KR102504936B1 - Concrete compressive strength tester that can share measured values in real time - Google Patents

Abstract

The present invention relates to a concrete compression strength tester capable of sharing measured values in real time. The concrete compression strength tester capable of sharing measured values in real time has an improved structure such that, when an impact rod grounded on the concrete surface is pressurized, a hammer is constrained by a clamp module and moves together with the impact rod to extend an impact spring, and when the hammer is released by the clamp module, the hammer is returned due to the restoring force of the impact spring to generate impact force, thereby ensuring reliability of concrete strength test data without being affected by an operator's skill level, and specifically, immediately correcting measurement errors on-site by quickly identifying anomalies by sharing measured values in real-time through a portable terminal. The concrete compression strength tester comprises an impact rod (10), a rail rod (20), a hammer (30), a clamp module (40), an impact spring (50), a control module (60), and a mobile device (70).

Description

Concrete compressive strength tester that can share measured values in real time}

The present invention relates to a concrete compressive strength tester capable of sharing measured values in real time. is tensioned, and when the hammer is released by the clamp module, the hammer returns by the restoring force of the impact spring and the structure is improved so that the impact force is generated, so that the reliability of the concrete strength test data is secured without being affected by the operator's skill level. In particular, It relates to a concrete compressive strength tester capable of sharing measured values in real time through a mobile terminal to quickly identify singularities and immediately correct measurement defects in the field.

In general, the rebound hardness method, one of the nondestructive testing methods for various concrete structures, measures the strength of concrete by hitting the surface of concrete with a Schmidt hammer to measure the degree of return or rebound hardness of the surface. The Schmidt hammer, a non-destructive test using the point where hardness changes, has a simple and internationally standardized test method.

However, in order to accurately measure the strength with a Schmidt hammer, the strike bar of the Schmidt hammer and the wall to be struck must be exactly right angles, and if the right angle is not formed between them, the accurate rebound hardness test of the wall cannot be performed, and thus the strength of the wall cannot be accurately measured.

Accordingly, in the previously disclosed Patent Registration No. 10-1848238, the Schmidt hammer has an accommodation space in which the Schmidt hammer is inserted and fixed, and the first support point provided in front of the accommodation space is in close contact with the concrete wall surface in the form of surface contact. A support for supporting the impact part of the hammer in a parallel state at an arbitrary position on the concrete wall; A fixture fixed to the floor on the side adjacent to the concrete wall so that the supporting force is exerted; A hinge operation is possible by a link connected between the support body and the fixture and hinged, and the first support point is brought into close contact with the concrete wall surface while adjusting the tilt of the support body using the hinge operation. Corresponding to the slope of the concrete wall surface A technique including a; joint arm part for maintaining the striking part of the Schmidt hammer in a parallel state has been previously suggested.

However, the prior art is intended to maintain a right angle between the striking bar and the wall of the Schmidt hammer, but the structure is complicated, the portability is reduced due to high weight, and when the striking surface is non-uniform, an accurate rebound hardness test cannot be performed while flowing. followed

KR 10-1358748 B1 (2013.03.21.)

Accordingly, the present invention has been conceived to solve the above problems, and when pressurizing the striking rod in a state where it is grounded on the concrete surface, the hammer is bound to the clamp module and moved together with the striking rod to tension the striking spring, and by the clamp module. When the hammer is released, the hammer is restored by the restoring force of the impact spring and the structure is improved so that the impact force is generated, so that the reliability of the concrete strength test data is secured without being affected by the worker's proficiency. The purpose is to provide a concrete compressive strength tester that can share measurement values in real time that can immediately correct measurement defects in the field while quickly identifying singularities by sharing them.

Characteristics of the present invention in order to achieve this object, is inserted into the rod hole 110 of the body housing 100, once the striking rod 10 is formed with a flat tip 12 in surface contact with the concrete surface; A rail rod 20 connected to the striking rod 10 and provided to provide a transfer force to the striking rod 10 in a protruding direction by a return spring 22; A hammer 30 having a center hole 32 formed in the center to be inserted into the rail rod 20 and linearly transported along the rail rod 20 to hit the striking rod 10; It is installed at the end of the rail rod 20 to restrain the hammer 30, and the hammer 30 at a position where the striking rod 10 is drawn into the body housing 100 to a predetermined depth through the rod hole 110 A clamp module 40 provided to release the restraint; One end is connected to the hammer 30 and the other end is bound to the body housing 100 so that the striking rod 10 rides the rod hole 110 into the body housing 100 and is tensioned when operating percussion spring 50; A control module 60 installed in the body housing 100 and equipped with a sensor module 62 to measure the distance moved backward after the hammer 30 hits the striking rod 10 by the striking spring 50 ); and a portable terminal 70 connected to the control module 60 through wired or wireless communication and equipped with a display unit 72 to store and output measured values of the sensor module 62 in real time.

At this time, the clamp module 40 is installed at the end of the rail rod 20, the disk 41 for limiting the movement area of the hammer 30, and the disk 41 installed on the support shaft 42a as the center The pivoting operation is performed, and the hook member 42 having the latch 42b at one end and the mill piece 42c at the other end is formed at one end of the hammer 30 corresponding to the disk 41, and the hook member 42 It is installed in the body housing 100 corresponding to the locking groove 43 engaged with the locking member 42b of the hook member 42 and the wheat piece 42c of the hook member 42, and the striking rod 10 rides the rod hole 110. It includes a support piece 44 for releasing the restraint state between the locking member 42b and the locking groove 43 by pressing the mill piece 42c at a position drawn into the main housing 100 to a predetermined depth, and the striking rod When the body housing 100 is pressed while the flat tip 12 of (10) is in close contact with the concrete surface, the striking rod 10 rides the rod hole 110 and enters the inside of the body housing 100, clamp module When the hammer 30 constrained to 40 moves together, the striking spring 50 is tensioned, and the striking rod 10 reaches a predetermined position, the support piece 44 presses the push piece 42c to hook When the constrained state of the clamp module 40 is released as the member 42 rotates, the hammer 30 moves by the restoring force of the impact spring 50 to hit the impact rod 10, and the hammer 30 strikes the impact rod. (10) is characterized in that the sensor module 62 is provided to detect a distance moving backward by a reaction force after a collision.

In addition, the support piece 44 is screwed onto the main body housing 100, and has a lever 44a at one end, and when the lever 44a is rotated, the support piece 44 is pitch-moved so that the main body The protruding length into the housing 100 is controlled, a plurality of stop grooves 44b are formed at equal intervals on the lever 44a, and the ball plunger 44c is formed in the body housing 100 corresponding to the stop groove 44b ) is installed to fix the position of the lever 44a at a predetermined angle, and the release timing between the latch 42b and the locking groove 43 is controlled by the movement of the support piece 44, and the lever 44a ) It is characterized in that the striking force of the hammer 30 can be finely adjusted by using a method of controlling the release point of restraint between the latch 42b and the locking groove 43.

In addition, the striking rod 10 is provided so that the hammer 30 striking force is applied in a state orthogonal to the concrete surface in the 360 ° direction by the right angle induction module 80, the right angle induction module 80, the striking rod A multi-housing 81 mounted on the end of the main body housing 100 concentrically with (10), and a multi-rod hole 82 formed on the multi-housing 81 at equal intervals of 90 degrees around the striking rod 10 ), and is installed in the probe piece 84, which is linearly transported and has a protruding feed force acting toward the concrete surface by the elastic body 83, and the multi-load hole 82, to detect the retracting position of the probe piece 84 A multi-sensor 85, a multi-disk 86 installed at the end of the rail rod 20 and limiting the movement area of the hammer 30, installed on the multi-disk 86, and turned on by the control module 60 /off operation, including an electromagnet 87 that restrains the hammer 30 with magnetic force, pressurizes the main housing 100 in a state where the flat tip 12 of the striking rod 10 is in close contact with the concrete surface, , When the plurality of probe pieces 84 are pressed to the concrete surface and drawn at the same distance while the striking rod 10 is correcting the angle so that it is orthogonal to the concrete surface and detected collectively by the multi-sensor 84, the control module ( In 60), the electromagnet 87 is turned off to release the hammer 30, and the main housing 100 is pressed while the flat tip 12 of the striking rod 10 is in close contact with the concrete surface. After the hammer 30 reaches a predetermined point, it is provided to receive the multi-sensor 84 detection signal, and at this time, the hammer 30 is provided so that the movement position within the body housing 100 is detected by the position sensor. to be characterized

In addition, a rail hole 24 is formed at the center of the rail rod 20, a stop rod 26 is installed, inserted into the rail hole 24, and one end connected to the main housing 100, the stop The rod 26 is installed in the main body housing 100 and is screwed with the adjusting device 28 that is rotated at an equal angle. When the striking rod 10 enters the main housing 100, the end of the stop rod 26 It is grounded in the rail hole 24 and is provided to limit the retraction distance of the striking rod 10, and when the adjusting member 28 is rotated at an equal angle, the protruding length of the stop rod 26 is controlled while the striking rod 10 It is characterized in that the retraction distance is adjusted so that the hammer 30 striking force is controlled.

In addition, the portable terminal 70 is characterized in that it is provided so as to be worn on the operator's arm by a shoulder strap 74 including a band.

In addition, the multi-housing 81 is provided to automatically correct the angle so that the hitting bar 10 is orthogonal to the concrete surface by the automatic angle correction module 200, and the automatic angle correction module 200, the probe piece ( 84) is installed, the first body 210 in which the first angle adjustment hole 212 is formed in the center, and accommodated in the first angle adjustment hole 212, centered on the first angle adjustment hole 212 It is connected to the first body 210 by a pair of first correction shafts 222 disposed at 0 ° and 180 ° positions to adjust the angle, and a second angle adjustment hole 224 is formed in the center. A pair of second correction shafts 232 accommodated in the second body 220 and the second angle adjustment hole 224 and disposed at 90° and 270° positions with respect to the first angle adjustment hole 212 The third body 230 is connected to the second body 220 and is installed to be angularly adjustable and has a mounting hole 234 formed in the center to mount the end of the body housing 100, and the first and second corrections. Detected by the first and second driving units 240 and 240' installed on the shafts 222 and 232 and operating the first and second correction shafts 222 and 232 to pivot, and the multi-sensor 85 The retraction position of the probe piece 84 is detected, and the retraction position value of the probe piece 84 detected by a pair of multi-sensors 85 disposed opposite to each other at equal intervals of 180° is compared with each other to obtain a difference value. calculation, and controlling any one or more of the first and second driving units 240 and 240' to change the angle of one or more of the second and third bodies 220 and 230 to correct the difference value within the error range while striking It is characterized in that it includes a calculation module that automatically corrects the angle so that the rod 10 is orthogonal to the concrete surface.

According to the configuration and operation of the present invention, when the hammer is restrained by the clamp module and moved together with the striking rod, the hammer spring is tensioned when pressurized while the striking rod is grounded on the concrete surface, and when the hammer is released by the clamp module, the striking rod is released. The structure is improved so that striking force is generated as the hammer is returned by the spring restoring force, so that the reliability of concrete strength test data is secured without being affected by the worker's proficiency. It has the effect of correcting the measurement defect immediately on the spot while grasping it clearly.

1 is a configuration diagram showing the overall configuration of a concrete compressive strength tester capable of sharing measured values in real time according to an embodiment of the present invention.
Figure 2 is a configuration diagram showing the operating state of a concrete compressive strength tester capable of sharing measured values in real time according to an embodiment of the present invention.
Figure 3 is a configuration diagram showing a right angle induction module of a concrete compressive strength tester capable of sharing measured values in real time according to an embodiment of the present invention.
Figure 4 is a configuration diagram showing a probe piece arrangement state of a right angle induction module of a concrete compressive strength tester capable of sharing measured values in real time according to an embodiment of the present invention.
5 is a block diagram showing a hammer striking force control structure of a concrete compressive strength tester capable of sharing measured values in real time according to an embodiment of the present invention.
6 to 7 are configuration diagrams showing an automatic angle correction module of a concrete compressive strength tester capable of sharing measured values in real time according to an embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, in the description of the present invention, if it is determined that the related known function may unnecessarily obscure the subject matter of the present invention as an obvious matter to those skilled in the art, the detailed description thereof will be omitted.

1 is a block diagram showing the overall configuration of a concrete compressive strength tester capable of sharing measured values in real time according to an embodiment of the present invention, and FIG. 2 is a configuration diagram showing measured values according to an embodiment of the present invention in real time. 3 is a block diagram showing the right angle induction module of the concrete compressive strength tester capable of sharing measured values in real time according to an embodiment of the present invention, FIG. 4 is a configuration diagram showing the arrangement of the probe piece of the right angle induction module of the concrete compressive strength tester capable of sharing the measured values in real time according to an embodiment of the present invention, and FIG. 5 is the measured value according to an embodiment of the present invention. 6 and 7 are diagrams showing a hammer striking force control structure of a concrete compressive strength tester capable of sharing in real time, and FIGS. It is a configuration diagram showing the automatic angle correction module.

The present invention relates to a concrete compressive strength tester capable of sharing measured values in real time, and when pressurized with a striking rod grounded to a concrete surface, a hammer is bound to a clamp module and moved together with the striking rod to tension the striking spring , When the hammer is released by the clamp module, the hammer is restored by the restoring force of the impact spring and the impact force is generated, so that the reliability of the concrete strength test data is secured without being affected by the operator's skill level. The striking rod 10, the rail rod 20, the hammer 30, the clamp module 40, and the striking spring ( 50), a control module 60, and a portable terminal 70, including the main components.

The striking rod 10 according to the present invention is inserted into the rod hole 110 of the body housing 100, and a flat tip 12 in surface contact with the concrete surface is formed at one end.

The striking rod 10 is configured to transmit the hammer 30 striking force to the concrete surface, which will be described later.

In addition, the rail rod 20 according to the present invention is connected to the striking rod 10, and is provided to provide a transfer force to the striking rod 10 in the protruding direction by the return spring 22.

The rail rod 20 extends in a straight line with the striking rod 10, and guides the hammer 30 to be described later to be linearly transportable.

In addition, the hammer 30 according to the present invention is provided with a center hole 32 formed in the center to be inserted into the rail rod 20, linearly transferred along the rail rod 20 to hit the striking rod 10 do.

The hammer 30 is a weight body, and is provided to hit the striking rod 10 by being linearly transported by the restoring force of the striking spring 50 to be described later.

In addition, the clamp module 40 according to the present invention is installed at the end of the rail rod 20 to restrain the hammer 30, and the striking rod 10 rides the rod hole 110 to the inside of the body housing 100. It is provided to release the restraint of the hammer 30 at a position drawn in at a predetermined depth.

That is, when pressing the striking rod 10 in a state in which it is grounded on the concrete surface, the hammer 30 is constrained by the clamp module 40 and moved together with the striking rod 10 to tension the striking spring 50, and clamp When the hammer 30 is released by the module 40, the hammer 30 is restored by the restoring force of the impact spring 50, and impact force is generated.

At this time, the clamp module 40 is formed mechanically or electronically, and a detailed description thereof refers to the description of FIG. 1 or FIG. 3 to be described later.

In addition, the striking spring 50 according to the present invention has one end connected to the hammer 30 and the other end bound to the body housing 100, so that the striking rod 10 rides the rod hole 110 to the body housing (100) It is provided so as to be tensioned during retraction operation into the inside.

In addition, the control module 60 according to the present invention is installed in the body housing 100, and the hammer 30 by the impact spring 50 measures the distance moved backward after hitting the impact bar 10. A sensor module 62 is provided.

In addition, the portable terminal 70 according to the present invention is connected to the control module 60 by wire or wireless communication, and is provided with a display unit 72 to store and output measurement values of the sensor module 62 in real time.

At this time, the portable terminal 70 is provided so that it can be worn on the operator's arm by a holding means 74 including a band.

As such, the concrete strength test is performed while wearing the portable terminal 70, and measurement values are shared in real time through the portable terminal 70 to quickly identify singularities and immediately correct measurement defects in the field. there is

1, the clamp module 40 is installed at the end of the rail rod 20, the disk 41 for limiting the movement area of the hammer 30, and the support shaft 42a installed on the disk 41 The pivoting operation is performed to the center, and the hook member 42 having the latch 42b at one end and the mill piece 42c at the other end is formed at one end of the hammer 30 corresponding to the disk 41, and the hook member ( 42) is installed in the body housing 100 corresponding to the locking groove 43 engaged with the locking member 42b and the mill piece 42c of the hook member 42, and the striking rod 10 is installed in the rod hole 110 It includes a supporting piece 44 that presses the mill piece 42c at a position drawn into the main body housing 100 to a predetermined depth to release the restraint state between the latch 42b and the locking groove 43.

Accordingly, as shown in FIG. 2 (a), when the body housing 100 is pressed while the flat tip 12 of the striking rod 10 is in close contact with the concrete surface, the striking rod 10 rides through the rod hole 110 to the main body. While entering the housing 100, the hammer 30 constrained to the clamp module 40 moves together, the striking spring 50 is tensioned, and when the striking rod 10 reaches a predetermined position, the supporting piece 44 ) presses the wheat piece 42c and the hook member 42 rotates, and when the restraint state of the clamp module 40 is released, the hammer 30 moves by the restoring force of the impact spring 50 as shown in FIG. 2 (b). to strike the striking rod 10, and the sensor module 62 is provided to detect a distance moving backward by a reaction force after the hammer 30 collides with the striking rod 10, as shown in FIG. 2 (c).

In addition, the support piece 44 is screwed onto the main body housing 100, and has a lever 44a at one end, and when the lever 44a is rotated, the support piece 44 is pitch-moved so that the main body The protruding length into the housing 100 is controlled.

At this time, a plurality of stop grooves 44b are formed at equal intervals on the lever 44a, and a ball plunger 44c is installed in the body housing 100 corresponding to the stop groove 44b to move the lever 44a to a predetermined level. It is provided to fix the position at an angle of.

As such, the release point of the restraint between the latch 42b and the locking groove 43 is controlled by the movement of the supporting piece 44, and the restraint between the locking bracket 42b and the locking groove 43 is controlled using the lever 44a. As the striking force of the hammer 30 can be finely adjusted by controlling the releasing time point, the accuracy of the inspection can be increased by precisely correcting the error due to the inherent elastic force and deformation of the striking spring 50 .

In FIG. 3, the striking rod 10 is provided so that the hammer 30 striking force is applied in a state orthogonal to the concrete surface in the direction of 360 degrees by the right angle induction module 80.

The right angle induction module 80 includes a multi-housing 81 mounted on the end of the body housing 100 so as to be concentric with the striking rod 10, and a multi-housing at equal intervals of 90 degrees around the striking rod 10 ( 81) is linearly transported along the multi-load hole 82 formed on the surface, and is installed in the probe piece 84 and the multi-load hole 82, where the protruding feed force acts toward the concrete surface by the elastic body 83, The multi-sensor 85 for detecting the retracting position of the probe piece 84, the multi-disk 86 installed at the end of the rail rod 20 and limiting the movement area of the hammer 30, and the multi-disk 86 It is installed and is operated on/off by the control module 60, and includes an electromagnet 87 that magnetically restrains the hammer 30.

In operation, the body housing 100 is pressed while the flat tip 12 of the striking rod 10 is in close contact with the concrete surface, and the angle is corrected so that the striking rod 10 is orthogonal to the concrete surface. When a plurality of probe pieces 84 are pressed against the concrete surface and drawn at the same distance and detected collectively by the multi-sensor 84, the control module 60 turns off the electromagnet 87 to restrain the hammer 30. As it is provided to release, the hammer 30 striking force is transmitted under the condition that the striking rod 10 is orthogonal to the concrete surface, so that the inspection precision is improved, and even unskilled workers can easily perform the strength test work.

On the other hand, the main body housing 100 is pressed in a state where the flat tip 12 of the striking bar 10 is in close contact with the concrete surface, and the multi-sensor 84 detects a signal after the hammer 30 reaches a predetermined point. At this time, the hammer 30 is provided so that the moving position is detected by a position sensor installed in the body housing 100.

5, a rail hole 24 is formed in the center of the rail rod 20, and a stop rod 26 is installed, which is inserted into the rail hole 24 and has one end connected to the main body housing 100, The stop bar 26 is installed in the main body housing 100 and is screwed with the control unit 28 rotated at an equal angle.

And, when the striking rod 10 is drawn into the body housing 100, the end of the stop rod 26 is grounded in the rail hole 24 to limit the pulling distance of the striking rod 10.

Accordingly, when the adjuster 28 is rotated at an equal angle, the protruding length of the stop rod 26 is controlled while the retraction distance of the striking rod 10 is adjusted so that the hammer 30 striking force is controlled. As it is provided, the striking spring 50 Inspection accuracy can be increased by precisely correcting errors caused by inherent elasticity and deformation.

In FIGS. 6 and 7 , the multi-housing 81 is provided to automatically correct the angle so that the striking bar 10 is orthogonal to the concrete surface by the automatic angle correction module 200 .

The automatic angle correction module 200 is accommodated in the first body 210 in which the probe piece 84 is installed and the first angle adjustment hole 212 is formed in the center, and the first angle adjustment hole 212. It is connected to the first body 210 by a pair of first correction shafts 222 disposed at 0 ° and 180 ° positions around the first angle adjustment hole 212 so as to be able to adjust the angle, The second body 220 in which the second angle adjustment hole 224 is formed in the center, accommodated in the second angle adjustment hole 224, and positioned at 90° and 270° around the first angle adjustment hole 212 It is connected to the second body 220 by a pair of second correction shafts 232 disposed thereon and is installed to adjust the angle, and a mounting hole 234 is formed in the center so that the end of the body housing 100 is mounted. The first and second driving units 240 installed on the third body 230 and the first and second correction shafts 222 and 232, respectively, and operating the first and second correction shafts 222 and 232 to pivot ( 240'), detects the retraction position of the probe piece 84 detected by the multi-sensor 85, and detects the probe piece detected by a pair of multi-sensors 85 disposed opposite to each other at equal intervals of 180° ( 84) is compared with each other to calculate a difference value, and at least one of the second and third bodies 220 and 230 is controlled by controlling at least one of the first and second driving units 240 and 240'. It includes an arithmetic module for automatically correcting the angle so that the striking rod 10 is orthogonal to the concrete surface while correcting the difference value within the error range by changing the angle.

Accordingly, since the angle of the striking bar 10 is automatically corrected so as to be orthogonal to the concrete surface by the automatic angle correction module 200, there is an advantage in that even unskilled workers can easily perform the strength test work.

As described above, the most preferred embodiment of the present invention has been described in the detailed description of the present invention, but various modifications may be made within a range that does not depart from the technical scope of the present invention. Therefore, the scope of protection of the present invention should not be limited to the above embodiments, but the scope of protection should be recognized from the techniques of the claims to be described later and from these techniques to equivalent technical means.

10: batting rod 20: rail rod
30: hammer 40: clamp module
50: impact spring 60: control module
70: mobile terminal

Claims (7)

A striking rod 10 inserted into the rod hole 110 of the body housing 100 and having a flat tip 12 formed in surface contact with the concrete surface at one end; A rail rod 20 connected to the striking rod 10 and provided to provide a transfer force to the striking rod 10 in a protruding direction by a return spring 22; A hammer 30 having a center hole 32 formed in the center to be inserted into the rail rod 20 and linearly transported along the rail rod 20 to hit the striking rod 10; It is installed at the end of the rail rod 20 to restrain the hammer 30, and the hammer 30 at a position where the striking rod 10 is drawn into the body housing 100 to a predetermined depth through the rod hole 110 A clamp module 40 provided to release the restraint; One end is connected to the hammer 30 and the other end is bound to the body housing 100 so that the striking rod 10 rides the rod hole 110 into the body housing 100 and is tensioned when operating percussion spring 50; A control module 60 installed in the body housing 100 and equipped with a sensor module 62 to measure the distance moved backward after the hammer 30 hits the striking rod 10 by the striking spring 50 ); And a portable terminal 70 connected to the control module 60 through wired or wireless communication and equipped with a display unit 72 to store and output measured values of the sensor module 62 in real time,
The clamp module 40 is installed at the end of the rail rod 20, and the disk 41 that limits the movement area of the hammer 30, and is installed on the disk 41 to pivot around the support axis 42a And, one end is formed at one end of the hammer 30 corresponding to the hook member 42 having the push-piece 42c and the disk 41 at the other end of the hook member 42b, and the hook member 42 has the hook member 42. It is installed in the body housing 100 corresponding to the locking groove 43 engaged with (42b) and the mill piece 42c of the hook member 42, and the striking rod 10 rides the rod hole 110 to the body housing (100) Includes a support piece 44 for releasing the restraint state between the locking member 42b and the locking groove 43 by pressing the mill piece 42c at a position drawn into the inside at a predetermined depth, and the striking rod 10 When the body housing 100 is pressed in a state where the flat tip 12 of ) is in close contact with the concrete surface, the striking rod 10 rides the rod hole 110 and is drawn into the body housing 100, and the clamp module 40 ) The hammer 30 constrained to moves together, the striking spring 50 is tensioned, and when the striking rod 10 reaches a predetermined position, the supporting piece 44 presses the mill piece 42c to hook the hook member ( 42) is rotated and when the restraint state of the clamp module 40 is released, the hammer 30 moves by the restoring force of the striking spring 50 to hit the striking rod 10, and the hammer 30 hits the striking rod 10 ) is provided so that the sensor module 62 detects the distance moving backward by the reaction force after collision,
The support piece 44 is screwed onto the body housing 100, and has a lever 44a at one end, and when the lever 44a is rotated, the support piece 44 is pitch-moved to move the body housing ( 100) The protrusion length is controlled to the inside, a plurality of stop grooves 44b are formed at equal intervals on the lever 44a, and the ball plunger 44c is formed in the body housing 100 corresponding to the stop groove 44b It is installed to fix the position of the lever 44a at a predetermined angle, and the release time point is controlled between the latch 42b and the lock groove 43 by the movement of the support piece 44, and the lever 44a A concrete compressive strength tester capable of sharing measured values in real time, characterized in that the hammer 30 striking force can be finely adjusted by controlling the release time between the catch 42b and the catch groove 43 by using.
delete delete According to claim 1,
The striking rod 10 is provided so that the hammer 30 striking force is applied in a state orthogonal to the concrete surface in the 360 ° direction by the right angle induction module 80,
The right angle induction module 80,
A multi-housing 81 mounted on the end of the body housing 100 so as to form a concentric with the striking rod 10;
A probe that is linearly transported along the multi-rod hole 82 formed on the multi-housing 81 at equal intervals of 90 degrees around the striking rod 10, and the protruding transport force acts toward the concrete surface by the elastic body 83 side (84),
A multi-sensor 85 installed in the multi-load hole 82 and detecting the retracting position of the probe piece 84;
A multi-disc 86 installed at the end of the rail rod 20 to limit the movement area of the hammer 30;
It is installed on the multi-disc 86 and is operated on / off by the control module 60 to include an electromagnet 87 that magnetically restrains the hammer 30,
A plurality of probe pieces ( 84) is pressed on the concrete surface and pulled in at the same distance and detected collectively by the multi-sensor 84, the control module 60 turns off the electromagnet 87 to release the hammer 30,
With the flat tip 12 of the striking rod 10 in close contact with the concrete surface, the body housing 100 is pressed to receive the multi-sensor 84 detection signal after the hammer 30 reaches a predetermined point. In this case, the hammer 30 is a concrete compressive strength tester capable of sharing the measured value in real time, characterized in that the moving position is detected in the body housing 100 by the position sensor.
According to claim 4,
A rail hole 24 is formed in the center of the rail rod 20, a stop rod 26 is installed, inserted into the rail hole 24, and one end connected to the main body housing 100, and the stop rod ( 26) is installed in the body housing 100 and is screwed with the adjuster 28 rotated at an equal angle,
When the striking rod 10 is pulled into the body housing 100, the end of the stop rod 26 is grounded in the rail hole 24 to limit the retracting distance of the striking rod 10,
When the adjuster 28 is rotated at an equal angle, the protruding length of the stop bar 26 is controlled while the retraction distance of the striking bar 10 is adjusted so that the hammer 30 striking force is controlled. Measured value, characterized in that A concrete compressive strength tester that can be shared in real time.
According to claim 1,
The portable terminal 70 is a concrete compressive strength tester capable of sharing measured values in real time, characterized in that it is provided to be worn on the operator's arm by a shoulder strap 74 including a band.
According to claim 4,
The multi-housing 81 is provided to automatically correct the angle so that the hitting bar 10 is orthogonal to the concrete surface by the automatic angle correction module 200,
The automatic angle correction module 200,
A first body 210 in which a probe piece 84 is installed and a first angle adjustment hole 212 is formed in the center;
The first body 210 is formed by a pair of first correction shafts 222 accommodated in the first angle adjustment hole 212 and disposed at 0° and 180° positions around the first angle adjustment hole 212. A second body 220 connected to and installed to be angularly adjustable and having a second angle adjusting hole 224 formed in the center;
The second body 220 is formed by a pair of second correction shafts 232 accommodated in the second angle adjustment hole 224 and disposed at 90° and 270° positions with respect to the first angle adjustment hole 212. A third body 230 connected to and installed to be angularly adjustable and having a mounting hole 234 formed in the center so that the end of the body housing 100 is mounted;
The first and second driving units 240 and 240' installed on the first and second correction shafts 222 and 232, respectively, and operating the first and second correction shafts 222 and 232 to pivot;
The retraction position of the probe piece 84 detected by the multi-sensor 85 is detected, and the retraction position of the probe piece 84 detected by a pair of multi-sensors 85 disposed opposite to each other at equal intervals of 180°. The values are compared with each other to calculate a difference value, and by controlling at least one of the first and second driving units 240 and 240' to change the angle of at least one of the second and third bodies 220 and 230, the difference A concrete compressive strength tester capable of sharing measured values in real time, characterized in that it comprises a calculation module for automatically correcting the angle so that the striking rod 10 is orthogonal to the concrete surface while correcting the value within the error range.

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