KR20110056031A - Installed on the underwater structure for measuring the wear of the concrete - Google Patents

Abstract

PURPOSE: A structure for measuring the wear of underwater concrete is provided to test the wear resistance of an underwater concrete structure against water hammering by quantitatively and objectively measuring the amount of wear caused by scour. CONSTITUTION: A structure for measuring the wear of underwater concrete comprises a fixed element(100) and a mobile element(200). The fixed element is fixed in a field where an underwater concrete structure is placed. The mobile element is loaded with a concrete specimen(220) for testing the wear of concrete and removably installed on the fixed element. The fixed element comprises a fixing member, an L-shaped support unit(104), and a connection bar(106).

Description

Installed on the underwater structure for measuring the wear of the concrete}

The present invention relates to a structure for measuring the amount of wear of concrete in water, and more specifically, to be installed at a site having the same conditions as concrete poured in water so that the concrete shows the wear rate of the concrete by the flowing water from time to time to analyze and analyze. The present invention relates to a structure for measuring the wear rate of underwater concrete.

Most of the concrete is poured into the discharge channel or the channel around the bottom of the dam where the water discharged from the dam flows.

Underwater concrete poured in such a flow path is exposed to flowing water for a long time, the surface is gradually worn out by the water. As the concrete wears out, concrete cracking, swelling, and partial detachment occur, which degrades performance and deteriorates water quality. There is a need to manage these concrete structures safely and efficiently.

In order to reduce the wear rate, a surface treatment method using chemical resin is sometimes applied to the concrete surface, but such a construction method has a high construction cost problem.

So it is very important to find the best concrete for the flowing environment.

In case of deterioration of concrete structure, it should be repaired or replaced promptly to prevent accidents.

However, in order to analyze the wear rate of underwater concrete, a worker penetrates directly into the site and grasps the condition of the concrete that has been poured underwater, or photographs the concrete floor by using imaging equipment. It is not easy to grasp the characteristics according to the water-repairing material and state, and it is not possible to cope with various damage appropriately.

This requires a system that can accurately and efficiently analyze the wear rate of underwater concrete. To date, this technique of underwater concrete wear rate analysis has not been proposed. There are also few guidelines and regulations related to aquatic structures around the world.

The present invention has been proposed in order to solve the problems described above, so that it can be frequently identified and analyzed how much wear rate of the concrete by the flowing water installed on the site having the same conditions as the concrete placed in water The State intends to provide structures for measuring the wear rate of underwater concrete.

In addition, the present invention is exposed to the water outlet of the actual water shock outlet to test the wear resistance of the water concrete structures, including dam facilities, so that the amount of wear to scour can be measured quantitatively and objectively The State intends to provide structures for measuring the wear rate of underwater concrete.

The present invention has the following means to solve the above problems.

The present invention is a fixed body 100 is fixedly installed on the site where the concrete is poured; The movable body 200 detachably installed in the fixed body 100 in a state in which the concrete test body 220 for testing the amount of concrete wear is mounted.

The fixed body is a rectangular lower plate (102); A lower plate fixture 108 for fixing the lower plate 102 to underwater concrete; L-shaped support 104 extending in a direction perpendicular to the surface at each corner of the lower plate 102; And a connecting bar 106 connecting the two L-shaped support members 104 formed in the longitudinal direction, respectively.

The movable body 200, a plurality of concrete test body 220 having a cylindrical shape; A frame portion 210 in which a space is partitioned so that each concrete test specimen 220 is mounted; A test body fixture 202 for fixing the concrete test body 220 to the frame portion 210; is provided.

The movable body 200 is fixed by the frame bar (218) for coupling the upper frame 214 of the connecting bar 106 and the frame portion 210 of the fixed body 100 to each other.

The test fixture fixture 202, the rod 230 is installed in the longitudinal direction of the frame portion 210 while pressing the upper surface of each concrete test specimen 220; A rod fixture 204 for fixing both ends of the rod 230 to the upper frame 214 of the frame portion 210 of the movable body 200; And a wire 216 fixed to both sides of the upper frame 214 of the frame part 210 while wrapping the outer side of the rod 230.

Each of the concrete test body 220 is characterized in that made of the same material as the concrete poured in the field.

Each concrete test body 220 is characterized in that made of different materials.

The present invention makes it possible to know quantitatively the damage to scour against water impact of underwater concrete.

In addition, the present invention is to grasp the characteristics according to the respective water-repairing materials and conditions to properly deal with various damages to safely and efficiently maintain the facilities.

In addition, the present invention makes it possible to easily prove the scale or shape of damage to scour of the underwater concrete structure without directly entering the water poured concrete.

The present invention will also make a significant contribution to increasing the efficiency of dam construction underwater inspection, repair reinforcement research or development of underwater repair materials.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment according to the present invention.

1 is an exploded perspective view of the structure for measuring the wear rate of the underwater concrete according to the invention, Figure 2 is a combined perspective view of the movable body shown in Figure 1, Figure 3 is a perspective view of the structure shown in Figure 1, Figure 4 The actual installation state diagram of the structure according to the invention.

Underwater concrete wear rate measurement structure according to the present invention can be analyzed in an accurate and easy way to the extent that the underwater concrete is worn by the flowing water installed on the site to have the same conditions as the concrete placed in the dam discharge or other water flow paths It is applied to underwater structures that make it possible.

As shown in the present invention, the fixed body 100 is fixedly installed on the underwater concrete and the movable body 200 is detachably installed on the fixed body 100, the movable body 200 is wear rate of underwater concrete It comprises a concrete test body 220 and a frame part 210 on which the concrete test body 220 is mounted, and a test fixture fixture 202 for fixing the concrete test body 220 to the frame part 210. do.

Underwater concrete wear rate measurement structure of the present invention can be installed to have a variety of angles with respect to the water flow direction on the outlet or the flow path as shown in FIG.

The fixture 100 may be installed using an anchor bolt or the like in the underwater concrete pouring site, it may be fixed to the site after the underwater concrete pouring as necessary. The fixture 100 is preferably fixedly installed in the underwater concrete to withstand up to the instantaneous maximum discharge water pressure.

The movable body 200 is installed through various fastening means to facilitate installation and removal on the stationary body 100. In the present specification, the wire is used as an example to fix the movable body 200 to the fixed body 100, but the method of fixing the movable body 200 to the fixed body 100 is not limited to the wire and various fixed Means may be used.

The movable body 200 is installed in the fixed body 100 in a state where the concrete test body 220 for testing the amount of concrete wear is mounted.

More specifically, the fixing body 100 is a rectangular bottom plate 102 and a lower plate fixture 108 for fixing the lower plate 102 to underwater concrete, the direction perpendicular to the surface at each corner of the lower plate 102. The connection bar 106 is connected to each of the L-shaped support 104 extending in the direction and the two L-shaped support 104 formed in the longitudinal direction facing each other is included.

Holes 102a are formed on the edges of the lower plate 102 at predetermined intervals, and the lower plate fasteners 108 are inserted into the holes 102a to fix the lower plate 102 to underwater concrete. The lower plate fixing member 108 may be used to fix the lower plate 102 by inserting it deep into the concrete poured through the hole 102a.

The connecting bar 106 is for connecting and supporting a pair of L-shaped support portions 104 which are formed to face each other in the longitudinal direction, and at the same time to support the movable body 200. Holes are formed at predetermined intervals on the sides thereof. The connecting ring 106 is formed. The link ring 106a is formed to correspond to the link ring 206a formed on the side of the movable body 200, and the link rings 106a and 206a thus formed are coupled to each other through the fixture 218 to fix it. The movable body 200 is fixed to the 100. Here, the fixing part 218 is preferably a bolt and nut type.

The movable body 200 is configured to be provided with a concrete test body 220, a frame portion 210, and a test body fixture 202.

The concrete test body 220 preferably has a smooth curved surface so as to be similar to the resistance value of the poured underwater concrete flows.

The concrete test body 220 may be made of the same material as the underwater concrete poured on the site, it may be made of different materials. When the concrete test specimen 220 is made of the same material as the underwater concrete, it is efficient to install a smaller number of the concrete test specimen 220. When the concrete test specimen 220 is made of a different material from the underwater concrete, it can be used to analyze the optimal concrete components on the site by mounting a plurality of concrete test specimens of various materials together.

The frame portion 210 is provided with a predetermined space is partitioned so that a plurality of concrete specimens 220 can be mounted, the lower frame 212 has a plate shape, the upper frame 214 has a ladder shape. . The lower frame 212 and the upper frame 214 are provided with a partition 212a and a space partition bar 214a at positions facing each other, respectively, and are divided into spaces defined by the partition 212a and the space partition bar 214a. Each concrete test body 220 is mounted.

As shown in FIG. 2, the test piece fixture 202 fixes the concrete test piece 220 to the frame part 210, and presses the upper surface of each concrete test piece 220 while pressing the frame part 210. Rod 230 is installed in the longitudinal direction of the rod fixing rod 204 for fixing both ends of the rod 230 to the upper frame 214 of the frame portion 210 of the movable body 200, the rod 230 The wire 216 fixed to both sides of the upper frame 214 of the frame portion 210 is formed while wrapping the outside of the.

The rod 230 presses the upper surface of each concrete specimen 220 to fix the plurality of concrete specimens 220 mounted on the frame portion 210 so as not to be separated from the frame portion 210. Connection rings 230a and 230b are formed at both ends of the 230, and the connection rings 230a and 23b are formed at both ends of the upper frame 214 of the frame portion 210. Is coupled to the rod through the fixture 204, the rod 230 is fixed to the frame portion 210 is prevented from being separated from the concrete test body 220.

Here, the rod fixture 204 is one side is fixed to the connecting ring (230a, 230b) of the rod 230, it is preferable that the bolt and nut type that the other side can be screwed, frame portion 210 ) And other types of fixing means for fixing the rod 230, for example, may be made of only wire.

The wire 216 is to press the rod 230 so that the concrete test body 220 is more firmly fixed to the frame portion 210, one side is formed on both sides of the upper frame 204, the connecting ring 214b It is preferably fixed to any one of the other side is preferably configured in the bolt and nut type to facilitate the coupling and separation by the user. Here, the wire 216 is provided by way of example, various types of fixing means may be used.

The movable body 200 is fixedly coupled by a frame fixture 218 which mutually couples the connecting bar 106 of the fixture 100 and the upper frame 214 of the frame portion 210. The connecting ring 106a formed at predetermined intervals in the connecting bar 106 and the connecting ring 206a formed at the side of the upper frame 214 are formed to match when the movable body 200 is seated on the fixed body 100. As such, both matching links 106a and 206a formed in this manner are coupled through the frame fixture 218 to fix the movable body 200.

It is important that the structure for measuring the wear rate of underwater concrete wear rate of the present invention is fixed so as not to deviate from the discharge water pressure, and the surface is exposed as much as possible so that wear can be performed well under the same conditions as underwater concrete in the field.

The installation / release and wear rate measurement process of the present invention configured as described above are as follows.

1. Install the fixture 100 in the outlet water.

2, the concrete test body 220 is mounted on the movable body 200.

3. The movable body 200 is moved to the fixed body 100 and fixed.

4. The structure of the present invention is exposed to water shock for a period of time.

5. The movable body 200 is separated from the fixed body 100.

6. Move the separated movable fan 200 to the land.

7. Remove the concrete specimen 220 from the movable body 200.

8. Measure the concrete specimen 220 with a balance.

9. After the measurement is finished, insert the concrete test body 220 into the movable body 200 and fix it to the underwater fixed body 100.

As described above, the present invention is to quantitatively and objectively measure the amount of wear caused by scour through exposure to the water outlet where the actual water shock is generated in order to test the abrasion resistance of water concrete structures including dam facilities It allows you to do it.

The above description is merely illustrative of the technical spirit of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention.

Therefore, the embodiments disclosed in the present invention are not intended to limit the technical spirit of the present invention but to explain, and the scope of the technical spirit of the present invention is not limited by these embodiments.

In addition, the protection scope of the present invention should be interpreted by the claims below, and all technical thoughts within the equivalent scope should be construed as being included in the scope of the present invention.

1 is an exploded perspective view of a structure for measuring the wear rate of underwater concrete according to the present invention.

2 is a perspective view of the movable body shown in FIG.

3 is a combined perspective view of the structure shown in FIG.

Figure 4 is an actual installation state of the structure according to the invention.

* Brief description of the main parts of the drawings

100: fixed body 102: lower plate

102a: fixture hole 104: L-shaped support

106: connecting bar 106a: connecting ring

108: bottom plate fixture

200: movable body 206a: connecting ring

210: frame portion 210a: rod connecting ring

212 lower frame 212a partition wall

214: upper frame 214a: space partition bar

214b: Hook 216: Wire

216a: fixed bolt 220: concrete test specimen

230: rod 230a, 230b: connecting ring

Claims (7)

Fixture 100 is fixed to the site where the concrete is poured underwater; A movable body 200 detachably installed in the fixed body 100 in a state in which a concrete test body 220 for testing the amount of concrete wear is mounted; Underwater concrete wear rate measurement structure is provided. The method of claim 1, The fixture is, Rectangular bottom plate 102; A lower plate fixture 108 for fixing the lower plate 102 to underwater concrete; L-shaped support 104 extending in a direction perpendicular to the surface at each corner of the lower plate 102; A connection bar 106 connecting the two L-shaped support portions 104 formed to face each other in the longitudinal direction; Underwater concrete wear rate measurement structure is provided. The method of claim 1, The movable body 200, A plurality of concrete test specimens 220 having a cylindrical shape; A frame portion 210 in which a space is partitioned so that each concrete test specimen 220 is mounted; A test fixture fixture 202 for fixing the concrete test specimen 220 to the frame portion 210; Underwater concrete wear rate measurement structure is provided. The method of claim 3, wherein The movable body 200 is fixed by means of a frame fixture 218 for coupling the upper frame 214 of the connecting bar 106 and the frame portion 210 of the fixture 100 to each other; Structure for measuring concrete wear rate. The method of claim 3, wherein The test fixture fixture 202, Rod 230 is installed in the longitudinal direction of the frame portion 210 while pressing the upper surface of each concrete test body 220; A rod fixture 204 for fixing both ends of the rod 230 to the upper frame 214 of the frame portion 210 of the movable body 200; Wires 216 fixed to both sides of the upper frame 214 of the frame portion 210 while wrapping the outer side of the rod 230; Underwater concrete wear rate measurement structure, characterized in that is provided. The method of claim 3, wherein Each concrete test body 220 is a structure for measuring the wear rate of underwater concrete, characterized in that made of the same material as underwater concrete poured on the site. The method of claim 3, wherein Each concrete test specimen 220 is a structure for measuring the wear rate of underwater concrete, characterized in that made of different materials.

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