KR102546504B1 - Apparatus and method for tensile test of concrete - Google Patents

Abstract

The present invention relates to a concrete tensile test apparatus and method for testing the tensile strength of a concrete specimen. The concrete tensile test apparatus according to an embodiment of the present invention includes a pressure rod for pressing a concrete specimen in a lying state, a pedestal positioned below the pressure rod to support the concrete specimen, and a pressure point at the center of the pressure rod. An alignment jig for aligning and supporting the position of the concrete specimen on the pedestal so as to match and press the center line of the uppermost circumference of the concrete specimen, wherein the alignment jig includes the pressing rod such that the pressing point and the center line of the fixing part coincide. A rod fixing part supported and fixed at three points, a specimen supporting part including a pair of seating rollers arranged side by side on both sides around the center line of the fixing part of the rod fixing part, and the center line of the fixing part is A jig connection portion connecting the rod fixing portion and the specimen supporting portion so as to be positioned side by side between the seating rollers, and three points supported by the pressure rod in the rod fixing portion are spaced at predetermined intervals within a semicircumference of the pressing rod. It may be a pair of spaced apart lower vertices and a central vertex meeting the center line of the fixing part vertically bisecting a chord connecting the pair of lower vertices. Therefore, it is possible to perform an accurate tensile test by easily aligning the concrete specimen.

Description

Apparatus and method for tensile test of concrete}

The present invention relates to a concrete tensile test apparatus and method for testing the tensile strength of a concrete specimen.

In general, buildings are tested for compressive strength because the compressive strength of concrete is important.

When testing the tensile strength, a bar-shaped specimen is installed by a tension mechanism and pulled to break it. Uneasy.

Accordingly, when performing the tensile test of concrete, the splitting tensile strength test is performed, and the splitting tensile strength test is performed by placing the concrete specimen in the press in a flat state, and then increasing the pressing speed of the press at a preset rate to destroy the concrete specimen. to test the tensile strength.

A test apparatus for performing a tensile test of such concrete has been disclosed in Korean Patent Registration Publication No. 10-1654811 (2016.9.8. notice).

The conventional tensile test apparatus for concrete described above could perform a tensile test in the form of pressurizing a specimen by a hydraulic piston in a state in which the specimen is seated on an upper portion of a pedestal.

However, since the conventional tensile test apparatus for concrete performs a tensile test after visually matching the center of the hydraulic piston and the center of the test piece with the naked eye, the exact pressure cannot be provided to the test piece due to the difference in the pressure application point. Therefore, it was difficult to obtain accurate test results of the tensile test.

In addition, since the specimen is pressurized in a lying state on the pedestal, there is a problem in that a safety accident occurs as the round specimen slips from the pedestal or is separated when the hydraulic piston is pressed.

The present invention has been made to solve the above problems, and the problem to be solved by the present invention is to match the pressure point of the pressure rod and the center line of the concrete specimen by an alignment jig so that the pressure rod accurately presses the center of the concrete specimen. The object of the present invention is to provide a concrete tensile test apparatus and method capable of obtaining accurate tensile test results by performing a tensile test.

In addition, to provide a concrete tensile test apparatus and method capable of installing an alignment jig by supporting the three points of the rod fixing part around the pressure rod to easily match the pressure point of the pressure rod and the center line of the concrete specimen. do.

In addition, the concrete specimen is supported by a pair of seating rollers to prevent the concrete specimen from slipping when the concrete specimen is pressurized, thereby preventing the occurrence of safety accidents, and the center of the pair of seating rollers is the fixing rod An object of the present invention is to provide a concrete tensile test apparatus and method that can easily match the center line of a concrete specimen and a fixture because they coincide with the top center line.

In addition, a gap measuring sensor for measuring the gap between the rod fixing parts is installed on the specimen support, so that the vertical strain of the concrete specimen can be easily measured in the form of measuring the gap through the gap measuring sensor, as well as the specimen support An object of the present invention is to provide a tensile test apparatus and method for concrete that can easily observe cracks occurring in concrete specimens by installing a crack measurement camera in the unit.

A pressure rod for pressing a concrete specimen in a lying state according to an embodiment of the present invention for achieving the above object, a pedestal positioned below the pressure rod to support the concrete specimen, and a pressure point at the center of the pressure rod An alignment jig for aligning and supporting the position of the concrete specimen on the pedestal so as to match and press the center line of the specimen located in the longitudinal direction of the uppermost end of the laid concrete specimen, wherein the alignment jig is supported by three points on the pressure rod A rod fixing part that is fixed and fixed, a specimen supporting part including a pair of seating rollers disposed side by side on both sides around the center line of the fixing part of the rod fixing part, and a center line of the fixing part between the pair of seating rollers A jig connection portion connecting the rod fixing portion and the specimen supporting portion so as to be located side by side, and three points supported by the pressure rod in the rod fixing portion are spaced apart at preset intervals within the semicircumference of the pressing rod. A central vertex that meets the center line of the fixing part that vertically bisects the lower vertex of the pair and the chord connecting the lower vertex of the pair.

The alignment jig may include a crack photographing camera installed on the specimen supporting part or the rod fixing part to photograph cracks occurring in the concrete specimen according to the pressure of the pressure rod.

The alignment jig may include a distance measurement sensor for measuring the vertical strain of the concrete specimen in the form of measuring the distance between the rod fixing part and the specimen supporting part.

The tensile test method for concrete according to an embodiment of the present invention uses the concrete tensile test apparatus according to the above embodiment, and the concrete tensile test method includes the steps of manufacturing the concrete specimen, the pressure rod and the pedestal Installing the alignment jig such that the pressing point of the pressing rod and the center line of the concrete specimen coincide with each other, seating the concrete specimen on the alignment jig, and pressing the concrete specimen by the pressure rod. and performing a tensile test, wherein the installing of the alignment jig includes installing the rod fixing part to the pressing rod so that the pressing point of the pressing rod and the center line of the fixing part coincide, and and seating the specimen support on an upper portion of the support so that the specimen support is positioned at the lower portion.

According to the present invention, by installing an alignment jig between the pressure rod and the pedestal, the pressure point of the pressure rod and the center line of the concrete specimen are easily matched through the alignment jig to accurately press the pressure point of the pressure rod to the center line of the concrete specimen. By performing a tensile test, accurate tensile test results can be obtained.

In addition, while three points are supported around the pressure rod through the fixed support portion and the pressure support portion of the rod fixing portion, the pressing point of the pressing rod and the center line of the fixing portion of the rod fixing portion can be easily matched and installed.

In addition, the concrete specimen is supported by a pair of seating rollers to prevent the concrete specimen from rolling or slipping during a tensile test to prevent safety accidents from occurring, and the pressure rod between the pair of seating rollers is prevented. Since it coincides with the pressurization point of the concrete specimen, it is possible to easily align and settle the specimen centerline and the pressurization point.

In addition, a gap measurement sensor is installed on the specimen support to easily measure the vertical strain of the concrete specimen in the form of measuring the distance between the rod fixing part and the specimen support, as well as cracking the concrete specimen on the specimen support. A crack measurement camera is installed to take pictures, so cracks occurring in concrete specimens can be easily observed.

1 is a perspective view showing a concrete tensile test apparatus according to an embodiment of the present invention.
2 is a perspective view showing an alignment jig constituting a concrete tensile test apparatus according to an embodiment of the present invention.
3 is a side view showing a tensile test apparatus for concrete according to an embodiment of the present invention.
4 is a plan view showing a rod fixing part of an alignment jig constituting a concrete tensile test apparatus according to an embodiment of the present invention.
5 is a plan view showing a specimen support of an alignment jig constituting a concrete tensile test apparatus according to an embodiment of the present invention.
6 is a front view showing a concrete tensile test apparatus according to an embodiment of the present invention, showing a state in which a concrete specimen is seated on a specimen support.
7 is a front cross-sectional view showing the operating state of the spacing maintaining part of the specimen support constituting the tensile test apparatus for concrete according to an embodiment of the present invention.

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

As shown in FIGS. 1 and 3 , the concrete tensile test apparatus 200 according to an embodiment of the present invention may include a pressure rod 210 and a pedestal 230.

The pressure rod 210 may press the concrete specimen 300 to perform a tensile test on the concrete specimen 300.

The pressure rod 210 may be implemented as a hydraulic mechanism in which the pressure rod 210 emerges and operates by hydraulic pressure.

The pressure rod 210 may pressurize the concrete specimen 300 at a preset pressure and speed.

The pressure rod 210 may be formed in a cylindrical shape, and may have a pressure head at the bottom of the pressure rod 210 having a circumference larger than that of the pressure rod 210 to press the concrete specimen 300. .

The concrete specimen 300 may be manufactured according to KS F 2403, and the tensile test apparatus 200 for concrete according to an embodiment of the present invention performs a tensile test by pressing and splitting the concrete specimen 300 in a horizontally laid state It can be tested by the splitting tensile strength test method.

Here, since the splitting tensile strength test method of the concrete specimen 300 is a known method, a detailed description thereof will be omitted.

The pedestal 230 may be located below the pressure rod 210 to provide a pressure force to the concrete specimen 300 in the form of supporting the load of the pressure rod 210.

The pedestal 230 may have a flat square or circular shape.

The pedestal 230 may be implemented as a bed of a press device, and the pedestal 230 may also be implemented in the form of seating a rigid plate on the bed of the press device.

As shown in FIGS. 1 to 3 , the concrete tensile test apparatus 200 according to an embodiment of the present invention may include an alignment jig 100.

The alignment jig 100 matches the uppermost end of the concrete specimen 300 to the pressurization point 211 located at the very center of the pressurization rod 210 so that the pressurizing force of the pressurization rod 210 is accurately provided to the concrete specimen 300 An accurate tensile test of the concrete specimen 300 can be performed.

Here, when the pressure point 211 of the pressure rod 210 and the specimen center line 310 connecting the longitudinal direction of the uppermost end of the concrete specimen 300 do not coincide, the pressure force of the pressure rod 210 is eccentric while providing accurate tension. It is difficult to obtain the result of the test, and there is a risk that the round concrete specimen 300 will slip between the pressure rod 210 and the pedestal 230 and be separated from the pressure rod 210 and the pedestal 230.

To prevent this, the alignment jig 100 matches the center line 310 of the concrete specimen 300 with the pressure point 211 located at the center of the pressure rod 210 to obtain accurate test results according to the tensile test. can

The alignment jig 100 includes a rod fixing part 110 fixed to the pressure rod 210, a specimen supporting part 120 supporting the concrete specimen 300 in the pedestal 230, and the rod fixing part 110 and the specimen A jig connection part 140 connecting the supporting part 120 may be included.

2 to 4, the rod fixing part 110 is located at the center of the rod fixing part 110 by supporting the three points P1, P2, and P3 around the pressing rod 210 formed in a circular shape. It is possible to match the pressing point 211 of the pressing rod 210 to the center line.

For example, when the rod fixing part 110 looks at the pressure rod 210 on a plane, draw an arbitrary string, draw a vertical bisector of the string, and extend it through the center. By supporting the three points (P1, P2, P3) of a pair of lower vertices (P1, P2) meeting the string and the upper vertex (P3) of the circumference where the bisector of the string meets the pressing rod 210, the center line of the fixing part (115) can be matched with the pressure point (211).

The rod fixing part 110 is formed in a band shape, and the pressure rod 210 may be inserted and positioned therein, and the inner circumference of the rod fixing part 110 has a pressure rod at a position corresponding to the lower vertices P1 and P2. A fixed support 111 supported around the periphery of the 210 may protrude.

In addition, the pressure support part 113 supported by the pressure rod 210 is also located at the upper vertex P3 in contact with the center line 115 of the fixing part orthogonal to the chord connecting the fixed support part 111, so that the pressure rod 210 As the circumference of is supported by a pair of fixed support 111 and press support 113, the center line 115 of the fixing rod 110 and the pressing point 211 of the pressing rod 210 coincide with each other. and can be installed.

At this time, the pressure support part 113 is fixed on the center line 115 at the inner circumference of the rod fixing part 110 so that the circumference of the pressure rod 210 can be closely fixed to the fixed support part 111 according to the size of the pressure rod 210. ) It is installed to be able to slide along and fix by pressing the circumference of the pressure rod 210, or it can be separated from the circumference of the pressure rod 210 to release the fixation.

The pressure support part 113 is screwed to the rod fixing part 110 and moves along the center line 115 of the fixing part by screwing, or the pressure support part 113 has a screw thread passing through the rod fixing part 110 and on the outer circumferential surface. A screw coupling portion 113a is formed, and a nut is fastened to the end of the screw coupling portion 113a so that the pressing support portion 113 moves along the center line 115 of the fixing portion according to the screw fastening of the nut. .

As shown in FIGS. 2, 3, 5, and 6, the specimen support 120 may be seated on the top of the support 230, and the concrete specimen 300 is seated on the specimen support 120. It can be.

The specimen supporting part 120 may include a supporting frame, and the supporting frame may have a square or circular frame shape, and a pair of seating rollers 130 may be installed therein.

A concrete specimen 300 may be seated between the pair of seating rollers 130, and the pair of seating rollers 130 are parallel to both sides around the center line 115 of the fixing part 110 of the rod fixing part 110. can be placed appropriately.

Here, since the seating rollers 130 are located on both sides around the center line of the fixing member, when the concrete specimen 300 is laid and seated on top of the pair of seating rollers 130, the top of the concrete specimen 300 The center line of the specimen 310 and the center line of the fixing member may coincide.

In addition, since the center line of the fixing member coincides with the pressing point 211 of the pressing rod 210, when the concrete specimen 300 is seated on the pair of seating rollers 130 in a state of lying down, the specimen center line 310 and the pressing rod Pressing point 211 of (210) can be matched.

The pair of seating rollers 130 may be installed on the square support frame 121, and the roller shafts of the pair of seating rollers 130 are supported by roller springs 129 so as to be in close contact with each other in a direction facing each other. Even if the space between the pair of seating rollers 130 is widened by the concrete specimen 300, the pair of seating rollers 130 may adhere to and support both sides of the concrete specimen 300 by elastic force.

In addition, the pair of seating rollers 130 support frame 121 so that even if one of the seating rollers 130 moves outward, the seating rollers 130 on both sides move at equal intervals from the specimen center line 310 It can be supported by the gap maintaining part 125 installed in.

As shown in FIG. 7, the space maintaining part 125 is installed in one of the pair of seating rollers 130 in the direction in which the first rack bar 126 moves, and the other one The second rack bar 127 is installed to face the first rack bar 126 vertically.

In addition, a pinion 128 is installed between the first rack bar 126 and the second rack bar 127, and when one of the pair of seating rollers 130 moves and the first rack bar 126 moves, the first rack bar 126 moves. While the pinion 128 engaged with the rack bar 126 rotates, the second rack bar 127 may also be moved so that the other seating roller 130 may also move together.

Of course, when one of the pair of seating rollers 130 moves to the outside and inside of the support frame 121, the other one by the first rack bar 126, the second rack bar 127 and the pinion 128 The seating roller 130 may also move in the same way to the outside and inside.

The gap maintaining part 125 may be located on both sides of the seating roller 130 in the support frame 121, or may be located on only one side.

The jig connection part 140 may connect the rod fixing part 110 and the specimen supporting part 120 to each other.

The jig connection part 140 may connect one end of the rod fixing part 110 and the specimen supporting part 120 to each other, and the branch connection part extends the center line 115 of the fixing part 110 of the rod fixing part ( 110) and the ends of the specimen support 120 in a state in which the pair of seating rollers 130 of the specimen support 120 coincide with each other.

The jig connection part 140 is formed in the form of a joint, and the rod fixing part 110 fixed to the pressure rod 210 can be connected to the specimen support part 120 so that it can move up and down together with the pressure rod 210.

At this time, the jig connection part 140 only movably connects the rod fixing part 110 and the specimen supporting part 120 to each other only up and down, but does not rotatably connect the rod fixing part 110 and the specimen supporting part 120. Therefore, even if the installation angle of the rod fixing part 110 is changed in the pressure rod 210, the center line of the fixing part 115 of the rod fixing part 110 and the pair of seating rollers 130 of the specimen supporting part 120 Between can always be located side by side.

The concrete tensile test apparatus 200 according to an embodiment of the present invention may include a gap measuring sensor 160.

When the concrete specimen 300 is pressurized by the pressure rod 210, the gap measurement sensor 160 measures the distance between the rod fixing part 110 and the specimen supporting part 120 to measure the thickness of the concrete specimen 300. Normal strain can be measured.

The distance measurement sensor 160 may be installed on the support frame 121 of the specimen support 120, and the distance measurement sensor 160 transmits light from the support frame 121 toward the rod fixing part 110. The distance may be measured by irradiating and measuring the time difference in which the irradiated light is reflected by the rod fixing part 110 and becomes incident.

The interval measurement sensor 160 may be implemented as a known distance measurement sensor.

The gap measurement sensor 160 can measure the vertical strain (vertical radial direction) of the specimen in the form of measuring the rate of change over time by measuring the spacing between the rod fixing parts 110 in the specimen support part 120 in real time. there is.

As shown in FIG. 3, the concrete tensile test apparatus 200 according to an embodiment of the present invention may include a crack imaging camera.

This crack photographing camera is located outside the concrete specimen 300 and can photograph cracks generated in the concrete specimen 300 when the concrete specimen 300 is pressed by the pressure rod 210.

The crack photographing camera is installed on the specimen support 230 and can photograph cracks occurring in the concrete specimen 300 in the form of photographing the front of the concrete specimen 300.

The crack imaging camera can take a digital image and provide it to the test measurement terminal, and the image captured by the crack imaging camera can be a still image or a video.

At this time, it is preferable that the crack imaging camera captures the center of the concrete specimen 300 in a state where the concrete specimen 300 is seated on the pedestal 230.

The crack imaging camera installs a camera installation unit 123 on the support frame 121 of the specimen support 230, and can be installed in the camera installation unit 123. It may be installed to be movable so as to be close to the concrete specimen 300 or away from the concrete specimen 300 so as to focus.

In addition, the camera installation unit 123 may be configured to enable adjustment of the height of the crack imaging camera according to the diameter of the concrete specimen 300.

The action and effect between each component described above will be described along with the tensile test method for concrete according to an embodiment of the present invention.

In the concrete tensile test method according to an embodiment of the present invention, a concrete specimen 300 is made of concrete to be tested.

The concrete specimen 300 is manufactured according to KS F 2403.

When the concrete specimen 300 is manufactured, the alignment jig 100 according to the above embodiment is placed between the pressure rod 210 and the pedestal 230 to align the centers of the pressure rod 210 and the concrete specimen 300. install

In the alignment jig 100, the rod fixing part 110 is installed on the pressure rod 210, and the specimen supporting part 120 can be seated on the pedestal 230.

In the rod fixing part 110, the fixing support part 111 is supported on both sides of the circumference of the pressing rod 210 on the inner circumference, and the center line of the fixing part is connected so as to be orthogonal to the center of the string connecting the fixing support part 111 located on both sides. A pressure support part 113 for fixing by pressing the circumference of the pressure rod 210 is installed at the portion where it meets the pressure rod 115.

In addition, a pair of seating rollers 130 for supporting the specimen are installed in the specimen supporting portion 120, and the pair of seating rollers 130 are spaced apart from each other or spaced apart from each other to narrow the supporting frame 121 ), and the pair of seating rollers 130 are connected by the elastic force of the roller spring 129 in a direction in which they converge.

In addition, the support frame 121 is configured with a spacer 125 so that when one of the pair of seating rollers 130 moves, the other one can move at equal intervals, and the spacer 125 is A first rack bar 126 is installed on one seating roller 130, a second rack bar 127 facing the first rack bar 126 is installed on the other, and the first rack bar 126 and the second rack bar are installed. Between (127) is configured in the form that the pinion (128) is engaged.

In addition, the rod fixing part 110 and the specimen supporting part 120 are connected by the jig connection part 140 so that the center line 115 of the fixing part 115 of the rod fixing part 110 and the pair of seating rollers 130 are matched. Connected, the jig connection part 140 is connected in the form of a joint so that the rod fixing part 110 can move up and down by the pressure rod 210.

In addition, a crack measurement camera 150 for photographing cracks occurring in the concrete specimen 300 according to the pressurization of the pressure rod 210 is installed in the specimen support 120, and the crack measurement camera 150 is It is installed in the camera installation unit 123 configured in the frame 121.

A gap measuring sensor 160 is installed in the specimen supporting part 120 to measure the strain in the vertical direction of the concrete specimen 300 by measuring the gap between the rod fixing part 110.

In the arrangement jig 100 according to the embodiment of the present invention configured as described above, in a state in which the rod fixing part 110 is inserted into the center of the pressing rod 210, the fixing support part 111 is brought into close contact with the circumference of the pressing rod 210. , Pressing and fixing the circumference of the pressing rod 210 through the pressing support part 113.

When the rod fixing part 110 is fixed to the pressing rod 210, the three points P1, P2, P3 are supported around the pressing rod 210 by the fixing support part 111 and the pressing support part 113. The pressing point 211 of the pressure rod 210 and the center line 115 of the fixing part of the rod fixing part 110 are matched and fixed, and the center line of the fixing part 115 is also between the pair of seating rollers 130. and are placed

On the other hand, when the alignment jig 100 is installed between the pressure rod 210 and the specimen support 120, the manufactured concrete specimen 300 is seated between the pair of seating rollers 130.

When the concrete specimen 300 is seated between the pair of seating rollers 130, the space between the pair of seating rollers 130 widens, and the concrete specimen 300 is supported on the pedestal 230, and the pair Since the seating rollers 130 are spread at equal intervals from each other by the spacing maintaining part 125 and the concrete specimen 300 is seated, even if the spacing between the pair of seating rollers 130 widens, the concrete specimen 300 The center line 310 of the specimen and the center line 115 of the fixing part can be kept consistent with each other.

When the concrete specimen 300 is seated between the pair of seating rollers 130, the concrete specimen 300 is pressed through the pressure rod 210 to perform a tensile test of the concrete.

The tensile test of concrete is performed using the splitting tensile test method (KS F 2423).

On the other hand, during the tensile test of concrete, while the pressure rod 210 presses the concrete specimen 300 through the crack camera, cracks generated are photographed and cracks observed through the photographed images to determine the shape of the cracks according to the tensile strength. Not only can it be observed, but also the strain in the vertical direction of the concrete specimen 300 (vertical radial direction in a flat state) can be measured for the spacing that changes in real time through the spacing sensor 160.

Therefore, the concrete tensile test apparatus 200 and method according to the embodiment of the present invention are the pressure point 211 of the pressure rod 210 and the specimen center line 310 of the concrete specimen 300 through the alignment jig 100 By matching and pressing the concrete specimen 300 at the center, it is possible to obtain more accurate tensile test results than before.

In addition, since the rod fixing part 110 of the alignment jig 100 is supported at three points (P1, P2, P3) by the fixed support part 111 and the pressure support part 113, the center of the pressure rod 210 is pressurized. It can be installed on the pressure rod 210 by easily matching the point 211 and the center line 115 of the fixing part 110 of the rod fixing part 110 .

In addition, since the concrete specimen 300 is supported by a pair of seating rollers 130, when the concrete specimen 300 is pressed by the pressure rod 210, the concrete specimen 300 is pushed and rolled, or the pressure rod 210 ) can prevent the occurrence of slipping accidents.

In addition, the crack measuring camera 150 is installed in the alignment jig 100 to photograph the cracks occurring in the concrete specimen 300 so that the type of cracks can be easily grasped.

In addition, the distance measurement sensor 160 is installed in the alignment jig 100 to measure the change in the distance between the rod fixing part 110 and the specimen supporting part 120, and the concrete specimen according to the pressure of the pressure rod 210 The normal strain of (300) can be easily measured.

In the above, the embodiments of the present invention have been described, but the scope of the present invention is not limited thereto, and is easily changed from the embodiments of the present invention by those skilled in the art to which the present invention belongs and recognized as equivalent. including all changes and modifications within the scope of

100: alignment jig 110: rod fixing part
111: fixed support 113: pressing support
113a: screw connection part 115: center line of fixing part
120: specimen support 121: support frame
123: camera installation unit 125: spacing maintenance unit
126: first rack bar 127: second rack bar
128: pinion 129: roller spring
130: seating roller 140: jig connection
150: crack measurement camera 160: gap measurement sensor
200: Tensile testing device for concrete 210: Pressing rod
211: pressure point 230: pedestal
300: concrete specimen 310: specimen center line

Claims (4)

A pressure rod that presses the concrete specimen in a lying state,
A pedestal located under the pressure rod to support the concrete specimen, and
An alignment jig for aligning and supporting the position of the concrete specimen on the pedestal so that the pressurization point at the center of the pressure rod and the center line of the specimen located in the longitudinal direction of the uppermost end of the laid concrete specimen are aligned and pressurized,
The alignment jig
A rod fixing part supported and fixed by three points on the pressure rod;
A specimen support portion including a pair of seating rollers arranged side by side on both sides around the center line of the fixing portion of the rod fixing portion, and
A jig connection portion connecting the rod fixing portion and the specimen support portion so that the center line of the fixing portion is located side by side between the pair of seating rollers,
The three points supported by the pressure rod in the rod fixing part are
A pair of lower vertices disposed spaced apart at a predetermined interval within the semicircumference of the pressing rod and a central vertex meeting the center line of the fixing part vertically bisecting the chord connecting the pair of lower vertices, tensile test of concrete, characterized in that Device. According to claim 1,
The alignment jig
Tensile test apparatus for concrete, characterized in that it comprises a crack photographing camera installed on the specimen support or the rod fixing unit to photograph cracks occurring in the concrete specimen according to the pressurization of the pressure rod. According to claim 1,
The alignment jig
Tensile test apparatus for concrete, characterized in that it comprises a distance measuring sensor for measuring the vertical strain of the concrete specimen in the form of measuring the distance between the rod fixing part and the specimen supporting part. In the concrete tensile test method using the concrete tensile test apparatus according to claim 1,
Manufacturing the concrete specimen,
Installing the alignment jig so that the pressure point of the pressure rod and the center line of the concrete specimen coincide with each other between the pressure rod and the pedestal;
Seating the concrete specimen on the alignment jig, and
Including the step of performing a tensile test by pressing the concrete specimen by the pressure rod,
The step of installing the alignment jig is
Installing the rod fixing part to the pressing rod so that the pressing point of the pressing rod and the center line of the fixing part coincide; and
A tensile test method for concrete comprising the step of seating the specimen support on the upper part of the support so that the specimen support is located under the rod fixing unit.

Images