JP6156964B1 - scale - Google Patents

Abstract

[PROBLEMS] To measure the height difference from the floor surface to the ceiling and the height from the floor surface to the horizontal reference line, or to measure the distance on both sides in the horizontal direction from the vertical reference line, such as a window frame. The purpose is to provide a scale that can be used for multiple purposes in frame construction. SOLUTION: A hollow and long first rod-shaped member, a hollow and short second rod-shaped member, and a long first that is slidable by being fitted into hollow portions of both the first member and the second member. A three-bar member, a first blocking means for blocking the third bar-shaped member from sliding on the first bar-shaped member, and a second block for blocking the third bar-shaped member from sliding on the second bar-shaped member. Means, wherein the first bar-shaped member has a first scale and a second scale, and the third bar-shaped member has a third scale and a fourth scale, A window for reading the third graduation and a window for reading the fourth graduation are formed, and the fifth graduation is symmetrical with the vicinity of the center as a reference point. [Selection] Figure 1

Description

  The present invention relates to a scale for measuring height and length, and more particularly to a scale for measuring the level of a formwork for constructing a concrete building and measuring the height and length from a reference position.

Conventionally, when constructing a concrete wall surface, a method of laying a plywood along the floor surface to construct the wall surface and laying the wall formwork on the pierced nail is used. Although the floor surface is slightly uneven, and the piers themselves have dimensional variations, there is a gap between the formwork, and when concrete is placed, the cement is mixed with the cement from the gap. Water leaks and burrs are likely to occur. Therefore, in order to prevent burrs from occurring, leveling of the pier is done at various places where the formwork is built, and leveling is adjusted by inserting packing materials such as plywood with different thicknesses between the pier and the plywood so that no gap is created. Is doing.
In addition, after building the wall formwork or slab formwork, it is necessary to check whether the formwork is correctly arranged as shown in the drawing, or whether there is any bending immediately after the concrete is placed.
In that case, when marking the concrete wall or the like, it is necessary to have a person who catches the point with a level machine or transit and a person who holds the scale upright, so that it is a work of two people. Therefore, a scale is disclosed in which scales are displayed on both side surfaces of the trapezoidal cross section, and are fixed by providing holes or the like through which the male screws of the formwork separator pass, and both ends are added (Patent Document 1).
In addition, a base plate member and a receiving member arranged at a predetermined interval on the fabric foundation are installed while adjusting the height with a pair of bolts and nuts, and after confirming the horizontal posture with a level, rise on the receiving member Although there is a method of placing a part, it takes a lot of time and labor to adjust the level of a large number of receiving members, so adjust the height to the reference line with a scale that is inserted into one of the bolts and standing up A level measuring tool is disclosed that can hold the receiving member horizontally with a level and can perform height adjustment and horizontal posture adjustment at a stretch (Patent Document 2).
On the other hand, since the positioning ruler used when placing the anchor at a predetermined position of the foundation mold may be displaced from the reference position, in order to solve this problem, a locking tool for locking the mold to the scale is attached. Thus, a positioning ruler is disclosed in which the reference point of the scale matches the reference position inside the mold (Patent Document 3).

Japanese Utility Model Publication No. 5-96314 JP-A-8-159766 Japanese Patent Laid-Open No. 11-200454

However, the method described in Patent Document 1 is effective when the scale is read by a transit or the like, and the work of inking is performed by one person, but the height to the slab formwork constituting the ceiling is measured. It cannot be used when level adjustment is performed, or when the height from the slab constituting the floor surface to the reference line is measured to adjust the level of the pier for installing the wall formwork. In addition, the method described in Patent Document 2 cannot be used for level measurement of a formwork for constructing a wall surface of a floor, and the method described in Patent Document 3 is effective when measuring a distance in one direction from a reference line. Even if it is, it cannot be adopted when measuring the distance in both directions from the reference line at the same time.
In view of the above circumstances, the present invention measures the height deviation from the floor surface to the ceiling and the height from the floor surface to the reference line, and the distance from the vertical reference line to both sides in the horizontal direction, such as a window frame. The purpose is to provide a multi-purpose scale that can be used in various scenes of formwork such as simultaneous measurement.

The scale according to the present invention is a long, long, first rod-like member that is hollow, is fitted into a hollow portion of the hollow, short second rod-like member, and both the first member and the second member, and is slidable. A third blocking member, a first blocking means for blocking the third blocking member from sliding on the first blocking member, and a first blocking member for blocking the sliding of the second blocking member by the third blocking member. 2 blocking means, and the first rod-shaped member is formed on the outer surface from one end to the other end where the third rod-shaped member is fitted, with the other end as a reference point. One scale and a second scale written with the one end as a reference point, and the third rod-shaped member extends from one end to the other end fitted to the first rod-shaped member. A third scale marked with the one end as a reference point and the second scale are continuous on the outer surface of The second bar-shaped member has a window for reading the third scale in the vicinity of the center in the length direction and the fourth scale. A window for reading four graduations is formed, and the outer surface other than the outer surface on which the windows are formed has fifth graduations written on both sides with the vicinity of the center as a reference point.
In this way, two scales are provided on the outer surfaces of the two long rod-like members whose lengths expand and contract when fitted, one of which is given a continuous numerical value, and the other is a numerical value starting from zero. Is written in the opposite direction, the height of the object can be measured, and the lengths on both sides from the reference position can be measured simultaneously. In addition, since the center of the short rod-shaped member that freely slides one long rod-shaped member is graduated in both directions, the laser beam can be used in combination with the laser beam to the ceiling or floor surface. It is possible to easily measure the deviation from the set value or the length in both directions.

Further, a fixing means for slidably fitting to the third rod-shaped member and detachably fixing the third member to the formwork, and a slidably fitted to the third rod-shaped member and recording measurement values If it is provided with a recording auxiliary means used for the measurement, it is easy to measure alone and record the measurement position.
Furthermore, a long fourth rod-shaped member that is pivotally supported by the one end of the first rod-shaped member and freely rotates between a position orthogonal to the position orthogonal to the first rod-shaped member is provided, Since the fourth bar-shaped member is provided with a sixth scale with the end portion pivotally supported by the first bar-shaped member as a reference point, the fourth bar-shaped member is adjacent when leveling the formwork due to unevenness of the floor surface. It is efficient because the formwork can be positioned at the same time.
In that case, if the fourth rod-shaped member is a plate-shaped or columnar member pivotally supported by the first rod-shaped member so as to be detachable and rotatable, the weight of the scale can be reduced according to the purpose. it can.
The first rod-shaped member, the second rod-shaped member, and the third rod-shaped member are such that the hollow inner dimensions of both the first rod-shaped member and the second rod-shaped member are larger than the outer dimensions of the third rod-shaped member. If it is large, the cross section may be polygonal. In this case, if the cross section is rectangular, both the first and third graduations and the second and third graduations are on one facing surface, and the fifth graduation is on the other facing surface. Can be described in
Further, the first blocking means and the second blocking means can be male threads that are screwed into screw holes provided in the first rod-shaped member or the second rod-shaped member, and the fixing means and the recording auxiliary. Each of the means may have a screw hole into which a male screw is screwed, and the male screw may be turned to be fixed at a predetermined position of the third rod-shaped member.

According to the scale of the present invention, it is possible to measure the height alone without using a stepladder, etc., even if the height is out of reach, and the vertical height and the horizontal length from the reference position at the same time. It can be measured alone. Furthermore, it is possible to perform leveling of the formwork and positioning of the adjacent formwork at the same time by one person.

FIG. 1 is a front view showing a scale of the present embodiment. FIG. 2 is a rear view showing the scale of this embodiment. FIG. 3 is a right side view showing the scale of this embodiment. FIG. 4 is a left side view showing the scale of this embodiment. FIG. 5 is a diagram in which the fourth member of the present embodiment is developed in an orthogonal position. FIG. 6 is a front view and a sectional view showing the second rod-shaped member. FIG. 7 is a side view and a cross section showing the second rod-shaped member. FIG. 8 is a side view showing the recording auxiliary member. FIG. 9 is a rear view showing the recording auxiliary member. FIG. 10 is a side view showing the fixing member. FIG. 11 is a front view showing the fixing member. FIG. 12 is a diagram illustrating an example of measuring the height of a beam formwork or a slab formwork using the scale of the present embodiment. FIG. 13 is a diagram showing an example of leveling when a formwork is built using the scale of this embodiment. FIG. 14 is a diagram illustrating an example of measuring the length from the reference position to the mold frame or window frame using the scale of the present embodiment.

Embodiments of the scale of the present invention will be described below.
1 to 5 are diagrams showing a scale according to this embodiment. FIG. 1 is a front view, FIG. 2 is a rear view, FIG. 3 is a right side view, FIG. 4 is a left side view, and FIG. It is the figure which expanded the member to the orthogonal position.
As shown in FIGS. 1 to 5, the scale 10 of the present embodiment has a rectangular cross section, a hollow and long first rod-shaped member 1, and a hollow and short second rod-shaped member 2 having a rectangular cross section. A hollow and long third rod-shaped member 3 that has a rectangular cross section and is fitted and slidable in the hollow portions of both the first member 1 and the second member 2, and one of the first rod-shaped members 1 A long fourth rod-like member 4 that is pivotally supported by the end portion 1a of the first rod-like member 1 and that freely rotates between a position perpendicular to the first rod-like member 1 and a position overlapping the first rod-like member 1 is provided.
Then, in the vicinity of the other end 1b of the first rod-shaped member 1 to which the third rod-shaped member 3 is fitted, there is a screw hole, the male screw 5 with a knob is screwed, and the third rod-shaped member 3 is the first rod-shaped member. 1 can be prevented from sliding (corresponding to the “first regulating means” of the present invention).
Similarly, there is a screw hole near one end of the second rod-shaped member 2, and the male screw 6 with knob is screwed together to prevent the third rod-shaped member 3 from sliding on the hollow portion of the second rod-shaped member 2. (Corresponds to the “second regulating means” of the present invention).
Furthermore, a recording auxiliary member (corresponding to “recording auxiliary means” of the present invention) 11 that is slidably fitted to the third rod-shaped member 3, closer to the end than the second rod-shaped member 2, and the first rod-shaped member 1. A hollow fixing member 12 that is slidably fitted to the third rod-shaped member 3 between the second rod-shaped member 2 and a pin 12b that is inserted into the mold from a round hole 12a formed in the fixing member 12 (fixing member and pin Corresponds to the “fixing means” of the present invention.
The recording auxiliary member 11 is a plane portion 11a orthogonal to the third rod-like member 3 so that a mark can be attached to the mold when measuring the height of the mold using the scale 10 of the present embodiment. Have Further, the fixing member 12 is provided with a round hole 12a so that the pin 12b can be inserted and fixed to the mold.
Each of the recording auxiliary member 11 and the fixing member 12 has a screw hole, and the male screws 7 and 8 with knobs can be screwed together to prevent the third rod-like member 3 from sliding.
Here, the first rod-shaped member 1, the second rod-shaped member 2, and the third rod-shaped member 3 may be formed by molding aluminum or the like, or may be formed by extrusion molding plastic, carbon fiber, glass fiber, or the like. In addition, although a rectangular cross section is used here, the cross section may be circular or triangular or hexagonal.

As shown in FIG. 1, the first rod-shaped member 1 has an outer surface from one end 1 a to the other end 1 b to which the third rod-shaped member 3 is fitted, and the other end 1 b as a reference point Z. The first scale M1 is provided, and the third rod-like member 3 is based on one end 3 on the outer surface from one end 3a to the other end 3b fitted to the first rod-like member 1. A third scale M3 with a point Z is provided.
Incidentally, in the scale 10 of the present embodiment, the length of the first rod-shaped member 1 is set to 100 centimeters, and the length of the third rod-shaped member 3 is set to 115 to 120 centimeters.
The first scale M1 has numerical values ranging from zero to 100 centimeters in millimeters.
In the third scale M3, numerical values from zero to 115 to 120 centimeters are given in millimeters.
A male screw 5 that prevents the third rod-shaped member 3 from sliding is provided in the vicinity of 10 centimeters of the first scale M1.
Therefore, by loosening the male screw 5 and pulling out the third rod-like member 3 to the maximum extent, the other end 1b where the first rod-like member 1 and the third rod-like member 3 are fitted is centered on the first rod-like member 1 side. Up to 100 centimeters, up to about 100 to 105 centimeters on the third rod-like member 3 side can be measured simultaneously.

As shown in FIG. 2, the first rod-like member 1 has one end 1a on the outer surface from one end 1a to the other end 1b to which the third rod-like member 3 is fitted, and a reference point Z. The second scale M2 is provided, and the third bar-shaped member 3 is continuous with the second scale M3 on the outer surface from one end 3a to the other end 3b fitted to the first bar-shaped member 1. A fourth scale M4 having a predetermined position near the other end 3b as a reference point is provided.
By the way, the second scale M2 has a numerical value from zero to 100 centimeters in millimeters.
In the fourth scale M4, the position of 15 to 20 centimeters from the other end 3b of the third bar-shaped member is set to zero, and the numerical values from 100 to 105 centimeters are assigned in millimeters.
Further, a male screw 5 for preventing the third rod-shaped member 3 from sliding is provided in the vicinity of 90 centimeters of the first scale M1.
Accordingly, by loosening the male screw 5 and pulling out the third rod-shaped member 3 to the maximum extent, the first rod-shaped member 1 and the third rod-shaped member 3 are zeroed on the first rod-shaped member 1 side, centering on the other end 1b. Can be measured from 100 to 205 centimeters on the third rod-like member 3 side. In addition, the length of the scale 10 can be shortened to about 120 centimeters by loosening the male screw 5 and fitting the third rod-shaped member 3 to the first rod-shaped member 1 as much as possible.

As shown in FIGS. 3 and 4, the second rod-shaped member 2 is a male screw with a knob that slidably fits the third rod-shaped member 2 and is screwed into a screw hole provided near the end of the second rod-shaped member 2. 6 is configured to prevent sliding.
In addition, symmetrical fifth scales M5 are provided on both sides with the center in the longitudinal direction as a reference point Z. As shown in FIGS. 1 and 2, since the second bar-shaped member 2 has a window 2a for reading the third scale M3 or the fourth scale M4 in the vicinity of the center, the second bar-shaped member 2 is slid. In this case, the position of the reference point Z of the fifth scale M5 is located on the third scale M3 or the fourth scale M4.
Incidentally, the length of the second rod-shaped member 2 in this embodiment is set to 15 centimeters, and the fifth scale M5 is set to zero at the center and numerical values up to 5 centimeters are attached to both sides in millimeters. Has been.
On the other hand, the fourth rod-like member 4 is pivotally supported by one end 1a of the first rod-like member 1 and is orthogonal to the first rod-like member 1 shown in FIG. 4 and a position overlapping the first rod-like member 1 shown in FIG. A sixth graduation M6 is provided so that it can be freely rotated by a folding hinge 4a between the position of the first and second positions, and an end portion pivotally supported by the first rod-shaped member 1 is a reference point.
Incidentally, in the scale 10 of this embodiment, the length of the fourth rod-like member 4 is set to 60 centimeters, and the numerical value from zero to 60 centimeters is attached to the sixth scale M6 in millimeters. Yes.

As shown in FIGS. 1 to 5, a recording auxiliary member 11 that freely slides the third rod-shaped member 3 is fitted to the third rod-shaped member 3 closer to the end than the second rod-shaped member 2. Since the recording auxiliary member 11 is formed with a flat portion 11a orthogonal to the third rod-like member 3, the recording auxiliary member 11 can be moved to a desired position and marked with a pencil or the like at the position and height where the mold is to be built. Easy.
At this time, a male screw 7 is provided to prevent the recording auxiliary member 11 from sliding on the third rod-shaped member 3 so that the recording auxiliary member 11 does not move.
A hollow fixing member 12 that freely slides the third rod-shaped member 3 is fitted between the first rod-shaped member 1 and the second rod-shaped member 2. The fixing member 12 has a protrusion 13 having a round hole 12a. The pin 12b is inserted from the round hole 12a so that the fixing member 12 can be fixed to the mold.
The scale 10 of the present embodiment has a maximum length of 200 to 205 centimeters. However, if the scale 10 is fixed to the mold with pins 12b, the height and length of the mold can be measured by one person.

6 and 7 are views showing the second bar-like member, FIG. 6 is a front view and a sectional view, and FIG. 7 is a side view and a sectional view.
As shown in FIG. 6, the second rod-like member 2 is a hollow short member having a rectangular cross section, and the second rod-like member 2 is prevented from sliding the third rod-like member 3 near the front end. There is a male screw 6 with a knob, which has a reference point Z near the center and a symmetrical fifth scale M5 on both sides.
Incidentally, the second rod-like member 2 of the present embodiment has a length of 15 centimeters, and the fifth scale M5 has a value near the center of zero and numerical values of up to 5 centimeters on both sides in millimeters.
Therefore, for example, if the horizontal laser beam or the vertical laser beam indicating the reference position is set so as to hit the reference point, it is observed where the horizontal laser beam or the vertical laser beam hits the fifth scale M5 at each measurement point. By doing so, the deviation from the original position can be obtained.
As shown in FIG. 7, the side surface of the second rod-like member 2 is provided with a window 2a through which the third scale M3 or the fourth scale M4 corresponding to the reference point Z of the fifth scale M5 can be read.
Therefore, the height and length up to the reference point Z can be easily read.

8 and 9 are diagrams showing the recording auxiliary member, FIG. 8 is a side view, and FIG. 9 is a rear view.
As shown in FIGS. 8 and 9, the recording auxiliary member 11 has a rectangular hollow portion that fits into the third rod-shaped member 3, and has a knob that prevents the third rod-shaped member 3 from sliding on the front surface. There are male screws 7, and the back side has a trapezoidal plate shape. Therefore, since the upper part of the side surface forms a straight line and the flat part 11a is formed, it is easy to mark with a pencil or the like.

10 and 11 are views showing the fixing member, FIG. 10 is a side view, and FIG. 10 is a front view.
As shown in FIGS. 10 and 11, the fixing member 12 has a rectangular hollow portion that fits into the third rod-shaped member 3, and a male screw with a knob that prevents the third rod-shaped member 3 from sliding on the front surface. 8 and a protrusion 13 having a round hole 12a on the back side. Accordingly, the third rod-like member 3 is fixed to the formwork by fixing the third rod-like member 3 to the formwork by inserting the pin 12b from the round hole 12a into the formwork after being fixed by the male screw 8 with a knob. Can be done alone.

Here, the dimension of each member shown above and the numerical value attached to the scale are examples, and it is not necessarily limited to this, and can be arbitrarily set.

Next, FIG. 12 for explaining an example of a method for measuring the height and length using the scale 10 of the present embodiment is the height of the beam formwork or slab formwork using the scale of the present embodiment. It is a figure which shows an example which measures this.
As shown in an example in FIG. 12, when building a condominium or the like with concrete, a wall formwork, a beam formwork, a slab formwork, and the like are built using a siding board, a separator, a pier, and the like.
In that case, before and after placing concrete, it is necessary to inspect whether the formwork is installed as shown in the drawing, and measure the height from the reference line to the object by irradiating the horizontal laser beam B. . First, the fourth scale M4 (not shown in the figure) of the scale 10 is set to the height at which the object is supposed to be. Next, the reference point Z of the fifth scale M5 is set so that the numerical value of the fourth scale M4 displayed on the side window 2a becomes the height of the laser beam B. And when the top part of the 3rd rod-shaped member 3 is made to contact | abut to a target object, if the laser beam B irradiates the reference point Z of the 5th scale M5, the height of a target object will be normal and it will be from the reference point Z. If the bottom is irradiated, it is too high, and if the top is irradiated, it is too low.

FIG. 13 is a diagram illustrating an example of leveling when a formwork is built using the scale of the present embodiment.
A plinth is placed on the plywood laid on the concrete floor, and a formwork is built on it. It is necessary to level out so as not to generate a gap. The horizontal laser beam B is irradiated and the height from the reference line to the point where the mold is built is measured.
First, the reference point Z of the fifth scale M5 is such that the numerical value of the fourth scale M4 (not shown in the figure) displayed in the window 2a (not shown in the figure) on the side surface of the scale 10 becomes the height of the laser beam B. Set. Then, the first rod-like member 1 of the scale 10 of the present embodiment in which the fourth rod-like member 4 is developed at a position orthogonal to each other is set at each position (A to J) of the mold for the one end 1a. At this time, if the laser beam B irradiates the reference point Z of the fifth scale M5, the level is normal. On the other hand, if the area below the reference point Z is irradiated, the floor surface is too high, and the numerical value is recorded as negative. Also, if you irradiate the top, it is too low and the value is recorded as a plus. And according to the recorded numerical value, the thickness of the packing material inserted between a plywood board and a crosspiece is adjusted.
Here, if the positions (A to J) of the slats that are sequentially built are marked using the sixth scale M6 of the developed fourth rod-shaped member 4, the work can be made more efficient.

FIG. 14 is a diagram illustrating an example in which the length from the reference position to the mold frame or window frame is measured using the scale according to the present embodiment.
As shown in FIG. 14, dimensions from the horizontal reference position K and the vertical reference position L are described in the layout drawing of the formwork.
First, the reference point Z of the first scale M1 of the scale 10 is adjusted to the horizontal reference position K or the vertical reference position L. And the fixing member 12 is fixed to a formwork with the pin 12b, and the length of one side is read with the 1st scale M1. Moreover, the 3rd rod-shaped member 3 is slid and the other edge part 3b of the 3rd rod-shaped member 3 is united with the measurement position of the other side. Then, the numerical value at the horizontal reference position K or the vertical reference position L of the third scale M3 (not shown in the figure) at that time is read.
Accordingly, the height and length from the horizontal reference position K or the vertical reference position L to the measurement positions on both sides can be read simultaneously, and the height of each position of the entire window frame from the horizontal reference position K or the vertical reference position L or The length can be read simultaneously.

It can be used as a scale when measuring the height that cannot be reached from the ground or when measuring the length from the reference position to the predetermined positions on both sides simultaneously.

DESCRIPTION OF SYMBOLS 1 1st rod-shaped member 1a, 2a One edge part 3a, 3b The other edge part 2 2nd rod-shaped member 2a Window 3 3rd rod-shaped member 4 4th rod-shaped member 4a Folding Hinge 5, 6, 7, 8 Male screw 10 with a knob 10 Scale 11 Recording auxiliary member 11a Plane portion 12 Fixing member 12a Round hole 12b Pin 13 Protrusion portion
Z reference point
M1 1st scale
M2 2nd scale
M3 3rd scale
M4 4th scale
M5 5th scale
M6 6th scale

Claims (8)

A hollow and long first rod-shaped member, a hollow and short second rod-shaped member, and a long and long third rod-shaped member which is slidable by being fitted in the hollow portions of both the first member and the second member. A first blocking means for blocking the third rod-shaped member from sliding on the first rod-shaped member; and a second blocking means for blocking the third rod-shaped member from sliding on the second rod-shaped member. ,
The first bar-shaped member has a first scale marked on the outer surface from one end to the other end where the third bar-shaped member is fitted, with the other end as a reference point, and the one A second scale with the end as a reference point,
The third rod-shaped member has a third scale marked on the outer surface from one end to the other end fitted to the first rod-shaped member with the one end as a reference point, and the second A fourth scale written with a predetermined position near the other end as a reference point so as to be continuous with the scale,
The second rod-shaped member is formed with a window for reading the third scale and a window for reading the fourth scale near the center in the length direction, and on the outer surface other than the outer surface where the window is formed, A scale having a fifth scale marked on both sides as a reference point. A fixing means for slidably fitting to the third rod-shaped member and detachably fixing the third member to the mold;
The scale according to claim 1, further comprising: a recording auxiliary unit that is slidably fitted to the third rod-like member and is used when recording a measurement value. A long fourth rod-shaped member that is pivotally supported by the one end of the first rod-shaped member and freely rotates between a position perpendicular to the first rod-shaped member and an overlapping position;
2. The scale according to claim 1, wherein the fourth rod-shaped member has a sixth scale whose end point is pivotally supported by the first rod-shaped member. The first rod-shaped member, the second rod-shaped member, and the third rod-shaped member are polygonal in cross section, and the hollow inner dimensions of both the first rod-shaped member and the second rod-shaped member are the third rod-shaped. The scale according to claim 1, wherein the scale is larger than an outer dimension of the member. 2. The scale according to claim 1, wherein the first blocking means and the second blocking means are male threads that are screwed into screw holes provided in the first rod-shaped member or the second rod-shaped member. Each of the fixing means and the recording auxiliary means has a screw hole into which a male screw is screwed,
The scale according to claim 2, wherein the male screw is turned and fixed to a predetermined position of the third rod-shaped member. The scale according to claim 3, wherein the fourth bar-shaped member is a plate-shaped or columnar member that is pivotally supported by the first bar-shaped member so as to be detachable and rotatable. Each of the first bar-shaped member, the second bar-shaped member, and the third bar-shaped member has a rectangular cross section, and both the first scale and the third scale, and both the second scale and the fourth scale. The scale according to claim 4, wherein the scale is attached to one opposing surface, and the fifth scale is attached to the other opposing surface.