JP3806411B2 - Test hammer tester - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a test hammer tester.
[0002]
[Prior art and problems to be solved by the invention]
For example, a concrete test hammer (for example, Japanese Utility Model Publication No. 61-131646) is commercially available as a non-destructive testing machine for measuring the hardness of the concrete surface by hitting the concrete surface and measuring its repulsive force. Has been.
[0003]
In this concrete test hammer, a hammer body is slidable in the longitudinal direction in a cylindrical main body, a plunger is provided at the front end of the main body so as to be able to project and retract, and the front end of the plunger abuts against the concrete surface. The hardness of the concrete can be measured by striking the hammer body against the end of the plunger with the elastic return force of the spring and measuring the amount of repulsion movement of the hammer body at this time.
[0004]
This concrete test hammer causes an error in the reference value depending on the frequency of use, for example, a spring for hitting the hammer body on the concrete surface via a plunger extends.
[0005]
For this reason, the standard value of a concrete hammer is usually verified periodically, or it is verified immediately before use so that correct measurement can be performed.
[0006]
The verification of the concrete test hammer is performed using a verification device having the following configuration.
[0007]
That is, a hardness value displayed by placing a steel body having a predetermined weight and a predetermined hardness in a cylindrical body and hitting a concrete test hammer toward the steel body is represented by a hardness value of the steel body. The reference is adjusted by setting (that is, a numerical value to be a reference value).
[0008]
Usually, for example, a concrete test hammer is hit by hitting a concrete test hammer from a vertical direction on a steel body having a weight of about 16 kg and a surface hardness of H _R C52 or more (the hardness of the hard body is 80). The reference matching is performed by setting the rebound hardness numerical value indicated by
[0009]
By the way, the concrete where the hardness measurement is actually performed most frequently shows a rebound hardness value of 30-40.
[0010]
Therefore, using a concrete test hammer with a rebound hardness value adjusted to 80 as a standard, when the hardness of an actual concrete surface with a rebound hardness of around 30 to 40 is measured, the standardized hardness value and the actually measured hardness value are However, there is a problem that a measurement error occurs due to too much openness. It is most preferable to perform reference adjustment in the area (near the area) of the hardness value actually measured.
[0011]
Therefore, in spite of the standard adjustment of the concrete test hammer, when measuring the hardness of the most frequently used concrete surface, it was impossible to measure the hardness with high accuracy.
[0012]
On the other hand, various low rebound value testers as described below have been proposed as standards for matching with low rebound hardness values of 30 to 40.
[0013]
This low resilience value tester has a steel body with a predetermined hardness and weight in the body, and a viscoelastic body (synthetic resin, oil, etc.) is placed between the steel body and the bottom of the body. The plunger is brought into contact with the steel body, and the steel body is hit by the hammer body through the plunger, so that the steel body moves downward by a predetermined amount by the viscoelastic body (that is, the hammer body hits the plunger). The viscoelastic body absorbs a predetermined amount of impact when it is applied), and by setting the rebound movement amount of the hammer body to be small (that is, for example, the rebound hardness is 30 to 40), the rebound value is low. It is intended to achieve the standard matching.
[0014]
However, as described above, this low-rebound value tester slidably connects the steel body and the main body with a viscoelastic body (synthetic resin, oil, etc.). Since the elastic force is likely to change with temperature and time, there is a problem in that the measured value varies depending on the surrounding environment during measurement.
[0015]
Therefore, after all, even if this low repulsion value tester is used, it is in the present situation that high-precision reference alignment cannot be performed with a low repulsion value (repulsion value of about 30 to 40).
[0016]
The present invention has solved the above-mentioned problems after repeated studies and examinations, can accurately adjust the hardness measurement values in the low repulsion value region, and can be used for environmental conditions such as temperature and aging. It is an object of the present invention to provide an innovative test hammer tester that is extremely practical and does not cause errors in measurement values due to changes.
[0017]
[Means for Solving the Problems]
The gist of the present invention will be described with reference to the accompanying drawings.
[0018]
A hammer body 2 is slidably provided in the test hammer main body 1, and the hammer body 2 is inserted into the test hammer main body 1 by means of an elastic return force of the spring 3 so as to be able to project and retract. The hardness measurement value of a test hammer configured so that the hardness of the measurement object 5 can be measured by the amount of movement of the hammer body 2 repelled by hitting the measurement object 5 such as concrete is determined based on a predetermined reference value. In the test hammer tester for matching, a hammer hard body 7 having a predetermined hardness is provided in the tester main body 6, and the hammer hard body 7 is placed between the tester main body 6 and the hammer hard body 7. the plate-shaped or disk-shaped or coil-shaped metallic elastic body 8 you repression support provided for the test body 6, this by fixing the ends of the metallic elastic body 8 in the test body 6 Metal bullet Deflection body 8 in the test body 6 movably in disposed, said striking hard body 7 is placed fixed in a substantially central portion of the metallic elastic body 8, the plunger 4 to this striking hard body 7 When the test hammer body 1 is pressed against the hammering hard body 7 and hits the hammering hard body 7 with the hammer body 2 via the plunger 4 at a predetermined position, the metal elastic body 8 is bent by this hammering. by the hitting hard body 7 is absorbed stably impact by the hitting test, characterized by being configured so as to obtain a repulsion hardness value of the weight corresponding striking hard body seven et stably It relates to a hammer tester.
[0019]
Further, the hitting hard body 7, the metal elastic body 8, or the hitting hard body 7 and the metal elastic body 8, the weight of the hitting hard body 7, the weight of the metal elastic body 8, or the hitting hard body. 7 and a weight adjusting mechanism 9 capable of adjusting the weight of the metal elastic body 8 are provided. The weight adjusting mechanism 9 is provided with the hitting hard body 7, the metal elastic body 8, or the hitting hard body 7 and the metal. By attaching / detaching the weight adjusting body 10 to / from the elastic body 8, the weight of the hitting hard body 7, the weight of the metal elastic body 8, or the weight of the hitting hard body 7 and the metal elastic body 8 is adjusted. The weight adjustment mechanism 9 adjusts the weight so that when the hammering hard body 7 is hit with the hammer body 2 via the plunger 4, the degree of impact absorption by the hitting is adjusted. Configured to be able to Those of the test hammer for assay of Claim 1, wherein the configuring the rebound movement of the serial hammer 2 so as to set to a predetermined amount of movement.
[0020]
Further, it relates to the weight adjusting member 10 as a weight adjusting bolt 10 or adjust the weight 2 SL placement test hammers verifier claim weights 10A, characterized in that the employed.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention (how to carry out the invention) considered to be suitable will be briefly described with reference to the drawings, showing its effects.
[0022]
The plunger 4 of the test hammer body 1 is brought into contact with the impacting hard body 7 in the measuring device body 6, the test hammer body 1 is pressed against the impacting hard body 7, and the plunger 4 is moved by the elastic return force of the spring 3 at a predetermined position. When the hammer body 2 is hit through the hitting hard body 7, the metal elastic body 8 supporting the hitting hard body 7 is bent by the impact caused by the hitting, thereby absorbing the impact caused by the hitting. Te, for example, so that the stably obtained a repulsive hardness value less the weight equivalent from a light striking hard body 7 heavy.
[0023]
At this time, the striking hard body 7 is not configured to bend and move due to the elastic action of a viscoelastic body such as rubber or oil, but the metal elastic body 8 is hardly affected by the environment such as temperature and time. By adopting a structure that bends and moves due to an elastic action, a constant rebound hardness value (that is, a hardness that serves as a reference value) that is stable even with temperature change and aging can be obtained.
[0024]
For example, by adjusting the weight of the impact hard body 7 or the degree of deflection of the metal elastic body 8 and setting the degree of absorption of the rebound hardness value 30 to 40, the influence of the environment such as temperature and time in the numerical range to be actually measured. It will be possible to adjust the standard stably without receiving.
[0025]
Therefore, according to the present invention, it is possible to perform stable reference adjustment without being substantially affected by environmental changes such as temperature and time in a low repulsion value region where it has been difficult to perform stable reference value adjustment.
[0026]
In addition, by pre-Symbol plate-like or disc-like or coil-shaped metal elastic body 8 is adopted as a metal elastic body 8, to secure the ends of the metallic elastic body 8 in the test body 6, the metal since the manufacturing elastic member 8 disposed freely moving deflected the test body 6, is置固constant mounting the striking hard body 7 at a substantially central portion of the metallic elastic body 8, striking hard body 7 with the plunger 4 When the ball is hit, the metal bullet body 8 that supports the striking hard body 7 is elastically bent to obtain a rebound hardness value that is a stable reference value. By adopting the disk-shaped or coil-shaped metal elastic body 8, it is possible to absorb the impact when the hammering body 7 is struck with the hammer body 2 via the plunger 4 with a simple configuration. More practical.
[0027]
Moreover, for example, the weight of the impact hard body 7, the weight of the elastic metal body 8, or the impact is applied to the impact hardness body 7, the metal elastic body 8 or the rigid body 7 and the metal elastic body 8. If the weight adjusting mechanism 9 capable of adjusting the weights of the hard body 7 and the metal elastic body 8 is provided, the metal elastic body 8 bends when the hammer body 2 is hit against the hitting hard body 7 via the plunger 4. The degree can be changed by adjusting the weight with the weight adjusting mechanism 9. That is, the weight adjusting mechanism 9 adjusts the weight of the impact absorbed when the plunger 4 is hit with the hammer body 2. It becomes more practical, such as being able to change.
[0028]
Further, for example, the weight adjusting mechanism 9 is attached to or removed from the impact hard body 7, the metal elastic body 8, or the impact hard body 7 and the metal elastic body 8. If the weight of the hitting hard body 7, the weight of the metal elastic body 8 or the weight of the hitting hard body 7 and the metal elastic body 8 can be adjusted, the hitting hard body 7 can be configured with a simple configuration. , The weight of the metal elastic body 8 or the weight of the impact hard body 7 and the metal elastic body 8 can be adjusted.
[0029]
Further, for example, if a weight adjusting bolt 10 or a weight adjusting weight 10A is adopted as the weight adjusting body 10, the weight of the hitting hard body 7, the weight of the metal elastic body 8 or the hitting hardness is further simplified and reduced in cost. The weight of the body 7 and the metal elastic body 8 can be adjusted, which makes it more practical.
[0030]
【Example】
The drawings illustrate one embodiment of the present invention and are described below.
[0031]
In this embodiment, a hammer body 2 is slidably provided in a test hammer body 1, and the hammer body 2 is provided on a test hammer body 1 so as to be able to project and retract by an elastic return force of a spring 3. The hardness measurement value of a concrete test hammer (see FIG. 4) configured so that the hardness of the concrete 5 can be measured by the amount of movement of the hammer body 2 repelled by hitting the concrete 5 via the plunger 4. The present invention relates to a tester for a concrete test hammer for adjusting a reference value to a predetermined reference value. A hammer hard body 7 having a predetermined hardness is provided in a tester body 6, and the tester body 6 and the hammer hard body 7 are provided. In the meantime, a plate-shaped metal elastic body 8 for elastically supporting the impact hard body 7 with respect to the tester main body 6 is provided, and the impact hard body 7 is fixed to the metal elastic body 8 for elastic support. Then, the plunger 4 is brought into contact with the striking hard body 7, the test hammer body 1 is pressed against the striking hard body 7, and the hammer body 2 is struck by the elastic return force of the spring 3 through the plunger 4 at a predetermined position. When the hard body 7 is struck, the metal elastic body 8 is bent by this impact, so that the front impact hard body 7 absorbs the impact caused by the impact, whereby the repulsion movement amount of the hammer body 2 is set to a predetermined amount. It is configured so that the amount of movement can be set.
[0032]
As shown in FIG. 1, the tester main body 6 includes a cylindrical body 6A, an impact hard body 7 and a metal elastic body 8 which are attached to the upper portion of the body 6A and housed in the body 6A. And a cylindrical cover portion 6B that covers from above.
[0033]
In addition, a guide cylinder 11 is provided on the upper portion of the cover portion 6B to guide a concrete test hammer and bring the tip of the plunger 4 into contact with the striking hard body 7 substantially perpendicularly.
[0034]
Specifically, the body portion 6A has a structure in which a through-hole 13 that penetrates from the upper side to the lower side is formed in the center portion thereof.
[0035]
In addition, a fitting recess 21 that can be fitted into the lower portion of the cover portion 6B is provided inside the body portion 6A.
[0036]
As shown in FIGS. 1 to 3, the cover portion 6 </ b> B is configured by a cylindrical body that can fit the lower portion into the fitting recess 21, and the insertion hole into which the guide tube 11 can be inserted and disposed at the upper center. 22 is provided, and a flange portion 23 in which a plurality of bolt insertion holes (not shown) through which the locking bolts 21 for fixing the cover portion 6B to the body portion 6A are inserted is provided on the lower outer edge portion.
[0037]
A striking hard body 7 and a metal elastic body 8 are disposed inside the body portion 6A.
[0038]
The hitting hard body 7 employs an anvil weight 7 having a predetermined weight and a predetermined hardness.
[0039]
The anvil weight 7 is made of steel and is formed in a disk shape, and a hitting convex portion 18 that hits the plunger 4 of the concrete test hammer and hits the hammer body 2 through the plunger 4 at the center. The configuration is provided. In this embodiment, the anvil weight 7 is made of steel. However, any hard body that can stably adjust the reference value as a test hammer tester may be used as appropriate.
[0040]
As the metal elastic body 8, a disk-shaped metal elastic body 8 (that is, a disk-shaped leaf spring) is employed. In the present embodiment, a disc-shaped plate spring is used as the metal elastic body 8, but may be used as appropriate as long as it can exhibit a bending elastic action, for example, a rectangular plate spring or a through hole. A configuration using a coil spring in 13 may be adopted.
[0041]
The anvil weight 7 is placed and fixed substantially at the center of the metal elastic body 8.
[0042]
Further, the striking hard body 7 and the metal elastic body 8 are fixed by weight adjusting bolts 10 described later.
[0043]
Then, the hitting hard body 7 and the metal elastic body 8 are disposed in the body portion 6A, the lower portion of the cover portion 6B is fitted into the fitting recess 21, and the insertion hole provided in the flange portion 23 of the cover portion 6B and the metal A locking bolt 12 is inserted into and screwed into an insertion hole 24 formed at a predetermined position of the elastic body 8 so that the anvil weight 7 is elastically supported on the metal elastic body 8 and arranged in the body portion 6A. The configuration is set up.
[0044]
At this time, when the anvil weight 7 is struck by the hammer body 2 via the plunger 4 of the concrete test hammer between the inner surface of the cover portion 6B and the outer surface of the anvil weight 7 and the metal elastic body 8, A space 19 is provided to allow the weight 7 and the metal elastic body 8 to bend.
[0045]
Further, a space 20 is provided between the lower surface of the metal elastic body 8 and the upper surface of the fitting recess 21 of the tester body 6 to allow the anvil weight 7 and the metal elastic body 8 to bend. Yes.
[0046]
The anvil weight 7 and the metal elastic body 8 are provided with a weight adjusting mechanism 9 for adjusting the weight of the anvil weight 7 and the metal elastic body 8.
[0047]
That is, the weight adjusting mechanism 9 attaches or removes the weight adjusting bolt 10 and the weight adjusting weight 10A, which become the weight adjusting body 10, to the anvil weight 7 and the metal elastic body 8, thereby removing the anvil weight 7 and the metal elastic body. The weight of the body 8 can be set to a predetermined weight.
[0048]
Specifically, a plurality of screw holes that communicate with each other are provided in the anvil weight 7 and the metal elastic body 8, and the weight adjusting weight 10A is attached to or removed from the portion provided with the plurality of screw holes by the weight adjusting bolt 10. Thus, the weight of the anvil weight 7 and the metal elastic body 8 is adjusted.
[0049]
Further, the central portion of the metal elastic body 8 is formed to be slightly thicker than other portions, and a screw hole is provided in the thick portion so that the weight adjusting bolt 10 can be firmly screwed and attached. It is composed.
[0050]
The weight adjusting bolt 10 also functions as a fixing bolt for mounting and fixing the anvil weight 7 on the metal elastic body 8 as described above.
[0051]
With the configuration of the weight adjusting mechanism 9, when the weight adjusting weight 10A is attached so that the weight of the anvil weight 7 and the metal elastic body 8 is increased, the weight of the anvil weight 7 and the metal elastic body 8 is increased. by become, upon striking the anvil weights 7 (hitting protrusions 18) with a hammer body 2 through the plunger 4, reduce the deflection degree of (by reducing the amount of movement of the anvil wait 7) metal elastic body 8 In other words, since the amount of impact impact absorption can be reduced, the amount of movement of the hammer body 2 repelling relative to the plunger 4 can be set large, and the rebound reference value can be set to a high value.
[0052]
On the other hand, when the weight adjusting weight 10A is removed so that the weight of the anvil weight 7 and the metal elastic body 8 is reduced, the weight of the anvil weight 7 and the metal elastic body 8 is reduced, so that the weight of the anvil weight 7 and the metal elastic body 8 is reduced. when struck the anvil weights 7 (hitting protrusions 18) in the hammer 2 Te, can increase the deflection degree of the (by increasing the amount of movement of the anvil wait 7) metal elastic body 8, i.e., the impact of the blow Since the amount of absorption can be increased, the rebound reference value can be set to a low value by setting the amount of movement of the hammer body 2 repelling relative to the plunger 4 to be small.
[0053]
The weight adjusting weight 10 may be appropriately employed as long as the weight of the anvil weight 7 and the metal elastic body 8 can be changed. For example, the weight adjusting weight 10 may have a disk shape or a rectangular shape.
[0054]
The weight adjusting bolt 10 and the weight adjusting weight 10A constituting the weight adjusting mechanism 9 can be easily attached and removed from the outside of the tester body 6 to easily adjust the weight of the anvil weight 7 and the metal elastic body 8. The structure is to get.
[0055]
That is, a detachable bottom plate 15 is provided at the bottom of the body portion 6A, the bottom plate 15 is removed, and the anvil weight 7 and the metal elastic body 8 are inserted through the through-hole 13 inside the body portion 6A (by inserting a hand). The weight adjusting weight 10A can be attached to or the weight adjusting weight 10A attached to the anvil weight 7 and the metal elastic body 8 can be removed, whereby the weight of the anvil weight 7 and the metal elastic body 8 can be adjusted.
[0056]
In the present embodiment, the bottom plate 15 is made of a synthetic resin having flexibility, and can be detachably fitted to the bottom of the body portion 6A.
[0057]
As a result, the bottom plate 15 can be easily attached to and detached from the body portion 6A, and the anvil weight 7 and the metal elastic body can be easily obtained simply by inserting a hand into the through hole 13 of the body portion 6A and attaching and removing the weight adjusting bolt. The weight of 8 can be adjusted.
[0058]
Further, by arranging a flexible synthetic resin at the bottom of the tester body 6, it can absorb the impact of the impact of the concrete hammer and the vibration of the bending movement of the metal elastic body 8, and more accurately. Highly accurate reference alignment can be performed.
[0059]
Reference numeral 17 in the figure denotes a guide auxiliary plate that assists in bringing the plunger 4 of the test hammer body 1 inserted through the guide cylinder 11 into contact with the upper surface of the striking convex portion 18.
[0060]
【The invention's effect】
Since the present invention is configured as described above, it is possible to accurately adjust the hardness measurement value in the low repulsion value region, and there is no error in the measurement value due to environmental changes such as temperature and time. This is a revolutionary test hammer tester with excellent practicality.
[0061]
That is, the impact hard body that strikes the hammer body via the plunger of the test hammer is not configured to bend and move by the elastic action of a viscoelastic body such as rubber or oil, but is affected by the environment such as temperature and time. By being configured to bend and move due to the elastic action of a metal elastic body that is hardly affected, it is possible to stably adjust the reference of the low value region without causing variations in the reference value even with temperature change and aging. It will be a revolutionary test hammer tester with excellent practicality.
[0062]
Furthermore, when the strike hit hard body flop plunger, will be obtained the rebound hardness value Kinzokudan biological for repression supporting the striking hard body becomes stable reference value deflected substantially uniformly, also elastic metal By adopting a plate-shaped, disk-shaped, or coil-shaped metal elastic body as a body, it absorbs the impact when hitting the impacting hard body with a hammer body via a plunger with a simple configuration, and originally from the impacting hard body It is an epoch-making test hammer tester that is excellent in practicality and can obtain a rebound hardness value lower than the rebound hardness value obtained.
[0063]
In the invention of claim 2 , the degree of flexure of the metal elastic body when the hammer body is hit against the hitting hard body via the plunger can be changed by adjusting the weight with the weight adjusting mechanism. , i.e., very practical to soo the image that can be easily be changed by making the weight adjustment weight adjustment mechanism before Symbol simple configuration absorption degree of impact when struck plunger with the hammer It becomes a tester for the test hammer.
[0064]
In a third aspect of the invention, the weight of the impact hard body, the weight of the metal elastic body or the weight of the impact hard body, and the weight of the metal elastic body are reduced in cost with a simpler configuration. It is a revolutionary test hammer tester that is extremely practical and can be adjusted.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an internal structure of a test hammer tester according to an embodiment of the present invention.
FIG. 2 is an explanatory cross-sectional view showing a state when an anvil weight is struck with a hammer body via a plunger of the present embodiment.
FIG. 3 is an explanatory perspective view showing a test hammer tester and a bottom plate according to the present embodiment.
FIG. 4 is a cross-sectional view showing an internal structure of a test hammer according to the present embodiment.
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 Test hammer body 2 Hammer body 3 Spring 4 Plunger 5 Measured object 6 Tester body 7 Impact hard body 8 Metal elastic body, elastic body 9 Weight adjustment mechanism
10 Weight adjustment body (weight adjustment bolt)
10A weight adjustment weight

Claims (3)

  A hammer body is slidably provided in the test hammer body, and this hammer body is applied to a measurement object such as concrete via a measurement object striking plunger that is provided on the test hammer body so as to be able to project and retract with the elastic return force of the spring. Test hammer tester configured to adjust the hardness measurement value of a test hammer configured to be able to measure the hardness of a measurement object based on the amount of movement of the hammer body repelled by the impact, with a predetermined reference value. In the tester body, a striking hard body having a predetermined hardness is provided, and between the tester main body and the striking hard body, a plate shape or a disk shape for elastically supporting the striking hard body with respect to the tester body Alternatively, by providing a coiled metal elastic body and fixing the end of the metal elastic body to the tester body, the metal elastic body is flexibly arranged on the tester body. Then, the hammering hard body is placed and fixed substantially at the center of the metal elastic body, the plunger is brought into contact with the hammering hard body, the test hammer body is pressed against the hammering hard body, and the plunger is fixed at a predetermined position. When the hitting hard body is hit with a hammer body, the metal elastic body is bent by this hitting, and the hitting hard body stably absorbs the impact due to the hitting, so that the hitting hard body is stably A test hammer tester configured to obtain a rebound hardness value equivalent to its weight. The hitting hard body, the metal elastic body or the hitting hard body, and the metal elastic body have a weight of the hitting hard body, a weight of the metal elastic body, or a weight of the hitting hard body and the metal elastic body. The weight adjusting mechanism can be adjusted by attaching or detaching the weight adjusting body to or from the hitting hard body, the metal elastic body or the hitting hard body and the metal elastic body. The weight of the hitting hard body, the weight of the metal elastic body or the weight of the hitting hard body and the metal elastic body can be adjusted, and by adjusting the weight by the weight adjusting mechanism, When the hammering body is struck with a hammer body via the plunger, it can be configured to adjust the degree of impact absorption by this hammering, and the rebound movement amount of the hammer body can be set to a predetermined movement amount Test Hammer for assay of Claim 1, wherein it has urchin configuration. The weight adjustor weight adjusting bolt or adjusting weight 2 SL placement test hammer for assay of Claim weight, characterized in that the employed as.

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