KR101159279B1 - An Indicator of Schmidt rebound test hammer - Google Patents

Abstract

The present invention relates to a probe that is a component of a Schmidt rebound test hammer in a non-destructive test using a Schmidt rebound test hammer to determine the degree of concrete homogeneity of a concrete structure or to determine the degree of deterioration.

To describe this in more detail, it has a frame body formed by including a guide rod hole for guiding the guide rod therein, and forms a horizontal wing of a square plate shape integrally on one side of the frame body, one of the frame body A support jaw is formed on the side to support the guide rod fixing part, and includes a fixing part having a fixing protrusion for fixing the guide rod fixing part at both ends of the support jaw, and is located between the support jaws. Regarding the Schmidt rebound test hammer probe formed by including a frame formed on the frame fixing piece mounting surface and a guide rod fixing portion coupled to one side of the frame, when measuring the compressive strength of concrete through the present invention The measurement error can be reduced to ensure the reliability of compressive strength evaluation.

Schmidt rebound test hammer, probe, guide rod, guide rod circular ground

Description

An indicator of Schmidt rebound test hammer

The present invention relates to a probe that is a component of a Schmidt rebound test hammer in a non-destructive test using a Schmidt rebound test hammer to determine the degree of concrete homogeneity of a concrete structure or to determine the degree of deterioration.

To describe this in more detail, it has a frame body formed by including a guide rod hole for guiding the guide rod therein, and forms a horizontal wing of a square plate shape integrally on one side of the frame body, one of the frame body A support jaw is formed on the side to support the guide rod fixing part, and includes a fixing part having a fixing protrusion for fixing the guide rod fixing part at both ends of the support jaw, and is located between the support jaws. The present invention relates to a Schmidt rebound test hammer probe formed by including a frame including a frame fixing piece mounting surface and a guide rod fixing portion coupled to one side of the frame.

At present, the non-destructive testing method for measuring the compressive strength of concrete has been widely used by the method of measuring surface repulsion by Schmidthammer and the ultrasonic test by ultrasonic, and a combination method using both of them.

In particular, the resilience hardness method is to measure the degree of rebound or resilience of the surface by hitting the concrete surface with a hammer. In particular, the Schmidthammer method is a method that uses the point that the resilience hardness changes according to the strength of the concrete. It is the most widely used non-destructive testing method in the world because of its internationally standardized advantages.

The principle of rebound hardness method is based on the experimental experience that there is a specific correlation between rebound hardness and concrete compressive strength when striking hardened concrete surface with Schmidthammer. It does not necessarily have a uniform relationship with the strength of the material, as it depends on the physical quantities associated with the physical properties of the material.In particular, in a heterogeneous material such as concrete, the repulsion can be made locally with the Schmidthammer. The difference depends on the presence or absence of aggregates on the impact surface, wet state, and age of concrete.

As for the conventional non-destructive testing machine, Schmitthammer, there is a utility model registration No. 20-0201924, a registered utility model, 'Schmidtham non-destructive tester equipped with a hit recorder', hereinafter 'Utility Model Registration No. 20-0201924 Schmitthammer non-destructive tester equipped with a recorder will be described.

Schmitthammer non-destructive testing machine equipped with the blow recorder is provided with a brand 2 protruding from the inner end of the housing 1, the brand 2 is supported by the compression spring (3), the brand At the rear end of (2), a hammer (5) is formed with an O-ring (4) interposed therebetween, and the hammer (5) is supported by a guide bar (6), a fixed plate (7) and a compression spring (8). In addition, the probe 20 and the guide rod 10 of the probe is installed on the upper part of the housing in which the fixed plate 7 is located, and the Schmidthammer is a non-destructive testing machine by the rebound hardness method in which the measurement scale plate 11 is installed to be exposed to the outside. .

However, there is a problem that an error occurs when measuring by the rebound hardness method due to the fluidity by the combination of the probe 20 and the guide rod 10.

In addition, in the case of the probe, the frame and the guide rod fixing part are fixed through the punching, so when the test is performed by using a conventional Schmidt rebound test hammer probe, flow occurs, measurement mismatch occurs, and shaking occurs. There is a flaw in the failure that prevents the probe from being used anymore.

The present invention has been made to provide a more improved Schmidt rebound test hammer probe to solve the above problems and to solve the problems of the prior art, including a guide rod hole for guiding the guide rod therein It has a frame body formed by forming, integrally formed with a horizontal plate of the rectangular plate shape on one side of the side of the frame body, and to form a supporting jaw to seat and support the guide rod fixing part on one side of the frame body, A frame having a fixing protrusion for fixing a guide rod fixing part at both ends of the supporting jaw, and including a frame fixing piece seating surface positioned between the supporting jaw and at one side of the frame. Schmidt rebound test using Schmidt rebound test hammer probe formed with guide rod fixing By reducing the measurement error when measuring the compressive strength of concrete due to the rebound hardness method using a hammer it is an object to ensure the reliability of the compressive strength evaluation.

Another object of the present invention is to form a U-shaped on both sides of the main body of the guide rod fixing part and to form a frame fixing piece to be mounted to the frame fixing piece mounting surface integrally, so that the guide rod fixing part is firmly bound to the frame Therefore, when measuring the Schmitt rebound test hammer, the fluidity of the Schmitt rebound test hammer and the punching part are broken due to the fluidity, thereby preventing measurement errors or inaccuracy, and reducing the measurement error of the Schmitt rebound test hammer. The purpose is to raise it.

Another object of the present invention, the side of the support jaw of the frame is to support the support projection of the guide rod fixing portion to prevent the guide rod fixing portion is pushed and moved in the state that the guide rod fixing portion is bound to the frame.

Another object of the present invention is the guide rod circular ground of the guide rod fixing part to support the guide rod in a concentric shaft and to form a semi-circular plate, so as to surround the guide rod, so as to surround the Schmidt rebound The purpose of the test hammer is to reduce the fluidity of the guide rod to increase the accuracy of the measurement and to reduce the error.

Another object of the present invention is that, in the case of the probe, the frame and the guide rod fixing part are fixed through the punching, so that the test of the Schmidt rebound test hammer shakes during the test, so that the break occurs in the punching part, so that the probe is no longer used. Although there are drawbacks that cannot be prevented, the purpose is to solve this problem by the support jaw, the fixing projection and the frame fixing piece.

The above and other objects of the present invention, the frame body 31 is formed by including a guide rod hole 32 for guiding the guide rod 10 therein, a square on one side of the side of the frame body 31 The plate-shaped horizontal wing 37 is integrally formed, and on one side of the frame main body 31, a support jaw 35 for seating and supporting the guide rod fixing part 40 is formed, and the support jaw 35 is formed. And a fixing part 33 having a fixing protrusion 34 for fixing the guide rod fixing part 40 at both ends of the frame, and the frame fixing comfortable surface 38 located between the supporting jaws 35. It is achieved by the Schmid rebound test hammer probe 20 formed by including a frame 30 and a guide rod fixing portion 40 to be coupled to one side of the frame 30, including.

The Schmidt Rebound Test Hammer can be used to reflect the material properties of concrete in cement composites in the test data to measure concrete resilience as an integrated material, and the Schmidt Rebound Test Hammer probe of the present invention is more accurate and accurate. It can grasp the condition of the structure, ensure the reliability of compressive strength evaluation, and contribute to the localization of equipment.

By forming a frame fixing piece integrally mounted on the frame fixing piece mounting surface having a U shape on both sides of the main body of the guide rod fixing part, the guide rod fixing part is firmly bound to the frame, thereby Schmitt rebound test hammer Due to the fluidity and the fluidity of the Schmidt rebound test hammer to prevent the measurement of the punched portion is broken and the accuracy is reduced, there is an advantage to increase the accuracy by reducing the measurement error of the Schmidt rebound test hammer.

The side of the supporting jaw of the frame supports the support protrusion of the guide rod fixing portion, thereby preventing the guide rod fixing portion from being pushed and moved while the guide rod fixing portion is bound to the frame, thereby reducing errors due to fluidity.

The guide rod circular ground of the guide rod fixing part supports the guide rod concentrically and has a semi-circular plate shape. Therefore, the guide rod is wrapped around the guide rod, so that the guide rod is wrapped around the guide rod. Lowering the fluidity of the guide rod increases the accuracy of the measurement and reduces the error.

In general, since the probe is fixed to the frame and guide rod fixing part by punching, the Schmidt's rebound test hammer's probe is shaken during the test, which causes breakage in the punching part and prevents the probe from being used anymore. However, the fixing protrusion and the frame fixing piece have the advantage of reducing the fluidity.

These and other objects and features of the present invention will be more clearly understood from the following detailed description based on the accompanying drawings.

1 to 8 show a specific implementation of the Schmidt rebound test hammer probe according to the present invention, Figure 1 is a cross-sectional view showing a Schmidt hammer non-destructive tester equipped with a conventional blow recorder, Figures 2 to 3 Is a combined perspective view and an exploded perspective view showing a combination of the Schmidt rebound test hammer probe and the guide rod according to the present invention, Figures 4 to 7 is a front view, a rear view, a plan view and a side view showing the Schmidt rebound test hammer probe according to the present invention 8 is a front view showing the guide rod fixing part of the Schmidt rebound test hammer probe according to the present invention.

The Schmidt rebound test hammer probe 20 is largely divided into a frame 30 and a guide rod fixing part 40.

Schmidt rebound test hammer probe 20 of the present invention has a frame body 31 formed by including a guide rod hole 32 for guiding the guide rod 10 therein, one side of the side of the frame body 31 The horizontal blade 37 of the rectangular plate shape is integrally formed therein, and a support jaw 35 for seating and supporting the guide rod fixing part 40 is formed on one side of the frame body 31, wherein the support jaw ( And a fixing part 33 having fixing protrusions 34 for fixing the guide rod fixing part 40 at both end portions of the 35, and between the support jaw 35 and the frame fixing piece mounting surface ( 38 and a guide rod fixing portion 40 coupled to one side of the frame 30 and formed.

Hereinafter, the frame 30 of the Schmidt rebound test hammer probe 20 will be described based on the drawings illustrated in FIGS. 2 to 7.

The frame 30 is provided with a frame body 31 including a guide rod hole 32 for guiding the guide rod 10 therein, the horizontal of the rectangular plate shape on one side of the frame body 31 Wings 37 are integrally formed, and support jaws 35 for seating and supporting the guide rod fixing part 40 are formed on one side of the frame body 31, and both side ends of the support jaws 35 are formed. And a fixing part 33 having a fixing protrusion 34 for fixing the guide rod fixing part 40 to the frame, and including a frame fixing piece seating surface 38 positioned between the supporting jaws 35. Form.

Also equipped with an electronic sensor mounting hole 36 for coupling an electronic sensor (not shown) on one side of the frame body 31 to mount the electronic sensor, to recognize the impact generated during each strike Schmidt The data measured by the rebound test hammer probe 20 is displayed.

When the frame 30 is described in more detail, the guide rod hole 32 is provided inside the frame to allow the Schmidt rebound test hammer probe 20 of the present invention to move smoothly along the guide rod 10. By integrally forming the horizontal blade 37 of the rectangular plate shape on one side of the frame body 31, the horizontal position of the Schmitt rebound test hammer probe 20 can be measured and calibrated.

A support jaw 35 is formed on one side of the frame body 31 to seat and support the guide rod fixing part 40, and the guide rod fixing part 40 is fixed to both side ends of the support jaw 35. By including a fixing portion 33 having a fixing projection 34 to fix the guide rod fixing portion 40, the side of the support jaw 35 is the support protrusion of the guide rod fixing portion (40) 46 to support the guide rod fixing portion 40 is bound to the frame 30, limiting the movement of the guide rod fixing portion 40 bound to the frame 30. In addition, when the guide rod fixing part 40 is fixed to the frame 30, the probe 20 of the Schmidt rebound test hammer is generally shaken during the test because it is fixed by punching, so that a break occurs in the punching part and causes the probe. Although there are drawbacks that can no longer be used, the problem is solved by the support jaw 35, the fixing protrusion 34 and the frame fixing piece 42 to be described below.

Hereinafter, as a component of the Schmidt rebound test hammer probe 20 based on the accompanying drawings shown in FIGS. 2 to 8, the guide rod fixing part 40 coupled to one side of the frame 30 will be described. do.

The guide rod fixing part 40 forms a rectangular plate-shaped main body 41 seated on the support jaw 35 of the frame 30, and has a U-shaped shape on both sides of the main body 41. The frame fixing piece 42 to be mounted to the fixed piece seating surface 38 is integrally formed, and two guide rod support pieces 43 formed vertically on one side of the main body 41 are integrally formed, and the guide A guide rod is formed on the end of the guide rod support piece 43 to mount the rod 10 has a circular guide surface 44, and comprises a horizontal piece 45 inclined at one end of the main body 41 do.

In more detail, the frame 30 is formed by integrally forming the frame fixing piece 42 mounted on the frame fixing piece mounting surface 38 having a U shape on both sides of the main body 41. The guide rod fixing part 40 is firmly bound, which prevents the punching portion from breaking due to the fluidity and the fluidity of the Schmidt rebound test hammer during the test of the Schmidt rebound test hammer, thereby reducing the accuracy of the Schmidt rebound test hammer. Increase the accuracy by reducing the measurement error of.

In addition, the side surface of the support jaw 35 of the frame 30 supports the support protrusion 46 of the guide rod fixing portion 40 so that the guide rod fixing portion 40 is coupled to the frame 30 in the state of the guide rod. The fixing part 40 is prevented from being pushed and moved.

In addition, by molding the combined portion of the frame 30 and the guide rod fixing portion 40, it may have a result of fixing more firmly than the combination by punching.

In addition, the guide rod circular support surface 44 supports the guide rod 10 in a concentric shaft and has a semi-circular plate shape so as to surround the guide rod, thereby supporting Schmid rebound. When testing the test hammer, the fluidity of the guide rod is decreased to increase the accuracy of measurement and to reduce the error.

In general, it is desirable that the recalibration test of the Schmidt rebound test hammer should be performed at 1,000 ~ 1,500 times.In this case, when the Schmidt rebound test hammer is hit by the test anvil, the repulsion shown on the instrument should be Ro = 80 ± 2. However, if this value is exceeded, the test is carried out and adjusted.

Configurations shown in the embodiments and drawings described herein are only preferred embodiments of the present invention, and do not represent all of the technical spirit of the present invention, and various equivalents that may be substituted for them at the time of the present application and It should be understood that there may be variations.

Therefore, although the present invention has been described in detail with reference to the specific embodiments described, it will be apparent to those skilled in the art that various modifications and changes can be made within the scope of the technical idea of the present invention, and such modifications and modifications belong to the appended claims. It is natural.

1 is a cross-sectional view showing a Schmidt hammer non-destructive tester equipped with a conventional blow recorder.

2 to 3 is a combined perspective view and an exploded perspective view showing a combination of the Schmidt rebound test hammer probe and the guide rod according to the present invention.

4 to 7 is a front view, a rear view, a plan view and a side view showing the Schmidt rebound test hammer probe according to the present invention.

8 is a front view showing the guide rod fixing part of the Schmidt rebound test hammer probe according to the present invention.

                   Description of the Related Art [0002]

 1 housing 2 brand 3 compression spring

 4: O-ring 5: hammer 6: guide bar

 7: fixing plate 8: compression spring 10: guide rod

20: Schmidt rebound test hammer probe

30 frame 31 frame body 32 guide rod hole

33: fixing part 34: fixing projection 35: support jaw

36: electronic sensor mounting hole 37: horizontal wing 38: frame fixing piece mounting surface

40: guide rod fixing part 41: main body 42: frame fixing piece

43: guide rod support piece 44: guide rod circular ground

45: horizontal piece 46: support protrusion

Claims (3)

It has a frame body formed by including a guide rod hole for guiding the guide rod therein, integrally forming a horizontal blade of a rectangular plate shape on one side of the frame body, the guide rod fixing part on one side of the frame body Forming a support jaw to support the seating, but including a fixing portion having a fixing projection for fixing the guide rod fixing part on both side ends of the support jaw, the frame fixing piece seating surface located between the support jaw A frame formed to include; Schmid rebound test hammer probe, characterized in that formed; including; guide rod fixing portion coupled to one side of the frame. The method of claim 1, wherein the guide rod fixing portion is A body having a rectangular plate shape seated on the support jaw of the frame; A frame fixing piece having a U shape on both sides of the main body and mounted on the frame fixing piece mounting surface; Two guide rod support pieces formed perpendicular to one side of the main body; A guide rod circular support surface on which the guide rod is mounted and formed at an end of the guide rod support piece; Schmid rebound test hammer probe, characterized in that it comprises a; horizontal piece formed inclined at one end of the main body. The guide rod circular support surface of claim 2 is Schmid rebound test hammer probe, characterized in that for supporting the guide rod and having the shape of a semi-circular plate.

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