KR100945259B1 - Measuring apparatus of mean texture depth - Google Patents

Abstract

The present invention comprises: a partition member for partitioning a patch forming area of a road surface, into which a volume of patch particles which can be filled in tissue of the road surface is poured; Flattening means for flatly spreading the patch particles in the partition member; Road surface tissue, which is elastically closely adhered to the road surface, and includes shaping means for shaping the patch particles while sweeping the flattened patch particles, thereby making it possible to easily and quickly measure the average texture depth of the road surface, and the surface texture of which the accuracy is quite high. Start the measuring instrument.

Road surface, texture, surface texture depth, MTD, patch

Description

Road surface organization measuring instrument {MEASURING APPARATUS OF MEAN TEXTURE DEPTH}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a road surface tissue measuring instrument, and more particularly, to a road surface tissue measuring instrument that enables easy and accurate measurement of the texture depth of a road surface.

In general, the road construction method is focused on the proper strength of the road surface, the appropriate sliding resistance, and the low noise characteristics.

In this road surface research, the depth of the road surface is closely related to the sliding resistance. Therefore, the depth of the road surface is measured and analyzed as follows.

First, spread a certain amount of sand evenly on the test surface to make a circular and flat patch as possible, and then measure the diameter of the patch, and then use the arithmetic correlation equation between this measurement and the volume of sand spread on the test surface. Calculate the organizational depth of At this time, the computed depth of the road surface is not the depth of each structure of the road surface, but the average structure depth of the road surface.

 By the way, since the texture depth measurement method of the road surface mentioned above makes a patch by hand, it takes much time to measure the texture depth of a road surface, and it is difficult to form a patch of a perfect shape, and the average structure depth measurement error of a road surface is large. Therefore, there is an urgent need for a solution to solve this problem.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems of the prior art, and an object thereof is to provide a road surface tissue measuring apparatus which enables easy and rapid measurement of the texture depth of a road surface, and the measurement result is quite accurate.

In order to solve the above problems, the present invention comprises: a partition member for partitioning a patch forming area of a road surface, into which a volume of patch particles which can be filled in the tissue of the road surface is poured; Flattening means for flatly spreading the patch particles in the partition member; The present invention provides a road surface tissue measuring apparatus including shaping means elastically adhered to the road surface and shaping the patch while sweeping the flattened patch particles.

The partition member may partition the patch forming area of the road surface into a rectangular shape.

The flattening means may include at least one trowel provided to be movable in the partition member to spread the patch particles.

The plurality of trowels are arranged at regular intervals in the movement direction of the trowel, can be moved integrally.

The trowel may be provided in two arranged at regular intervals in the moving direction of the trowel so that the patch particles can be poured therebetween.

The width of the trowel may be approximately equal to the width of the patch forming area of the road surface.

The shaping means includes at least one shaping member provided to move in the partition member to sweep the patch particles; The shaping member protrudes further toward the road surface than the flattening means, and may be a flexible material.

The shaping means may be combined with the flattening means to interlock with the flattening means.

It may further include a guide for guiding the movement of the planarization means and shaping means.

The guide may include a guide rod fixed to the partition member and penetrating the planarization means or the shaping means.

The flattening means and the shaping means may further include a conveying means for automatically conveying.

The conveying means includes a motor; A pulley rotated by the motor; It may include a connecting member for connecting the pulley with the flattening means or the shaping means.

It may further include a patch length measuring means for measuring the length of the patch in the movement direction of the flattening means and shaping means.

The patch length measuring means may include a measuring needle provided in the partition member, and a measuring needle indicating the scale of the measuring device in association with the flattening means or the shaping means.

The road surface tissue measuring instrument according to the present invention as described above has the advantage that the average tissue depth data of the road surface can be obtained easily and quickly, and the accuracy of the data is considerably high.

1 is a perspective view of a road surface texture measuring apparatus according to the present invention, FIG. 2 is a cross-sectional view taken along line AA of FIG. 1, FIG. 3 is a cross-sectional view of a road surface texture before the measuring operation of the present invention, and FIG. 4 is a planarization operation of the present invention. Fig. 5 is a sectional view of the road structure, and Fig. 5 is a sectional view of the road structure after the patch shaping operation of the present invention, and Fig. 6 is a schematic view of the patch formed by the present invention.

As shown, the road surface tissue measuring apparatus according to the present invention is characterized by partitioning a patch forming area of the road surface 2 into which a volume of patch particles 4 can be poured which can be filled into the tissue of the road surface 2. The partition member 10, the flattening means 20 which flatly spreads out the patch particles 4 in the partition member 10, and the patch particles 4 which are elastically tightly contacted with the road surface 2 and spread out flatly, And shaping means 30 for shaping (P).

The patch particles 4 may be any one of powder, sand, sludge, etc., as long as the particles can be embedded in the texture of the road surface 2. Among them, sand can be used easily and inexpensively, and does not affect the environment. It may have an advantage such as not.

The partition member 10 may be configured in any structure as long as it can partition the road surface 2, but it is preferable that the upper and lower surfaces are formed in an open ring shape so that the patch particles 4 are easily poured and unfolded. Do.

The partition member 10 may be formed in various shapes such as a circular ring, an elliptical ring, a square ring, and the like, by being formed in a rectangular ring shape that partitions the patch forming area of the road surface 2 into a rectangular shape as in the present embodiment. The flattening means 20 and the shaping means 30 are more preferable in that the flattening and shaping can be performed simply by reciprocating without moving in all directions.

The flattening means 20 may include a trowel 22 which can be moved in the partition member 10 so that the flattening means can be unfolded while sweeping the patch particles 4 in the partition member 10.

The trowel 22 may have any structure as long as it can be flattened, but is configured in a block shape such as a substantially hexahedral passage as in the present embodiment, so that the patch particles 4 are easy to sweep, and the structure is simple. It may have advantages such as being firm, robust, and easy for a worker to hold and move by hand.

In particular, the trowel 22 is configured such that the width of the trowel 22 is approximately equal to the width of the patch-forming area of the road surface 2, that is, the inner width of the partition member 10, so that the trowel 22 is easily reciprocated. It is advantageous in that the planarization operation can be made.

In addition, the trowel 22 has a shape in which the end portion 22 ′ in contact with the patch particles 4 is gradually narrowed in area, such as a wedge shape, so that the trowel 22 is in the partition member 10. It is advantageous in that the patch particles 4 can be easily wiped off without being caught by the accumulated patch particles 4.

The trowel 22 may be composed of one, or may be composed of two or more.

When the trowel 22 is composed of two or more plural pieces, the plurality of trowels 22 move in the direction of movement of the trowel, that is, the flat / shaping work direction (arrow) so that the flattening operation can be repeatedly performed several times in a short time. A) can be arranged at regular intervals. In particular, the plurality of trowels 22 may be integrally moved so that the flattening operation can be performed at the same time. That is, the plurality of trowels 22 may be coupled to each other through a bracket 24 or the like so as to be tied together.

Furthermore, the trowel 22 is composed of two so that the patch particles (4) can be poured therebetween, the patch particles (4) poured between the two trowels 22 in accordance with the movement of the trowel (22) It can be spread out from between the two trowels 22 by the appropriate amount on the road surface 2, so that the trowel 22 can be easier than to planarize the patch particles (4).

The shaping means 30 includes a shaping member 32 which is provided to be movable in the partition member 10 and sweeps the patch particles 4. More preferably, the shaping member 32 is more protruded toward the road surface 2 than the trowel 22, and is provided with a flexible material having a bending property. Examples of the flexible material include sponge, styrofoam, rubber, and cotton balls.

Like the trowel 22, the shaping member 32 is preferably configured such that the width of the shaping member 32 is approximately equal to the width of the inside of the partition member 10.

The shaping member 32 is integrated with the flattening means 20 to have this advantage because the measuring operation can be easily and quickly performed when the shaping means 30 is interlocked with the flattening means 20. Can be combined. That is, the shaping member 32 may be coupled to the flattening means 20, in particular, the trowel 22 by a method such as adhesive, welding, screw fastening, or the like. It may be supported by the shaping member frame 34.

On the other hand, the road surface measuring mechanism further includes a guide 40 for guiding the movement of the flattening means 20 and the shaping means 30, thereby making the flattening means 20 and the shaping means 30 accurate and easy. It can have the advantage that it can be operated.

When the flattening means 20 and the shaping means 30 are interlocked as in the present embodiment, the guide 40 may be any one of two combinations of the guide 40 and the shaping means 30. It is more preferable to combine only. Therefore, in the present embodiment, it is easier to structurally combine the guide 40 with the flattening means 20 than the shaping means 30, the guide 40 is the flattening means 20, that is, trowel An example combined with (22) is disclosed. Of course, when the flattening means 20 and the shaping means 30 are operated separately, the guide 40 may be combined with the flattening means 20 and the shaping means 30 independently.

In addition, the guide 40 may be implemented in various ways. In the present embodiment, the guide 40 is fixed to the partition member 10 and has a guide rod hole 22A formed in the trowel 22. It may be implemented by a guide rod 42 penetrating the trowel 22 through.

 Of course, the guide 40 is not limited to the above-described embodiment and may be implemented in various ways.

Furthermore, the guide rod 42 is combined at the edge of the trowel 22 rather than the center of the trowel 22 so as not to interfere with the patch particles 4 when the patch particles 4 are poured between the two trowels 22 as in the present embodiment. Is preferred. Furthermore, when the guide rod 42 is combined with the edge of the trowel 22 as in the present embodiment, the trowel so that the flattening means 20 and the shaping means 30 can be uniformly and stably supported. It is more preferable to combine with both edges of (22), respectively.

In addition, the present road surface measuring mechanism includes a conveying means 50 for automatically conveying the flattening means 20 and the shaping means 30, so that the flattening work and the shaping work can be performed more accurately, and the convenience of use is improved. It can have the advantage that it can be.

When the flattening means 20 and the shaping means 30 are interlocked as in the present embodiment, the transfer means 50 is any one of two combinations with the flattening means 20 and the shaping means 30, respectively. It is more preferable to combine only one. Therefore, in this embodiment, it is easier to structurally combine the conveying means 50 with the planarizing means 20 than the shaping means 30, the conveying means 50 is the planarizing means 20 That is, an example combined with the trowel 22 is disclosed. Of course, the transfer means 50 may be independently combined with the planarization means 20 and the shaping means 30 when the planarization means 20 and the shaping means 30 are operated separately.

In addition, the transfer means 50 may be implemented in various ways, as in the present embodiment, a motor 52 for generating power and a pulley (fully) rotated by the power of the motor 52. 54 and the connecting member 56 connecting the pulley 54 and the flattening means 20, in particular, the trowel 22. Of course, the transfer means 50 is not limited to the above-described embodiment may be implemented in various ways.

The transfer means 50 may be mounted in a space provided in the partition member 10 to be integrated with the partition member 10.

Further, the motor 52 and the pulley 54 are either one of the flattening means 20 and the shaping means 30 along the moving direction (arrow A) of the flattening means 20 and the shaping means 30. It may be located only, or both may be located. In addition, the pulley 54 may be provided with a spring 58 to allow the connecting member 56 to be wound around the pulley 54.

The motor 52 may be manipulated and controlled by a motor control panel 51 installed in the partition member 10.

The connection member 56 may be implemented by a wire as in the present embodiment, or may be implemented by various methods such as a belt and a chain. The connecting member 56 may be installed to be exposed to the outside of the partition member 10, or may be installed so that a part of it is concealed inside the partition member 10 as in this embodiment. That is, the partition member 10 may be provided with a connection member passage 10A for guiding the connection member 56 in the partition member 10 so that a part of the connection member 56 may be inserted into the partition member 10. Can be. In addition, the connecting member guide roller 10B may be mounted in the partition member 10 so that the connecting member 56 may be smoothly guided.

In addition, in the present road surface measuring mechanism, the width of the partition member 10 is constant so that the width of the patch P along the width direction of the partition member 10 is always the same, but according to the moving direction of the flattening means and the shaping means. Since the length of the patch P is a variable, the patch length measuring means 60 for measuring the length of the patch P is further included, so that the area of the patch P is accurate, quickly and conveniently calculated. It can have the advantage of being able to be.

The patch length measuring means 60 is measured to measure the scale of the measuring device 62 in conjunction with the measuring device 62 and the flattening means 20 or the shaping means 30 provided in the partition member 10. It may be implemented with a needle (64). Of course, the patch length measuring means 60 is not limited to the above-described embodiment, it can be implemented in various ways.

Looking at the method according to the road surface texture measuring apparatus according to the present invention configured as described above are as follows.

First, as shown in FIG. 3, the road surface 2 is cleaned, and then the road surface structure measuring device of the present invention is placed on the road surface 2, and the patch particles 4 are measured using a measuring device such as a cylinder. After preparing a predetermined amount), the prepared patch particles 4 are poured into the partition member 10 so as to be loaded between the two trowels 22. At this time, the flattening means 20 and the shaping means 30 is the partition member 10 so that the measuring needle 64 of the patch length measuring means 60 indicates the scale '0' of the measurer 62. Preferably at one end of The patch particles 4 loaded between the two trowels 22 are more preferably evened using a stick or the like.

Next, the motor control panel 51 is operated to drive the motor 52 of the transfer means 50. Then, the pulley 54 is rotated by the motor 52, the connection member 56 is moved as the pulley 54 is rotated.

In addition, the flattening means 20 and the shaping means 30 are pulled by the connecting member 56, so that the flattening means 20 and the shaping means 30 are moved.

Accordingly, the patch particles 4 loaded between the two trowels 22 are unfolded from the two trowels 22 by appropriate amounts and spread on the road surface 2. The patch particles 4 spread on the road surface 2 are flattened by being swept away by the trowel 22. Then, at the same time as the flattening operation, while the shaping member 32 is moved with the trowel 22 in a curved state, shaping is performed. That is, as the shaping member 32 sweeps the patch particles 4 stacked on the tissues of the road surface 2, as shown in FIG. 5, the patch particles 4 become the road surface 2. In accordance with the depth of each of the tissues of the road surface (2) is filled with each other and is spread out formally.

At this time, even if the shaping member 32 is a flexible material, since the patch particles 4 are unfolded to some extent through the flattening operation, the shaping member 32 is sufficiently swept without being caught by the patch particles 4. I can make it.

When the shaping is performed as described above, the patch P is formed.

In addition, by measuring the measurement needle 64 of the patch measuring length means 60 together to indicate any scale of the measuring device 62, the length of the patch (P) is measured together.

In the patch P formed as described above, since the patch particles 4 are unfolded in accordance with the height of each structure of the road surface 2, there is no height error in each structure of the road surface 2. In addition, the shape of the patch (P), the patch forming area of the road surface (2) is partitioned into a substantially rectangular shape by the partition member 10, the width of the trowel 22 and the shaping member (32) Since the width of is substantially the same as the width of the inside of the partition member 10, it takes a substantially rectangular shape. Therefore, the length of each side of the said patch P can be measured easily and correctly, and the area of the said patch P can be calculated. In particular, as described above, the width of the patch P is constant, and the length of the patch P is automatically measured by the patch length measuring means 60, thereby making the area of the patch P more accurate, It can calculate quickly and conveniently.

If the area of the patch P calculated as described above is substituted into the following [Equation 1], the average depth of each structure of the road surface 2 can be calculated, but the road surface 2 structure thus calculated The average depth of can be used as analytical data of the road surface (2).

[Equation 1]

.

.

Here, MTD is the average depth of the texture of the road surface 2 to be obtained by the present invention, V is the volume of the patch particles 4, A is the area of the patch (P).

In the above, the embodiment of the road surface tissue measuring instrument according to the present invention has been described, which is only some examples of various embodiments of the road surface tissue measuring instrument according to the present invention. Various modifications can be made within the scope of the technical idea of the present invention.

1 is a perspective view of a road surface texture measuring instrument according to the present invention.

2 is a cross-sectional view taken along the line A-A of FIG.

3 is a cross-sectional view of the road surface structure before the measurement operation of the present invention.

4 is a cross-sectional view of the road surface structure after the planarization operation of the present invention.

5 is a cross-sectional view of the road surface structure after the patch shaping operation of the present invention.

6 is a schematic view of a patch formed by the present invention.

<Explanation of symbols on main parts of the drawings>

2; Road surface 4; Patch particles

10; Partition member 20; Leveling means

22; Trowel 24; Bracket

30; Shaping means 32; Orthopedic Member

40; Guide 42; Guide rods

50; Transfer means 52; motor

54; Pulley 56; Connecting member

60; Patch length measuring means 62; rater

64; Measuring needle

Claims (14)

A partition member for partitioning a patch forming area of the road surface, into which a volume of patch particles which can be filled in tissue of the road surface is poured; Flattening means installed on the partition member so as to be movable and flattening the patch particles in the partition member; And a shaping means installed on the partition member so as to move the flattened patch particles while being elastically in close contact with the road surface. The method according to claim 1, And the partition member is configured to partition the patch forming area of the road surface into a rectangular shape. The method according to claim 1, The planarization means is a road surface measurement mechanism including at least one trowel provided to be movable in the partition member to spread the patch particles. The method according to claim 3, The plurality of trowels are arranged on a predetermined interval in the movement direction of the trowel, road surface texture measurement mechanism which is moved integrally. The method according to claim 4, The trowel is provided with two road surface texture measuring apparatus arranged at regular intervals in the movement direction of the trowel so that the patch particles can be poured therebetween. The method according to any one of claims 3 to 5, And the width of the trowel is the same as the width of the patch forming zone of the road surface. The method according to claim 1, The shaping means includes at least one shaping member provided to move in the partition member to sweep the patch particles, The shaping member further protrudes toward the road surface than the flattening means, and the road surface texture measuring instrument is a flexible material. The method according to claim 1 or 7, And said shaping means is coupled to said planarizing means in association with said planarizing means. The method according to any one of claims 1,5,7, And a guide for guiding the movement of the planarization means and the shaping means. The method according to claim 9, The guide is fixed to the partition member, the road surface measurement mechanism comprising a guide rod penetrating the planarization means or the shaping means. The method according to any one of claims 1,5,7, The road surface structure measuring apparatus further comprises a conveying means for automatically conveying the flattening means and the shaping means. The method according to claim 11, The conveying means A motor; A pulley rotated by the motor; And a connecting member connecting the pulley with the flattening means or the shaping means. The method according to any one of claims 1,5,7, And a patch length measuring means for measuring the length of the patch along the moving direction of the flattening means and the shaping means. The method according to claim 13, The patch length measuring means comprises a measuring device provided in the partition member, and measuring needles in conjunction with the flattening means or shaping means to indicate the scale of the measuring device.

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