KR102189475B1 - Test Anvil For Schmidt Hammers - Google Patents

Abstract

Provided is an anvil for a Schmidt hammer. According to an exemplary embodiment of the present invention, the anvil for a Schmidt hammer includes: an anvil part with which a tip of the Schmidt hammer collides; a fastening part arranged to be spaced apart from the anvil part by a predetermined distance and pressurizing and fixing an outer side surface of the Schmidt hammer; a fixing part coupled to the other end portion of a support column and an outer side surface of the anvil part and pressurizing and fixing the outer side surface of the Schmidt hammer; and a support part coupled to the fixing part and the fastening pat to support the fastening part. Therefore, the anvil for a Schmidt hammer can reinforce coupling power with the Schmidt hammer.

Description

Anvil for Schmidt Hammers {Test Anvil For Schmidt Hammers}

The present invention relates to a test anvil for a Schmidt hammer.

In general, Schmidt hammers that measure the strength of concrete or mortar are composed of a body and a tip. The tip is made of a cylindrical metal material, and the body is formed in a tube shape so that the tip can be mounted therein, and one end of the tip may be exposed to the outside.

At this time, the spring inside the body may apply a restoring force to the tip so that one end of the tip moves along the length direction of the body, so that the one end of the tip strikes the outer surface of the object to be measured. In this process, the strength of concrete or mortar can be measured by the degree to which the tip hits and bounces off the object, that is, the rebound hardness.

In the conventional Schmidt hammer, various changes such as spring change occurred during the hitting process. In general, correction is performed after about 1500 hits, but the most well-known correction method is to use a Schmidt hammer on a test anvil made of a material with a known strength value.

However, in this process, the measurement personnel directly fixed the Schmidt hammer to the test anvil and used it, and the measured value changed due to the human hand.

An embodiment of the present invention is to provide an anvil for a Schmitt hammer that enhances the coupling force with the Schmitt hammer and minimizes interference of a measurer in a measurement process.

According to an aspect of the present invention, the tip of the Schmidt hammer collides with the anvil portion; A fastening part disposed to be spaced apart from the anvil part by a predetermined distance, and configured to pressurize and fix the outer surface of the Schmidt hammer; A fixing part that is coupled to the other end of the support column and an outer surface of the anvil part, and pressurizes the outer surface of the Schmitt hammer to fix it; And a support part that is coupled to the fixing part and the fastening part to support the fastening part, and is provided with an anvil for a Schmidt hammer.

In addition, the fastening part may include a first fastening body in a ring shape having a hole formed in the center; A guiding member formed in a cylindrical shape having a direction horizontal to the ground in a longitudinal direction, disposed inside the hole of the first fastening body, and having both ends connected to the inner surface of the first fastening body; A ring-shaped second fastening body disposed to be spaced apart from the first fastening body and having a hole formed at a center thereof; A counter-rotating member coupled to an outer surface of the second fastening body, having a shape corresponding to the outer surface of the support pillar at a center thereof, and having a corresponding screw hole through which the support pillar passes; A rotation shaft formed in a cylindrical shape having a direction horizontal to the ground in a longitudinal direction, disposed inside the hole of the second fastening body, and having both ends connected to the inner surface of the second fastening body; One or more fastening arms having a direction perpendicular to the ground in a longitudinal direction and positioned inside the holes of the first fastening body and the second fastening body; And a fastening cylinder connected to the outer surface of the first fastening body and having a hollow part formed therein in a longitudinal direction perpendicular to the ground, one end located inside the fastening cylinder, and the other end of the second fastening body. It is connected to and may include a fastening moving part including a moving piston that slides along the longitudinal direction of the fastening cylinder.

In addition, the fastening arm includes a fastening tip protruding from an outer surface facing the Schmidt hammer, in contact with the outer surface of the Schmitt hammer, and having a curved shape on one side corresponding to the outer surface of the Schmitt hammer, A rotation hole into which the rotation shaft is inserted is formed on an outer surface adjacent to the other end direction of the fastening arm, and the first guiding hole is a hole extending in a direction perpendicular to the ground, and the first guiding hole at the other end of the first guiding hole. A second guiding hole may be formed in communication with the guiding hole and extending in a direction inclined at a predetermined angle with a direction in which the first guiding hole extends.

In addition, the fixing part is formed in a ring shape in which a through hole, which is a hole, is formed in the center, is coupled to an outer surface of the anvil part, and at least one piston hole having the through hole direction in the longitudinal direction from the outer circumferential direction is formed therein. Fixed body; An anti-pressure cylinder located inside the fixed body and formed in a tube shape; An anti-pressure piston located inside the anti-pressure cylinder and inside the piston hole, and having one end facing the through hole; A support member coupled to one end of the anti-pressure piston and pressing and supporting an outer surface of the Schmidt hammer; And a support rotation motor formed on an outer surface of the fixed body in the direction of the support column, and is coupled to the support column to rotate the support column.

The anvil for a Schmidt hammer according to an embodiment of the present invention strengthens the coupling force with the Schmitt hammer and minimizes interference of a measurer in the calibration process of the Schmitt hammer, thereby obtaining a constant result value.

1 is a side view of an anvil for a Schmidt hammer according to an embodiment of the present invention.
2 is a perspective view of a fastening part according to an embodiment of the present invention.
3 is a cross-sectional view of a fastening part according to an embodiment of the present invention.
4A and 4B are diagrams showing an operating state of a fastening unit according to an embodiment of the present invention.
5 is a perspective view of a support according to an embodiment of the present invention.
6 is a perspective view of a fixing part according to an embodiment of the present invention.
7 is a cross-sectional view of a fixing part according to an embodiment of the present invention.
8A and 8B are state diagrams showing an operating state of a fixing unit according to an embodiment of the present invention.
9 is a photograph of an anvil for a Schmidt hammer according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art can easily implement the present invention. The present invention may be implemented in various different forms, and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and the same reference numerals are assigned to the same or similar components throughout the specification.

1 is a side view of an anvil for a Schmidt hammer according to an embodiment of the present invention. In the following description, the direction of the fastening part 300 in the anvil part 100 is defined as upward, and the direction of the anvil part 100 in the fastening part 300 is defined as downward based on FIG. 1.

Referring to FIG. 1, an anvil 1 for a Schmidt hammer according to an embodiment of the present invention may include an anvil part 100, a fastening part 300, a support part 500, and a fixing part 700.

Through this, the anvil 1 for a Schmidt hammer according to an embodiment of the present invention minimizes interference of a measurer during the operation of the Schmitt hammer, and thus a result value can be consistently obtained.

The Schmidt hammer includes a Schmitt hammer body 10 with a hollow portion formed therein and a Schmidt hammer tip 30 that is located in the hollow portion of the Schmitt hammer body 10 and is drawn out from the Schmitt hammer body 10 through user manipulation. can do.

When an operator puts the end of the Schmidt hammer body 10 on an object to measure the strength and operates a button (not shown) formed on one side of the Schmidt hammer body 10, the Schmitt hammer body 10 The hammer tip 30 protrudes and strikes the object to be measured strength. Thereafter, due to the repulsive force, the Schmidt hammer tip 30 is pushed back into the inside of the Schmidt hammer body 10 and the internal measuring unit (not shown) is manipulated to display the strength value on the Schmidt hammer display unit (not shown). .

In an embodiment of the present invention, the anvil part 100 may collide with the Schmitt hammer tip 30 of the Schmitt hammer. To this end, the anvil unit 100 may be made of a material having a reference strength fixed at room temperature, such as hapgunggang, which will be a reference point when correcting the Schmidt hammer.

2 is a perspective view of a fastening part according to an embodiment of the present invention, and FIG. 3 is a cross-sectional view of a fastening part according to an embodiment of the present invention.

1 to 3, the fastening part 300 may be disposed to be spaced apart from the upper surface of the anvil part 100 by a predetermined distance.

In addition, the fastening part 300 includes a first fastening body 320, a guiding member 321, a second fastening body 330, a corresponding rotating member 340, a rotating shaft 331, a fastening arm 360 and fastening It may include a moving part 350.

The first fastening body 320 may be spaced apart from the anvil part 100 by a predetermined distance. In addition, the first fastening body 320 may be provided in the form of a ring in which the first fastening hole 323 is formed in the center, and a space in which the Schmidt hammer is inserted into the first fastening hole 323 in the center may be formed.

A guiding member 321 may be positioned in the first fastening hole 323 of the first fastening body 320. The guiding member 321 may be formed in a cylindrical shape having a direction parallel to the ground in a longitudinal direction. In addition, both ends of the guiding member 321 are coupled to the inner surface of the first fastening body 320 in which the first fastening hole 323 is formed, so that the fastening arm 360 to be described later is used as the guiding member 321. Guiding can be made to move.

In addition, one or more first auxiliary support holes 325 may be formed in the first fastening body 320 to penetrate from an upper surface to a lower surface of the first fastening body 320. An auxiliary pillar 530 to be described later is inserted into the first auxiliary support hole 325 so that the movement of the first fastening body 320 may be guided along the length direction of the auxiliary pillar 530.

Meanwhile, the second fastening body 330 may be disposed to be spaced apart from the lower surface of the first fastening body 320 by a predetermined distance. In addition, the second fastening body 330 may have a ring shape in which a second fastening hole 333 that is a hole in the center is formed. In this case, the second fastening hole 333 is disposed so that the center thereof is aligned with the first fastening hole 323, so that a space in which the Schmidt hammer body 10 is disposed perpendicular to the anvil part 100 may be secured.

In addition, the second fastening body 330 is spaced apart by a predetermined distance from the lower side of the first fastening body 320, so as to secure a distance to be moved due to the fastening moving part 350 to be described later.

In addition, the second fastening body 330 may have one or more second auxiliary support holes 335 penetrating from the top to the bottom of the second fastening body 330. In this case, the position of the second auxiliary support hole 335 may correspond to the position of the first auxiliary support hole 325. In the second auxiliary support hole 335, an auxiliary pillar 530, which will be described later, is inserted, so that the movement of the first fastening body 320 and the second fastening body 330 is guided along the length direction of the auxiliary pillar 530. You can do it.

Meanwhile, the rotation shaft 331 may be disposed in the second fastening hole 333 of the second fastening body 330. For example, the rotation shaft 331 may be formed in a cylindrical shape having a direction parallel to the ground in a longitudinal direction. In addition, both ends of the rotation shaft 331 may be coupled to the inner surface of the second fastening body 330, so that the fastening arm 360, which will be described later, is bound to the second fastening body 330.

Meanwhile, the corresponding rotating member 340 may be coupled to the outer surface of the second fastening body 330. For example, the corresponding rotating member 340 may be formed in a plate shape, and a corresponding screw hole 341, which is a hole having the same length direction as that of the support pillar 510, may be formed in the center. A support pillar 510 to be described later may pass through the corresponding screw hole 341. In this case, a spiral groove or protrusion may be formed in the corresponding screw hole 341 to correspond to the thread 511 formed on the outer peripheral surface of the support column 510. Through this, when the support column 510 rotates, the fastening part 300 may be moved upward or downward along the screw thread 511 in response thereto.

Meanwhile, a plurality of fastening arms 360 may be provided, and each of the fastening arms 360 may face each other and may be disposed inside the holes of the first fastening body 320 and the second fastening body 330. In addition, the fastening arm 360 may extend in a direction perpendicular to the ground, so that one end is positioned above the first fastening body 320 and the other end is formed to be adjacent to the rotation shaft 331.

At this time, a fastening tip 365 may protrude from one end of the fastening arm 360. The fastening tip 365 can increase the frictional force with the Schmidt hammer body 10 when the fastening arm 360 contacts the Schmidt hammer body 10, so that the fastening arm 360 and the Schmitt hammer body 10 are strongly coupled. have. To this end, the fastening tip 365 may be made of a material having high frictional force and elasticity such as synthetic rubber or natural rubber, but is not limited thereto.

Alternatively, the shape of the fastening tip 365 may correspond to the cylindrical shape of the Schmidt hammer body 10, so that the surface in contact with the Schmitt hammer body 10 may be formed to be concavely curved. Through this, the fastening tip 365 may be brought into close contact with the outer surface of the Schmidt hammer body 10, thereby increasing the fastening property with the Schmitt hammer body 10.

Meanwhile, a plurality of holes including a rotation hole 361, a first guiding hole 363, and a second guiding hole 364 may be formed in the fastening arm 360.

The rotation hole 361 may be formed to penetrate the fastening arm 360 on an outer surface adjacent to the other end of the fastening arm 360. In addition, the rotation hole 361 may have a direction perpendicular to the length direction of the fastening arm 360 in the length direction. At this time, the rotation hole 361 has a shape corresponding to the rotation shaft 331, so that the rotation shaft 331 is inserted into the rotation hole 361. Through this, the fastening arm 360 may be rotated about the rotation axis 331.

The fastening arm 360 rotates about the rotational shaft 331 and may be fastened or released with the Schmitt hammer in response to the movement of the first fastening body 320 and the second fastening body 330.

Meanwhile, a first guiding hole 363 and a second guiding hole 364 may be formed at a position corresponding to the guiding member 321 of the fastening arm 360.

The first guiding hole 363 may be a hole formed to have a width corresponding to the guiding member 321 and extending in the same direction as the length direction of the fastening arm 360. The guiding member 321 is inserted into the first guiding hole 363 so that when the fastening arm 360 is rotated with respect to the rotation shaft 331, the movement of the fastening arm 360 is reduced to the first guiding hole 363 It can be guided in the extension direction of.

The second guiding hole 364 may be a hole connected to communicate with the other end of the first guiding hole 363. Through this, the guiding member 321 may guide the fastening arm 360 along the extension direction of the first guiding hole 363 as well as the second guiding hole 364.

In this case, the direction in which the second guiding hole 364 extends may be formed to be inclined to a space into which the Schmitt hammer body 10 is inserted at a predetermined angle with the extending direction of the first guiding hole 363.

That is, the fastening arm 360 is guided along the guiding member 321 inserted into the first guiding hole 363 and the second guiding hole 364, and movement may be restricted.

Meanwhile, referring to FIGS. 3 and 4, the fastening moving part 350 may include a fastening cylinder 351 and a moving piston 353.

The fastening cylinder 351 may be coupled to the outer surface of the first fastening body 320. In addition, the fastening cylinder 351 has a cylindrical hollow portion having a longitudinal direction perpendicular to the ground therein, and a portion of the hollow portion, for example, a lower end portion, may be exposed to the outside. In addition, the internal hollow portion of the fastening cylinder 351 may be connected to an external pump (not shown), so that pressure is supplied to the internal hollow portion from the pump or vice versa. For example, the pump is configured as an air pump that controls the air pressure, and air may be injected into the fastening cylinder 351 or, conversely, air may be discharged from the inside.

The moving piston 353 may have a direction perpendicular to the ground in a longitudinal direction, and may have a cylindrical shape so as to correspond to the shape of the inner hollow portion of the fastening cylinder 351. In addition, at least a portion including one end of the movable piston 353 is located inside the fastening cylinder 351 and may be pushed or pushed back through the pressure supplied to the fastening cylinder 351.

In addition, the other end of the movable piston 353 is coupled to the second fastening body 330, so that the second fastening body 330 can be lifted or lowered downward according to the internal hydraulic pressure of the fastening cylinder 351.

4A and 4B are diagrams illustrating an operating state of a fastening unit according to an embodiment of the present invention.

4 (a) and (b) will be described the fastening process of the fastening part 300 of the embodiment of the present invention with the Schmidt hammer body 10.

When a fluid such as air is removed from the inside of the fastening cylinder 351 and a negative pressure is generated, the moving piston 353 is pushed in the direction of the fastening cylinder 351 and moves the second fastening body 330 connected to the other end upward. Will be lifted. That is, the distance between the first fastening body 320 and the second fastening body 330 is narrowed.

In this process, the guiding member 321 moves downward along the extending directions of the first guiding hole 363 and the second guiding hole 364 based on the fastening arm 360. At this time, since the other end of the second guiding hole 364 faces the space into which the Schmitt hammer body 10 is inserted, one end of the fastening arm 360 rotates in the opposite direction of the space into which the Schmitt hammer body 10 is inserted. And the gaps between the plurality of fastening tips 365 are open to each other. In this process, the rotation shaft 331 allows the fastening arm 360 to be rotatable, but is bound to the rotation shaft 331 to prevent the fastening arm 360 from being separated from the fastening part 300.

Through this, the fastening part 300 can form a space into which the Schmitt hammer body 10 is inserted through the fastening moving part 350, and at the same time, the fastening part 300 and the Schmitt hammer body 10 are fastened. Can be released.

On the other hand, when positive pressure is generated inside the fastening cylinder 351 to push the moving piston 353, the second fastening body 330 moves downward in response to the movement of the moving piston 353.

For this reason, the guiding member 321 also moves upward based on the fastening arm 360. In this process, the guiding member 321 forms the second guiding hole 364 and the first guiding hole 363. It moves through sequentially.

Since the first guiding hole 363 extends in the same direction as the length direction of the fastening arm 360, the guiding member 321 passes through the second guiding hole 364 and enters the first guiding hole 363. In the process, one end of the fastening arm 360 and the fastening tip 365 may be made to stand upright in the direction of the space into which the Schmitt hammer body 10 is inserted, so that it may come into contact with the Schmitt hammer body 10.

Through this, the anvil 1 for a Schmidt hammer according to an embodiment of the present invention allows the fastening part 300 and the Schmitt hammer body 10 to be mechanically fastened, thereby preventing interference by the measurer in the calibration process of the Schmitt hammer. It can be minimized, so the result can be obtained consistently.

5 is a perspective view of a support according to an embodiment of the present invention.

Meanwhile, in an embodiment of the present invention, the support part 500 may include a support column 510, an auxiliary column 530, and a support ring 550.

The support pillar 510 may be positioned between the anvil portion 100 and the fastening portion 300. In this case, the support pillar 510 has a direction perpendicular to the upper surface of the anvil unit 100 in a longitudinal direction, and an end portion in the ground direction may be connected to the fixing unit 700.

In this case, a spiral thread 511 may be formed on the outer surface of the support pillar 510. In addition, the support pillar 510 may be inserted into the corresponding screw hole 341 of the corresponding rotating member 340 of the fastening part 300.

In an embodiment of the present invention, the support column 510 may be rotated by a fixing part 700 to be described later. At this time, the corresponding screw hole 341 of the corresponding rotating member 340 has a spiral groove or protrusion formed to correspond to the screw thread 511, so that the support column 510 is rotated according to the rotation direction of the support column 510. It can be moved in the longitudinal direction, that is, upward or downward.

Through this, the support pillar 510 may determine the position of the fastening part 300 in the vertical direction through rotation.

Meanwhile, the auxiliary pillar 530 may be formed in a pillar shape having the same length direction as the support pillar 510. In addition, the lower end of the auxiliary pillar 530 may be coupled to the fixing part 700. In this case, the position of the auxiliary pillar 530 may be arranged to correspond to the position of the first auxiliary support hole 325 and the second auxiliary support hole 335.

In addition, the cross section in the width direction of the auxiliary pillar 530 corresponds to the cross section in the width direction of the first auxiliary support hole 325 and the second auxiliary support hole 335, and the auxiliary pillar 530 is a first auxiliary support hole 325 ) And the second auxiliary support hole 335 and may be in contact with the fastening part 300.

Through this, the auxiliary pillar 530 guides the fastening portion 300 along the longitudinal direction of the auxiliary pillar 530, thereby improving stability when the fastening portion 300 is moved.

On the other hand, the support ring 550 is located above the auxiliary pillar 530 and the support pillar 510, one side may be coupled to the upper end of the support pillar 510 and the auxiliary pillar 530. In addition, the support ring 550 may be provided in a ring shape in which a support ring hole 551 is formed in the center.

The operator inserts the Schmidt hammer body 10 into the support ring hole 551, the first fastening hole 323, and the second fastening hole 333, and into the anvil 1 for a Schmitt hammer according to an embodiment of the present invention. Schmidt hammer can be fixed.

Through this, the support part 500 moves the fastening part 300, and stability may be improved in the process of moving the fastening part 300.

In addition, the support ring 550 serves as a shield in the process of inserting the Schmidt hammer, thereby preventing the end of the Schmitt hammer from colliding with other components. Through this, it is possible to prevent damage to the anvil 1 for a Schmitt hammer according to an embodiment of the present invention with a Schmitt hammer.

6 is a perspective view of a fixing part according to an embodiment of the present invention, FIG. 7 is a cross-sectional view of a fixing part according to an embodiment of the present invention, and FIGS. 8A and 8B are an embodiment of the present invention. It is a state diagram showing the operation state of the fixing unit according to the example.

Meanwhile, referring to FIGS. 6 and 7, the fixing part 700 may be coupled to an outer surface of the anvil part 100, for example, an upper surface. In addition, the fixing unit 700 may include a fixed body 710, a pressure-resistance cylinder 720, a pressure-resistance piston 721, a support member 750, and a support rotation motor 760.

In one embodiment of the present invention, the fixed body 710 may be positioned under the fastening part 300 and formed in a ring shape in which a through hole 715 is formed in the center. In addition, one side of the fixed body 710 is coupled to the upper surface of the anvil unit 100, and a part of the upper surface of the anvil unit 100 may be exposed through the through hole 715.

In addition, a piston hole 711 penetrating to an inner surface in the through hole 715 direction may be formed inside the fixed body 710. In the piston hole 711, an anti-pressure piston 721 to be described later may be started along the longitudinal direction of the piston hole 711.

Meanwhile, an extension wall 713 as a wall may be formed on the inner circumferential surface of the through hole 715. At least a portion of the outer surface of the extension wall 713 may contact the anvil part 100.

In this case, the cross-sectional area in the width direction of the extension wall 713 may increase from the inner circumferential surface of the fixed body 710 toward the center of the through hole 715. That is, the upper surface of the extension wall 713 may be inclined upward at a predetermined angle so as to interact with the support member 750 to be described later.

Meanwhile, the anti-pressure cylinder 720 may be located inside the fixed body 710. For example, the anti-pressure cylinder 720 may be coupled to the end of the piston hole 711 so that the pressure-resistance piston 721 can be moved inside the anti-pressure cylinder 720 and in the piston hole 711.

The pressure-resisting cylinder 720 may have the same length direction as the length direction of the piston hole 711 and may be formed in the form of a tube having a hollow portion therein. Through this, it is possible to form a space in which the anti-pressure piston 721 can be located. In addition, the anti-pressure cylinder 720 is connected to the pump, and the pump may form a constant pressure in the anti-pressure cylinder 720. For example, the pump may be configured as an air pump, and may supply a certain amount of air pressure to the internal space of the constant pressure cylinder 720 through the air pressure.

On the other hand, the pressure piston 721 is at least a part of the other end is located inside the pressure cylinder 720, a part is located inside the piston hole 711, the remaining part including one end is in the direction of the through hole 715 It may be exposed to the outside of the piston hole 711. In addition, the pressure resistant piston 721 is formed in a cylindrical shape, so that the pressure resistant piston 721 and the piston hole 711 can be easily started.

The anti-pressure piston 721 may receive a constant pressure from the other end direction due to the pressure formed in the internal hollow portion of the anti-pressure cylinder 720.

Meanwhile, the support member 750 may be coupled to one end of the pressure resistant piston 721. A support tip 751 may protrude on an outer surface of the support member 750 in the direction of the through hole 715.

For example, the support tip 751 may have a surface in contact with the end of the Schmidt hammer and the outer surface adjacent to it is curved concave, so that the end of the Schmidt hammer and the outer surface adjacent to the end of the Schmitt hammer are in close contact.

In addition, an elevation member 753 may be positioned on one side of the support member 750, for example, an outer surface in the direction of the extension wall 713. In one embodiment of the present invention, the elevating member 753 is made of a material having elasticity such as synthetic rubber, natural rubber, or polymer resin, and is based on the support member 750 and the extension wall 713 continuously. You can apply pressure.

In this case, the cross-sectional area in the width direction of the elevating member 753 may be formed such that the cross-sectional area in the width direction decreases from the direction of the fixed body 710 toward the center of the through hole 715.

That is, the elevating member 753 may have a shape in which the lower surface is inclined in correspondence with the shape of the upper surface of the extension wall 713. Through this, the lifting member 753 is in close contact with the fixed body 710 when the support member 750 moves in the direction of the inner side of the fixed body 710, and the support member 750 When moving in the center direction, the support member 750 may be lifted upward by applying a restoring force to the support member 750.

Meanwhile, the fixed elastic member 730 may be positioned between the inner side surface of the fixed body 710 and the support member 750. For example, the fixed elastic member 730 is composed of a spiral spring surrounding the outer surface of the anti-pressure piston 721, and the pressure due to the restoring force is applied to the inner surface of the fixed body 710 and the outer surface of the support member 750. Can be added.

8A and 8B, it is intended to describe the operation method of the fixing part 700 in an embodiment of the present invention.

Referring to (a) of FIG. 8, the Schmidt hammer tip 30 may be located inside the Schmidt hammer body 10. The Schmidt hammer tip 30 may be in a state of continuously receiving a restoring force due to the hammer elastic member 11 located inside the Schmitt hammer body 10.

The operator may make the end of the Schmidt hammer body 10 mounted with the Schmidt hammer tip 30 in contact with the upper surface of the anvil part 100 through the through hole 715 for correction of the Schmitt hammer. Thereafter, after fixing the Schmidt hammer body 10 through the fastening part 300, the fastening part 300 may be moved in the direction of the anvil part 100 by rotating the support pillar 510. Through this, the end of the Schmidt hammer body 10 and the Schmitt hammer tip 30 may pass through the through hole 715 to be in close contact with the upper surface of the anvil part 100.

In this process, the support member 750 is pushed in the direction of the support body 710 by the Schmidt hammer body 10, but the pressure of the anti-pressure piston 721 and the anti-pressure cylinder 720 and the restoring force applied by the fixed elastic member 730 are used. It can be fixed by pressing the outer surface adjacent to the end of the Schmidt hammer body 10.

Through this, the anvil 1 for a Schmidt hammer according to an embodiment of the present invention may enhance the bonding force with the Schmitt hammer.

Thereafter, the Schmidt hammer is operated so that the end of the Schmidt hammer tip 30 strikes the upper surface of the anvil portion 100, so that the intensity value of the anvil portion 100 may be displayed on the display portion of the Schmitt hammer. And, as shown in (b) of FIG. 8, when the measured Schmidt hammer body 10 is lifted upward, the Schmidt hammer tip 30 flowing inside the Schmidt hammer body 10 is the Schmidt hammer body It does not respond to the movement of (10) and remains as it is.

At this time, the support member 750 moves to the center of the through hole 715 due to the pressure and presses the outer surface of the Schmitt hammer tip 30. This prevents the Schmidt hammer tip 30 from flowing inside the Schmitt hammer body 10, thereby preventing the Schmidt hammer tip 30 from distorting the measurement result due to unintended interaction with the display. can do.

At this time, the lifting member 753 has a restoring force, and when the support member 750 moves to the center of the through hole 715, upward pressure is applied to the support member 750. That is, the support member 750 presses the outer surface of the Schmidt hammer tip 30 and is lifted upwards, so that the operator applies a force upward to separate the Schmitt hammer tip 30 from the support member 750. It can be easily separated when applied.

Conversely, there may be a case where the Schmidt hammer tip 30 in contact with the support member 750 is moved downward. For example, when the Schmidt hammer body 10 is not properly contacted with the anvil portion 100 to operate the button. In this case, the Schmidt hammer body 10 is spaced apart from the upper surface of the anvil portion 100 and the Schmidt hammer tip 30 does not properly hit the anvil portion 100, so that the measurement result may be distorted.

When the Schmitt hammer tip 30 is exposed in this way, the support member 750 and the elevating member 753 are lifted upward by grabbing the Schmitt hammer tip 30. That is, the support member 750 and the elevating member 753 prevent the Schmitt hammer tip 30 that is not in close contact from touching the display unit, thereby stopping measurement. Through this, the support member 750 and the lifting member 753 may improve the accuracy of the average of the result values.

In addition, the lifting member 753 having elastic force prevents the support member 750 and the anti-pressure cylinder 720 from being deformed due to upward pressure, and the support member 750 is in direct contact with the extension wall 713. It can prevent wear while doing.

Through this, the anvil 1 for a Schmidt hammer according to an embodiment of the present invention can enhance the coupling force with the Schmitt hammer, but prevent distortion of the measurement result.

Meanwhile, the support rotation motor 760 may be located on the upper surface of the fixed body 710 corresponding to the position of the support pillar 510. In addition, the support rotation motor 760 may be formed in the form of an electric motor having a support rotation shaft 761 rotated on one side. The support rotation shaft 761 is coupled to the support column 510, and when the support rotation shaft 761 rotates, the support column 510 may also rotate together.

Through this, the support rotation motor 760 may rotate the support pillar 510 so that the fastening part 300 moves upward or downward in response to the rotation.

Meanwhile, the anvil 1 for a Schmidt hammer according to an embodiment of the present invention may further include a control unit (not shown). The control unit may include the above-described pump and power source (not shown).

After the Schmitt hammer is inserted into the anvil 1 for a Schmitt hammer according to an embodiment of the present invention, the controller may control a fastening process and a process in which the Schmitt hammer approaches the anvil unit 100.

That is, by minimizing operator interference during the measurement process, it is possible to prevent distortion of the measurement result due to the operator's hand. Through this, the anvil for a Schmidt hammer according to an embodiment of the present invention can strengthen the coupling force with the Schmitt hammer, minimize interference of the measurer in the calibration process of the Schmitt hammer, and obtain a constant result.

9 is a photograph of an anvil for a Schmidt hammer according to another embodiment of the present invention.

Meanwhile, an anvil for a Schmidt hammer according to another embodiment of the present invention may include an anvil 1000, a coupling part 3000, and a flange part 5000.

In another embodiment of the present invention, the anvil 1000 may collide with the Schmidt hammer tip 30 of the Schmidt hammer. To this end, the anvil 1000 may be made of a material having a reference strength fixed at room temperature, such as hapgunggang, which will be a reference point when correcting the Schmidt hammer.

The coupling part 3000 may be combined with the anvil 1000 to form a hole into which the Schmitt hammer body 10 and the Schmitt hammer tip 30 are inserted.

The flange portion 5000 may mutually couple the coupling portion 3000 and the anvil 1000 so that the Schmidt hammer inserted in the coupling portion 3000 is in close contact with the anvil 1000.

Through this, in the anvil for a Schmidt hammer according to another embodiment of the present invention, the coupling portion 3000 and the anvil 1000 are integrated, so that measurement can be easily performed.

Although the embodiments of the present invention have been described above, the spirit of the present invention is not limited to the embodiments presented in the present specification, and those skilled in the art who understand the spirit of the present invention will add components within the scope of the same spirit. It will be possible to easily propose other embodiments by changing, deleting, adding, etc., but it will be said that this is also within the scope of the present invention.

1: Schmidt hammer anvil 10: Schmidt hammer body
11: hammer elastic member 30: Schmidt hammer tip
100: anvil part 300: fastening part
320: first fastening body 321: guiding member
323: first fastening hole 325: first auxiliary support hole
330: second fastening body 331: rotating shaft
333: second fastening hole 335: second auxiliary support hole
340: counter rotating member 341: counter screw hole
350: fastening moving part 351: fastening cylinder
353: moving piston 360: fastening arm
361: rotating hole 363: first guiding hole
364: 2nd guiding hole 365: fastening tip
500: support part 510: support column
511: thread 530: auxiliary column
550: support ring 551: support ring hole
700: fixed part 710: fixed body
711: piston hole 713: extension wall
715: through hole 720: anti-pressure cylinder
721: anti-pressure piston 730: fixed elastic member
750: support member 751: support tip
753: elevating member 760: supporting rotary motor
761: support rotary shaft 1000: anvil
3000: coupling portion 5000: flange portion

Claims (4)

An anvil portion where the tip of the Schmidt hammer collides;
A fastening portion disposed to be spaced apart from the anvil portion by a predetermined distance, and fixing an outer surface of the Schmidt hammer by pressing;
A fixing part that is coupled to the other end of the support column and the outer surface of the anvil part and pressurizes the outer surface of the Schmitt hammer to fix it; And
It is coupled to the fixing portion and the fastening portion, and includes a support portion supporting the fastening portion,
The fastening part,
A first fastening body provided in the form of a ring in which a first fastening hole is formed in the center and spaced apart from the anvil part by a predetermined distance;
A guiding member formed in a cylindrical shape having a direction horizontal to the ground in a longitudinal direction, disposed inside the hole of the first fastening body, and having both ends connected to the inner surface of the first fastening body;
It is disposed spaced apart from the lower surface of the first fastening body by a predetermined distance, and is provided in a ring shape in which a second fastening hole is formed in the center, and the second fastening hole is 2 fastening body;
A counter-rotating member coupled to the outer surface of the second fastening body, having a shape corresponding to the outer surface of the support pillar in the center, and having a corresponding screw hole through which the support pillar passes;
A rotation shaft formed in a cylindrical shape having a direction horizontal to the ground in a longitudinal direction, disposed inside the hole of the second fastening body, and having both ends connected to the inner surface of the second fastening body;
At least one fastening arm having a direction perpendicular to the ground in a longitudinal direction and positioned inside the second fastening hole of the first fastening body and the second fastening body; And
A fastening cylinder connected to the outer surface of the first fastening body and having a hollow part formed therein in a longitudinal direction perpendicular to the ground, and one end is located inside the fastening cylinder, and the other end is connected to the second fastening body. It is connected, and includes a fastening moving part including a moving piston that slides along the longitudinal direction of the fastening cylinder,
The fastening arm,
Protruding from the outer surface facing the Schmidt hammer, contacting the outer surface of the Schmidt hammer, and including a fastening tip having a curved shape corresponding to the outer surface of the Schmidt hammer, the fastening tip is a fastening arm When contacting the Schmidt hammer body, it increases the frictional force with the Schmitt hammer body to make the fastening arm and the Schmitt hammer body strongly bonded.
A rotation hole into which the rotation shaft is inserted is formed on an outer surface adjacent to the direction of the other end of the fastening arm,
A direction in which the first guiding hole, which is a hole extending in a direction perpendicular to the ground, communicates with the first guiding hole at the other end of the first guiding hole, and is inclined at a predetermined angle with the direction in which the first guiding hole extends A second guiding hole extended to is formed,
The fixing part,
A fixed body formed in a ring shape in which a through hole, which is a hole, is formed in the center, is coupled to an outer surface of the anvil part, and has at least one piston hole formed therein from an outer circumferential direction to the through hole direction;
An anti-pressure cylinder located inside the fixed body and formed in a tube shape;
An anti-pressure piston located inside the anti-pressure cylinder and in the piston hole, and having one end facing the through hole;
A support member coupled to one end of the anti-pressure piston and supporting by pressing the outer surface of the Schmidt hammer; And
Anvil for a Schmidt hammer, which is formed on an outer surface of the fixed body in the direction of the support column, and includes a support rotation motor coupled with the support column to rotate the support column. delete delete delete

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