JP7170156B1 - Determination device for the name of the reinforcing bar diameter - Google Patents

Abstract

An object of the present invention is to provide a judgment instrument capable of judging the name of a deformed steel bar. SOLUTION: A judging instrument capable of judging the name of a deformed steel bar, comprising a base portion including an upper side, both side sides and a lower side, and one side portion composed of an upper side, an inner side, an outer side and a lower side, The other side composed of the one side, the upper side, the inner side, the outer side, and the lower side, wherein the lower side of the one side is connected to a part of the upper side of the base, the other side, where the lower edge of the side joins another portion of the upper edge of the base, and a groove, wherein the groove comprises the remaining portion of the upper edge of the base and the one of the upper edges. the groove portion comprising the inner edge of the side portion and the inner edge of the other side portion, and the upper edge of the base portion including the one portion, the another portion, and the remaining portion; and at least one of the inner edge of the one side and the inner edge of the other side has a plurality of graduations. [Selection drawing] Fig. 5

Description

TECHNICAL FIELD The present invention relates to an instrument for determining the diameter of reinforcing bars, and more particularly to an instrument for determining the name of deformed steel bars.

Reinforcing bars are bars of steel that are put inside concrete structures to increase the overall strength of the structure. Reinforcing bars come in various types, such as deformed bars with projections on the surface and round bars, but currently deformed steel bars are mostly used.

Reinforcing bars are strong in tension, but they are elongated and bend easily, so they bend under compression. Concrete, on the other hand, is strong in compression but offers little resistance in tension, and will break if subjected to bending, which is a combination of tension and compression. Therefore, by inserting reinforcing bars into concrete, the shortcomings of both can be compensated for, and the building can be made strong against tensile force, compressive force, and bending. At construction sites, it is necessary to appropriately select the type of reinforcing bars (in particular, the diameter of the reinforcing bars).

The role of reinforcing bars in reinforced concrete construction is very large, and the necessary strength, number, etc. are specified in the design documents.

It is easy to visually check the number of reinforcing bars, but it is difficult for inexperienced engineers to judge the diameter. In addition, since the strength, diameter, and number of reinforcing bars required for buildings are usually determined by structural calculations, it is not enough to have a diameter larger than that specified in the design documents.

If the reinforcing bar diameter is wrong, it will take a lot of money and time to correct it. If the problem is found after the building is completed, large-scale reinforcement, correction, or rebuilding may be required.

Reinforcing bars used in construction are called deformed steel bars (deformed reinforcing bars), and their names are determined according to their thickness. Reinforcing bars used in construction work generally have designations D10 to D38 (further D41 and D51). This D represents a deformed steel bar, and the number after it represents the diameter of the reinforcing bar. The diameter of this reinforcing bar is a value obtained by rounding the nominal diameter defined in the standard, and it cannot be actually confirmed by measurement. Nor can the nominal diameter be measured.

The diameter of the deformed steel bar is stamped on the material, but it is often difficult to find the stamp that specifies the diameter at the construction site. Also, since the diameter varies depending on the measurement position, we thought that a dedicated measuring instrument would be necessary.

It is actually difficult to confirm the diameter of rebar assembled on site. For example, a deformed steel bar of D19 means "19 mm in diameter", but its nominal diameter is 19.1 mm and its outermost diameter is about 21 mm. A wide variety of rebars are delivered to construction sites, so it would be good to have a measuring method or device to quickly determine the diameter of the rebars.

The following Patent Documents 1 and 2 are cited as conventional examples of measuring deformed steel bars.

Patent Document 1 discloses a measuring method using a simple jig.

Patent Document 2 discloses a measuring method using a slide gauge.

Non-Patent Document 1 is sold as a reinforcing bar gauge (Landark Co., Ltd.).

Non-Patent Document 2 describes the current field wisdom for determining deformed steel bars.

However, none of these documents can determine deformed steel bars quickly and accurately.

JP-A-2020-2538 JP 2018-179729 A

https://www. land-art. co. jp/products/detail. php? product_id=51032 https://kenchikuchishiki. com/kouzouhinshitsu/tekkin/tekkinhanbetsu/

According to one aspect of the present invention, there is provided a judging instrument capable of judging the name of a reinforcing bar by measuring a predetermined portion of the reinforcing bar at a construction site.

According to one aspect of the present invention, there is provided a judging instrument which can be easily carried at any time and which can quickly clarify the name of a reinforcing bar.

According to one aspect of the present invention, a determination instrument capable of determining the diameter (name) of a deformed steel bar,
a base including a top side, side sides and a bottom side;
one side consisting of an upper edge, an inner edge, an outer edge, and a lower edge, wherein the lower edge of the one side joins a portion of the upper edge of the base;
the other side consisting of an upper edge, an inner edge, an outer edge, and a lower edge, wherein the lower edge of the other side joins another portion of the upper edge of the base;
a groove, the groove comprising a remaining part of the upper side of the base, the inner side of the one side, and the inner side of the other side, and the upper side of the base is the groove portion consisting of the portion, the another portion, and the remaining portion;
with
A judging instrument is provided, characterized in that at least one of the inner edge of the one side and the inner edge of the other side has a plurality of scales of names.

According to one aspect of the present invention, it is possible to provide an instrument that has a simple structure and does not use a power supply or the like and does not cause failures.

According to another aspect of the present invention, it is possible to provide an instrument that does not require the technical judgment of an engineer (user) and that allows intuitive judgment regardless of technical ability or experience.

Other objects, features and advantages of the present invention will become apparent from the following description of embodiments of the invention taken in conjunction with the accompanying drawings.

FIG. 1 shows an outline of a judging instrument capable of judging the name of a deformed steel bar according to one embodiment of the present invention. FIG. 2 shows a judging instrument capable of judging the name of a deformed steel bar according to one embodiment of the present invention, and shows a state in which it is inserted into a deformed steel bar for measurement. FIG. 3 shows part of a judgment instrument capable of judging the name of the deformed steel bar according to the embodiment of FIG. FIG. 4 shows a determination instrument capable of determining the designation of a deformed steel bar according to an additional embodiment of the invention. FIG. 5 shows a schematic of a judging instrument capable of judging the name of a deformed steel bar according to another embodiment of the present invention. FIG. 6 shows a judging instrument capable of judging the name of a deformed steel bar according to another embodiment of the present invention. FIG. 7 shows a judging instrument capable of judging the name of a threaded deformed steel bar (threaded rebar) according to another embodiment of the present invention. FIG. 8 shows a modification of a judging instrument capable of judging the name of a deformed steel bar according to another embodiment of the present invention. FIG. 9 shows a measurement technique according to an additional embodiment (auxiliary means) of the invention.

FIG. 1 shows an outline of a judging instrument capable of judging the name of a deformed steel bar according to one embodiment of the present invention. In addition, the object to be measured in this example is a deformed steel bar used at a construction site.

The judgment instrument 100 of FIG.

The base 110 has a rectangular shape and is the part where the user holds the judging instrument by hand. The base 110 includes an upper side 111 , both side sides (a left side 112 and a right side 113 ), and a lower side 114 .

One side (the left side in this example) 120 is trapezoidal in shape and the left and right sides are symmetrical in this example. On at least one surface of the left side portion 120, the name of the deformed steel bar (such as D10) is written. The left side portion 120 is composed of an upper edge 121 , an inner edge 122 , an outer edge 123 and a lower edge 124 . The right side portion 130 is composed of an upper edge 131 , an inner edge 132 , an outer edge 133 and a lower edge 134 .

Also, the lower side 124 of the side portion 120 is configured to be coupled with a portion of the upper side 111 of the base portion 110 .

On at least one of the inner sides 122, 132 of the left and right side portions 120, 130, a scale (name) for determining the name of the deformed steel bar is written. In this embodiment, the names written on the scale are from D10 to D38 which are generally used, but it is also possible to measure up to D51. In this embodiment, the right side portion 130 has the same configuration as the left side portion 120, so further explanation is omitted.

As described above, the groove portion 140 is a portion configured by joining a portion of the upper side 111 of the base portion 110 and the lower sides 124, 134 of the left and right side portions 120, 130, so that the deformed steel bar can be inserted. It has a grooved or inverted trapezoidal shape.

The groove portion 140 includes a remaining portion of the upper side 111 of the base portion 110 (corresponding to the portion of the upper side 111 not coupled to the lower sides 124 of the left and right side portions 120) 141, inner sides 122 of the left and right side portions 120 and 130, 132.

With the configuration described above, when the deformed steel bar to be measured is put into the groove 140 and the deformed steel bar is caught in the groove 140, the user can read the scale at that position to determine the name of the deformed steel bar. .

In addition, in manufacturing the determination instrument of the present embodiment, if the base and side portions are large, a portion of the lower side of the base portion and a portion of the side portions may be cut off. As a result, the height of the base (left and right sides) can be reduced and the width of the side can be reduced.

In addition, considering the ease of processing, unit price, yield, etc., the materials used in manufacturing the determination instrument of the present embodiment include, for example, stainless steel, aluminum (or aluminum alloy), etc., but other materials can also be used. , the present embodiment can be applied.

FIG. 2 shows a judgment instrument capable of judging the name of a deformed steel bar according to an embodiment of the present invention, showing a state in which a deformed steel bar is inserted and measured.

FIG. 3 shows part of a judgment instrument capable of judging the name of the deformed steel bar according to the embodiment of FIG.

The height a of the scale with respect to the lower side of the base 110 (for example, the intersection of the extension lines of the inner sides 122 and 132) can be obtained by using the angle α and the radius b of the outermost diameter of the deformed steel bar to be measured. Since cos α×e and e=b/tan α, it is obtained by a=cos α×(b/tan α). Note that the height a of the scale in FIG. 2 indicates the height of the scale of D22.

The height a of the scale is based on the lower side of the base, but in the judging instrument of this embodiment, the inner sides of the left and right sides (extension lines) intersect at the lower side of the base. This can also be understood from FIG.

The angle α is the angle between the inner side 122 of the side portion 120 (or the inner side 132 of the side portion 130 ) and the perpendicular line 115 extending perpendicularly to the upper side 111 of the base portion 110 . In the example of FIG. 2, the angle α indicates 12 degrees. Also, in this embodiment, the angle α is in the range of greater than 0 degrees and less than 90 degrees.

In addition, the angle α of 12 degrees is practical because of ease of measurement and the size of the instrument (the instrument of this example has a size of 103 mm × 72.1 mm, as shown in FIG. 1). Although it was decided in consideration of easiness and usability, other angles are also possible. However, a narrower angle α results in a taller instrument and a narrower instrument width, and a larger angle α results in a lower instrument height and a wider instrument width.

Here, in general, Table 1 shows the relationship between the nominal diameter and the outermost diameter for the name of the deformed steel bar.

Since the diameter of the deformed reinforcing bar varies depending on the measurement location and the manufacturer, in the determination tool of this embodiment, the outermost diameter (outermost diameter), which has relatively little difference, is measured to determine the name.

In the judgment instrument of this embodiment, the contact point between the deformed steel bar and the instrument is confirmed by confirming the name described within the scale of the target designation name, so as to clarify the discrimination of the name of the deformed steel bar. structure. Here, the scale range of the target appellation refers to the part below the height of the scale of the target appellation and above the height of the scale of the standard that is one smaller than the target appellation (target When the name that becomes is the smallest, it is the upward direction of the upper side of the base).

For example, in FIG. 2, a circumferential portion of a deformed steel bar is inserted into the groove of the judging instrument of this embodiment. In particular, in FIG. 2, they are in contact on the scale line of the name of D22, because the diameter of the deformed steel bar of D22 is the outermost diameter (25 mm). Normally, the diameter of the D22 deformed steel bar is generally smaller than the outermost diameter (25 mm) of the D22, so , and the scale line of the designation D19, which is one standard lower than D22), the circumferential portion of the deformed steel bar comes into contact with the measuring instrument (inner side) in the groove.

FIG. 4 shows a determination instrument capable of determining the designation of a deformed steel bar according to an additional embodiment of the invention.

Specifically, as shown in FIG. 4, after inserting the deformed steel bar into the groove of the instrument, the auxiliary tool (bar-shaped) of the bar-shaped determination instrument can be inserted from the lower side of the base. can be determined. In order to insert a rod-shaped auxiliary tool, a penetration part is provided from the lower side of the base of the determination instrument of the present embodiment to the groove part. The width of the rod-shaped auxiliary tool is narrower than the width of the through portion. With such a configuration, it is possible to further prevent the possibility of difficulty in determining the name of the deformed steel bar with the scale of the determination instrument shown in FIGS. 2 and 3 and the possibility of misreading. That is, although the structure is a little more complicated than the embodiment shown in FIGS. 2 and 3, it is possible to make the determination of the name easier to understand.

A usage example of the auxiliary tool of the judgment instrument of the present embodiment will be described. A deformed steel bar to be measured is inserted into the groove of the determination instrument of this embodiment. After that, the auxiliary tool of the judging instrument of this embodiment is inserted from the lower side of the judging instrument, and the point where the auxiliary tool comes into contact with the deformed steel bar and stops is called the deformed steel bar. FIG. 4 shows an example in which the deformed steel bar of D16 has an outermost diameter of 18 mm, so the notation of D16 may be hidden. It can be determined that the deformed steel bar inserted into the determination instrument of the example is D16. In addition, since it is generally smaller than the outermost diameter of the deformed steel bar, it can be easily determined that the scale is D16. Also, although not clearly shown in FIG. 4, a portion of the surface of the base may be cut out in order to make D16 marked on the aid easier to read. In addition, as a further embodiment, each scale of the assisting device may be given a different color so that it can be visually distinguished.

A description will be given of how to mark the auxiliary tool of the present embodiment. In FIG. 4, when D16, h=f'-b, and when f'=b/sinα, the relationship of h=b/sinα-b is used. Here, b indicates the radius of the outermost diameter of the target name. Then, the scale should be added so that the distance from the tip of the auxiliary tool (the part that comes into contact with the deformed steel bar) to the scale of the target name is h.

FIG. 5 shows a schematic of a judging instrument capable of judging the name of a deformed steel bar according to another embodiment of the present invention. One difference from the embodiment of FIG. 1 is that the inner edge 132 of the right side 130 is stepped. The inner edges of the opposite sides define widths within the groove. This width is calculated based on the outermost diameter of the deformed steel bar. Details will be described with reference to the embodiments in FIG. 6 and subsequent figures.

FIG. 6 shows a judging instrument capable of judging the name of a deformed steel bar according to another embodiment of the present invention, showing a state in which a deformed steel bar is inserted and measured.

Compared with the embodiment shown in FIGS. 2 to 4, the structure of the judging instrument is slightly more complicated, but the judgment of the name of the deformed steel bar can be made easier.

A method of using this embodiment will be described. In this embodiment, the deformed steel bar to be measured is inserted into the groove of the determination instrument of this embodiment, and the point where the deformed steel bar stops (the scale corresponding to the contact point between the deformed steel bar and the determination instrument) is the name of the reinforcing bar. becomes.

The shape of the determination instrument of this embodiment will be described.

In this embodiment, the width is the outermost diameter of each deformed steel bar, and the height is the radius of the outermost diameter.

Since the portion m is a marginal portion, by reducing the height of the marginal portion, the overall size of the judgment instrument can be reduced and the portability can be improved.

Here, in FIG. 6, the dimension of one scale is y=√(4bc-4c^2). Here, in FIG. 6, the margin of the scale is m=by (y is unsigned, absolute value), the radius of the outermost diameter of the target reinforcing bar is b, and the outermost Let c be the radius of the diameter. In addition, when calculating the dimension y at the outermost diameter of the smallest reinforcing bar (D10 in the embodiment of FIG. 6), it is sufficient if c<b, for example, c=0. Table 2 shows an example of calculation results. In addition, the numerical value of the calculation result is rounded off to the second decimal place.

If the origin is the center of the circle with the outermost diameter of the reinforcing bar, the circle can be represented by x^2+y^2=b^2. Here, if x=−b+2×c, the dimension y=±√(4bc−4ĉ2) can be obtained. Here, in the example of FIG. 6, the sign (±) is irrelevant since y represents the coordinates.

FIG. 7 shows a judging instrument capable of judging the name of a deformed steel bar according to yet another embodiment of the present invention.

The structure of the groove portion of the determination instrument of the embodiment of FIG. 6 is improved for threaded deformed steel bars (threaded reinforcing bars). As shown in FIG. 7, the screw deformed steel bar used in the judging instrument has flat left and right sides, unlike the deformed steel bar shown in FIG. The dimensions of each portion of screw reinforcing bars are determined by each manufacturer. In the present embodiment, the reinforcing bar is D13 or more.

The maximum value of each manufacturer's name may be used as the reference value.

Let J be half the maximum value of the outermost diameter of the short axis of the target deformed steel bar, and let K be half the maximum value of the outermost diameter of the long axis. As shown in FIG. 7, J is the maximum value of the outermost diameter in the horizontal direction (a direction different from the insertion direction of the deformed steel bar by 90 degrees), and K is the maximum outer diameter of the deformed steel bar in the insertion direction. value.

Let J' and K' be the half of the maximum value of the deformed bar that is one smaller.

The height at this time is the maximum value k of each deformed steel bar, and the height is the radius K of the outermost diameter.

Since there is a margin in the portion m, it is possible to reduce the overall size of the judging instrument and improve its portability by reducing the height by this amount.

The dimension of y is ±√(K^2-(2*J'-J)^2).

m=K−y (y is unsigned, absolute value).

A formula for calculating the y dimension is described below.

Since the object to be measured is the flat part of J, the judging instrument can be made smaller by shortening the height accordingly.

In the case of threaded reinforcing bars, the dimensions of j and k are determined by each manufacturer. Since the j surface is flat, the type of reinforcing bar can be determined by measuring the dimension of j.

At this time, the measuring instrument can be made smaller by calculating in the same manner as in the embodiment of FIG.

FIG. 9 shows a measurement technique according to an additional embodiment (measurement aid) of the invention.

In the case of the insertion type, it may be difficult to insert in places where deformed steel bars are crowded. For example, part of the deformed steel bar is already embedded in concrete. The side of the judging instrument hits the concrete, making it difficult to insert the deformed steel bar into the groove.

Even in such a case, the name of the diameter of the deformed steel bar can be determined.

Since it is difficult to measure the core-to-core dimension of the knots of deformed steel bars, the dimension is measured from corner to corner.

As shown in Table 4, since the average maximum value of the node spacing is generally determined, instead of measuring the spacing of one node, the present embodiment measures the spacing of three nodes. to judge.

The principle of this embodiment will be described. For example, with a reference node (0th node) as a reference, three nodes are counted, and the distance from the first to the third (three times the interval between one node) is measured with a scale. Then divide the value measured on the scale by 3. For example, if the measured value on the scale is 60 mm, divide by 3 to get 20 mm. Then, it can be seen that the name of the measured deformed steel bar is "D29".

In this embodiment, the measuring instrument (fixing means of the measurement auxiliary means) is pressed against the reference node of the reinforcing bar to be measured, and the name written outside the third node from the reference node is the target. It is configured so that it can be determined as the name of the reinforcing bar. The length of the scale of the name of the target reinforcing bar is N times the maximum value of the average interval from the reference node to the target name of the node. In the deformed steel bar on the upper side in FIG. 9, the length from the reference node to the upper side of the third node matches the D25 scale of the measuring instrument of this embodiment. Therefore, it can be determined that the name of the deformed steel bar on the upper side of FIG. 9 is D25. Similarly, it can be determined that the name of the deformed steel bar on the lower side of FIG. 9 is D32. Table 4 shows an example of scale length (N=3).

Accuracy of determination is improved by attaching a measurement auxiliary means for determining the name of the deformed steel bar diameter by measuring by a method such as this embodiment in accordance with the insertion type determination instrument as shown in FIGS. 1 to 7. be able to.

In addition, a fixing means (protrusion below the scale of D10 in FIG. 9) is provided for fixing the judging instrument according to the present embodiment to the inner side of the reference knot of the target deformed steel bar. This enables stable measurement.

In this embodiment, an example of a judgment tool for judging the name of a deformed steel bar based on three knots has been described. , 4, . . . ).

Although the embodiment of the present invention has been described as above, various alternatives, modifications, or variations are possible for those skilled in the art based on the above description, and the present invention can be implemented in various ways without departing from the scope of the invention. It encompasses alternatives, modifications or variations.

For example, in the present embodiment, an instrument for determining the name of a deformed steel bar was described, but other than the deformed steel bar, other types of steel bars and other materials for which the relationship between the name and the outer diameter are predetermined can also be applied to

Judging instrument 100, base 110, left side 120, right side 130, groove 140 upper side 111, left side 112, right side 113, lower side 114, upper side 121, inner side 122, outer side 123, lower side 124, upper side 131, inner edge 132, outer edge 133, lower edge 134

Claims (9)

A determination instrument capable of determining the name of a deformed steel bar,
a base including a top side, side sides and a bottom side;
one side consisting of an upper edge, an inner edge, an outer edge, and a lower edge, wherein the lower edge of the one side joins a portion of the upper edge of the base;
the other side consisting of an upper edge, an inner edge, an outer edge, and a lower edge, wherein the lower edge of the other side joins another portion of the upper edge of the base;
a groove, the groove comprising a remaining part of the upper side of the base, the inner side of the one side, and the inner side of the other side, and the upper side of the base is the groove portion consisting of the portion, the another portion, and the remaining portion;
with
at least one of the inner side of the one side and the inner side of the other side has a plurality of scales for names;
At least one of the inner sides is stepped,
The width y of the scale of the name is obtained by y = √(4bc-4c^2), where b is the outermost radius of the target reinforcing bar, and c is the outermost radius of the deformed steel bar that is one size smaller. A judgment instrument characterized by: A determination instrument capable of determining the name of a deformed steel bar,
a base including a top side, side sides and a bottom side;
one side consisting of an upper edge, an inner edge, an outer edge, and a lower edge, wherein the lower edge of the one side joins a portion of the upper edge of the base;
the other side consisting of an upper edge, an inner edge, an outer edge, and a lower edge, wherein the lower edge of the other side joins another portion of the upper edge of the base;
a groove, the groove comprising a remaining part of the upper side of the base, the inner side of the one side, and the inner side of the other side, and the upper side of the base is the groove portion consisting of the portion, the another portion, and the remaining portion;
with
at least one of the inner side of the one side and the inner side of the other side has a plurality of scales for names;
At least one of the inner sides is stepped,
The width y of the scale of the name is obtained by y = √(K^2-(2*J'-J)^2), and is half the maximum value of the outermost diameter of the minor axis of the target deformed steel bar. J, half of the maximum value of the outermost diameter of the long axis is K, and half of the maximum value of the deformed steel bar one smaller than K is J'. Furthermore, a measurement auxiliary means for determining a name is provided, the measurement auxiliary means has a fixing means for fixing to the deformed steel bar to be measured,
The length of the scale of the nickname in the auxiliary means is N times the maximum value of the average interval of the clauses of the target nickname based on the reference clause, where N is an integer of 1 or more. 3. The instrument according to claim 1 or 2, characterized by: The scale range of the nominal name is equal to or less than the height of the scale of the nominal name and higher than the height of the scale of the nominal name of the standard one level below the nominal name,
1 and 2, wherein the range of the scale of the name when the scale of the name is the smallest is equal to or less than the height of the scale of the name and higher than the height of the upper side of the base. 4. The judgment instrument according to any one of 3. 3. The judging instrument according to claim 1 or 2, further comprising: a penetrating portion extending from said lower side of said base portion to said groove portion; A method for manufacturing a judgment instrument capable of judging the name of a deformed steel bar,
forming a base including a top edge, side edges and a bottom edge;
forming a side portion comprising a top edge, an inner edge, an outer edge, and a bottom edge, wherein the bottom edge of the one side joins a portion of the top edge of the base; When,
Forming the other side consisting of a top edge, an inner edge, an outer edge and a bottom edge, wherein the bottom edge of the other side joins another part of the top edge of the base and
a groove, the groove comprising a remaining part of the upper side of the base, the inner side of the one side, and the inner side of the other side, and the upper side of the base forming the groove comprising the one part, the another part, and the remaining part;
Further, a step of attaching a plurality of designation scales to at least one of the inner edge of the one side portion and the inner edge of the other side portion;
with
At least one of the inner sides is stepped,
The width y of the scale of the name is obtained by y = √(4bc-4c^2), where b is the outermost radius of the target reinforcing bar, and c is the outermost radius of the deformed steel bar that is one size smaller. A method for manufacturing a judgment instrument characterized by: A method for manufacturing a judgment instrument capable of judging the name of a deformed steel bar,
forming a base including a top edge, side edges and a bottom edge;
forming a side portion comprising a top edge, an inner edge, an outer edge, and a bottom edge, wherein the bottom edge of the one side joins a portion of the top edge of the base; When,
Forming the other side consisting of a top edge, an inner edge, an outer edge and a bottom edge, wherein the bottom edge of the other side joins another part of the top edge of the base and
a groove, the groove comprising a remaining part of the upper side of the base, the inner side of the one side, and the inner side of the other side, and the upper side of the base forming the groove comprising the one part, the another part, and the remaining part;
Further, a step of attaching a plurality of designation scales to at least one of the inner edge of the one side portion and the inner edge of the other side portion;
with
At least one of the inner sides is stepped,
The width y of the scale of the name is obtained by y = √(K^2-(2*J'-J)^2), and is half the maximum value of the outermost diameter of the minor axis of the target deformed steel bar. A method for manufacturing a judgment instrument, wherein J is half of the maximum value of the outermost diameter of the long axis, and K is half of the maximum value of the deformed steel bar that is one smaller than K, and J' is half of the maximum value. 8. A method for manufacturing a judgment instrument according to claim 6 or 7, further comprising a step of cutting a part of the side part or a part of the lower side of said base. A method for measuring the name of a target reinforcing bar using the determination instrument according to claim 3,
a step of pressing the fixing means of the measurement auxiliary means against a reference node of the reinforcing bar to be measured;
determining, from the reference clause, the appellation appearing outside the Nth clause;
A method comprising:

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