JP2021179398A - Concrete overstrike evaluation device and concrete overstrike evaluation measuring method - Google Patents

Abstract

To propose a concrete overstrike evaluation device and a concrete overstrike evaluation measuring method that allow quantitative measurement without variations.SOLUTION: There is provided a concrete overstrike evaluation device 1 comprising: a main body part 2 that has grip parts 22 on its right and left sides; a scaled penetration rod 3 that is disposed below the main body part 2; a load meter 4 that is inserted between the main body part 2 and the penetration rod 3; and a display 5 that displays a result of measurement performed by the load meter 4. Also provided is a concrete overstrike evaluation measuring method using the concrete overstrike evaluation device 1.SELECTED DRAWING: Figure 1

Description

The present invention relates to a concrete piling evaluation device and a piling evaluation measuring method.

When constructing a concrete structure, it is necessary to appropriately determine the timing of concrete stacking so that cold joints do not occur on the stacking joint surface by stacking concrete. As a method of setting the timing of stacking concrete, the penetration resistance value of the mortar of the concrete and the penetration depth of the concrete may be measured and determined by using the measurement result. Specifically, the penetration resistance value (proctor penetration resistance value) is measured by a proctor penetration tester using a mortar specimen in a laboratory. In addition, at the construction site, the slump test thrust rod is inserted into the concrete and the depth (penetration depth) that can be inserted is measured. Then, the relationship between the penetration resistance value and the penetration depth is determined to determine whether or not the state is suitable for stacking (see, for example, Non-Patent Document 1). In this case, it is necessary to determine the relationship between the penetration resistance value and the penetration depth in all the formulations used and perform a preliminary test to obtain the control value at the time of implementation.
In addition, in the conventional method using a thrust rod, the technician's senses act, and the measured value varies (individual difference) depending on the technician, so that quantitative measurement may not be possible. In addition, since it is necessary to perform both an indoor test and a field test, the work is troublesome.

Katsuhiko Hirakawa, 3 others, "Evaluation method of allowable stacking time by human power penetration of thrust rod used for slump test method and its application to construction work", Annual Proceedings of Concrete Engineering, Vol.24, No.1, p. 1047-1052, 2002

An object of the present invention is to propose a concrete laying evaluation device and a concrete laying evaluation measurement method that enable simple quantitative measurement without variation.

The concrete stacking evaluation device of the present invention that solves such a problem includes a main body portion having grip portions on the left and right, a penetrating rod with a scale arranged below the main body portion, and the main body portion. It is provided with a load meter interposed between the penetration rod and a display unit for displaying the measurement result of the load meter.
According to the concrete stacking evaluation device, the left and right grip portions can be gripped when the intrusive rod is inserted into the concrete, so that the verticality of the intrusive rod can be easily maintained. Therefore, the measurement result is stable and quantitative measurement becomes possible. In addition, since the intrusive rod has a scale, the intrusive depth can be visually confirmed.
If the intrusive rod is formed by connecting a plurality of rod members, the length of the intrusive rod can be adjusted. Therefore, it is possible to change the length of the intrusive rod according to the situation even when the driving height is large or the depth to the overlapping surface is different for each construction cycle (lot).
Further, if the tip of the intrusive rod is provided with a detachable thrust portion, the thrust portion can be changed according to the size of the aggregate contained in the concrete, so that stable measurement becomes possible.
Further, if the intrusive rod includes a shaft rod and a cylindrical scale rod externally attached to the shaft rod, the direction of the scale can be changed to a direction that is easy for the measurer to see. It will be easier to work.

Further, the concrete piling evaluation measurement method of the present invention utilizes the concrete piling evaluation device, in which the intrusion rod is inserted into the concrete to measure the penetration depth of the penetration rod and the penetration depth is measured. A step of measuring the load when the rod is inserted, a step of calculating the measured penetration resistance value based on the load, and a step of converting the concrete penetration resistance value into the mortar penetration resistance value in the measured penetration resistance value. It is provided with a step of calculating the proctor penetration resistance value by multiplying the coefficient β and the coefficient α for converting the penetration resistance value of the mortar into the proctor penetration resistance value.
According to the concrete piling evaluation measurement method, the penetration depth and the penetration resistance value can be quantitatively measured at the same time by using the concrete piling evaluation device of the present invention, and the proctor penetration evaluation value can be measured. By calculating, it is possible to evaluate the timing of piling concrete according to the same criteria as when using the conventional measurement method.

According to the concrete laying evaluation device and the concrete laying evaluation measurement method of the present invention, when constructing a concrete structure by laying concrete, the timing of laying concrete is quantitative and simple without variation. It becomes possible to evaluate.

It is a figure which shows the concrete stacking evaluation apparatus of 1st Embodiment, (a) is a front view, (b) is a side view. It is a perspective view which shows the main body part. It is a top view which shows the shape of the grip part which concerns on other forms. It is a figure which shows each member of the intrusive bar of 1st Embodiment, (a) is a front view of a shaft bar, (b) is a front view of a scale bar. (A) to (c) are perspective views showing the protrusions according to other forms. It is a flowchart which shows the concrete stacking evaluation measurement method. It is an experimental result by a concrete stacking evaluation device, and is a graph showing the relationship between the elapsed time from water injection and the penetration depth. It is an experimental result by a concrete stacking evaluation apparatus, and is a graph which shows the relationship between the penetration resistance value of concrete and the penetration resistance value of mortar. It is a front view which shows the concrete stacking evaluation apparatus of 2nd Embodiment. It is a figure which shows each member of the intrusive bar of the 2nd Embodiment, (a) is a front view of a shaft bar, (b) is a front view of a scale bar. (A) and (b) are perspective views showing an example of an end portion of a scale bar member. (A) is a front view showing the concrete stacking evaluation device of the third embodiment, and (b) is an exploded perspective view of an intrusive rod.

Hereinafter, when constructing a concrete structure having a predetermined shape by laminating a plurality of stages of concrete, an implementation of a concrete piling evaluation device 1 used for evaluating the timing of piling concrete on the upper surface of the cast concrete. The form will be described.

<First Embodiment>
FIG. 1 shows the concrete stacking evaluation device 1 of the first embodiment. As shown in FIG. 1, the concrete stacking evaluation device 1 of the first embodiment includes a main body portion 2, a penetration rod 3, a load meter 4, and a display portion 5.
As shown in FIG. 2, the main body portion 2 has a base 21 and grip portions 22 and 22 extending to the left and right from the base 21. The base 21 is made of an aluminum alloy and is a side view table-shaped member whose upper surface is inclined with respect to the bottom surface. The shape of the base 21 is not limited, and may be, for example, a triangular shape (triangular columnar shape) when viewed from the side. Further, the upper surface of the base 21 does not necessarily have to be inclined with respect to the bottom surface, and the base 21 may be a square columnar shape. Further, the base 21 may be a hollow member or a member having a concave front view formed by a bottom plate and left and right vertical plates. Further, the material constituting the base 21 is not limited, and may be, for example, stainless steel or steel.

The grip portion 22 is made of a rod-shaped member made of an aluminum alloy fixed to the base 21. The grip portion 22 is a so-called handle provided on the left and right sides of the base 21 so that the measurer can grip it with both hands. The left and right grip portions 22 are fixed to the left and right side surfaces of the base 21, and extend to the side of the base 21. The left and right grip portions 22 and 22 may be left and right ends of a single rod-shaped member that penetrates the base 21. Further, the shape of the member constituting the grip portion 22 is not limited, and may be, for example, an annular shape (see FIG. 3A) or a T-shape (FIG. 3B). )reference). Further, the material constituting the grip portion 22 is not limited as long as it has a predetermined strength, and may be, for example, stainless steel, steel, wood, synthetic resin, or the like.

As shown in FIG. 1, the intrusive rod 3 is arranged on the lower side of the main body portion 2. The intrusive rod 3 of the present embodiment includes a shaft rod 31, a cylindrical scale rod 32 outer to the shaft rod 31, and a protrusion 33 detachably provided at the tip of the shaft rod 31.
The shaft rod 31 is made of a stainless steel rod having a predetermined length. FIG. 4A shows the shaft rod 31. The outer diameter of the shaft rod 31 of the present embodiment is 16 mm, but the outer diameter dimension of the shaft rod 31 is not limited. As shown in FIG. 4A, a male screw portion 34 is formed at the upper end of the shaft rod 31. Further, a recess (female threaded portion 35) that has been threaded is formed on the lower end surface of the shaft rod 31. The structure of the end portion of the shaft rod 31 is not limited, and for example, a female screw portion 35 may be formed at the upper end portion and a male screw portion 34 may be formed at the lower end portion, or the upper end portion may be formed. A male screw portion 34 or a female screw portion 35 may be formed on both of the lower end portions. Further, the male screw portion 34 or the female screw portion 35 may be formed as needed. Further, the material constituting the shaft rod 31 is not limited to stainless steel, and may be, for example, an aluminum alloy.

The scale bar 32 is made of a cylindrical member made of stainless steel. FIG. 4B shows the scale bar 32. The scale bar 32 has the same length as the shaft bar 31 excluding the male screw portion 34. The scale bar 32 of the present embodiment has an inner diameter of 16 mm and an outer diameter of 20 mm. By using a member having an inner diameter equal to or larger than the outer diameter of the shaft rod 31 as the scale rod 32, the scale rod 32 can rotate around the shaft rod 31 when the scale rod 32 is mounted on the shaft rod 31. The inner diameter of the scale bar 32 is preferably smaller than the outer diameter of the protrusion 33. In this way, the protrusion 33 can prevent the scale bar 32 from falling off. The shape and dimensions of the scale bar 32 may be determined according to the shaft bar 31. As shown in FIG. 4 (b), a scale is attached to the outer surface of the scale bar 32 (penetration bar 3). The scale of the scale bar 32 is the length from the tip of the penetration bar 3 including the height of the protrusion 33.

As shown in FIG. 4A, the protrusion 33 of the present embodiment is made of a columnar member having an outer diameter (20 mm) equivalent to the outer diameter of the scale bar 32. The outer diameter of the protrusion 33 is preferably equal to or less than the outer diameter of the scale bar 32. The lower end of the protrusion 33 is flat, and a male screw portion 34 that can be screwed to the female screw portion 35 of the shaft rod 31 is formed at the upper end of the protrusion 33. When the thrust portion 33 is screwed to the lower end of the shaft rod 31, the upper surface of the thrust portion 33 comes into contact with the lower end of the scale rod 32. The shape of the upper end of the thrust portion 33 may be formed according to the joining type with the shaft rod 31, for example, when the male screw portion 34 is formed at the lower end of the shaft rod 31, the female screw portion 35 is formed. Is formed, and the male screw portion 34 may be omitted when joining to the shaft rod 31 via a jig or the like.
A scale is attached to the outer surface of the protrusion 33. The scale of the thrust portion 33 has zero at the lower end of the thrust portion 33. Further, the scale of the thrust portion 33 is marked on the entire circumference of the thrust portion 33. The scale of the thrust portion 33 may be engraved or printed on the outer surface of the thrust portion 33.
The shape of the protrusion 33 is not limited, and can be changed according to the concrete to be measured (mixture, aggregate amount, aggregate size, etc.). The shape of the protrusion 33 may be, for example, a conical shape (see FIG. 5 (a)) or a hemisphere (see FIG. 5 (b)) whose diameter decreases toward the lower end, or the lower end penetrates. It may have an enlarged diameter portion larger than the outer diameter of the rod 3 (see FIG. 5 (c)).

As shown in FIG. 1, the load meter 4 is interposed between the main body portion 2 and the penetration rod 3. The upper surface of the load meter 4 is fixed to the lower surface of the base 21, and the intrusive rod 3 is fixed to the lower surface of the load meter 4. In this embodiment, a compression type load cell having a capacity of 200 N (minimum value of 0.05 N) is used as the load meter 4. The capacity of the load meter 4 is not limited to 200N. Further, the type of the load cell 4 is not limited to the compression type load cell.
The load meter 4 is fixed to the base 21 via bolts. The method of fixing the load meter 4 and the base 21 is not limited, and for example, the load meter 4 may be fixed via a jig such as an attachment.
The load meter 4 is fixed to the upper end of the intrusive rod 3 via the attachment 41. The attachment 41 is made of a columnar member having an outer diameter larger than that of the intrusive rod 3 (scale rod 32), and a female screw portion 42 is formed on the lower surface of the attachment 41. A male screw portion 34 formed at the upper end of the intrusive rod 3 can be screwed to the female screw portion 42. When the penetration bar 3 is fixed to the attachment 41, the upper end of the scale bar 32 comes into contact with the attachment 41 on the lower surface. That is, the scale bar 32 is in a state of being sandwiched between the attachment 41 and the protrusion 33. The shape of the lower surface of the attachment 41 is preferably larger than the cross-sectional shape of the intrusive rod 3. The shape of the attachment 41 is not limited to a columnar shape, and may be, for example, a rectangular parallelepiped shape. Further, the method of fixing the load meter 4 and the penetration rod 3 is not limited, and for example, the male screw of the penetration rod 3 may be directly screwed to the load meter 4.

The display unit 5 displays the measurement result of the load meter 4. As shown in FIG. 1, the display unit 5 of the present embodiment is fixed on the base 21 of the main body unit 2. The display unit 5 is detachably attached to the base 21 via a hook-and-loop fastener (not shown). The method of fixing the display unit 5 and the base 21 is not limited, and for example, bolts or jigs may be used for fixing.
A cable 43 extending from the load meter 4 is connected to the display unit 5. The display unit 5 displays the measurement result on the load meter 4 transmitted via the cable 43.

Next, a concrete stacking evaluation measurement method using the concrete stacking evaluation device 1 of the present embodiment will be described. As shown in FIG. 6, the concrete stacking evaluation measurement method of the present embodiment includes a measurement step S1, a measurement value calculation step S2, and a conversion value calculation step S3.
In the measurement step S1, the intrusive rod 3 is inserted into the existing concrete, the intrusive depth is measured, and the load is measured. When inserting the intrusive rod 3 into the existing concrete, the measurer holds the left and right grips 22 and 22 with his right hand and his left hand, respectively, while maintaining the verticality of the intrusive rod 3. Then, when the load when the intrusive rod is inserted is displayed on the display unit, this is read. Further, after pushing the penetration rod 3 to a depth where it can be inserted, the penetration depth is measured by reading the scale of the scale rod 32 on the surface (upper surface) of the already-cast concrete.

In the measured value calculation step S2, the measured penetration resistance value is calculated from the measured load by the equation 1. Since the value measured by the concrete stacking evaluation device 1 of the present embodiment is a load (N), the bottom area of the protrusion 33 is divided from the load and converted into a measured penetration resistance value. The display unit 5 may automatically calculate and display the measured penetration resistance value.
Measurement penetration resistance value (N / mm ² ) = load (N) ÷ area of bottom surface of protrusion (mm ² ) ・ ・ ・ Equation 1

In the conversion value calculation step S3, the proctor penetration resistance value and the conversion penetration depth are calculated.
The proctor penetration resistance value is calculated by multiplying the measured penetration resistance value by the coefficient α and the coefficient β. Since the measured intrusive resistance value is the resistance value when the intrusive rod is inserted into concrete, it is converted into the proctor intrusive resistance value for mortar by multiplying by the coefficient αβ. The coefficient β is a coefficient obtained from the relationship between the case where the concrete penetration resistance value is measured using the concrete stacking evaluation device 1 of the present embodiment and the case where the mortar penetration resistance value is measured. Further, the coefficient α is a coefficient obtained from the relationship between the penetration resistance value of the mortar measured by using the concrete piling evaluation device 1 and the penetration resistance value of the mortar measured by using the Proctor penetration tester. ..
The converted intrusive depth is calculated by multiplying the measured value of the intrusive depth by the coefficient γ. Since the outer diameter φ1 (20 mm) of the penetration rod 3 (scale rod 32) of the present embodiment is different from the outer diameter φ2 of the thrust rod generally used for measuring the penetration depth, it is a coefficient in the measured value of the penetration depth. By multiplying by γ (= φ2 / φ1), the measured value of the penetration depth measured by the concrete stacking evaluation device 1 is converted into the value when the thrust rod is used.

As described above, according to the concrete piling evaluation device 1 and the concrete piling evaluation measuring method of the present embodiment, the penetration depth and the penetration resistance value can be quantitatively measured at the same time, which is efficient. In addition, since the penetration depth and the penetration resistance value can be grasped at the site without requiring an laboratory test, the timing of stacking can be evaluated.
In addition, by calculating the proctor penetration resistance value, it is possible to evaluate the timing of concrete splicing based on the same criteria as when the conventional measurement method is used.

Further, since the left and right grip portions 22 and 22 can be gripped when the intrusive rod 3 is inserted into the concrete, the verticality of the intrusive rod 3 can be easily maintained. Therefore, it is possible to suppress the variation in the measurement result depending on the measurer, and as a result, the measurement result is stable and quantitative measurement becomes possible.
Further, since the penetration rod 3 has a scale, the penetration depth can be visually confirmed. Since the scale rod 32 of the penetration rod 3 is rotatable with respect to the shaft rod 31, the direction of the scale can be changed to a direction that is easy for the measurer to see.
Further, by changing the protruding portion 33 fixed to the tip of the intrusive rod 3, it is possible to perform measurement according to the composition of concrete (for example, the size of aggregate) and the like.
Further, since the upper surface of the base 21 is inclined, the display surface of the display unit 5 can be easily confirmed by the measurer who is gripping the grip portion 22.

Next, the results of measuring the penetration depth and the penetration resistance value into the concrete by using the concrete stacking evaluation device 1 of the present embodiment will be described.
(1) Intrusive depth The intrusive depth when the intrusive rod 3 was inserted into the concrete produced by the composition shown in Table 1 was measured (Example). In addition, as a comparative example, a conventional slump test thrust rod was inserted into concrete having the same composition and the penetration depth was measured. FIG. 7 shows the relationship between the water injection time of concrete and the penetration depth.

As shown in FIG. 7, the intrusive depth by the concrete stacking evaluation device 1 and the intrusive depth by the thrust rod showed the same tendency. Therefore, the coefficient γ (= penetration depth φ2 by the thrust rod ÷ penetration depth φ1 by the concrete stacking evaluation device 1) set based on the data accumulated in the laboratory test and the field measurement is used for the concrete stacking evaluation. It was confirmed that the penetration depth of the thrust rod used in the conventional measuring method can be calculated by multiplying the penetration depth by the device 1. Therefore, even when the concrete piling evaluation device 1 is used, by multiplying by the coefficient γ, it is possible to evaluate the timing of concrete piling according to the same judgment criteria as when the conventional measurement method is used. ..

(2) Penetration resistance value Next, using the concrete stacking evaluation device 1 of the present embodiment, the penetration resistance value of the concrete of the composition shown in Table 1 and the penetration resistance of the mortar screened for the concrete of the composition of Table 1 The value and was measured. The test results are shown in FIG. FIG. 8 is a graph showing the relationship between the penetration resistance value of mortar having the same elapsed time and the penetration resistance value of concrete. As shown in FIG. 8, the intrusive resistance value of mortar and the intrusive resistance value of concrete are generally in a proportional relationship. As a result, it was confirmed that the penetration resistance value of concrete can be converted into the penetration resistance value of mortar by multiplying the penetration resistance value by a predetermined coefficient β (β = 1 in the case of FIG. 8). Further, since the proctor penetration resistance value is a value obtained by measuring the penetration resistance value of the mortar using the proctor penetration tester, the mortar measured by using the concrete pouring evaluation device 1 of the present embodiment. It is presumed to show a linearity equivalent to the penetration resistance value. Therefore, it is presumed that the proctor penetration resistance value can be calculated by multiplying the penetration resistance value of the mortar measured by using the concrete piling evaluation device 1 by the coefficient α. Therefore, if the proctor penetration resistance value is calculated by multiplying the coefficient α and the coefficient β by the concrete penetration resistance value measured using the concrete stacking evaluation device 1, it is the same as when the conventional measurement method is used. It is possible to evaluate the timing of concrete splicing based on the criteria of.

<Second embodiment>
In the second embodiment, a case where the height from the position (scaffolding) of the measurer to the upper surface of the concrete to be measured changes by stacking the concrete will be described.
FIG. 9 shows the concrete stacking evaluation device 1 of the second embodiment. As shown in FIG. 9, the concrete stacking evaluation device 1 of the second embodiment includes a main body portion 2, a penetration rod 3, a load meter 4, and a display portion 5. Since the configurations of the main body 2, the load meter 4, and the display unit 5 of the concrete stacking evaluation device 1 of the second embodiment are the same as those shown in the first embodiment, detailed description thereof will be omitted.

As shown in FIG. 9, the upper end of the intrusive rod 3 is fixed to the lower surface of the load meter 4 via the attachment 41. The intrusive rod 3 of the present embodiment includes a shaft rod 31, a cylindrical scale rod 32 outer to the shaft rod 31, and a protrusion 33 detachably provided at the tip of the shaft rod 31. Since the details of the thrust portion 33 are the same as those of the thrust portion 33 shown in the first embodiment, detailed description thereof will be omitted. FIG. 10A shows the shaft rod 31, and FIG. 10B shows the scale rod 32.

As shown in FIG. 10A, the shaft rod 31 is formed to have a predetermined length by connecting a plurality of shaft rod members 36 in the axial direction. Since the shaft rod 31 (penetration rod 3) can be changed to a predetermined length by increasing or decreasing the number of shaft rod members 36, adjust the length according to the height position of the concrete to be measured. Can be done. The shaft rod member 36 is made of, for example, a stainless steel rod having a predetermined length. A male screw portion 34 is formed at the upper end of the shaft rod member 36. Further, a recess (female threaded portion 35) that has been threaded is formed on the lower end surface of the shaft rod member 36. The structure of the end portion of the shaft rod member 36 is not limited, and for example, a female screw portion 35 may be formed at the upper end portion and a male screw portion 34 may be formed at the lower end portion, or the upper end portion may be formed. A male screw portion 34 or a female screw portion 35 may be formed on both the lower end portion and the lower end portion. Further, the male screw portion 34 or the female screw portion 35 may be formed as needed. Further, the material constituting the shaft rod member 36 is not limited to stainless steel, and may be, for example, an aluminum alloy.

As shown in FIG. 10B, the scale bar 32 is formed to have a predetermined length by connecting a plurality of scale bar members 37 in the axial direction. Since the scale bar 32 (penetration bar 3) can be changed to a predetermined length by increasing or decreasing the number of scale bar members 37, adjust the length according to the height position of the concrete to be measured. Can be done.
The scale bar member 37 is made of a stainless steel cylindrical member having the same length as the shaft bar member 36 excluding the male screw portion 34. The inner diameter of the scale bar member 37 is equal to or larger than the outer diameter of the shaft bar member 36. A scale is attached to the outer surface of the scale bar member 37. The scale of the scale rod member 37 is the length from the tip of the penetration rod 3 including the height of the protrusion 33. Further, the scale of the scale bar member 37 is continuous with the scale of the upper and lower scale bar members 37. At the upper end and the lower end of the scale bar member 37, engaging portions that engage with the ends of other scale bar members 37 arranged above and below may be formed. As the engaging portion, for example, as shown in FIG. 11A, a protrusion 37a that protrudes from the end of one scale bar member 37 and can be inserted into the inside of the other scale bar member 37 may be used. .. Further, as shown in FIG. 11B, the engaging portion is an annular convex portion 37b protruding from the end surface of one scale bar member 37 and a concave portion 37c formed on the end surface of the other scale bar member 37. You may.

Since the concrete stacking evaluation method using the concrete stacking evaluation device 1 of the second embodiment is the same as the content shown in the first embodiment, detailed description thereof will be omitted.
According to the concrete stacking evaluation device 1 of the second embodiment, the length of the intrusive rod 3 can be adjusted by connecting the plurality of shaft rod members 36 and the scale rod member 37. Therefore, it is possible to change the length of the intrusive rod 3 according to the situation even when the driving height is large or the depth to the joint surface is different for each construction cycle (lot).
Since the operation and effect of the concrete stacking evaluation device 1 of the other second embodiment are the same as those shown in the first embodiment, detailed description thereof will be omitted.

<Third embodiment>
The concrete piling evaluation device 1 of the third embodiment is different from the concrete piling evaluation device 1 of the first embodiment and the second embodiment in that a bar material having a scale is used as the intrusive bar 3. There is.
FIG. 12 shows the concrete stacking evaluation device 1 of the third embodiment. As shown in FIG. 12A, the concrete stacking evaluation device 1 of the third embodiment includes a main body portion 2, a penetration rod 3, a load meter 4, and a display portion 5. Since the configurations of the main body 2, the load meter 4, and the display unit 5 of the concrete stacking evaluation device 1 of the third embodiment are the same as those shown in the first embodiment, detailed description thereof will be omitted.

The upper end of the penetration rod 3 is fixed to the lower surface of the load meter 4 via the attachment 41. The intrusive rod 3 of the present embodiment includes a stainless steel rod (rod). A protrusion 33 is provided at the lower end of the bar. Since the details of the thrust portion 33 are the same as those of the thrust portion 33 shown in the first embodiment, detailed description thereof will be omitted.
A scale is attached to the outer surface of the intrusive rod 3. The scale of the intrusive rod 3 shall be the length including the height of the thrust portion 33. As shown in FIG. 12B, a male screw portion 34 is formed at the upper end of the intrusive rod 3. Further, a recess (female threaded portion 35) that has been threaded is formed on the lower end surface of the penetration rod 3. The structure of the end portion of the intrusive rod 3 is not limited, and for example, a female screw portion 35 may be formed at the upper end portion and a male screw portion 34 may be formed at the lower end portion, or the upper end portion and the upper end portion. A male screw portion 34 or a female screw portion 35 may be formed on both of the lower end portions. Further, the male screw portion 34 or the female screw portion 35 may be formed as needed. Further, the material constituting the intrusive rod 3 is not limited to stainless steel, and may be, for example, an aluminum alloy. Further, the length of the intrusive rod 3 may be adjustable by connecting a plurality of rod members in the axial direction.

According to the concrete stacking evaluation device 1 of the third embodiment, since the outer surface of the intrusive rod 3 is provided with a scale, maintenance is easier than when the shaft rod 31 and the scale rod 32 are combined. .. Further, even when a plurality of rod members are connected in the axial direction to change the length, the length changing work (attachment / detachment between the rod members) is easy.
Since the operation and effect of the concrete stacking evaluation device 1 of the other third embodiment are the same as those shown in the first embodiment, detailed description thereof will be omitted.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above-described embodiments, and each of the above-mentioned components can be appropriately changed without departing from the spirit of the present invention.
In each of the above embodiments, the thrust portion 33 is detachably provided at the tip of the intrusive rod 3, but the thrust portion 33 does not necessarily have to be detachable and is fixed to the tip of the penetration rod 3. May be.
The scale of the intrusive rod 3 does not necessarily have to be displayed over the entire length, and may be displayed only in the section inserted into the concrete.
The scale attached to the intrusive bar 3 (scale bar 32) may be written over the entire circumference of the intrusive bar 3 or may be written along a part of the intrusive bar 3 along the axial direction. Further, the scale of the intrusive rod 3 (scale rod 32) may be printed on the outer surface or may be engraved.
In the above embodiment, the case where the scale is marked on the entire circumference of the thrust portion 33 has been described, but it may be formed only in a part of the protrusion 33 (a portion visible from a part of the direction). When the scale is partially formed, the protrusion 33 is attached to the lower end of the penetration rod 3 so as to match the position of the scale of the penetration rod 3.
Since the height of the protrusion 33 is known, the scale of the protrusion 33 may be omitted.
The dimension from the lower end of the intrusive rod 3 may be displayed on the scale without providing the protrusion 33.
The load meter 4 and the display unit 5 may have a wireless communication function. By doing so, the measured value (load) of the load meter 4 can be transmitted to a computer or the like, the load can be converted into the intrusive resistance value by the computer, and then the intrusive resistance value can be displayed on the display unit 5.

1 Concrete stacking evaluation device 2 Main body 21 Base 22 Grip 3 Penetration bar 31 Shaft bar 32 Scale bar 33 Protrusion 34 Male thread 35 Female thread 36 Shaft bar member (bar member)
37 Scale bar member (bar member)
4 Load meter 41 Attachment 42 Female thread 43 Cable 5 Display

Claims (5)

The main body with grips on the left and right,
An intrusive bar with a scale arranged below the main body,
A load meter interposed between the main body and the intrusive rod,
A concrete stacking evaluation device, characterized by comprising a display unit for displaying the measurement result of the load meter. The concrete stacking evaluation device according to claim 1, wherein the intrusive rod is formed by connecting a plurality of rod members. The concrete stacking evaluation device according to claim 1 or 2, wherein the tip of the intrusive rod is provided with a removable protrusion. The concrete according to any one of claims 1 to 3, wherein the intrusive rod includes a shaft rod and a cylindrical scale rod outerized from the shaft rod. Overlapping evaluation device. A method for measuring concrete laying evaluation using the concrete laying evaluation device according to any one of claims 1 to 3.
The process of inserting the intrusive rod into concrete to measure the penetration depth of the intrusive rod and measuring the load when the intrusive rod is inserted.
The process of calculating the measured penetration resistance value from the load and
The proctor penetration resistance value is obtained by multiplying the measured penetration resistance value by the coefficient β for converting the concrete penetration resistance value into the mortar penetration resistance value and the coefficient α for converting the mortar penetration resistance value into the proctor penetration resistance value. A method for evaluating and measuring concrete pouring, which is characterized by having a process of calculating.

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