KR101654811B1 - Concrete tensile strength test method by fast loading - Google Patents

Abstract

The present invention relates to a complex test device for evaluating concrete static and dynamic material characteristics and a concrete strength test method using the same and, more specifically, relates to a concrete strength complex test device and a concrete strength test method using the same, wherein the concrete strength complex test device is designed to test a creep test, a compression strength test, a shock withstand test, a general loading bending strength test, a fast loading bending strength test, a general loading tensile strength test, and a fast loading tensile strength test in one test device according to the need.

Description

Technical Field [0001] The present invention relates to a concrete fast tensile strength test method,

TECHNICAL FIELD The present invention relates to a concrete rapid load tensile strength test method using a composite test apparatus for evaluating concrete static and dynamic material properties.

Fatigue test, compressive strength test, bending strength test and tensile strength test are essential to satisfy concrete usage conditions.

The fatigue strength test is the most basic test to measure the amount of deformation of creep moderately progressing with time after momentary deformation when an external force is applied to the object. The compressive strength test applied a static load to the concrete specimen As a test for evaluating the bearing capacity and stability of concrete, concrete, prestressed concrete and prestressed concrete mainly use the compressive strength of concrete. Therefore, the compressive strength test of concrete is one of the most important tests of concrete.

Also, the bending strength test is a test for measuring the degree of bending and stress of concrete, and the tensile strength test is a test for measuring the tensile strength of concrete.

The impact resistance test is a test for measuring the stress of concrete when a strong load is applied. It is usually equipped with a device for additionally applying an additional load or a test separate from the compressive strength test.

Each test apparatus has been developed variously in order to improve the convenience according to the type of the test specimen. However, since it is common that each test is carried out by a separate test apparatus, there are inconveniences due to absence of equipment when various tests are carried out collectively.

In this regard, the prior art documents are as follows.

Korean Patent No. 10-149422 entitled " Performance Test Apparatus of Pile Bidirectional Loading Device and Performance Test Method Using the Pile "is a method of measuring the bearing capacity of a pile by using an upper plate member 210 and a lower plate member 220 The present invention relates to an apparatus and a method for testing the performance of a biasing load device 200 capable of generating a maximum pressing force. That is, the ring-shaped concrete supporting body 1 in which the center inserting portion 5 is formed, the outer confining member 2, the pair of spacing filling supports 3, And a load cell (4) arranged between the bidirectional loading device (200) and measuring the pressing force generated by the expansion of the bidirectional loading device (200); The bidirectional loading device 200 is inserted and disposed so as to be closely contacted between the load cell 4 and the gap filling support 3 on the other side in a state in which the expansion direction is horizontal and the bidirectional loading device 200 is inserted horizontally The load cell 4 measures the pressing force of the bi-directional loading device 200 caused by the expansion of the bi-directional loading device 200. The performance testing device of the pile bi-directional loading device and the performance testing method of the pile bi- , Which is a device for measuring the load performance of the pile in both directions, there is no description in the literature on the development of techniques for carrying out various tests.

Korean Patent Laid-Open Publication No. 10-0774777 entitled " Method and Apparatus for Loading Test Using Dual Pack-Anchor ", is provided with a pack-anchor manufactured by a wire or a round bar on the ground supporting pile of a pile, A load test method using a double pack anchor for reinforcing the ground by checking the reaction force of pile and the condition of pile after loading, Anchoring test of pack-anchors using pack-grouting on large-diameter piles placed at the site, and optimization of pile foundation based on this, and reinforcement of damages of drilled piles by mortar injection The present invention relates to a load test method using a double pack anchor and a reinforcing method using the same and a related device. However, there is no description of how to perform the bending strength test and the tensile strength test together with the load test although the technique of the load test method using the double pack-anchor is implemented.

Therefore, the necessity of equipment development that can carry out various concrete related tests by a single test apparatus is more emphasized.

[Patent Document 1] Korean Patent No. 10-149422 entitled " Performance Test Apparatus of Pile Bidirectional Loading Device and Performance Test Method Using It, "2015.02.15 [Patent Document 2] Korean Patent Laid-Open Publication No. 10-0774777 entitled " Method and Apparatus for Loading Test Using Dual Pack Anchor ", 2007.11.01

In order to solve the above problems, the present invention proposes a concrete fast load tensile strength test method using a test apparatus capable of various tests by one test apparatus.

The present invention is characterized in that " a pedestal (100) whose upper surface is formed into a flat plate; A columnar member (200) having a thread on its outer periphery, the columnar member (200) being provided on both sides of the upper surface of the pedestal (100); A frame member horizontally disposed above the pedestal 100 is provided with a through groove into which each of the column portions 200 is inserted, and a rotating portion that rotates along the thread of the column portion by a power source applied to the through- (300) having a height adjuster (320) and a height adjusted according to the rotation of the rotation unit (320); A hydraulic cylinder 400 fixed through the center of the main body 300; The first hydraulic pipe 10, the second hydraulic pipe 20, and the third hydraulic pipe 30 are connected to the upper portion of the hydraulic cylinder 400, A hydraulic valve unit 500 for controlling the flow of hydraulic pressure; A hydraulic piston 600 positioned at the inner diameter of the hydraulic cylinder 400 and moving up and down with a predetermined displacement according to a hydraulic pressure flowing into the hydraulic cylinder 400; (700) coupled to a lower surface of the hydraulic piston (600) and applying pressure to a test body placed on the pedestal (100); The hydraulic oil is supplied to the hydraulic valve unit 500 through the first hydraulic pipe 10 according to a control signal or the hydraulic pressure supplied from the hydraulic valve unit 500 through the second hydraulic pipe 20, An oil pressure unit 800 configured to receive oil for use; The hydraulic oil supplied from the hydraulic pressure valve unit 500 through the third hydraulic pipe 30 is charged into the interior of the hydraulic pump unit 500 in accordance with the control signal or the charged hydraulic oil is supplied through the third hydraulic pipe 30 An accumulator 900 configured to rapidly discharge the oil to the hydraulic valve unit 500; And a control unit (1000) for generating control signals for the hydraulic valve unit (500), the hydraulic unit (800), and the accumulator (900). The control signal is classified into a creep signal, a general load signal, and a rapid load signal, and when the control unit 1000 generates a creep signal, the hydraulic valve unit 500 controls the hydraulic unit 800 is supplied to the hydraulic cylinder 400 so that the load applied to the test object is maintained constant through the ashing pad 700. The control unit 1000 generates a general load signal The hydraulic valve unit 500 continuously supplies the hydraulic oil supplied from the hydraulic unit 800 to the hydraulic cylinder 400 in a constant amount and supplies the hydraulic oil to the hydraulic cylinder 400 via the ashing pad 700 When the controller 1000 generates a rapid load signal, the hydraulic valve unit 500 controls the hydraulic oil supplied from the hydraulic unit 800 to the third hydraulic pipe 30, To the accumulator 900 The hydraulic oil filled in the accumulator 900 is supplied to the third hydraulic pipe 30 after the accumulator 900 is filled with the hydraulic oil. Is rapidly supplied to the hydraulic cylinder (400) via the hydraulic valve unit (500) through the hydraulic cylinder (400), and the load applied to the test body through the ashing pad (700) is increased rapidly Provides a concrete tensile strength test method.

According to the present invention, a creep test, a compressive strength test, a bending strength test, a tensile strength test, and an impact resistance test can be carried out in one test apparatus, and convenience and efficiency are great.

In addition, since the present invention can measure the stress of a test body through a test apparatus capable of imparting both a general load condition and a rapid load condition, the convenience of testing corresponding to various test conditions is improved.

1 is a perspective view of the test apparatus of the present invention.
2 is a front view of the test apparatus of the present invention.
[Fig. 3] is a view showing a state in which the position of the body part is adjusted for performing a test in the test apparatus of the present invention.
4 is a view showing a state in which the hydraulic piston moves downward to perform a test in the test apparatus of the present invention.
5 is a photograph of the test apparatus of the present invention.
6 is a plan view of the test apparatus of the present invention.
7 is a simplified plan view of a piping in which hydraulic oil is supplied to an accumulator in the test apparatus of the present invention.
[Fig. 8] is an example of a tensile strength test using the test apparatus of the present invention.
[Fig. 9] is an example of a tensile strength test using the test apparatus of the present invention.
10 is an embodiment of a tensile frame and a tensioned paper belt used in a tensile strength test using the test apparatus of the present invention.

I. Concrete strength test system

The composite concrete strength test apparatus according to the present invention is constructed as follows.

(1) a pedestal 100 having an upper surface formed into a flat plate;

(200) having a pair of cylindrical members on both sides of an upper surface of the pedestal (100);

(3) A frame member horizontally provided above the pedestal 100 is provided with a penetration groove into which each of the pillar portions 200 is inserted, and a power source applied to the penetration groove is provided along a thread of the pillar portion A main body 300 having a rotating portion 320 and a height adjustable according to rotation of the rotating portion 320;

(4) a hydraulic cylinder 400 fixed through the central portion of the main body 300;

(5) communicates with the upper part of the hydraulic cylinder 400 and is connected to the first hydraulic pipe 10, the second hydraulic pipe 20 and the third hydraulic pipe 30 A hydraulic valve unit 500 for controlling the flow of hydraulic pressure;

(6) a hydraulic piston 600 positioned at the inner diameter of the hydraulic cylinder 400 and moving up and down with a predetermined displacement according to the hydraulic pressure flowing into the hydraulic cylinder 400;

(7) a dieser 700 coupled to a lower surface of the hydraulic piston 600 to apply pressure to a test body placed on the pedestal 100;

The hydraulic oil is supplied to the hydraulic valve unit 500 through the first hydraulic pipe 10 in accordance with the control signal of the control unit 8 or through the second hydraulic pipe 20 at the hydraulic valve unit 500 An oil pressure unit 800 configured to supply and discharge hydraulic oil to be discharged;

The hydraulic oil supplied from the hydraulic pressure valve unit 500 through the third hydraulic pipe 30 is charged to the inside of the third hydraulic pipe 30 An accumulator 900 configured to rapidly discharge the hydraulic pressure to the hydraulic valve unit 500 through a hydraulic circuit; And

(10) a control unit (1000) for generating control signals for the hydraulic valve unit (500), the hydraulic unit (800) and the accumulator (900);

1 is a perspective view of a composite concrete strength test apparatus according to the present invention, and FIG. 2 is a front view of the test apparatus. The components constituting the above testing apparatus will be mainly described with reference to these.

First, the present invention comprises a pedestal 100, a column 200, and a main body 300. The frame includes a frame, components attached thereto, and a hydraulic pipe (a first hydraulic pipe and a second pipe) The oil pressure unit 900 and the control unit 1000, which are connected to each other through a hydraulic pipe, become basic components.

The pedestal 100 has a flat upper surface to support the pillars 200 and the main body 300. The pedestal 100 serves as a support member for placing the test body. More specifically, one or more guide grooves 110 may be formed on the upper surface of the pedestal 100 to be inserted into the guide grooves 110 in a predetermined depth. In this case, a lower bending jig 1300 for bending strength test may be installed in the guide grooves 110 Can be installed.

Further, an additional support base for positioning the test body may be provided on the upper surface of the support, but basically, it is preferable that the upper surface of the support 100 is made flat so that the test body can be easily installed.

In addition, a pair of pillar parts 200 are provided side by side on both sides of the upper surface of the pedestal 100, wherein the pillar part 200 is a cylindrical member, and a thread is formed on the outer circumference. A body portion 300 described later is inserted into the column portion 200 and a ceiling portion covering the upper surface of the column portion 200 may be further provided for more rigid support. The thread formed on the outer periphery of the pillar 200 is formed for the up-and-down movement of the main body 300.

The main body part 300 fitted to the column part 200 is a frame member horizontally disposed above the pedestal 100 and has a through groove 310 through which the column parts 200 are inserted, The through hole 310 is provided with a rotation part 320 which rotates along the thread of the column part 200 by an applied power source so that the height of the rotation part 320 can be adjusted according to the rotation of the rotation part 320.

The through hole 310 formed in the main body 300 has a structure for inserting the pillar 200 and is installed horizontally above the pedestal 100 but is not fixedly installed, 200 are formed at the periphery of the through-hole 310 so that the upper and lower ends of the through-hole 310 may be formed along the outer peripheral thread. However, the rotation unit 320 may be operated according to a control command by a power source to which the gear unit is coupled, and the main unit 300 is moved up and down Moving. FIG. 6 is a plan view of the test apparatus of the present invention, showing through-holes 310 and embodiments of the rotating unit 320 provided therein.

3 shows a state where the position of the main body 300 is adjusted for performing a test in the test apparatus of the present invention. The up / down movement of the main body 300 may be controlled using a separate remote controller, or may be controlled through the controller 1000.

A hydraulic cylinder 400, a hydraulic valve unit 500, and a hydraulic piston 600 may be set in the main body 300. The hydraulic cylinder 400 is fixed through the central portion of the main body 300 and the upper portion of the hydraulic cylinder 400 is connected to the hydraulic cylinder 400, And a hydraulic valve unit 500 for controlling the flow of the hydraulic oil supplied from the first hydraulic pipe 10 to the third hydraulic pipe 500 30) have. A hydraulic piston 600 is disposed on the inner surface of the hydraulic cylinder 400 so that the hydraulic piston 600 moves up and down with a predetermined displacement according to the hydraulic pressure flowing into the hydraulic cylinder 400.

When the hydraulic oil supplied from the hydraulic unit 800 flows into the hydraulic valve unit 500 through the first hydraulic pipe 10, the hydraulic valve unit 500 directly contacts the hydraulic cylinder 400 Or may be supplied to the accumulator 900 through the third hydraulic pipe 30. [ The flow direction of the hydraulic oil is determined according to the control signal generated by the control unit 1000 for the static test (general load test) or the dynamic test (rapid load test). In the present invention, various tests It is a big feature that it can be easily performed in one device.

4 shows a state in which the hydraulic piston 600 moves downward in the test apparatus of the present invention, and FIG. 5 is a photograph of the test apparatus of the present invention.

When the oil for hydraulic oil is supplied to the hydraulic cylinder 400 from the hydraulic valve unit 500, the hydraulic piston 600 moves downward by the hydraulic pressure. In the lower surface of the hydraulic piston 600, A load corresponding to the hydraulic pressure in the hydraulic cylinder 400 is applied to the test object 700 after the ash pad 700 is mounted on the test object.

Ⅱ. Control of concrete strength test system

The control signal generated in the control unit 1000 of the composite concrete strength testing apparatus is classified into a creep signal, a general load signal, and a rapid load signal.

(1) When the controller 1000 generates a creep signal,

The hydraulic valve unit 500 provides the hydraulic oil supplied from the hydraulic unit 800 to the hydraulic cylinder 400 so that the load applied to the test body through the ashing pad 700 is maintained constant do.

(2) When the control unit 1000 generates a general load signal,

The hydraulic pressure valve unit 500 continuously supplies the hydraulic oil supplied from the hydraulic pressure unit 800 to the hydraulic cylinder 400 so as to gradually increase the load applied to the test body through the ashing pad 700 Respectively.

(3) When the controller 1000 generates the rapid load signal,

The hydraulic valve unit 500 supplies the hydraulic oil supplied from the hydraulic unit 800 to the accumulator 900 through the third hydraulic pipe 30 and then supplies the hydraulic oil to the accumulator 900 The hydraulic oil filled in the accumulator 900 flows through the third hydraulic pipe 30 through the hydraulic valve unit 500 and then the hydraulic oil is supplied to the accumulator 900 through the third hydraulic pipe 30, The hydraulic cylinder 400 is rapidly supplied and the load applied to the test body through the ashing pad 700 is controlled to increase rapidly.

The above control may be performed by controlling the operation of the hydraulic unit 800, the hydraulic valve unit 500 and the accumulator 900 in the control unit 1000.

The oil pressure unit 800 is preferably disposed at a position close to the pedestal 100. The oil pressure unit 800 supplies the oil for hydraulic oil to the oil pressure valve unit 500 through the first oil pressure pipe 10 so that the oil for hydraulic oil is supplied to the oil pressure unit 500 according to the opening / The hydraulic cylinder 400 is directly supplied to the hydraulic cylinder 400 or is charged through the third hydraulic pipe 30 to the accumulator 900 and then through the third hydraulic pipe 30 to the hydraulic cylinder 400, . The hydraulic oil discharged from the hydraulic cylinder 400 to the hydraulic valve unit 500 is collected into the hydraulic unit 800 through the second hydraulic pipe 20.

The controller 1000 can be configured to select a test type according to a selection of a device user. Tests for determining the fracture characteristics of concrete specimens can be roughly divided into creep test, general load test and rapid load test. The above general load test and rapid load test can be classified into compressive strength test, bending strength test And a general load test or a rapid load test for tensile strength test.

The controller 1000 can be configured to set various test modes according to the user's choice. The test mode includes 1) creep test mode, 2) compression strength test mode, 3) General bending strength test mode, 5) rapid load-bending strength test mode, 6) general tensile strength test mode, and 7) rapid load tensile strength test mode.

For example, when the apparatus user selects the creep test mode in the control unit 1000, the control unit 1000 generates a creep signal and performs a normal load test mode (compression strength test, general bending strength test, general intangible strength test) It is possible to generate a general load signal.

In addition, when the apparatus user selects the rapid load test mode (impact test, rapid load-strength test, rapid load tensile strength test), the controller can generate a rapid load signal. In order to perform the rapid load test, the preliminary pressurization is performed. In this case, the control unit 1000 first generates a creep signal and generates the rapid load signal in a state where a constant load is applied to the test object, will be.

The hydraulic oil is filled in the accumulator 900 according to the rapid load signal and when a charge completion signal is generated from the accumulator 900, the controller 1000 controls the accumulator 900 In this case, the hydraulic oil filled in the accumulator 900 is rapidly discharged at once to the hydraulic cylinder 400 through the third hydraulic pipe 30, So that the ashing (700) can further pressurize the specimen to perform the rapid load test.

The accumulator 900 can be installed on both sides of the main body 300 with the hydraulic cylinder 400 interposed therebetween.

7 is a simplified plan view of a piping in which hydraulic oil is supplied to an accumulator 900 in the test apparatus of the present invention. 7, the hydraulic oil supplied from the hydraulic unit 800 to the hydraulic valve unit 500 is supplied to the accumulator 900 through the third hydraulic pipe 30, You can check the status.

The tests performed in connection with the present invention are described below.

Ⅲ. concrete Rapid loading The tensile strength  Test Methods

The concrete rapid tensile strength test method is carried out according to the following steps (a) to (f).

(a) a horizontal support 1410 formed at a predetermined height from the pedestal 100, a pair of vertical supports 1420 connected to one end of the horizontal support 1410 to support the horizontal support 1410, And a test body upper coupling part 1430 coupled to the horizontal support part 1410 in a downward direction, wherein the horizontal support part 1410 has a hole formed at both upper ends thereof; The lower ends of the vertical supports 1420 are fixed to the upper surface of the pedestal 100,

 A pair of vertical frames 1510 inserted into the holes of the tension paper zone 1400 so that the upper and lower frames are freely movable, a ceiling frame 1520 coupled with the upper ends of the vertical frames 1510, A tension frame 1500 configured to include a bottom frame 1530 coupled with a bottom portion and a test body bottom engagement portion 1540 coupled upwardly in the bottom frame 1530; Engaging the ceiling frame (1520) with the lower end of the resting leg (700);

(b) installing the upper and lower ends of the dumbbell-shaped tensile test body 3 so that the upper and lower ends of the dumbbell-type tensile test body 3 are gripped by the upper end fitting 1430 and the lower end fitting 1540, respectively;

(c) adjusting a height of the body portion 300;

(d) The control unit 1000 generates a creep signal, and moves downwardly to a dumbbell-shaped tensile test body 3 having a fixed upper end as a force for moving the tension frame 1500 downward by a constant hydraulic pressure. Applying a tensile force;

(e) applying a tensile load to the dumbbell type tensile test body (3) at a rapid hydraulic pressure to cause the controller (1000) to generate a rapid load signal and move the ashing pad (700) in a downward direction; And

(f) checking at least one of tensile displacement and stress until fracture of the dumbbell-shaped tensile test body (3);

The step (a) includes a horizontal support 1410 formed at a predetermined height from the pedestal 100, a pair of vertical supports 1440 connected to one ends of the horizontal support 1410 to support the horizontal support 1410, (1400) having a hole on the upper both sides of the upper side of the horizontal support (1410), and a test body upper coupling part (1430) coupled to the horizontal support part (1410) in a downward direction. A pair of vertical supports 1420 are fixed to the upper surface of the pedestal 100 and a pair of vertical guides are inserted into the holes of the tension sheet 1400 to freely move up and down, A ceiling frame 1520 coupled with an upper end of the vertical frame 1510, a bottom frame 1530 coupled with a lower end of the vertical frame 1510, A tensile frame 1500 configured to include a test body lower coupling 1540 coupled to the lower frame 1540; And joining the ceiling frame 1520 with the lower end of the ashes.

In step (a), a tensile paper sheet 1400 and a tension frame 1500 as shown in FIG. 8 are installed on the top of the pedestal for tensile strength test.

The tension paper belt 1400 includes a horizontal support 1410 formed at a predetermined height from the support 100 and one end connected to one end of the horizontal support 1410 to support the horizontal support 1410, And a pair of vertical supports 1420 fixed to the upper surface of the pedestal 100. In order to engage and fix the upper end of the dumbbell-type tensile test body 3, a test body upper end fitting 1430 is provided at the lower end of the horizontal support And two holes 1440 are formed on both sides of the top of the horizontal support 1410.

The tension frame 1500 includes a pair of vertical frames 1510, a ceiling frame 1520, and a pair of vertical frames 1520, which are inserted into the holes of the tension paper belt 1400 and are free to move up and down. The upper end of the ceiling frame 1520 is fastened to the lower end of the ash pad 700 and the upper end of the bottom frame 1530 is connected to the upper end of the lower frame 1530. [ And a test body lower end coupling portion 1540 for coupling and fixing the lower end of the dumbbell type tensile test body 3 is provided.

The tensile frame 1500 and the tensile paper 1500 used in the tensile strength test using the test apparatus of the present invention shown in FIG. 10 may be implemented in various forms, such as the upper test piece coupling port 1430 and the lower test piece coupling port 1540. A ball type universal joint may be used as in the embodiment of the zone 1400. Also, it is preferable that the load cell provided for measuring the stress of the dumbbell type tensile test body 3 is installed at the lower end of the horizontal support table 1410, and then the test tool upper end fitting 1430 is installed.

The tensile paper frame 1400 is fixed to the upper surface of the pedestal and the tension frame 1500 is fixed to the ashing pad 700 so that the tension of the tension frame 1500, The vertical frame 1510 of the dumbbell-shaped tensile test body 1500 moves freely upward and downward, thereby applying tensile force to the dumbbell-shaped tensile test body 3 to be installed.

In the step (b), the upper and lower ends of the dumbbell-shaped tensile test body 3 are held by the upper and lower test pieces 1430 and 1540, respectively. That is, the dumbbell-shaped tensile test body 3 is fixed to the test body upper end fitting 1430 of the tensioning paper belt 1400 and the test body lower end fitting 1540 of the tensioning frame 1500. The upper and lower ends of the dumbbell-shaped tensile test body 3 are fixed to the tensioning paper belt 1400 and the tension frame 1500, respectively, and the tension of the asymmetric tension test body 3 depends on the up and down movement of the ashing pad 700.

In the step (c), the height of the main body 300 is adjusted. Considering the type and morphological characteristics of the tensile test specimen, the height of the tensile test specimen can be adjusted so as to apply a tensile force to the specimen in consideration of the scale of the tensile paper zone and the tensile frame.

 In the step (d), the control unit 1000 generates a creep signal, and the hydraulic unit 800 supplies a predetermined amount of hydraulic oil to the hydraulic cylinder 400 to maintain the hydraulic pressure constant, And a downward tensile force is applied to the dumbbell-shaped tensile test body 3 whose upper end position is fixed as the force for moving the tension frame 1500 downward by hydraulic pressure.

Since the impact applied to a building usually occurs when a constant load is constantly applied to a building, in order to create a condition similar to a situation where an impact is applied to a real building, a certain tensile load is previously applied to a dumbbell- 3).

In the step (e), the control unit 1000 further applies a tensile load to the dumbbell-type tensile test body 3 at a rapid hydraulic pressure to generate a rapid load signal and move the ashing pad 700 downward .

When the control unit 1000 generates a rapid load signal, the hydraulic oil supplied from the oil pressure unit 800 is supplied to the accumulator 900 through the third hydraulic pipe 30, The unit 500 is controlled.

The accumulator 900 is charged by the hydraulic pressure discharge signal from the controller 1000 when the accumulator 900 generates a charging completion signal corresponding to a predetermined amount of oil for hydraulic oil, The dumbbell-shaped tensile test body 3 is rapidly fed to the hydraulic cylinder 400 through the third hydraulic pipe 30 so as to move the ash pad 700 in a downward direction, So that the tensile load is applied momentarily.

In other words, the hydraulic pressure unit 800 transmits the hydraulic oil to the hydraulic valve unit 500 by the rapid load signal, and the hydraulic valve unit 500 transmits the hydraulic oil to the hydraulic cylinder 400 To the accumulator (900) through the third hydraulic pipe (30) without supplying the hydraulic oil to the accumulator (900). This is to fill the accumulator 900 with the hydraulic oil so that the instantaneous additional tensile load transmitted through the tension frame 1500 is strongly formed by discharging the charged hydraulic oil at once.

There is no limitation on the method of temporarily discharging the oil for hydraulic oil from the accumulator 900. In one embodiment, a load capable of destroying the critical amount or the rectangular parallelepiped-shaped flexural test body 2 is formed by using the internal expanding portion It is possible to discharge a large amount of oil at a time to generate a strong load.

The step (f) is a step of checking at least one of tensile displacement and stress until fracture of the dumbbell type tensile test body (3). The tensile displacement and the stress can be checked by the sensor for a predetermined time, and the tensile displacement and the stress at the time of breaking of the dumbbell type tensile test body 3 can be checked. The tensile displacement can be measured by a displacement measuring sensor provided on the dumbbell-shaped tensile test body 3. Also, the stress can be measured by a load cell provided in the ashing pad 700. [

The hydraulic oil present in the hydraulic cylinder 400 is recovered to the hydraulic unit 700 through the hydraulic valve unit 500 and the second hydraulic pipe 20 when the test is completed.

The steps (d) to (f) may be programmed to proceed automatically according to the selection of the tensile strength test mode in the controller 1000.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the invention. It is therefore intended that the appended claims cover such modifications and variations as fall within the true scope of the invention.

100: pedestal 200: column portion 300:
310: penetrating groove 320: rotating part 400: hydraulic cylinder
500: Hydraulic valve part 600: Hydraulic piston 700:
800: Hydraulic unit 900: Accumulator 1000: Control unit
1100: upper bending jig support part 1200: upper bending jig
1300: lower bending jig 1400: tensile paper zone
1410: horizontal support 1420: vertical support
1430: Top joint of specimen 1500: Tension frame
1510: Vertical frame 1520: Ceiling frame
1530: bottom frame 1540: bottom joint of test body
10: first hydraulic pipe 20: second hydraulic pipe 30: third hydraulic pipe
1: Cylindrical specimen 3: Dumbbell-type tensile specimen

Claims (1)

A pedestal 100 having an upper surface formed into a flat plate;
A columnar member (200) having a thread on its outer periphery, the columnar member (200) being provided on both sides of the upper surface of the pedestal (100);
A frame member horizontally disposed above the pedestal 100 is provided with a through groove into which each of the column portions 200 is inserted, and a rotating portion that rotates along the thread of the column portion by a power source applied to the through- (300) having a height adjuster (320) and a height adjusted according to the rotation of the rotation unit (320);
A hydraulic cylinder 400 fixed through the center of the main body 300;
The first hydraulic pipe 10, the second hydraulic pipe 20, and the third hydraulic pipe 30 are connected to the upper portion of the hydraulic cylinder 400, A hydraulic valve unit 500 for controlling the flow of hydraulic pressure;
A hydraulic piston 600 positioned at the inner diameter of the hydraulic cylinder 400 and moving up and down with a predetermined displacement according to a hydraulic pressure flowing into the hydraulic cylinder 400;
(700) coupled to a lower surface of the hydraulic piston (600) and applying pressure to a test body placed on the pedestal (100);
The hydraulic oil is supplied to the hydraulic valve unit 500 through the first hydraulic pipe 10 according to a control signal or the hydraulic pressure supplied from the hydraulic valve unit 500 through the second hydraulic pipe 20, An oil pressure unit 800 configured to receive oil for use;
The hydraulic oil supplied from the hydraulic pressure valve unit 500 through the third hydraulic pipe 30 is charged into the interior of the hydraulic pump unit 500 in accordance with the control signal or the charged hydraulic oil is supplied through the third hydraulic pipe 30 An accumulator 900 configured to rapidly discharge the oil to the hydraulic valve unit 500; And
A control unit 1000 for generating control signals for the hydraulic valve unit 500, the hydraulic unit 800, and the accumulator 900; Wherein the control signal is classified into a creep signal, a general load signal, and a rapid load signal,
When the control unit 1000 generates the creep signal, the hydraulic valve unit 500 supplies the hydraulic oil supplied from the hydraulic unit 800 to the hydraulic cylinder 400, ) To keep the load applied to the specimen constant,
When the control unit 1000 generates a general load signal, the hydraulic valve unit 500 continuously supplies the hydraulic oil supplied from the hydraulic unit 800 to the hydraulic cylinder 400, The load applied to the specimen is increased through the damper 700,
When the control unit 1000 generates the rapid load signal, the hydraulic valve unit 500 controls the hydraulic oil supplied from the hydraulic unit 800 through the third hydraulic pipe 30, The accumulator 900 is supplied to the accumulator 900. When the accumulator 900 is filled with the hydraulic oil, the accumulator 900 is supplied with the hydraulic oil filled therein, The hydraulic cylinder 400 is rapidly supplied through the pipe 30 to the hydraulic cylinder 400 through the pipe 30 to increase the load applied to the test body through the ashing pad 700. [ A method of rapid tensile strength test of concrete using each step of the method.
(a) a horizontal support 1410 formed at a predetermined height from the pedestal 100, a pair of vertical supports 1420 connected to one end of the horizontal support 1410 to support the horizontal support 1410, And a test body upper coupling part 1430 coupled to the horizontal support part 1410 in a downward direction, wherein the horizontal support part 1410 has a hole formed at both upper ends thereof; The lower ends of the vertical supports 1420 are fixed to the upper surface of the pedestal 100,
A pair of vertical frames 1510 inserted into the holes of the tension paper zone 1400 so that the upper and lower frames are freely movable, a ceiling frame 1520 coupled with the upper ends of the vertical frames 1510, A tension frame 1500 configured to include a bottom frame 1530 coupled with a bottom portion and a test body bottom engagement portion 1540 coupled upwardly in the bottom frame 1530; Engaging the ceiling frame (1520) with the lower end of the resting leg (700);
(b) installing the upper and lower ends of the dumbbell-shaped tensile test body 3 so that the upper and lower ends of the dumbbell-type tensile test body 3 are gripped by the upper end fitting 1430 and the lower end fitting 1540, respectively;
(c) adjusting a height of the body portion 300;
(d) The control unit 1000 generates a creep signal, and moves downwardly to a dumbbell-shaped tensile test body 3 having a fixed upper end as a force for moving the tension frame 1500 downward by a constant hydraulic pressure. Applying a tensile force;
(e) applying a tensile load to the dumbbell type tensile test body (3) at a rapid hydraulic pressure to cause the controller (1000) to generate a rapid load signal and move the ashing pad (700) in a downward direction; And
(f) checking at least one of tensile displacement and stress until fracture of the dumbbell-shaped tensile test body (3);

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