JP2011164060A - Method and device for evaluation of surface roughness on concrete wall - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and device for evaluating roughness level on a concrete wall surface which can achieve easier measuring with less variation per measurer. <P>SOLUTION: The evaluation device 10 includes a frictional resistor 12 located on the surface of the concrete wall 8, a support means 14 supporting the frictional resistor 12, a load applying means 16 for loading the support means 14 so as to vertically-press the frictional resistor 12 onto the surface of the concrete wall 8 at a constant force, and a rectilinear travel means 18 for linearly-moving the support means 14 along the surface of the concrete wall 8 while contacting the frictional resistor 12 to the surface of the concrete wall 8. Then a measuring means 20 measures a resistance load on the frictional resistor 12 when linearly-moving with being loaded, evaluating roughness level on the concrete wall 8 based on variation in the resistance load. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a concrete wall surface roughness evaluation method and an evaluation apparatus for evaluating the degree of surface roughness after the surface of a concrete wall is roughened.

When finishing concrete walls (mainly outer walls) of building structures with finishing building materials such as tiles, plasterers, stones, and paints, the surface of the concrete walls is roughened to increase the adhesion between the concrete walls and the finishing building materials. The method of applying the process is taken.
The following methods are known as main methods for processing the rough surface.
1. A method of grinding the concrete surface with ultra-high pressure water (100-300MPa).
2. A method of polishing the concrete surface with a polishing machine (disk sander, belt sander, etc.).
3. A method of roughening the concrete surface by applying a setting retarder to the casting surface side of the concrete formwork to delay the setting of the concrete surface.

  However, when the surface of the concrete wall is processed into a rough surface, if the roughness is insufficient, the adhesive strength between the concrete wall and the finishing building material will decrease in the future, and the finishing building material may float or peel off. In the worst case, building materials may fall off.

Therefore, it is necessary to inspect the adhesion between the concrete wall and the finishing building material.
The method for inspecting the adhesive strength between the concrete wall and the finishing building material is to use a testing machine as shown in Non-Patent Document 1, for example, periodically after finishing the construction of the finishing building material or when using the building structure. Are often tested for adhesion.

However, since the adhesive strength test by the testing machine is performed after finishing the building material for finishing, even if it is found that the rough surface treatment is insufficient, the rough surface treatment cannot be repeated.
In addition, according to Non-Patent Document 2, the adhesion strength test using a testing machine has been reported to have little correlation between the roughness of the concrete surface and the adhesion strength.

On the other hand, a method for evaluating the roughness of the surface of a concrete wall before constructing a finishing building material has been proposed.
As an example, there is a method of measuring the glossiness as shown in Patent Document 1.
As another example, there are a method of measuring using a surface roughness meter and a method of measuring the surface roughness by image analysis using a microscope.
Further, the present invention is a method for evaluating the degree of coarseness from the frictional resistance of the wall surface. When testing the frictional resistance of a tire such as a road surface, for example, a testing machine as shown in Non-Patent Document 3 is used. There is a method to test the coefficient of friction.

JP2009-24468

Guidelines for Supervision of Building Construction 2007 Edition (Volume 2) Takayama et al .: Effects of roughening and water absorption modifiers on the anti-peeling performance of exterior tile direct tension construction method Part 2, Summary of Academic Lectures of Architectural Institute of Japan (China) Materials Construction A-1, pp.107-108, 2008.9 Handbook of Pavement Test Method, Japan Road Association, pp.969 "6-5 Measuring Method of Slip Resistance on Pavement Surface"

However, among the methods for evaluating the roughness of the concrete surface, the evaluation based on the glossiness varies depending on the properties of the concrete, and it is difficult to quantitatively evaluate the concrete surface roughness.
In addition, the method of measuring the glossiness using a metal foil as disclosed in Patent Document 1 has a problem that the variation varies depending on the type of metal foil and the measurer who applies the metal foil.
Further, there are a stylus method and a light reflection method as a method of measuring using a surface roughness meter, but since the area to be evaluated by both methods is small and targets minute unevenness, the intent of the present invention is intended. It is not suitable for the evaluation of roughening for the purpose of strengthening the adhesion of finishing building materials.
In addition, the method using a microscope cannot be evaluated simply because it requires advanced technology to perform image analysis.
In addition, since the testing machine according to Non-Patent Document 3 was developed to measure the sliding resistance of the pavement surface, this testing machine that normally performs the measurement by installing the testing machine horizontally applies the principle of a pendulum. Therefore, it is not suitable for the vertical wall which is the object of the present invention.

  The present invention has been made in view of the above circumstances, and its purpose is to evaluate the degree of surface roughness after roughening the surface of the concrete wall, and there is little variation by the measurer, An object of the present invention is to provide a method and an apparatus capable of easily measuring the degree of surface roughness.

  In order to achieve the above object, the present invention is a method for evaluating the surface roughness of a concrete wall, in which the surface roughness of the surface of the concrete wall is subjected to a roughing process, and the friction resistance is selected from the concrete resistance. A step of arranging on the surface of the wall, a moving step of moving the frictional resistor on the surface of the concrete wall at a constant speed, and measuring a resistance load when the frictional resistor moves in the moving step. And a measuring step for calculating, and an evaluation step for calculating and evaluating the degree of coarseness from the measured resistance load.

  The present invention also relates to a concrete wall surface roughness evaluation apparatus for evaluating a roughening processing amount obtained by roughening a surface of a concrete wall, the friction resistor being disposed on the surface of the concrete wall. And supporting means for supporting the frictional resistor; load applying means for applying a load to the supporting means so that the frictional resistor is pressed with a constant force in a direction perpendicular to the surface of the concrete wall; Linear movement means for linearly moving the support means along the surface of the concrete wall while contacting the friction resistance body with the surface of the concrete wall; and measuring means for measuring a resistance load when the friction resistance body moves. It is characterized by having.

  According to the method and apparatus for evaluating the surface roughness of the concrete wall of the present invention, the degree of surface roughening treatment of the concrete wall of the building structure is determined by the resistance load when the frictional resistor is moved along the concrete wall. By measuring and evaluating, it is possible to quantify the difference in the surface roughness after the roughening treatment and easily evaluate it at the construction site.

It is explanatory drawing including the cross section of the surface roughness evaluation apparatus of the concrete wall which concerns on 1st Embodiment. It is a top view of the surface roughness evaluation apparatus of the concrete wall which concerns on 1st Embodiment. It is a bottom view of the surface roughness evaluation apparatus of the concrete wall which concerns on 1st Embodiment. It is the figure which looked at the frictional resistance object concerning a 1st embodiment from the concrete wall side. It is a flowchart showing the surface roughness evaluation method of the concrete wall which concerns on 1st Embodiment. It is explanatory drawing containing the cross section of the surface roughness evaluation apparatus of the concrete wall which concerns on 2nd Embodiment. It is the figure which looked at the frictional resistor which concerns on 2nd Embodiment from the concrete wall side. It is a resistance load figure measured by the Example based on 1st Embodiment.

Hereinafter, a first embodiment of the present invention will be described in detail with reference to FIGS.
In the present embodiment, the surface of the concrete wall 8 extends in the vertical direction.
The evaluation device 10 includes a friction resistor 12, a support means 14, a load applying means 16, a linear moving means 18, a measuring means 20, and a frame 22.

The friction resistance body 12 is made of a flexible material such as rubber, sponge, or nonwoven fabric. Although it deform | transforms by applying a load with respect to the frictional resistor 12, what does not generate | occur | produce a crack and a tear in that case, and a deformation | transformation returns when a load is unloaded is desirable.
For example, when rubber is used for the friction resistor 12, natural rubber, chloroprene rubber, urethane rubber, nitrile rubber or the like is used as the rubber type, and a hardness of 10 to 40 (Shore A) is preferable. The rubber should be excellent in compression set resistance, tear resistance, and wear resistance.
As such a friction resistor 12, a commercial product such as a chloroprene rubber sheet “CB245N (made by Kureha Elastomer Co., Ltd.)” having a thickness of 1 mm can be used.
In addition, since moderate softness is required so that the difference in frictional resistance appears depending on the degree of coarseness, materials such as plastic, paper, fiber, glass, ceramics, and metal are also selected according to the degree of coarseness. sell.
The frictional resistance body 12 has a shape having a substantially flat surface 12 a in contact with the concrete wall 8. The flat surface 12a has a uniform surface roughness.
The frictional resistor 12 has, for example, a plate shape as shown in FIG. 1, and its thickness is preferably 1 to 50 mm so that cracks and tears do not occur when a load is applied.
The friction resistance body 12 is supported by the support means 14 on the opposite surface 12 b of the substantially flat surface 12 a in contact with the concrete wall 8.

For example, as shown in FIG. 4, the friction resistance body 12 is supported by the support means 14 by a method in which an embedded nut 1402 is provided in the friction resistance body 12 and a bolt protruding from the support means 14 is fastened to the nut 1402. Various conventionally known methods such as bonding using an adhesive can be employed.
In addition, since it is expected that the frictional resistor 12 will be cracked, torn, and worn by repeated evaluation, it is desirable that the frictional resistor 12 can be easily replaced as a consumable. It is desirable to be interchangeable.
The support means 14 is preferably a metal member (block) as a high-rigidity material for pressurizing the frictional resistor 12, but may be a plastic member (block) having a high rigidity for weight reduction. Examples of plastic include acrylonitrile / butadiene / styrene copolymer synthetic resin (ABS resin) and polycarbonate.

The load applying means 16 applies a constant load in the vertical direction to the surface of the concrete wall 8 so as to press the friction resistance body 12 against the concrete wall 8 via the support means 14.
The load applying unit 16 includes an elastic unit 1602, a substrate 1604 facing the support unit 14, a guide member 1606, and a roller 1608.

  The elastic means 1602 is constituted by, for example, a coil spring, and one end of the elastic means is coupled to the support means 14 and the other end is coupled to the substrate 1604 that opposes the support means 14. The elastic means 1602 applies a certain load to the support means 14 by urging the support means 14 and the substrate 1604 in a direction away from each other.

  The guide member 1606 is made of, for example, a rod. One end of the guide member 1606 is fixed to the substrate 1604, and the other end is movably inserted into a hole 1404 provided in the support means 14. By this guide member 1606, the supporting means 14 and the frictional resistance body 12 are supported so as to be movable in a direction perpendicular to the surface of the concrete wall 8 via the substrate 1604, and the frictional resistance body 12 is prevented from moving. A uniform load can be applied to the surface of the concrete wall 8.

The roller 1608 is rotatably supported on the substrate 1604.
Here, the frame 22 of the evaluation apparatus 10 is attached and fixed to the concrete wall 8, and is supported by the plurality of leg portions 22b that are detachably attached to the concrete wall 8, and the leg portions 22b. It is comprised from the board part 22a which faces the concrete wall 8 in parallel. The plate portion 22a is provided with a rail 22c extending linearly.
The frame 22 is attached to the concrete wall 8 so that the rail 22c extends in the horizontal direction.
The roller 1608 is engaged with the rail 22c and linearly moved along the rail 22c.
In addition, conventionally well-known various methods are employable for the attachment to the concrete wall 8 of the leg part 22b.
As the support means 14 and the frame 22, for example, JIS G4051 carbon steel for machine structure S40C can be adopted.

That is, when the frame 22 is attached to the concrete wall 8, a certain load is applied to the support means 14 and the frictional resistance body 12 by the elastic force of the elastic means 1602 via the plate portion 22a, the roller 1608, and the substrate 1604. Become.
The load in the direction perpendicular to the surface of the concrete wall 8 changes even when the frictional resistance body 12 is linearly moved in the horizontal direction with respect to the surface of the concrete wall 8 as will be described later. In this case, the load applied in the vertical direction may be measured and controlled using a load converter (load cell).

The linear moving means 18 linearly moves the support means 14 along the surface of the concrete wall 8 in a horizontal direction while bringing the frictional resistor 12 into contact with the surface of the concrete wall 8.
The linear moving means 18 includes a linear material 1802, a reel 1804, a rail 22 c, and a roller 1608.

The linear member 1802 is made of a wire, a chain, or the like, and has one end connected to the support means 14 and the other end fixed to the reel 1804 and wound.
The reel 1804 is rotatably supported by the leg portion 22 b of the frame 22.
The rail 22c guides the support means 14 and the frictional resistance body 12 via the roller 1608 so as to be linearly movable in the horizontal direction.
Accordingly, by rotating the reel 1804 and winding the linear material 1802, the roller 1608 engaged with the rail 22 c rotates, and the support means 14 and the frictional resistance body 12 are linearly moved along the surface of the concrete wall 8. The
Since the linear movement of the frictional resistor 12 must be performed at a constant speed, the rotation of the reel 1804 is made constant.
In order to make the linear movement speed constant, it is possible to control the movement speed by measuring the movement distance per unit time using a displacement meter. However, as a simpler method, the number of rotations of the reel 1804 can be controlled. It is preferable to control by.
It should be noted that other methods may be used as long as the friction resistor 12 is moved horizontally and at a constant speed. For example, the friction resistor 12 may be moved using a hydraulic cylinder or an electric motor.

Next, the measuring means 20 is inserted in the middle part of the linear material 1802 in the longitudinal direction, and measures the resistance load applied to the linear material 1802 when the frictional resistor 12 moves linearly.
The measuring means 20 only needs to be able to measure a load, and various conventionally known measuring devices can be employed.
It should be noted that the resistance load changes when the frictional resistance body 12 is caught or detached from the protrusion provided by roughening the surface of the concrete wall 8. Therefore, the degree of coarseness of the surface of the concrete wall 8 can be determined by measuring the resistance load by the measuring means 20.

The operation of the present embodiment configured as described above will be described with reference to FIG.
First, the evaluation device 10 in a state where the support means 14 is brought close to the end of the frame 22 is arranged and fixed on the concrete wall 8 to be measured (S1). Due to the fixing to the concrete wall 8, a certain load is applied to the frictional resistance body 12 from the elastic means 1602.
Next, the zero point of the measuring means 20 is confirmed (S2).
Thereafter, the reel 1804 starts rotating at a constant speed (S3). As the reel 1804 rotates, the frictional resistor 12 and the support means 14 move linearly on the surface of the concrete wall 8 at a constant speed in the horizontal direction.
During this linear movement, the resistance load applied to the linear material 1802 is measured by the measuring means 20 (S4).
Then, when the support means 14 reaches the end of the frame 22, the rotation of the reel 1804 is stopped and the measurement is finished (S5, S6).
Next, the degree of coarsening of the concrete wall is calculated and evaluated based on the obtained resistance load variation (S6, S7).

Evaluation of coarseness is performed as follows, for example.
As shown in FIG. 8, the roughness of the surface of the concrete wall can be evaluated from the interval at which the polarity of the slope of the curve indicating the resistance load change changes, the relative value of the resistance load, and the like.
Specifically, when the interval at which the polarity of the curve slope changes is wide, it can be recognized that the interval between the protrusions provided on the surface of the concrete wall is large.
Further, when the interval at which the polarity of the curve slope changes is uniform, it can be recognized that the coarseness is uniform.
Further, when the relative value of the resistance load until the polarity of the inclination changes is large, it can be recognized that the height of the protrusion is high.

  Therefore, according to the method and apparatus for evaluating the surface roughness of the concrete wall according to the present embodiment, it is possible to reduce the variation by the measurer and to easily evaluate the degree of roughening of the concrete wall.

Next, a second embodiment will be described with reference to FIGS. In addition, the same code | symbol is attached | subjected and demonstrated to the location and member similar to 1st Embodiment.
The surface of the concrete wall 8 extends in the vertical direction.
The evaluation device 30 includes the friction resistor 12, the support means 14, the load applying means 16, the rotating means 32, the measuring means, and the frame 22.
In the second embodiment, unlike the first embodiment, the frictional resistor 12 is rotated instead of linearly moved.
As shown in FIG. 7, the frictional resistor 12 and the support means 14 have a fan shape when viewed from the surface of the concrete wall 8, the plate portion 22 a has a circular shape, and the rail 22 c has an annular shape.

Since the friction resistance body 12 and the support means 14 differ only in shape, description thereof is omitted.
The load applying unit 16 includes an elastic unit 1602, a substrate 1604, a guide member 1606, and a roller 1608.
The rotating unit 32 includes a rotating shaft 3202, a rail 22 c, and a roller 1608.
The rotating shaft 3202 is fixed to the support means 14 and movably penetrates the substrate 1604 and is supported rotatably by the plate portion 22a of the frame 22.
The rotation shaft 3202 serves as a rotation operation axis, and the support member 14 and the frictional resistance body 12 are supported by the guide member 1606 so as to be movable in a direction perpendicular to the surface of the concrete wall 8 via the substrate 1604. Thus, a uniform load can be applied to the surface of the concrete wall 8 to the friction resistor 12 while preventing blurring.

A jig 3204 such as a handle is coupled to the rotating shaft 3202, and the rotating shaft 3202 is rotated by rotating the jig 3204. As a result, the frictional resistor 12 rotates and moves along the surface of the concrete wall 8 around the rotation shaft 3202 in a state where a load is applied.
The measuring means is provided in the jig 3204 and can measure a resistance load, that is, a torque when a force for rotating the rotating shaft 3202 is applied.
Any measuring means may be used as long as it can measure a load (torque), and various conventionally known measuring devices can be employed.

Depending on the degree of coarseness of the surface of the concrete wall 8, the torque when the frictional resistor 12 rotates is changed.
Therefore, by measuring the torque with the measuring means attached to the jig 3204, the degree of roughening of the concrete wall is calculated and evaluated by the variation of the load (torque) as in the first embodiment. Is possible.
In the second embodiment, since the frictional resistor 12 is rotated, the measurement can be performed a plurality of times continuously, and more accurate measurement can be performed.

In the present embodiment, the surface of the concrete wall 8 is extended in the vertical direction on the assumption that the surface of the concrete wall is roughened to prevent the finishing building material applied to the side of the building from falling. However, if the surface of the concrete wall 8 is roughed for other purposes and the degree of roughening is to be evaluated, the concrete wall 8 is extended. The present invention is applied even if the direction is another direction.
Further, although the embodiment using the elastic means 1602 as the load applying means 16 has been described, other methods may be used as long as a certain load is applied to the friction resistance body 12 in the vertical direction on the surface of the concrete wall 8, such as a hydraulic cylinder. You may employ | adopt the method of making it pressurize using and tightening with a screw.

DESCRIPTION OF SYMBOLS 10, 30 ... Evaluation apparatus 8 ... Concrete wall 12 ... Friction resistor 14 ... Support means 16 ... Load application means 18 ... Linear movement means 20 ... Measuring means 22 ... Frame 32 ... Rotation means

Claims (10)

A method for evaluating the surface roughness of a concrete wall, wherein the surface roughness of the concrete wall is subjected to a roughening process to evaluate a roughening treatment amount,
Placing a frictional resistor on the surface of the concrete wall;
A moving step of moving the frictional resistor at a constant speed on the surface of the concrete wall;
In the moving step, a measuring step for measuring a resistance load when the frictional resistor moves,
An evaluation step for calculating and evaluating the degree of coarseness from the measured resistance load;
A method for evaluating the surface roughness of a concrete wall, comprising:   The movement of the friction resistor in the moving step is performed in a state where a constant load is applied to the friction resistor in a direction perpendicular to the surface of the concrete wall. Method for evaluating the surface roughness of concrete walls. The surface of the concrete wall extends in the vertical direction,
The method for evaluating the surface roughness of a concrete wall according to claim 1 or 2, wherein the movement of the frictional resistor in the moving step is a linear movement in a horizontal direction. The surface of the concrete wall extends in the vertical direction,
The method for evaluating the surface roughness of a concrete wall according to claim 1 or 2, wherein the movement of the frictional resistor in the moving step is a rotational movement.   The surface roughness of the concrete wall according to any one of claims 1 to 4, wherein the friction resistor is any one of rubber, sponge, and nonwoven fabric, and has a plate shape with a thickness of 1 to 50 mm. Evaluation methods. A concrete wall surface roughness evaluation apparatus for evaluating a roughening processing amount obtained by roughening a surface of a concrete wall,
A frictional resistor disposed on the surface of the concrete wall;
Support means for supporting the frictional resistance body;
Load applying means for applying a load to the support means so that the frictional resistance body is pressed with a constant force in a direction perpendicular to the surface of the concrete wall;
Linear moving means for linearly moving the support means along the surface of the concrete wall while contacting the frictional resistor with the surface of the concrete wall;
Measuring means for measuring a resistance load when the frictional resistor moves;
An apparatus for evaluating the surface roughness of a concrete wall, comprising: The surface of the concrete wall extends in the vertical direction,
A frame that has a plate portion facing the surface of the concrete wall and is attached to the concrete wall;
The load applying means includes a guide member coupled to the support means so as to be movable in the vertical direction, a substrate that faces the support means and holds the guide member, and is interposed between the support means and the substrate. Elastic means for biasing in the direction of separating them and
The linear moving means includes a linearly attached rail attached to the plate portion, a roller engaged with the rail so as to be linearly movable and rotatably supported on the substrate, and one end of the supporting means A linear member connected to the frame, and a reel that is rotatably supported by the frame and on which the other end of the linear member is wound,
The surface roughness evaluation apparatus for a concrete wall according to claim 6, wherein the linear movement is performed by rotating the reel to wind up a linear material. A concrete wall surface roughness evaluation apparatus for evaluating a roughening processing amount obtained by roughening a surface of a concrete wall,
A frictional resistor disposed on the surface of the concrete wall;
Support means for supporting the frictional resistance body;
Load applying means for applying a load to the support means so that the frictional resistance body is pressed with a constant force in a direction perpendicular to the surface of the concrete wall;
Rotating means for rotating the supporting means along the surface of the concrete wall while contacting the frictional resistor with the surface of the concrete wall;
Measuring means for measuring a resistance load when the frictional resistor rotates,
An apparatus for evaluating the surface roughness of a concrete wall, comprising: The surface of the concrete wall extends in the vertical direction,
A frame that has a plate portion facing the surface of the concrete wall and is attached to the concrete wall;
The load applying means includes a guide member coupled to the support means so as to be movable in the vertical direction, a substrate that faces the support means and holds the guide member, and is interposed between the support means and the substrate. Elastic means for biasing in the direction of separating them and
The rotating means includes a rail that is attached to the plate portion and extends in an arc shape, a roller that is movably engaged with the rail and is rotatably supported on the substrate, and extends in the arc shape. A rotation shaft that extends in the vertical direction at the center of the rail, is fixed to the support means, penetrates the substrate, and is rotatably supported by the plate portion; and a jig that rotates the rotation shaft. ,
The method for evaluating the surface roughness of a concrete wall according to claim 8, wherein the rotational movement is performed by rotating the rotating shaft by the jig.   10. The apparatus for evaluating a surface roughness of a concrete wall according to claim 6, wherein the friction resistor is replaceable.

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