KR20210055986A - An ultra high performance concrete durability monitoring system using self sensing ability - Google Patents

Abstract

One embodiment of the present invention provides a durability monitoring system for ultra-high performance concrete, comprising: ultra-high performance concrete containing conductive carbon; a power supply unit for applying an electric signal to the ultra-high performance concrete; a sensing unit electrically connected to the ultra-high performance concrete and sensing the electrical signal output from the ultra-high performance concrete; and a measuring unit electrically connected to the sensing unit and determining the durability of the ultra-high performance concrete by using resistance information received from the sensing unit.

Description

Durability monitoring system of ultra-high performance concrete using self-sensing performance {AN ULTRA HIGH PERFORMANCE CONCRETE DURABILITY MONITORING SYSTEM USING SELF SENSING ABILITY}

The present invention relates to a monitoring system for ultra-high-performance concrete, and more particularly, to a system that implements self-sensing performance by introducing conductive carbon into ultra-high-performance concrete, and monitors durability by measuring a change in the resistance fraction of ultra-high-performance concrete. About.

Concrete has excellent strength and durability, and is also the most widely used building material for building social infrastructure because of its excellent price-performance ratio. However, like other building materials, its durability may decrease due to creep, shrinkage, natural disasters, corrosion, freezing and thawing, stress, and fire. In recent years, as the aging infrastructure increases, there is an increasing demand for a method of determining the durability of concrete structures.

An important technical task in a method for determining the durability of a concrete structure is to judge the durability of concrete while minimizing the impact on the structure. Existing methods such as non-destructive testing or core sampling have the advantage of having a small effect on the structure, but there is a disadvantage that excessive time and cost are required to perform these methods, since several tests must be performed in various places. In addition, the non-destructive inspection or core sampling method has a disadvantage in that it is difficult to perform regular inspection because it takes excessive time and cost.

Recently, various attempts have been made in order to overcome the limitations of non-destructive testing or core sampling methods. Among them, self-sensing concrete (SSC) can regularly measure the physical properties of concrete by mixing fillers or sensors into the concrete.

For example, a paper published by F. Azhari, N. Banthia ("Cement-based sensors with carbon fibers and carbon nanotubes for piezoresistive sensing." Cement and Concrete Composites 34.7 (2012): 866-873.) is a carbon fiber. And a method of determining the durability of concrete by mixing carbon nanotubes to improve electrical conductivity of concrete.

However, since the mechanical properties such as strength or durability of the self-sensing concrete and electrical properties such as electrical conductivity are placed in a tradeoff, excellent strength or durability may be lost by mixing a conductive material. Therefore, there is a need to develop a material capable of imparting electrical properties while maintaining or improving the natural mechanical properties of concrete.

KR 101888481 B

F. Azhari, N. Banthia et al., Cement and Concrete Composites 34.7 (2012)

The present invention is to solve the above-described problems of the prior art, and an object of the present invention is to implement self-sensing performance by introducing conductive carbon into ultra-high-performance concrete, and to monitor durability by measuring the change in resistance fraction of ultra-high-performance concrete. It is to provide a system to do.

One aspect of the present invention is an ultra-high performance concrete containing conductive carbon; A power supply for applying an electric signal to the ultra-high performance concrete; A sensing unit electrically connected to the ultra-high-performance concrete and detecting an electrical signal output from the ultra-high-performance concrete; And a measuring unit electrically connected to the sensing unit and determining the durability of the ultra-high-performance concrete using resistance information received from the sensing unit.

In one embodiment, the ultra-high-performance concrete is made of an ultra-high-performance concrete composition, and the ultra-high-performance concrete composition has a water-binder ratio (W/B) of 0.2 to 0.25, cement, conductive carbon, binder, filler, water reducing agent , Steel fibers and water, and cured at 60°C for 3 days, or after curing at 90°C for 2 days, the compressive strength of 3 or 4 days of age may be expressed over 150 MPa.

In one embodiment, the conductive carbon is a group consisting of graphene, carbon fiber, carbon nanowire, carbon nanotube, single-walled carbon nanotube, multi-walled carbon nanotube, bundle-type carbon nanotube, and a combination of two or more of them. It may include one selected from.

In one embodiment, the apparent density of the conductive carbon may be 0.01 to 0.07 g/mL.

In one embodiment, the binder may be one selected from the group consisting of silica fume, silica sand, blast furnace slag, fly ash, and a combination of two or more of them.

In one embodiment, the filling material may be one selected from the group consisting of recovered dust, electric furnace steelmaking dust, casting dust, quartz fine powder, limestone fine powder, stone powder, and a combination of two or more of them.

In one embodiment, based on 100 parts by weight of the cement, the content of the binder is 120 to 150 parts by weight, the content of the filling material is 20 to 50 parts by weight, the content of the water reducing agent is 1 to 10 parts by weight, the content of the water Silver may be 15 to 35 parts by weight, and the content of the conductive carbon may be 1 to 10 parts by weight.

In one embodiment, based on the total amount of the matrix, the content of the steel fiber may be 1 to 3% by volume.

In one embodiment, the ultra-high performance concrete composition may have a surface resistance of 500 Ω/sq or less, measured according to ASTM D-257, after curing at 60 to 90°C.

In one embodiment, the measuring unit receives the resistance information from the sensing unit, calculates a fractional change in resistance (FCR) defined by Equation 1 below, and determines the durability of the ultra-high-performance concrete. An analysis unit that determines; And an output unit that displays a change in a fraction of the resistance calculated by the analysis unit.

[Equation 1]

FCR(%) = (RR ₀ )/R ₀ x 100

Here, R denotes the surface resistance of the ultra-high-performance concrete with a _{change in stress, and R 0} denotes the surface resistance of the ultra-high-performance concrete before the stress changes.

In an embodiment, the system for monitoring durability of the ultra-high-performance concrete may further include a connection part electrically connecting the ultra-high-performance concrete and the power supply unit.

In one embodiment, the connection portion may include a reinforcement reinforced in the concrete structure.

According to an aspect of the present invention, by introducing conductive carbon into the ultra-high-performance concrete, self-sensing performance may be implemented, and durability may be monitored by measuring a change in the resistance fraction of the ultra-high-performance concrete.

The effects of the present invention are not limited to the above effects, and should be understood to include all effects that can be deduced from the configuration of the invention described in the detailed description or claims of the present invention.

1 is a result of a compression test on specimens prepared according to an embodiment and a comparative example of the present invention and a change in the fraction of resistance of ultra-high-performance concrete.

Hereinafter, the present invention will be described with reference to the accompanying drawings. However, the present invention may be implemented in various different forms, and therefore is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, when a part is said to be "connected" with another part, this includes not only "directly connected" but also "indirectly connected" with another member interposed therebetween. . In addition, when a part "includes" a certain component, this means that other components may be further provided, not excluding other components, unless specifically stated to the contrary.

When a range of numerical values is described herein, the value has the precision of significant figures provided according to the standard rules in chemistry for significant figures, unless a specific range thereof is stated otherwise. For example, 10 includes a range of 5.0 to 14.9, and the number 10.0 includes a range of 9.50 to 10.49.

“…” written in the specification Wealth”, “… A term such as “module” refers to a unit that processes at least one function or operation, which may be implemented as hardware or software, or a combination of hardware and software.

The weight percentage described herein is determined based on the total weight of the ultra-high performance concrete composition unless otherwise stated, and the weight part is determined based on 100 parts by weight of Portland cement unless otherwise stated. In addition, the volume percentage described in the present specification is determined based on the volume of the matrix unless otherwise stated.

As used herein, the term "matrix" generally refers to a component constituting a continuous phase in a composite including two or more components, and in the present specification, a component constituting the continuous phase in an ultra-high performance concrete composition I mean. For example, cement in a concrete composition can constitute such a matrix.

As used herein, the term "concrete" refers to concrete in a broad sense including high-performance concrete, ultra-high-performance concrete, fiber reinforced concrete, ready-mixed concrete, and the like.

As used herein, the term "ultra high performance concrete" refers to concrete having a compressive strength of 150 MPa or more.

The term "self sensing concrete" as used herein refers to concrete that can measure the physical properties of concrete by inserting a filler or a sensor into the concrete.

As used herein, the term "workability" refers to a property of concrete that does not cause separation of materials in the construction process of concrete and has a suitable year for construction.

The term "piezoresistive effect" as used herein refers to an effect of increasing or decreasing the resistance of a semiconductor or metal according to a change in an external force applied to the semiconductor or metal.

As used herein, the term "electric curing" refers to a method of accelerating curing concrete by using electric heat generated by applying direct current or alternating current power.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Durability monitoring system of ultra-high performance concrete

Durability monitoring system of ultra-high-performance concrete according to an aspect of the present invention, ultra-high-performance concrete; A power supply for applying an electric signal to the ultra-high performance concrete; A sensing unit electrically connected to the ultra-high-performance concrete and detecting an electrical signal output from the ultra-high-performance concrete; And a measuring unit electrically connected to the sensing unit and determining the durability of the ultra-high-performance concrete using resistance information received from the sensing unit. Since the mechanical and electrical properties of concrete have a trade-off relationship, conventionally, it was not possible to provide concrete capable of realizing both types of properties. Accordingly, in practice, the self-sensing performance was partially implemented by using concrete of general strength with self-sensing performance.

However, when a structure is built by using both general strength concrete and ultra-high-performance concrete with self-sensing performance, there is a risk of collapse of the structure due to unilateral stress applied to the concrete with poor mechanical properties due to different mechanical properties between the two materials.

Therefore, there is a need to develop a material capable of imparting electrical properties while maintaining or improving the natural mechanical properties of concrete.

Republic of Korea Patent Publication No. 10-1888481 discloses a concrete that has self-sensing performance while maintaining excellent mechanical properties by mixing ultra-short glass fibers and steel fibers. However, the concrete disclosed in Korean Patent Publication No. 10-1888481 has a compressive strength of only 94 to 122 MPa.

The ultra-high-performance self-sensing concrete manufactured according to the present invention not only has self-sensing performance by the conductive carbon dispersed therein, but also can have excellent compressive strength by easily implementing high-temperature curing conditions with excellent thermal conductivity.

Since general ultra-high performance concrete has a high resistance characteristic of more than 5 MΩ, there is no change in resistance even when cracks or the like occur. Therefore, in order to detect cracks in such ultra-high performance concrete, a separate sensor or other sensing means must be provided. However, in the ultra-high performance self-sensing concrete according to an embodiment of the present invention, conductive carbons are closely connected to each other in the matrix to show low resistance. In this case, when a crack occurs due to yielding, the connection between the fibers is destroyed and the resistance is reduced. It can increase rapidly. By measuring the change in resistance, durability of the concrete can be measured without a separate sensor.

The ultra-high-performance concrete is made of an ultra-high-performance concrete composition, and the ultra-high-performance concrete composition has a water-binder ratio (W/B) of 0.2 to 0.25, and includes cement, conductive carbon, binder, filler, water reducing agent, steel fiber, and water. And, after curing at 60° C. for 3 days or at 90° C. for 2 days, the compressive strength at 3 or 4 days of age may be expressed as 150 MPa or more, or 180 MPa or more. For example, after curing at 60° C. for 3 days, the compressive strength at 3 or 4 days of age may be 150 MPa or more, and after curing at 90° C. for 2 days and at 3 or 4 days of age, the compressive strength may be 150 MPa or more.

The conductive carbon includes one selected from the group consisting of graphene, carbon fiber, carbon nanowire, carbon nanotube, single-walled carbon nanotube, multi-walled carbon nanotube, bundle-type carbon nanotube, and a combination of two or more of them. It may, and preferably, may include a multi-walled carbon nanotube, but is not limited thereto.

Such conductive carbon is a material for imparting electrical conductivity or piezo-resistance effect to ultra-high-performance concrete, which is a non-conductor, and may provide an electromagnetic wave shielding effect to ultra-high-performance concrete by forming a network with steel fibers.

As a non-limiting example of the present invention, the conductive carbon is a multi-walled carbon nanotube, in particular, a method of manufacturing a multi-walled carbon nanotube using a'continuous process' previously filed by the applicant of the present invention (application number: 10-2018 -0024472)' may be a multi-walled carbon nanotube.

Such multi-walled carbon nanotubes may be aggregated to exist as bundle-type carbon nanotubes. The bundle-type carbon nanotubes may basically exist in a form in which a plurality of carbon nanotubes, preferably, a plurality of multi-walled carbon nanotubes, are aggregated with each other. Each of the carbon nanotubes and their aggregates may be linear, curved, or a mixture thereof.

At this time, the average bundle diameter of the bundle-type carbon nanotubes may be 0.5 µm or more, 1.5 µm or more, or 2.5 µm or more, and may be 20 µm or less, 19 µm or less, or 18 µm or less, and the average bundle length is 10 µm or more, It may be 20 μm or more, or 30 μm or more, and may be 200 μm or less, 190 μm or less, or 180 μm or less. In addition, the Raman spectral intensity ratio (I _G / I _D ) of the multi-walled carbon nanotube may be 0.7 or more, 0.8 or more, or 0.9 or more, 1.5 or less, 1.4 or less, or 1.3 or less, and the average diameter is 5 nm or more. , 7 nm or more, or 9 nm or more, and may be 50 nm or less, 48 nm or less, or 46 nm or less.

The apparent density of the conductive carbon may be 0.01 g/mL or more, 0.02 g/mL or more, or 0.03 g/mL or more, and 0.07 g/mL or less, 0.06 g/mL or less, or 0.05 g/mL or less. If the apparent density of the conductive carbon is less than 0.01 g/mL, an excessive scattering problem may occur, and if it exceeds 0.07 g/mL, the dispersibility of the conductive carbon may be lowered when mixing the ultra-high performance concrete composition.

The binder may be one selected from the group consisting of silica fume, silica sand, blast furnace slag, fly ash, and a combination of two or more of them, and preferably, a combination of silica fume and silica sand. It may be, but is not limited thereto. Such a binder can improve the fluidity of the ultra-high-performance concrete composition due to low friction between particles, and can improve the durability of the ultra-high-performance concrete by forming a tight structure by filling the voids inside the ultra-high-performance concrete. In addition, it is possible to improve the watertightness of ultra-high-performance concrete by causing a pozzolanic reaction with a filling material such as fine limestone powder.

The filling material may be one selected from the group consisting of recovered dust, electric furnace steelmaking dust, casting dust, quartz fine powder, limestone fine powder, stone powder, and a combination of two or more of them, and preferably, quartz fine powder, but limited thereto. It does not become. Such a filling material can improve the durability of the ultra-high-performance concrete by forming a tight structure by filling the voids in the ultra-high-performance concrete.

As a non-limiting example of the present invention, the water reducing agent may be a high performance water reducing agent. The high performance water reducing agent can strongly disperse cement particles, thus improving the workability of ultra-high performance concrete. In addition, it is possible to improve the durability of ultra-high performance concrete by lowering the water-binder ratio (W/B).

As a non-limiting example of the present invention, the curing condition may be 60°C or higher, 65°C or higher, or 70°C or higher, and 90°C or lower, 85°C or lower, or 80°C or lower. Curing conditions may be adjusted in the above-described range in consideration of the temperature and humidity of the construction site, and if the curing temperature condition is excessively low, the hydration reaction decreases and the durability of the ultra-high-performance concrete may decrease, and if excessively high As moisture evaporates, voids can form and cracks may occur in the ultra-high-performance concrete.

In this case, the curing may be performed by one selected from the group consisting of electric curing, electric heat curing, pressurized curing, high frequency curing, steam curing, autoclave curing, and a combination of two or more of them, but is not limited thereto.

With respect to 100 parts by weight of the cement, the content of the binder may be 120 parts by weight or more, 125 parts by weight or more, or 130 parts by weight or more, and may be 150 parts by weight or less, 145 parts by weight or less, or 140 parts by weight or less, and the filler The content of 20 parts by weight or more, 25 parts by weight or more, or 30 parts by weight or more, may be 50 parts by weight or less, 45 parts by weight or less, or 40 parts by weight or less, and the content of the water reducing agent is 1 part by weight or more, 2 parts by weight Parts by weight or more, or 3 parts by weight or more, and may be 10 parts by weight or less, 9 parts by weight or less, or 8 parts by weight or less, and the content of water is 15 parts by weight or more, 17 parts by weight or more, or 19 parts by weight or more, and 35 It may be less than or equal to 33 parts by weight, or less than 31 parts by weight.

As a non-limiting example of the present invention, the content of the conductive carbon may be 1 part by weight or more, 2 parts by weight or more, or 3 parts by weight or more, and may be 10 parts by weight or less, 9 parts by weight or less, or 8 parts by weight or less. . The content of conductive carbon may be adjusted within the above-described range in consideration of the material properties of the ultra-high-performance concrete to be implemented, for example, surface resistance, electromagnetic wave shielding effect, compressive strength, and the like. If the content of the conductive carbon is less than 1 part by weight, the material properties of the ultra-high-performance concrete may be deteriorated, and if it exceeds 10 parts by weight, the original mechanical properties of the ultra-high-performance concrete may be reduced.

The content of the steel fibers may be 1 vol% or more, 1.2 vol% or more, or 1.4 vol% or more, 3 vol% or less, 2.8 vol% or less, or 2.6 vol% or less based on the cement. The content of the steel fiber may be adjusted within the above-described range in consideration of the material properties of the ultra-high-performance concrete to be implemented, for example, surface resistance, electromagnetic shielding effect, compressive strength, and the like. If the content of the steel fiber is less than 1% by volume, the material properties of the ultra-high-performance concrete may be deteriorated, and if it exceeds 3% by volume, an excessive load may be generated in the blender during the mixing process of the ultra-high-performance concrete composition, and the high price of steel fiber As a result, economic feasibility may be significantly reduced.

These steel fibers are materials for imparting durability or compressive strength to ultra-high-performance concrete, and may implement an electromagnetic wave shielding effect by forming a network with conductive carbon.

The ultra-high performance concrete composition may have a surface resistance of 500 Ω/sq or less, 300 Ω/sq or less, or 200 Ω/sq or less, measured according to ASTM D-257, after curing at 60 to 90°C.

These ultra-high performance concrete compositions can be applied to disaster prevention facilities or collective energy facilities, for example, dams or nuclear power plants.

The power supply unit refers to a region electrically connected to the ultra-high performance concrete to apply a variable voltage.

The sensing unit refers to an area that senses the electrical signal output from the ultra-high-performance concrete, measures the surface resistance of the ultra-high-performance concrete to generate resistance information, and transmits the generated resistance information to the measurement unit. This sensing unit is electrically connected to the ultra-high-performance concrete, and may be installed on one side of the ultra-high-performance concrete. The connection may refer to a wireless connection using wireless communication technology in addition to a wired connection such as an electric wire.

The measuring unit refers to an area for determining the durability of the ultra-high-performance concrete by using the resistance information received from the sensing unit. Such a measuring unit is electrically connected to the sensing unit and may receive resistance information from the sensing unit. The connection may refer to a wireless connection using wireless communication technology in addition to a wired connection such as an electric wire.

The measuring unit receives the resistance information from the sensing unit, calculates a fractional change in resistance (FCR) defined by Equation 1 below, and determines the durability of the ultra-high-performance concrete; And an output unit that displays a change in a fraction of the resistance calculated by the analysis unit.

[Equation 1]

FCR(%) = (RR ₀ )/R ₀ x 100

Here, R denotes the surface resistance of the ultra-high-performance concrete with a _{change in stress, and R 0} denotes the surface resistance of the ultra-high-performance concrete before the stress changes. The R ₀ may be a value measured after the structure including the ultra-high performance concrete is manufactured. Alternatively, it may be an average of resistance values measured for a predetermined time before the measurement of R.

The stress acting on the ultra-high-performance concrete may be changed by pressure, rotational force, impact, shrinkage, tension, strength, melting, temperature, humidity, freezing and abrasion, and the like. As the stress changes, cracks may occur inside the ultra-high-performance concrete, the network structure formed by conductive carbon or steel fibers may collapse, and the resistance of the ultra-high-performance concrete may rapidly increase as the network structure collapses. have.

That is, the sudden change in the resistance of the ultra-high-performance concrete may mean that a crack occurs or the network structure collapses inside the ultra-high-performance concrete, and the durability of the ultra-high-performance concrete can be predicted by measuring the sudden change in resistance.

The analysis unit receives the resistance information from the sensing unit, calculates a resistance fraction change (FCR) value and compares it with a predetermined threshold value, and the resistance fraction change (FCR) value calculated by the analysis unit is the threshold. If it exceeds the value, a warning message can be displayed through the output unit. Such an analysis unit may be arranged to be electrically connected to the sensing unit. The connection may refer to a wireless connection using wireless communication technology in addition to a wired connection such as an electric wire.

The threshold value may be 1% or more, 10% or more, 20% or more, 30% or more, or 40% or more, and may be 100% or less, 90% or less, 80% or less, or 70% or less. The threshold value may be adjusted within the above-described range according to the user. If the threshold value is less than 1%, the monitoring system operates in response to a temporary stress change, so that the reliability of the system may decrease, and if it exceeds 100%, the accuracy of the system may decrease.

The durability monitoring system of the ultra-high-performance concrete may further include a connection part electrically connecting the ultra-high-performance concrete and the power supply unit. Here, the connection portion refers to a region that transmits the variable voltage applied from the power supply to the ultra-high-performance concrete.

The connection portion may include a reinforcement reinforced in the concrete structure.

Hereinafter, embodiments of the present invention will be described in more detail. However, the following experimental results are only representative of the above examples, and the scope and contents of the present invention are reduced or limited by the examples, and thus cannot be interpreted. Effects of each of the various embodiments of the present invention that are not explicitly presented below will be specifically described in the corresponding section.

Example 1

Portland cement 100 parts by weight, silica fume 25 parts by weight, silica sand 110 parts by weight, high performance water reducing agent 5 parts by weight, fine quartz powder 35 parts by weight, steel fiber 2.0% by volume, water 24 parts by weight, 1.5 parts by weight of multi-walled carbon nanotube powder prepared I did.

100 parts by weight of Portland cement, 25 parts by weight of silica fume, 110 parts by weight of silica sand, 5 parts by weight of a high-performance water reducing agent, 35 parts by weight of fine quartz powder, and 2.0% by volume of steel fiber were added to a blender and blended to prepare a blend.

1.5 parts by weight of the multi-walled carbon nanotube powder was added to 24 parts by weight of water, and ultrasonic waves were applied to prepare a carbon nanotube dispersion, and then added to the blend and blended to obtain an ultra-high performance concrete composition.

The volume% of the steel fibers was measured based on the total amount of the matrix.

Example 2

An ultra-high performance concrete composition was obtained in the same manner as in Example 1, except that the multi-walled carbon nanotube powder was adjusted to 3.0 parts by weight.

Example 3

An ultra-high performance concrete composition was obtained in the same manner as in Example 1, except that the multi-walled carbon nanotube powder was adjusted to 3.6 parts by weight.

Example 4

An ultra-high performance concrete composition was obtained in the same manner as in Example 1, except that the multi-walled carbon nanotube powder was adjusted to 4.5 parts by weight.

Example 5

An ultra-high performance concrete composition was obtained in the same manner as in Example 1, except that the multi-walled carbon nanotube powder was adjusted to 6 parts by weight.

Comparative Example 1

An ultra-high performance concrete composition was obtained in the same manner as in Example 1, except that steel fibers and multi-walled carbon nanotube powder were not added.

Comparative Example 2

An ultra-high performance concrete composition was obtained in the same manner as in Example 1, except that the multi-walled carbon nanotube powder was not added.

Experimental Example 1. Resistance performance measurement experiment

In order to measure the change in resistance performance of ultra-high-performance concrete according to the addition of multi-walled carbon nanotubes or steel fibers, an ultra-high-performance concrete composition was poured and cured to prepare a washer-shaped specimen.

The prepared specimens were measured for surface resistance according to ASTM D-257 and are shown in Table 1.

division Weight percent of multi-walled carbon nanotubes (%) Volume percentage of steel fiber (%) Surface resistance (Ω/sq) Example 1 0.5 2.0 1.6×10 ⁵ Example 2 1.0 2.0 241 Example 3 1.2 2.0 30 Example 4 1.5 2.0 17 Example 5 2.0 2.0 11 Comparative Example 1 0 0 6×10 ⁹ Comparative Example 2 0 2.0 1.5×10 ⁴

Referring to Table 1, when compared with the ultra-high-performance concrete prepared according to Comparative Examples 1 to 2, the ultra-high performance concrete prepared according to Examples 1 to 5 has surface resistance as the amount of multi-walled carbon nanotubes or steel fibers increased. It can be seen that this decreases. In particular, ultra-high-performance concrete in which 1.2 to 2.0% by weight of multi-walled carbon nanotubes are added and 2.0% by volume of steel fibers are added at the same time has a synergistic effect between the multi-walled carbon nanotubes and steel fibers, resulting in surface resistance of 11 to 30 Ω/sq. Show.

According to these experimental results, as the amount of conductive carbon or steel fiber such as multi-walled carbon nanotubes increases, the surface resistance decreases, so that the power or heat generation amount of the ultra-high-performance concrete can be easily controlled. In other words, it is possible to provide ultra-high-performance concrete with easy control of the calorific value by adjusting the input amount of conductive carbon or steel fiber.

As the surface resistance decreases, the change in the fraction becomes more pronounced, so the durability monitoring system of the ultra-high-performance concrete according to the present invention can accurately determine the durability of the ultra-high-performance concrete by controlling the amount of conductive carbon or steel fiber input.

Experimental Example 2. Compressive strength comparison experiment

In order to compare the durability or compressive strength of ultra-high-performance concrete according to the curing method, a cubic-shaped specimen was prepared by pouring and curing an ultra-high-performance concrete composition.

Specifically, the ultra-high-performance concrete composition obtained according to Examples 1 to 5 was poured, and 15 V was applied for 15 minutes on the next day to adjust the internal temperature of the ultra-high-performance concrete composition to 60°C, followed by seconds for 3 days. A specimen was prepared by electric curing while maintaining the internal temperature of the high-performance concrete composition at 60°C.

The ultra-high-performance concrete composition obtained according to Comparative Example 2 was prepared by adjusting the temperature of the ultra-high-performance concrete composition to 60°C using a thermo-hygrostat the next day it was placed, and maintaining the temperature of the ultra-high-performance concrete composition at 60°C for 3 days. The specimen was prepared by steam curing.

The compressive strength of the prepared specimens was measured according to KS F 2405 and is shown in Table 2.

division Weight percent of multi-walled carbon nanotubes (%) Compressive strength for 3 days of age (MPa) Example 1 0.5 187.390 Example 2 1.0 194.283 Example 3 1.2 196.564 Example 4 1.5 175.486 Example 5 2.0 150.752 Comparative Example 2 0 181.064

Referring to Table 2, it can be seen that the compressive strength of the ultra-high-performance concrete prepared according to Examples 1 to 5 is high when compared with the ultra-high-performance concrete prepared according to Comparative Example 2. In particular, compared to the compressive strength of the specimen prepared according to Comparative Example 2, it can be seen that the compressive strength of the specimen prepared according to Example 3 increased by 8.56%.

That is, under the same temperature conditions, it can be seen that the compressive strength of ultra-high-performance concrete manufactured according to the electric curing method is superior to that of the ultra-high-performance concrete manufactured according to the steam curing method. This is because there is a difference in the amount of heat actually transferred to the ultra-high performance concrete composition.

A network structure may be formed inside the ultra-high-performance concrete manufactured according to the electric curing method. Here, the network structure may be formed by infiltrating an empty space existing between a matrix of conductive carbon or steel fibers such as multi-walled carbon nanotubes. According to the electric curing method, heat can be uniformly transferred through the network structure. In addition, conductive carbon, such as multi-walled carbon nanotubes, has excellent heat conduction performance and thus can efficiently transfer heat.

Experimental Example 3. Magnetic Sensing Performance Comparison Experiment

1 shows the results of a compression test on specimens prepared according to Example 3 and Comparative Example 2 and a fractional change in resistance (FCR) of ultra-high performance concrete.

Referring to FIG. 1, immediately after the pressure applied to the specimen reaches the compressive strength, the FCR of the specimen manufactured according to Example 3 rapidly increases, whereas the FCR of the specimen manufactured according to Comparative Example 2 is 0. It can be seen that it converges on. That is, in the ultra-high-performance concrete according to the present invention, as the stress changes, the network structure collapses and the FCR may increase rapidly, which is a piezo-resistance effect even though the ultra-high-performance concrete according to the present invention does not belong to semiconductors or metals. Means you can have.

Therefore, the user can determine the durability of the ultra-high-performance concrete by setting a threshold value, measuring the change in the fraction of resistance using the ultra-high-performance concrete having self-sensing performance according to the present invention, and comparing the two values.

The above description of the present invention is for illustrative purposes only, and those of ordinary skill in the art to which the present invention pertains will be able to understand that other specific forms can be easily modified without changing the technical spirit or essential features of the present invention. will be. Therefore, it should be understood that the embodiments described above are illustrative and non-limiting in all respects. For example, each component described as a single type may be implemented in a distributed manner, and similarly, components described as being distributed may also be implemented in a combined form.

The scope of the present invention is indicated by the claims to be described later, and all changes or modified forms derived from the meaning and scope of the claims and the concept of equivalents thereof should be construed as being included in the scope of the present invention.

Claims (12)

Ultra-high performance concrete containing conductive carbon;
A power supply for applying an electric signal to the ultra-high performance concrete;
A sensing unit electrically connected to the ultra-high-performance concrete and sensing an electrical signal output from the ultra-high-performance concrete; And
Containing, a durability monitoring system of ultra-high-performance concrete, which is electrically connected to the sensing unit and determines the durability of the ultra-high-performance concrete using resistance information received from the sensing unit. The method of claim 1,
The ultra-high performance concrete is made of an ultra-high performance concrete composition,
The ultra-high performance concrete composition has a water-binder ratio (W/B) of 0.2 to 0.25,
Including cement, conductive carbon, binder, filler, water reducing agent, steel fiber and water,
Durability monitoring system of ultra-high-performance concrete in which the compressive strength of 3 days or 4 days of age is expressed over 150 MPa after curing at 60°C for 3 days or 90°C for 2 days. The method of claim 2,
The conductive carbon includes one selected from the group consisting of graphene, carbon fiber, carbon nanowire, carbon nanotube, single-walled carbon nanotube, multi-walled carbon nanotube, bundle-type carbon nanotube, and a combination of two or more of them. , Ultra-high performance concrete durability monitoring system. The method of claim 2,
The apparent density of the conductive carbon is 0.01 to 0.07 g / mL, the durability monitoring system of ultra-high performance concrete. The method of claim 2,
The binder is one selected from the group consisting of silica fume, silica sand, blast furnace slag, fly ash, and a combination of two or more of them, the durability monitoring system of ultra-high performance concrete. The method of claim 2,
The filling material is one selected from the group consisting of recovered dust, electric furnace steelmaking dust, casting dust, quartz fine powder, limestone fine powder, stone powder, and a combination of two or more of them, the durability monitoring system of ultra-high performance concrete. The method of claim 2,
Based on 100 parts by weight of the cement,
The content of the binder is 120 to 150 parts by weight,
The content of the filling material is 20 to 50 parts by weight,
The content of the water reducing agent is 1 to 10 parts by weight,
The content of water is 15 to 35 parts by weight,
The content of the conductive carbon is 1 to 10 parts by weight, durability monitoring system of ultra-high performance concrete. The method of claim 2,
Based on the total amount of cement,
The content of the steel fiber is 1 to 3% by volume, durability monitoring system of ultra-high performance concrete. The method of claim 2,
The ultra-high-performance concrete composition has a surface resistance of 500 Ω/sq or less, measured according to ASTM D257, after curing at 60 to 90° C., and durability monitoring system of ultra-high-performance concrete. The method of claim 1,
The measuring unit receives the resistance information from the sensing unit, calculates a fractional change in resistance (FCR) defined by Equation 1 below, and determines the durability of the ultra-high-performance concrete; And
An output unit that displays the change in the fraction of resistance calculated by the analysis unit; including, durability monitoring system of ultra-high performance concrete:
[Equation 1]
FCR(%) = (RR ₀ )/R ₀ x 100
Here, R denotes the surface resistance of the ultra-high-performance concrete with a _{change in stress, and R 0} denotes the surface resistance of the ultra-high-performance concrete before the stress changes. The method of claim 1,
The ultra-high-performance concrete durability monitoring system further comprises a connection part electrically connecting the ultra-high-performance concrete and the power supply unit. The method of claim 11,
The connection unit includes a reinforcement reinforced in a concrete structure, durability monitoring system of ultra-high performance concrete.

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