KR20180102757A - Pull-out test specimen, Method for manufacturing specimen, and Pull-out tester - Google Patents

Abstract

The present invention relates to a fiber reinforcing concrete block, and relates to a fiber reinforcing concrete specimen, a manufacturing method of a specimen, and a fiber pull-out tester. In particular, the pull-out specimen comprises: a block forming one surface and the other surface, and formed of concrete; and a fiber inserted into the block at one side, and protruding to the other surface of the block at the other side thereof.

Description

Drawing test specimen, Drawing test specimen production method and Drawing test apparatus. {Pull-out test specimen, Method for manufacturing specimen, and Pull-out tester}

The present invention relates to a fiber reinforced concrete block, and a fiber reinforced concrete specimen, a method of manufacturing a specimen, and a fiber drawing tester.

Patent Document 001 relates to a drawing tester. More specifically, it is possible to use a plurality of gears and pull out the bolts by the rotational force of the gears, so that they can be used without a separate power source, can be tested by a single person, and can be manufactured at low cost. Feature. The power transmission unit is detachably mounted and the support base can be inserted into the housing, thereby facilitating the movement. To this end, Patent Document 001 discloses a pull-out tester for pulling out a bolt embedded in a concrete surface and estimating the strength of the concrete, comprising: a gear assembly having a plurality of gears meshed with each other; And a housing for receiving the gear assembly. The gear assembly includes a housing, a housing, and a housing.

Patent Document 002 discloses a method for forming a circular clamp and a jig of a pulling and fastening device so that a soft geosynthetic fiber reinforcement can be wound and fixed, thereby easily joining and pulling the geosynthetic reinforcement, It is also possible to evaluate on-site resistance and fixability of the geosynthetic fiber reinforcement, and it is possible to apply on-site soil nailing method using geosynthetics, It is about the method.

Patent Document 003 discloses that 5 to 50 parts by weight of a filler composed of aluminum hydroxide, calcium carbonate or a mixture thereof based on 100 parts by weight of a urethane resin; 70 to 90 parts by weight of a molded product obtained by drawing basalt fiber, aramid fiber, glass fiber, carbon fiber or a mixture of at least one selected from the foregoing; 5 to 20 parts by weight of a curing agent; 1 to 10 parts by weight of an adhesion promoter; And 3 to 15 parts by weight of a water-reducing finishing agent. The FRP composition according to Patent Document 003 improves the mechanical performance, durability, impact resistance and strength by allowing the high strength urethane resin to be impregnated into a composite material obtained by drawing basalt fiber, glass fiber, carbon fiber or metal fiber, And to simplify the production process.

Patent Document 004 discloses a composition comprising 0.1 to 25 parts by weight of N- (2-aminoethyl-3-aminopropyl) trimethoxysilane based on 100 parts by weight of a phenol resin; 10 to 300 parts by weight of aluminum hydroxide, calcium sulfate, kaolin, talc or mixtures thereof; 0.1 to 25 parts by weight of an antifoaming agent; And 0.1 to 25 parts by weight of a dispersing agent; 5 to 40 parts by weight of a curing agent based on 100 parts by weight of a phenol resin; 10 to 30% by weight of a phenolic resin composition consisting of a curing agent mixture comprising 5 to 100 parts by weight of a resorcinol resin; And 70 to 90% by weight of a fiber material, and a method of using the semi-fireproof reinforcement panel composition. The semi-fireproof reinforcement panel composition according to Patent Document 004 prevents environmental accidents caused by heat and fire at the time of occurrence of a fire, thereby preventing a secondary accident, and is environment-friendly and aims to improve maintenance and reinforcement.

KR 10-2010-0002545 A (Published on January 07, 2010) KR 10-1455753 B1 (Registration date October 22, 2014) KR 10-1667530 B1 (Registration date October 13, 2016) KR 10-1599432 B1 (Registered on February 25, 2016)

The present invention relates to a fiber reinforced concrete block, and a fiber reinforced concrete specimen, a method of manufacturing a specimen, and a fiber drawing tester.

The present invention relates to a draw sample of the present invention which forms one side 101a and another side 101b and includes a block 101 made of concrete and one side 102a inserted into the block 102b And the other side 102b projects from the block face.

A method for manufacturing a drawn specimen of the present invention includes a fiber fixing step (S100) for fixing one side of a fiber and a second side of a fiber in a straight line, a block forming step (S200) for molding a concrete to insert a fiber intermediate side, And a chamfering step (S300) of forming a plane.

The pull test apparatus according to the present invention is characterized in that the pull test apparatus includes a load cell 201 to which a block face 101b is fixed, a first grip 202 for fixing a fiber side 102a, An actuator 203 for moving the actuator 203, and a displacement sensor 204 for measuring the movement distance of the actuator.

The drawing test apparatus according to the present invention includes a position corrector (400) including a moving tool (402) for moving the first grip or the load cell linearly.

The draw test apparatus according to the present invention is characterized in that the draw test apparatus according to the present invention includes a chamber 501 forming a receiving space therein and accommodating the load cell and the first figure in the receiving space, a door 502 formed on one side of the chamber, .

The present invention has the effect of measuring the adhesive force of concrete attached to the inside of concrete.

The drawn specimen of the present invention has the effect of forming the internal fibers of the concrete straightly or at various angles.

The present invention has the effect that the concrete block and the tester can be easily and strongly fastened.

The draw test apparatus of the present invention has an effect of automatically performing error correction by judging the state of the specimen installation, has the effect of realizing the constant temperature and humidity test conditions, can quickly implement the specimen fastening, The pulling direction can be variously implemented.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a perspective view of a concrete block and fiber arrangement of a drawn specimen of the present invention. FIG.
FIG. 2 is a conceptual diagram of a production sequence according to the drawing process of the present invention. FIG.
3 is a perspective view of a drawing test apparatus according to the present invention.
4 is a conceptual diagram for correcting a correct position of a drawn specimen mounted on a drawing test apparatus according to the present invention.
5 is a structural view of a chamber of a drawing test apparatus according to the present invention.
6 is a conceptual diagram illustrating various pullout load generation of the pulling test apparatus of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(Example 1-1) A drawing specimen of the present invention forms one face 101a and the other face 101b, and a block 101 made of concrete; one side 102a is inserted into the block 102b; (102b) protruding from the block face.

The concrete material has high brittleness. Therefore, a concrete structure subjected to tensile load easily cracks and breaks. To solve these problems, we invented a concrete material with increased toughness and reduced brittleness. The improved concrete material contains a large amount of microfibers inside. Microfibers increase the ductility of concrete. Therefore, the deformation amount of the concrete structure is increased, and the effect of reducing the concentration of crack tip stress can be obtained.

The toughness size of the concrete structure is influenced by the micro fiber and concrete bond strength. In other words, the bonding force varies depending on the kind of the microfibers and the materials used in the concrete. Accurate and economical design is possible by measuring the bond strength between two materials to ensure high toughness of concrete. The object of the present invention is a drawing specimen for judging the bonding force between concrete and microfibers. In the drawn specimen of the present invention, the minute fibers are attached to the block-shaped concrete in one direction, and the pulling force is determined by measuring the load and the amount of drawing required for drawing the minute fibers. Therefore, the micro fiber is attached to the same length as the concrete block thickness, and the micro fiber is protruded by the concrete block for the micro fiber grip.

(Example 1-2) In the drawn specimen of the present invention, in Example 1-1, the fibers include those formed perpendicular to the other surface of the block.

In order to impart one-directional pulling force of the microfibers inserted into the concrete, one side of the microfibers protruded from one side of the concrete block and the other side of the microfibers inserted into the concrete block are maintained in a straight line, Forming a vertical.

(Example 1-3) The drawn specimen of the present invention is the one in Example 1-1, in which one side of the fiber passes through one side of the block and the other side.

In order to determine the accurate pulling force, the length of the micro fiber inserted into the concrete must be accurately measured. However, there is a problem that the microfibers can not be inserted in the straight direction during the concrete molding. Therefore, when the microfibers are inserted in the linear direction, the length of the microfibers can be determined by the thickness of the concrete block. As a result, it is necessary to satisfy the micro fiber condition that the concrete block penetrates through one side and the other side in a straight line.

(Example 1-4) The drawn specimen of the present invention is the one in Example 1-1, wherein the fiber is formed of any one selected from among PE, PP, and PVA.

The microfibers inserted into the concrete block are made of a polymer material. Preferably, polypropylene (PP), polyethylene (PE), and polyvinyl alcohol (PVA) are used, and even materials not shown above exhibit the same purpose, .

(Examples 1-5) The drawn specimens of the present invention are those having a fiber thickness of 0.01 mm to 0.1 mm and a uniform thickness in Example 1-1. Preferably 0.039 mm in diameter.

In the micro fiber drawing test, if the necking phenomenon occurs in the middle of the micro fiber, accurate test results can not be obtained. Therefore, the microfibers must be formed in a uniform thickness. If the thickness of the minute fiber is 0.06 mm or more, the effect of mixing the concrete with the minute fiber is lowered. If the thickness of the minute fiber is less than 0.1 mm, the production of the minute fiber is affected. Therefore, the fiber thickness of 0.01 mm to 0.1 mm corresponds to a numerical range having critical meaning and effect.

 (Example 1-6) The drawn specimen of the present invention was formed on one surface of the block in Example 1-1, and formed into a plurality of the adhesive grooves 103, which were arranged at uniform intervals and formed in a uniform size .

Pull-out small size specimens can not be easily fixed to the drawing machine. For stable fixing of the drawing specimen and tester, adhesive material is attached to the other side of the concrete block and fixed to the testing machine. In order to improve the adhesion efficiency between the adhesive material and the concrete block, a plurality of grooves are formed on the other surface of the concrete block, and the adhesive material inserted into the grooves enables stable fixing of the concrete block and the tester.

 (Examples 1-7) In the drawn specimens of the present invention, the adhesive grooves are formed in a hemispherical shape, a hexahedron shape, a tetrahedron shape, a linear or circular triangular shape, a linear or circular semicircular shape, Or formed in a rectangular shape of a circle.

The wider the inner surface area of the adhesive groove, the greater the bonding efficiency. Therefore, it is preferable to form a plurality of adhesive grooves. On the other hand, as the size of the adhesive grooves increases, the deformation of the concrete block may occur due to the pullout load. The adhesive grooves were formed in the shapes shown in Examples 1-7.

(Example 2-1) A method of manufacturing a drawn specimen of the present invention comprises a fiber fixing step (S100) for fixing a fiber on one side and the other side in a straight line, a block forming step (S200) for forming a concrete to insert a fiber intermediate side, And a chamfering step (S300) of forming a plane on the block surface (101b).

The micro fiber drawn in the concrete block should keep the micro fiber in the concrete block straight and the concrete block surface attached to the tester should maintain the right angle with the micro fiber.

Specimen fabrication under these conditions maintains the microfibers in a straight line, which requires a fiber fixation step in which one side and the other side of the microfibers are fixed and tensioned at an appropriate load.

The mold is formed on the middle side while the micro fiber is kept straight, and the block is formed by pouring concrete into the mold.

After the concrete block is formed, the one side of the concrete block is processed horizontally, and the microfibers are also cut together in the horizontal processing.

(Example 2-2) In the method for manufacturing a drawn specimen of the present invention, the block molding step includes a fiber-penetrating die in Example 2-1.

The concrete form pierces the micro fiber. Therefore, the die forms a micro fiber through hole in advance.

(Example 2-3) In the method of manufacturing a drawn specimen of the present invention, in the example 2-2, the fiber through-die forms a concrete injection surface or a concrete injection port.

For forming the concrete, the form forms a concrete injection surface or a concrete injection port. Stable refuse For mold release, the mold is made to be assembled.

(Example 2-4) In the method for manufacturing a drawn specimen of the present invention, in the example 2-1, one side of the fiber and the other side of the fiber are straight lines in the gravity direction in the fiber fixing step.

The straightness of the microfibers and the formability of the concrete must be considered. For this purpose, the microfibers are preferably formed in a straight line, and the concrete form is preferably formed in the direction of gravity.

(Example 2-5) The drawn specimen manufacturing method of the present invention includes the groove machining step (S400) of working the groove on the block face after the chamfering step in the example 2-1.

The grooves are machined on the specimen's specimen to completely fix the specimen to the test machine as previously suggested. Grooving is performed after chamfering.

(Embodiment 2-6) In the method of manufacturing a pull test specimen of the present invention, in the embodiment 2-1, the mold used in the block molding step includes a side mold 521 forming a side surface of the block, And a second die 523 forming the other side of the block. The first die and the second die cover one side and the other side of the opening of the side die.

A micro fiber through hole 524 is formed in the center of the first and second molds, and the through hole forms a tapered shape. The small hole in the tapered shape accommodates the thickness of the minute fiber, and the large hole in the tapered shape accommodates the angle change of the minute fiber. That is, the microfibers inside the block are not necessarily formed vertically, but can form an inclination. In order for the micro fiber to be inclined in the block, a straight line connecting the first die and the through hole of the second die must form an inclination inside the die. Also for the implementation of various tilt angles, the first and second molds must be assembled in various positions with the side molds.

(Example 3-1) A draw test apparatus of the present invention comprises a load cell 201 to which a block surface 101b of the first embodiment is fixed, a first grip 202 for fixing the fiber side 102a of the first embodiment, An actuator 203 for moving the grip or the load cell, and a displacement sensor 204 for measuring the movement distance of the actuator.

The drawing of the microfibers inserted in the concrete block gives a load in the same direction as the fiber direction. The load application uses an actuator fixed to one side of the micro fiber. The drawing speed does not cause any dynamic influence on the microfibers and applies a speed range in which the microfibers are not damaged during the drawing process. Preferably, the drawing speed is given at a rate of 0.01 mm / min.

The first grip is used for coupling the micro fiber and the actuator. The first grips completely fix one side of the microfibers, do not cause damage to the microfibers, and should not cause slippage during the drawing process. The load size of the micro fiber is measured by a load cell. The amount of microfibers drawn from the concrete block is measured by a displacement sensor. The displacement sensor is preferably a laser displacement sensor, or an LVDT or the like can be used.

(Example 3-2) A draw test apparatus according to Example 3-1 of the present invention includes a first controller 205 for receiving the load cell load signal and the displacement signal of the displacement sensor and driving the actuator, .

The load cell shown above measures the load, and the displacement sensor measures the amount of drawing. The graph shows the relationship between the load and the pullout. The first controller measures the electrical signals of the load cell and the displacement sensor to show the relationship between the load and the displacement, and also drives the actuator.

(Example 3-3) The draw test apparatus according to the present invention includes a specimen fixing unit 300 according to Example 3-1, one side of which is coupled to the block face 101b and the other side of which is coupled to the load cell do.

Conventional experiments utilize common results obtained from a plurality of experiments as useful result values. When the specimen is fixed to the load cell, the test efficiency is reduced. Therefore, it is desirable to construct a plurality of specimen fixing parts by test piece. The present invention utilizes a specimen fixing unit which is easy to be coupled with and separated from a load cell. In other words, it is possible to fix the test specimen to a plurality of specimen holders, and to assure the ease of combining the specimen with the load cell quickly and accurately during the test process.

(Embodiment 3-4) In the draw test apparatus of the present invention, in the embodiment 3-3, one side of the specimen fixing section is formed in a plane.

The specimen fixture is fixed to the concrete block. That is, it is necessary to maintain the other surface and the plane of the concrete block.

(Embodiment 3-5) In Embodiment 3-3, the draw test apparatus of the present invention is characterized in that the specimen fixing section has a fixing section 301 which is engaged with a load cell; And a specimen clamping plate 302 coupled to the block face, wherein the fixed portion and the load cell are coupled by fastening means 303.

The fixing unit and the load cell are coupled by a fastening means in order to improve the mounting convenience of the specimen fixing unit and the load cell. On the other hand, the mating face of the specimen fixture forms a plane for parallel connection with the concrete block.

(Embodiment 3-6) In the draw test apparatus of the present invention, in the embodiment 3-5, the fastening means includes a groove-and-projection connection 303a, a screw connection 303b, and a magnetic connection 303c do.

The above-mentioned fastening means apply various constructions as follows. The fixing device is applied so that the fixing part and the load cell are coupled to each other at the correct position by applying grooves and projections, and formed so as not to be separated by the pulling load. As an example thereof, two objects to be combined are coupled by screwing. That is, a male screw is formed on the fixing part, and a female screw is formed on the load cell or the screw is screwed on the screw. Also, the fixed part and the load cell are connected by using the magnetic force of the magnet. A plurality of magnets having different polarities are formed on the contact surfaces when the magnets are coupled, and the position is accurately and quickly determined.

(Examples 3-7) In the draw test apparatus of the present invention, in the embodiment 3-3, the second grip 311 is formed on the specimen fixing part.

The plane of the specimen fixing part is combined with the concrete block, and the bonding material can be an adhesive or a second grip. The second grip fixes the concrete block, and can use a clip, a clamp, a clamp, or the like.

(Embodiment 4-1) A draw test apparatus according to the present invention includes a position corrector 400 in Embodiment 3-1, which comprises a moving tool 402 for linearly moving the first grip or the load cell.

The microfibers protruding from the side of the concrete block should maintain a straight line with the microfibers inside the concrete convex. If the joining position of the concrete block face and the specimen fixing plate is not correct, the straight line is not maintained, and accurate test results can not be obtained. That is, the first grip or the load cell is mounted with a position compensator capable of moving the position of the micro fiber in order to form a straight line.

The position corrector is formed in a plurality of positions, preferably using two position correlators to enable position correction for the two axes. The position compensator can be equipped with a micrometer to calibrate its position in micrometers.

(Example 4-2) The drawing test apparatus of the present invention includes the camera 401 formed on the block side in the embodiment 4-1.

The micrometer of the position compensator enables position correction of a small size. However, there is a limit to visually confirming the magnitude of the abnormal angle of the microfibers. Fit the camera and monitor for accurate measurement of unsteady angles. The camera records the position of the concrete block and the micro fiber, and confirms the photographed image with the monitor. That is, the image displayed on the monitor is checked, and the micrometer is adjusted to correct the correct angle.

(Example 4-3) A draw test apparatus according to the present invention is a draw test apparatus according to the embodiment 4-2, which comprises a second controller 403 for determining an angle of a straight line and a fiber center line of a block surface from an image signal of the camera, And a display (404) for displaying the angles of the two controllers with images and / or numbers.

Judging the abnormal angle from the shape viewed on the monitor may be inaccurate because it is the naked eye identification. Therefore, a straight line formed on the other side of the concrete block and a straight line of the micro fiber protruded on one side of the concrete block are extracted from the image information of the camera, the degree of abnormality is determined from the extracted data, . It is desirable to process the abnormality level in the real time.

(Embodiment 4-4) The drawing test apparatus of the present invention includes a second actuator 405 for driving the moving tool 420 so that the angle of the second controller is perpendicular to that of Embodiment 4-3 .

The second actuator is mounted on the micrometer, the degree of abnormality is calculated in the second controller, and the correction value calculated in the second controller is transmitted to the second actuator to automatically correct the abnormal value.

(Example 5-1) A draw test apparatus of the present invention is a draw test apparatus according to Example 3-1, which comprises: a chamber (501) which forms a receiving space therein and accommodates a load cell and the first figure in the receiving space; And a door (502) formed on one side of the chamber.

The chamber is configured to reduce external effects during the test process, and the load cell and specimen are housed inside the chamber. Further, in order to secure the ease of specimen mounting, one side of the chamber is provided with a door, and the door and the chamber are fixed with a fastening device.

(Example 5-2) A draw test apparatus of the present invention is the draw test apparatus according to Example 5-1, wherein the thermoelectric element 503, the humidifier 504, the dehumidifier 505, the thermometer 506, And a hygrometer 507.

To maintain the same experimental environment during repeated experiments, the temperature and humidity inside the chamber are kept uniform. Or environmental conditions within the chamber must be intentionally variable to determine changes due to low and high temperature conditions, or to make decisions based on humidity changes. To this end, the chamber accommodating space is equipped with a thermometer and a hygrometer to measure temperature and humidity in real time, a thermoelectric element is mounted to control the temperature, and humidity is controlled by installing a humidifier and a dehumidifier.

(Example 5-3) The draw test apparatus of the present invention is the draw test apparatus according to Example 5-2, which receives the signals of the thermometer 506 and the hygrometer 507 and controls the thermoelectric element, the humidifier or the dehumidifier, And a controller 508.

The drawing controller is equipped with a third controller. The third controller controls the thermoelectric element, the humidifier, and the controller according to the set temperature and humidity, and implements the set experimental environment. This real-time feedback ensures stable environmental conditions.

(Example 5-4) A draw test apparatus according to the present invention is a draw test apparatus according to Example 5-3, which includes a display 509 for receiving a signal from the thermometer 506 and the hygrometer 507 and displaying a signal outside the chamber; .

The temperature and humidity input to the third controller need to be grasped in real time by the experimenter and can be confirmed through a display mounted outside the testing machine. In addition, the operation status of the thermoelectric element, the humidifier, and the dehumidifier can be grasped simultaneously.

(Example 5-5) The drawing test apparatus of the present invention includes the viewing window 510 formed on one side of the chamber and / or the door in the embodiment 5-1.

The chamber is equipped with a see-through window to visually grasp the test conditions generated inside the chamber.

(Embodiment 6-1) In the pull test apparatus according to Embodiment 3-1, the actuator 203 includes a first actuator 601 for moving the grip in the vertical direction, a second actuator for moving the grip in the horizontal direction A second actuator 602, a third actuator 603 rotated about the vertical direction of the grip; Or the like.

The microfibers embedded in the concrete structure are located at various angles and at various positions. That is, the fibers are formed in a straight line and the load is not applied in the fiber length direction. The fibers in the concrete structure are subjected to rotational force, bending load, or compressive load depending on the direction and position.

To determine this, the microfibers projected from the concrete block should be given various loading directions. Specifically, the horizontal load and the torsional load should be implemented as well as the vertical load.

In the present invention, three actuators are provided. The first actuator implements vertical movement of the microfibers, the second actuator runs horizontally from the microfiber protrusion direction, and the third actuator exerts a torsional load in the microfiber vertical direction.

(Embodiment 6-2) In the draw test apparatus according to the embodiment 3-1 of the present invention, the actuator 203 includes a first actuator 601 for moving the grip in the vertical direction, A second actuator 602, a third actuator 603 rotated about the vertical direction of the grip; Or a combination of two or three of these.

The microfibers inserted into the concrete structure can have a combination of two or more loads. To experimentally satisfy this condition, the first to third actuators operate two or three at the same time.

(Example 6-3) The draw test apparatus according to the present invention receives the load cell load signal and the displacement sensor signals of the first to third actuators in Examples 6-1 and 6-2, And a fourth controller 604 for driving the actuator.

101: Block 102: Fiber
103: Adhesive groove 201: Load cell
202: First grip 203: Actuator
204: displacement sensor 205: controller
301: fixing part 302: specimen fixing plate
303: fastening means 311: second grip
400: Position compensator 401: Camera
402: Moving sphere 403: Second controller
404: Display 405: Second actuator
521: side mold 522: first mold
523: second die 524: through hole

Claims (5)

A block 101 formed of a concrete, forming a first surface 101a and a second surface 101b;
And a fiber (102) having one side (102a) inserted into the block (102b) and the other side (102b) protruding from the block face.
A fiber fixing step (S100) for fixing one side of the fiber and the other side of the fiber in a straight line;
A block forming step (S200) of forming concrete so as to insert the fiber intermediate side;
And forming a plane on the block surface (101b) (S300).
A load cell 201 to which the block surface 101b of claim 1 is fixed;
A first grip 202 for fixing the fiber side 102a of claim 1;
An actuator (203) for moving the grip or the load cell;
And a displacement sensor (204) for measuring the movement distance of the actuator.
The method of claim 3,
And a moving part (402) for linearly moving the first grip or the load cell.
The method of claim 3,
A chamber 501 for accommodating the load cell and the first figure in the accommodation space;
And a door (502) formed on one side of the chamber.

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