magnitude of the axial stress is not counted;

2) The permanent anchoring end is tightly combined with the concrete without slippage;

3) The stress influence of corrosion products of the easily corroded coating is not counted;

pre-pressure of concrete

When the cross section of the corrosion-prone coating is completely lost, the corrosion products do not participate in stress, and the core fiber and the concrete establish final tension-compression balance, so that the prestress applied to the concrete by the retraction of the core fiber is maximized. From the formula (9), it is found that the compressive preload applied to the concrete by the retraction of the core fiber

Comprises the following steps:

the tensile stress of the core fiber is:

in order to make the permanent anchoring end reliable and not slip, a sufficient length is required, the adhesive anchoring force of the permanent anchoring end is set to T _a = τ π dl', intelligent fiber drawing force is

According to the balance of the bonding anchoring force of the permanent anchoring end and the drawing force of the intelligent fiber, T _a ＝T _t That is to say that,

obtaining:

substituting equation (18) into equation (19) to obtain:

if the permanent anchorage end is made reliable and does not slip

Wherein,

the composite elastic modulus of the core fiber and the concrete is as follows:

the modulus of elasticity of the concrete is: e _m ；

In the finished product, the volume fractions of the core fiber, the corrosion-prone coating and the concrete are respectively as follows: v _f1 、V _c1 、V _m ，V _f1 +V _c1 ＝V _s ，V _f1 +V _c1 +V _m ＝1。

τ is the bonding force of the smart fiber to the concrete interface (which is a known quantity when the concrete composition, smart fiber composition and structure are determined), l' is the anchoring length of the permanent anchoring end in the concrete (length of one end), and d is the anchoring end cross-sectional diameter.

Drawings

FIG. 1 is a schematic diagram of a process for preparing intelligent fibers;

FIG. 2 is a diagram of the shape recovery mechanism of corrosion driven smart fibers;

FIG. 3 is a schematic diagram of a corrosion-driven intelligent fiber self-healing process;

FIG. 4 is a force balance process diagram of the perishable coating under the effect of elastic restoring force of the core fiber;

FIG. 5 is a graph showing the effect of the change in the content of intelligent fibers and the initial tensile stress on the concrete prestress in the calculation process of example 1.

Fig. 6 is a schematic diagram of several structures of the intelligent fiber designed by the invention.

Fig. 7 is a layout of anchor points.

FIG. 8 is a schematic structural view of a concrete specimen of example 1.

Detailed Description

Basic parameters of material

According to the internal force calculation formula, the core fiber of the intelligent fiber is made of copper-plated steel fiber (the diameter is 0.2mm, the copper plating amount is ignored), the corrosion-prone coating is made of metal iron, and when the cross-sectional area of the core fiber and the corrosion-prone coating is 1:1, the prestress storage of the intelligent fiber is maximized. The content of the intelligent fiber in the concrete is 4v%, and the basic parameters of the intelligent fiber and the concrete are shown in the table 1.

TABLE 1 basic Material parameters of Corrosion-susceptible coatings, core fibers and concrete

Axial stress condition of concrete when the prestress is completely released

Assuming that the intelligent fibers are uniformly arranged in the concrete in a single direction, the cross section of the corrosion-prone coating is lost, and the prestress applied to the concrete by the intelligent fiber shape recovery reaches the maximum value.

Core fiber stored stress:

the core fiber retraction applies a pre-stress to the concrete of:

from the above calculation results, it can be seen that the maximum pre-stress of the intelligent fiber with the content of 4% to the concrete reaches 9.3MPa, and if the volume fraction of the intelligent fiber and the initial tensile force of the core fiber are continuously increased, the pre-stress applied to the concrete is continuously increased.

When the volume fraction V of the smart fiber is as shown in FIG. 5 _s Initial tension sigma of the core fiber _o The compressive pre-stress of the base body is increased continuously. Therefore, the magnitude of the prestress can be controlled by the magnitude and volume fraction of the intelligent fiber initial tensile stress, and the application of the prestress is beneficial to crack closure, stress concentration reduction, rigidity increase, corrosion resistance improvement and toughness improvement of concrete. The presence of pre-stressing forces greatly aids the crack resistance of the concrete element, especially of low modulus polymer fibre concrete elements.

According to the design and calculation, the following concrete test pieces are prepared:

example 1

As shown in FIG. 8, the concrete specimen is characterized in that the concrete specimen has dimensions of 200mm × 20mm × 40mm (length × width × height), and is divided into two sections A and B by a piece of absorbent cotton paper perpendicular to the length direction of the specimen and having a thickness of 0.3mm, and the absorbent cotton paper simulates a through crack of the specimen to form a corrosive medium channel. The A and B parts of the test piece are connected by 20 shape memory steel fibers with the length of 180mm and the diameter of 0.28mm, the core fiber of each intelligent fiber is copper-plated steel fiber with the diameter of 0.2mm and the strength of 3000MPa, the initial tensile stress of the core fiber is 2000MPa, the corrosion-prone coating is electroplated iron metal, and the thickness is 0.04mm. The 20 fibers are arranged close to the side and vertically penetrate through the water-absorbing tissue paper, the middle section of each fiber is wrapped by the water-absorbing tissue paper with the length of 50mm and the thickness of 0.2mm to serve as a water-absorbing channel, so that the corrosion speed of the corrosion-prone layer of the intelligent fiber is increased, and the recovery speed of the intelligent fiber is accelerated.

Soaking the test piece in 6wt% sodium chloride solution, and finding that a small amount of brown rust appears at the crack after 48 hours, and finding that the width of the crack is narrowed through measurement; cleaning rust on absorbent tissue paper between the part A and the part B of the test piece, and then continuously soaking in a sodium chloride solution for 48 hours to find that brown rust exuded from the tissue paper at the crack is less than that of the last time, and further narrowing the width of the crack by measurement; after 15 days of continued soaking, no brown rust was found to seep out of the cracks, and the cracks were substantially closed. The intelligent fiber shape recovery is realized under the drive of the electrochemical corrosion, and the generated restoring force enables the parts A and B of the test piece to be close to each other, and the water-absorbing tissue paper serving as a corrosive medium channel is extruded to be thinned, so that the liquidity of the water-absorbing tissue paper is reduced. The more serious the corrosion of the iron coating of the intelligent fiber is, the greater the restoring force of the intelligent fiber is, and finally the water-absorbing tissue paper is extruded to be incapable of having the liquidity, so that the through crack is closed, and a corrosive medium cannot enter the inside of the test piece to form self-healing.

Comparative example 1

The characteristics and preparation method of the concrete sample of comparative example 1 are substantially the same as those of example 1. The difference is that 20 steel fibres connecting the two parts of test pieces a and B have a core fibre with an initial tensile stress of 0Mpa, i.e. are electroplated with a 0.04mm thick iron coating without tension.

Soaking the concrete sample of the comparative example 1 in 6% sodium chloride solution, and finding that a small amount of brown rust at the crack is exuded after 48 hours, and finding that the width of the crack is unchanged through measurement; cleaning rust on absorbent tissue paper between the part A and the part B of the test piece, and then continuously soaking in a sodium chloride solution for 48 hours to find that the tissue paper at the crack has brown rust exudation, and the width of the crack is not narrowed through measurement; after 15 days of continued soaking, it was found that the tan rust at the cracks was oozed out with almost constant crack width. The experimental result shows that the 20 steel fibers do not have the shape memory function, so that the through crack formed by the absorbent tissue paper cannot be closed, and the steel fibers prepared by the electroplated iron coating under the condition of no tension have the memory function and cannot heal the concrete crack.

Comparative example 2

The characteristics and the preparation method of the concrete sample of comparative example 2 are substantially the same as those of example 1. The difference is that 20 steel fibres connecting the two parts of test pieces a and B have a core fibre with an initial tensile stress of 0Mpa, i.e. are electroplated with a copper coating of 0.04mm thickness in the absence of tension.

Soaking the concrete sample of the comparative example 2 in 6% sodium chloride solution, and finding no abnormal change at the crack after 48 hours, wherein the width of the crack is kept unchanged; after the steel pipe is continuously soaked in the sodium chloride solution for 48 hours, no brown rust seeps out, and the width of a crack is kept unchanged; and continuing soaking, wherein after 15 days, the crack position is unchanged, and the crack width is kept unchanged. Experimental results show that the 20 steel fibers do not have the shape memory function, so that the through cracks formed by the absorbent tissue paper cannot be closed, and the steel fibers prepared by the electro-coppering coating do not have the memory function and cannot heal the concrete cracks.

Comparative example 3

The characteristics and preparation method of the concrete sample of comparative example 3 are substantially the same as those of example 1. The difference is that 20 steel fibres connecting the two parts of test pieces a and B have a core fibre with an initial tensile stress of 2000Mpa, i.e. are electroplated with a copper coating of 0.04mm thickness without tension.

Soaking the concrete sample of the comparative example 3 in 6% sodium chloride solution, and finding no abnormal change at the crack after 48 hours, wherein the width of the crack is kept unchanged; after the steel pipe is continuously soaked in the sodium chloride solution for 48 hours, no brown rust seeps out, and the width of a crack is kept unchanged; and continuing soaking, wherein after 15 days, the crack position is unchanged, and the crack width is kept unchanged. The experimental result shows that the 20 steel fibers have no shape memory function, so that the through crack formed by the absorbent tissue paper cannot be closed, and the steel fibers prepared by the electro-coppering coating under the condition of tensile force have no memory function and cannot heal the concrete crack.

Example 2

The characteristics and preparation method of the concrete sample of example 2 are substantially the same as those of example 1. Except that 20 steel fibers for connecting the two parts of the test pieces A and B, and steel fibers without copper plating protection for the core fibers, were used, the same as in example 1.

Soaking the test piece in 6% sodium chloride solution, and finding that a small amount of brown rust appears at the crack after 48 hours, and finding that the width of the crack is narrowed through measurement; cleaning rust on absorbent tissue paper between the part A and the part B of the test piece, and then continuously soaking in a sodium chloride solution for 48 hours to find that brown rust exuded from the tissue paper at the crack is less than that of the last time, and further narrowing the width of the crack by measurement; after 15 days of continued soaking, the crack was found to open, with the widest part of the crack reaching 0.5mm, widening by 0.2mm compared to the initial crack, and 5 steel fibers broken. The experimental result shows that the 20 steel fibers have the shape memory function, but the core fibers are broken due to electrochemical corrosion because the surfaces of the core fibers are not plated with copper, so that the through cracks formed by the absorbent tissue paper are opened again, and the closing force for the healing of the concrete cracks cannot be provided continuously.

Example 3

The concrete test piece characteristics and preparation method of example 3 are substantially the same as example 1. Except that 20 steel fibers connecting the two parts of the test pieces A and B were prepared so that the initial tensile stress of the core fiber was 1500MPa, and the other conditions were the same as in example 1.

The test piece was immersed in a 6wt% sodium chloride solution, and the test result was substantially the same as example 1 in the case where the test conditions were completely the same as example 1.

The invention also tries the matching design of other core materials (such as mineral fibers, carbon fibers, glass fibers, basalt fibers, ceramic fibers and other metal fibers) and other corrosion-prone coatings, and achieves good effects.

In summary, the corrosion-driven smart fiber designed and prepared by the invention shows excellent memory function under corrosion conditions, and shows excellent crack closing function or crack self-healing function when being used in concrete.

Claims

1. A corrosion-driven smart fiber characterized by: the corrosion-driven intelligent fiber consists of a core fiber and/or a core fiber with a corrosion-resistant coating and a corrosion-prone coating; the core fiber and/or the core fiber with the corrosion-resistant coating is in a tensile stress state along the length direction of the fiber; the corrosion-prone coating is in a compressive stress state along the length direction of the fiber; and the core fiber and/or the core fiber with the corrosion-resistant coating and the corrosion-prone coating are in a tension-compression balance state along the length direction of the fiber; the corrosion-prone coating is coated outside the core fiber and/or the core fiber with the corrosion-resistant coating; the corrosion driving intelligent fiber is formed by a single fiber or a stranded wire formed by twisting and stranding a plurality of fibers;

the corrosion rate of the corrosion-prone coating is greater than the corrosion rate of the core fiber under equivalent corrosion environments;

the corrosion rate of the corrosion-susceptible coating is greater than the corrosion rate of the corrosion-resistant coated core fiber under equivalent corrosion conditions.

2. The corrosion-driven smart fiber of claim 1, wherein:

the corrosion-driven intelligent fiber comprises a core fiber and a corrosion-prone coating, and the corrosion-prone coating is coated on part or all of the position outside the core fiber;

or

The corrosion-driven intelligent fiber comprises a corrosion-resistant coating, a core fiber and a corrosion-prone coating; a corrosion-resistant coating is coated on part or all of the positions outside the core fiber; when part or all of the positions outside the core fiber are coated with the corrosion-resistant coating, the obtained material is defined as A; coating a corrosion-prone coating on part of or all of the surface A,

or

The corrosion-driven intelligent fiber comprises a core fiber, a corrosion-prone coating and a corrosion-resistant coating; the core fiber is coated with a corrosion-prone coating; a corrosion-resistant coating is coated on part of the position of the corrosion-prone coating;

or

wherein the core fiber and/or the core fiber with the corrosion-resistant coating is in a tensile stress state along the length direction of the fiber; the corrosion susceptible coating is under compressive stress along the length of the fiber.

3. The corrosion-driven smart fiber of claim 1, wherein: the core fiber is at least one of inorganic fiber and polymer fiber; the equivalent diameter of the core fiber is less than or equal to 20mm.

4. The corrosion-driven smart fiber of claim 1, wherein: the corrosion-resistant coating is made of at least one of copper, nickel, chromium, cadmium, silver and gold elements.

5. The corrosion-driven smart fiber of claim 1, wherein: the cross section of the corrosion-driven intelligent fiber is selected from one of a circle, a polygon and a special-shaped cross section, the special-shaped cross section comprises at least one of a groove shape, a cross shape, a # -shaped cross section, a trilobal cross section, a quincunx cross section and a star shape,

the surface of the corrosion-driven intelligent fiber is in an indentation shape or a ribbed shape;

the shape of the corrosion-driven intelligent fiber is flat, prismatic, wavy, hook-shaped, big-head, double-tip or cluster.

6. A method of making the corrosion-driven smart fiber of any one of claims 1 to 5, wherein: applying a tensile force to the core fiber or the core fiber with the corrosion-resistant coating; then preparing a corrosion-prone coating in a set area on the surface of the coating; removing the tensile force to obtain a sample; the applied tensile force is 10% to 90% of the load-bearing capacity of the core fiber or the core fiber with the corrosion resistant coating.

7. The method of making a corrosion-driven smart fiber of claim 6, wherein: in the whole corrosion-driven intelligent fiber, in order to maximize the prestress applied by the intelligent fiber to the outside, the optimal acquisition method comprises the following steps:

in the formula (11), the first and second groups,

a pre-stress stored for the core fiber;

σ _o is the initial tensile stress value of the core fiber;

E _c ，E _f the modulus of elasticity of the perishable coating and the core fiber, respectively;

A _f Is the cross-sectional area of the core fiber,

a is the cross-sectional area of the intelligent fiber;

namely:

let F' =0, then:

(E _c -E _f )V _f ² -2E _c V _f +E _c ＝0 (14)

when E is _c ＝E _f Then, get

At the moment, F can be the maximum value, namely Fmax is obtained;

when E is _c ≠E _f For equation of time

Order to

and because 0 < V _f < 1, and when E _c ＜E _f When it is, then

root of immature bitter orange

Not satisfying 0 < V _f The condition < 1 should be left off; when in

8. Use of a corrosion-driven smart fiber according to any one of claims 1 to 5, wherein: including use in concrete or fiber reinforced resin composites;

when the corrosion-driving smart fiber is used in concrete, the corrosion-driving smart fiber is anchored in the concrete; the corrosion driving condition is the environment in which the concrete is used.

9. Use of a corrosion-driven smart fiber according to claim 8, wherein: when the corrosion-driven intelligent fiber is used in concrete, the consumption of the corrosion-driven intelligent fiber is 0.01-20 v%.