KR20050048059A - Device for measuring a proceeding concrete crack - Google Patents

Abstract

The present invention relates to a crack progress meter of concrete for displaying the progress of cracks generated on the surface of the concrete structure, more specifically, the progress state of the fine crack width by visually displaying the change in the width as the crack width is widened It relates to a concrete crack progress meter that can be easily confirmed.

Crack progress measuring device of the concrete according to the present invention is a crack progress measuring device for measuring the crack progress of the concrete surface, the cantilever shape is bonded to one surface centered on the crack formed on the surface of the concrete structure and cross the crack A main body case having a fixed portion integrally formed therewith; A slide member attached to the other concrete surface around the crack and slidably installed along the bottom of the fixing part; The sensor is installed at the front end of the bottom of the fixing part at predetermined intervals and is installed on the upper surface of the plurality of sensor terminals and the slide member connected to the light emitting devices of different colors, and the predetermined angle so as to sequentially contact the plurality of sensor terminals. A sensor unit comprising a sensor contact plate having an inclined portion thereof; And a power connection terminal and a power connection lead installed on the bottom surface of the fixed part and the top surface of the slide member to apply power to the sensor contact plate and the sensor terminal.

Description

Device for measuring a proceeding concrete crack

The present invention relates to a crack progress meter of concrete for displaying the progress of cracks generated on the surface of the concrete structure, more specifically, the progress state of the fine crack width by visually displaying the change in the width as the crack width is widened It relates to a concrete crack progress meter that can be easily confirmed.

In general, the most influential factor in durability and structural safety in concrete structures is the occurrence of cracks. Since concrete is a material having a lower tensile strength than compressive strength, it is inevitable that cracks occur in concrete structures. The cause of the concrete crack is caused by various causes such as dry shrinkage of the structure, excessive stress or material problems. Some of these concrete cracks do not affect the structural safety of the structure, but some cracks cause structural defects in the structure and ultimately collapse of the structure. Therefore, in order to ensure the safety of concrete structures, the occurrence of cracks must be investigated. Especially, the cracks in progress must be observed with interest.

Accordingly, conventionally, crack progress was measured using a crack cage or a microscope. In the conventional crack investigation, the crack cage is used to measure the crack width or the depth of the crack at a specific point, and after a predetermined time, the crack width at the same point is repeatedly measured to evaluate the progress of the crack. It was done by the method.

However, in the conventional crack inspection method, the measurement width is measured manually by the measurer. Therefore, there may be a large measurement error depending on the measurer. If the measurement point is not accurate, the crack progression cannot be determined. There is a problem in that it is difficult to find the crack in progress quickly because it is judged whether the crack progress by comparing with.

Accordingly, the present invention is to solve the problems of the prior art, the main object of the present invention is that as the crack progresses a plurality of sensor terminals are sequentially in contact with the inclined portion of the sensor contact plate light emitting elements of different colors sequentially It is to provide a crack progress meter of the concrete that can be quickly and accurately judged even by the change of minute cracks by visually displaying the progress of the crack by emitting light.

In order to achieve the above object, the crack progress meter of the concrete according to the present invention is a crack progress meter for measuring the crack progress of the concrete surface,

A body case bonded to one surface of the crack formed on the surface of the concrete structure and integrally formed with a cantilever-shaped fixing part that crosses the crack;

A slide member attached to the other concrete surface around the crack and slidably installed along the bottom of the fixing part;

The sensor is installed at the front end of the bottom of the fixing part at predetermined intervals and is installed on the upper surface of the plurality of sensor terminals and the slide member connected to the light emitting devices of different colors, and the predetermined angle so as to sequentially contact the plurality of sensor terminals. A sensor unit comprising a sensor contact plate having an inclined portion thereof;

And a power connection terminal and a power connection lead installed on the bottom surface of the fixed part and the top surface of the slide member to apply power to the sensor contact plate and the sensor terminal.

Hereinafter, with reference to the accompanying drawings will be described in detail the crack progress meter of the concrete according to the present invention.

First, Figure 1 is a perspective view showing a crack progress meter of concrete according to the present invention, Figure 2 is a perspective perspective view for showing the sensor portion of the crack progress meter shown in Figure 1, Figure 3 is a sensor shown in Figure 2 Negative schematic circuit diagram. As shown, the concrete crack progress measuring instrument 10 of the present invention is largely adhered to one surface centered on the crack (2) formed on the surface of the concrete structure, cantilever-shaped fixing part across the crack (2) The box 20 is formed in the horizontal direction and is bonded to the other concrete surface around the crack 2, and can slide left and right along the bottom surface of the cantilever-shaped fixing part 20. It consists of a slide member 50 installed. At this time, the main body case 30 is provided with a power supply unit 31 consisting of a plurality of batteries, and a switch 16 for turning on / off the power supply unit. In addition, reference numeral 17 is a connection socket for connecting an external buzzer, and 18 is a connection plug for connecting an external power supply. The lower cover 31 is detachably installed on the bottom of the main body case 30 to facilitate the mounting of the built-in power supply.

Subsequently, a guide protrusion 52 having a predetermined height is vertically protruded on one side of the upper surface of the slide member 50, and a predetermined guide groove is formed on the bottom of the fixing part 20 to correspond to the guide protrusion 52. (22) is formed. Therefore, as the width of the crack 20 is widened, the slide member 50 moves horizontally along the guide groove 22 of the fixing part 20. In addition, the upper surface of the fixing portion 20 is provided with a display portion 12 made up of a plurality of light emitting elements (such as LEDs) for indicating the progress of the crack. At this time, the power supply unit 11 is electrically connected to the display unit 12.

As shown in FIG. 2, a connection part 23 is formed on the bottom surface of the tip of the fixing part 20 to protrude downward. On the bottom face of the connecting portion 23 and the top face of the slide member 50, a sensor portion 70 for measuring the progress state of the crack is provided. The sensor unit 70 is provided on the bottom surface of the connecting unit 23 at a predetermined interval and connected to a plurality of sensor terminals 71, 72, 73 and light emitting elements of different colors, and the slide member 50. It is installed on the upper surface of the () consists of a plurality of sensor terminals (71, 72, 73) so as to be sequentially connected to the sensor contact plate 75 formed with an inclination of a predetermined angle.

On the other hand, both ends of the sensor terminals (71) (72) (73) are provided with a power connection terminal (64) electrically connected to the power supply unit (11) of the main body case (30) at a predetermined distance from the slide member. Power supply lead 65 is provided on both sides of the upper surface of the upper surface 50 so as to be always connected to the power supply connection terminal 64. The power supply lead 65 is electrically connected to the sensor contact plate 75. have. The power connection leads 65 provided at both sides are electrically connected to each other. Therefore, when the power switch 16 is turned on, the power connection terminal 64 and the power connection lead 65 form a closed circuit so that a predetermined light enters the power switch 16. On the other hand, when it is necessary to determine the initial position of the sensor contact plate 75, it is preferable to install the zero connection terminal 74 apart from the sensor terminals 71, 72, 73 apart by a predetermined distance. Therefore, in this case, when the power switch 16 is turned on, the power connection terminal 64, the power connection lead 65, the sensor contact plate 75, and the zero connection terminal 74 form a closed circuit, and the power switch 16 ), A predetermined light enters. However, in this initial state, since the sensor terminals 71, 72, 73 are not connected to the sensor contact plate 75, no light emitting element is emitted from the display portion 12.

3 is a schematic circuit diagram showing a circuit configuration of the sensor unit 70 according to the present invention. As shown, the sensor connecting plate 75 is installed to be movable left and right with the slide member 50, the inclined portion 77 inclined at a predetermined angle is formed on one side, the power connection terminal It is electrically connected to the power supply section 11 via the 64 and the power connection lead 65. The sensor terminals 71, 72, and 73 are fixed to the bottom of the fixing part 20 so as to be spaced apart from each other, and are electrically connected to the light emitting devices L1, L2, and L3 having different colors. have. On the other hand, the zero connection terminal 74 is provided at the outermost so as to be spaced apart from the sensor terminals 71, 72, 73 by a predetermined distance and is electrically connected to the power supply unit 11.

Therefore, since the sensor connection plate 75 and the sensor terminal are separated from each other in the initial state, that is, the initial stage where the crack progress measuring instrument 10 according to the present invention is installed, light does not enter the light emitting elements L1, L2, and L3. Subsequently, when the slide member 50 is adjusted to the right to adjust the sensor connecting plate 75 to be in contact with the zero connecting terminal 74, the power switch 16 is turned on so that the zero point can be set and the power is properly applied. You can check if it is coming in.

When the slide member 50 further moves to the right side (arrow direction) as the crack 2 opens after a predetermined time, the inclined portion of the sensor contact plate 75 is connected to the sensor terminals 71 and 72. It is connected to 73 sequentially. Accordingly, the light emitting elements L1, L2, and L3 corresponding to the sensor terminals 71, 72, and 73 are sequentially turned on.

At this time, the power connection terminal 64 is installed to be spaced apart from the sensor terminals 71, 72, 73 and the power connection terminal 65 is installed relatively long so that the slide member 50 is always moved. It is formed to be connectable to the power supply connection terminal 64. And the tip of the sensor terminals 71, 72, 73 are sharply formed to improve the reactivity of the sensor. Therefore, the measurer can easily visually check the progress of the crack without measuring the crack width manually. In addition, a predetermined buzzer 80 may be installed so that a warning sound may be generated when the crack is wider than a set width.

Next, Figure 4 is an exploded perspective view showing another embodiment of the concrete crack progress measuring instrument according to the present invention, as shown, the lower portion of the main body case 30 so that the lower battery can be easily mounted therein The cover 31 is detachably attached with a screw or the like. On the upper surface of the main body case 30, a connection plug 18 for connecting an external power supply 90 through a cable and a connection socket 17 for connecting an external buzzer or a wireless transmitter 80 are provided. have. In addition, a guide protrusion 24 and a guide groove 54 are formed on the bottom surface of the connecting portion 23 and the top surface of the slide member 50 to smoothly guide the movement of the slide member 50. In addition, a predetermined position of the fixing part 20 and the slide member 50 is provided so that the through-hole 28 and the insertion hole 58 through which the zero pin 45 penetrates or is inserted. Therefore, the zero pin 45 is inserted into the through hole 28 and the insertion hole 58 to easily grasp the zero position of the sensor contact plate 75.

4, the upper case 40 and the lower case 60 are provided at upper and lower portions of the main body case 30 and the slide member 50. Therefore, when transporting the crack progress meter 10 of the concrete according to the present invention, the main body case 30 and the slide member 50 are accommodated in the upper and lower cases 40 and 60. And when the crack progress measuring instrument 10 according to the present invention is to be installed on the surface of the concrete structure, using the upper case 40 in a state where the lower case 60 is peeled off, the installation position of the crack progress measuring instrument 10 is accurately grasped. Can give That is, after the adhesive is applied to the concrete surface, the main case 30 and the slide member 50 together with the upper case 40 is firmly adhered to the surface, and then lightly pulls the upper case 40 to measure the crack progression. 10 remains attached to the concrete surface.

1 and 5 will be described the operation of the crack progress measuring device 10 of the concrete according to the present invention. As described above, the main body case 30 and the slide member 50 are adhered to the surface of the concrete structure using the upper case 40, and then the blue light emitting device is turned on by pressing the switch 16 of the main body case 30. The crack progress meter 10 is operated. At this time, if necessary, the reference point is identified using a scale formed on the side surfaces of the connecting portion 23 and the slide member 50.

When the width of the crack 2 becomes wider after a predetermined time, the main body case 30 and the slide member 50 adhered to the concrete surface, respectively, move to both sides. At this time, since the slide member 50 is slidably installed on the bottom of the fixing part 20, the slide member 50 moves to the right in response to the change in the crack width. Then, the sensor unit 70 provided between the bottom surface of the connecting portion 23 and the top surface of the slide member 50 detects the change state of the crack. That is, as shown in FIG. 3, as the slide member 50 moves, the inclined portions of the sensor contact plates 75 are sequentially connected to the sensor terminals 71, 72, and 73 so that the yellow light emitting device L1 is provided. The orange light emitting element L2 and the red light emitting element L3 emit light in this order. Therefore, the measurer can easily visually check the progress of the crack depending on the color of light emitted or the number of light emitting devices. In addition, the buzzer 80 sounds a warning sound when the crack is wider than the set width.

On the other hand, the inclined portion of the sensor contact plate 50

f: width of crack progression gap to be measured

d: gap between sensor terminals

The interval d between the sensor terminals 71, 72 and 73 and the inclination angle of the sensor contact plate using the above equation when determining the interval of the crack 2 to be measured at each crack progression. ) Can be obtained.

As described above, the crack progress measuring device of the concrete according to the present invention, as the slide member moves to the right side in response to the change of the crack width, the inclined portion of the sensor contact plate is connected to the sensor terminal in order to provide light emitting devices of different colors. Since the light is sequentially emitted, the measurer has an effect of visually confirming the progress of the crack according to the color of light emitted or the number of light emitting devices.

In addition, the crack progress meter of the concrete according to the present invention has an effect that can respond quickly because the buzzer sounds a warning when the crack is more than the set width.

1 is a perspective view showing a crack progress meter of concrete according to the present invention;

Figure 2 is an exploded perspective view showing the part of the sensor of the crack progress meter of concrete according to the present invention,

3 is a schematic circuit diagram showing a circuit configuration of a sensor unit shown in FIG. 2;

Figure 4 is an exploded perspective view showing another embodiment of the crack progress measurement of concrete according to the present invention,

5 is a perspective view showing the action of the crack progress meter of concrete according to the present invention.

***** Description of the symbols for the main parts of the drawings ******

11 power supply unit 12 display unit

10: main body case 20: fixed part

23 connection part 40 upper case

50: slide member 64: power connection terminal

65: power connection wire 70: sensor

71, 72, 73: sensor end 75: sensor contact plate

80: buzzer 90: external power

Claims (4)

In the crack progress meter of concrete for measuring the crack progress of the concrete surface, A body case bonded to one surface of the crack formed on the surface of the concrete structure and integrally formed with a cantilever-shaped fixing part that crosses the crack; A slide member attached to the other concrete surface around the crack and slidably installed along the bottom of the fixing part; The sensor is installed at the front end of the bottom of the fixing part at predetermined intervals and is installed on the upper surface of the plurality of sensor terminals and the slide member connected to the light emitting devices of different colors, and the predetermined angle so as to sequentially contact the plurality of sensor terminals. A sensor unit comprising a sensor contact plate having an inclined portion thereof; And a power connection terminal and a power connection lead installed on a bottom surface of the fixed part and an upper surface of the slide member to apply power to the sensor contact plate and the sensor terminal. The method of claim 1, A guide protrusion of a predetermined height is vertically inclined on one side of the upper surface of the slide member, and a predetermined guide groove is formed on the bottom of the fixing part to correspond to the guide protrusion. The method of claim 1, A connection part is formed to protrude downwardly at the bottom end of the fixing part, and a plurality of sensor terminals are installed on the bottom of the connection part so as to be spaced apart from each other, and power connection terminals are installed at both ends so as to be spaced apart from the sensor terminal. Crack Progress Meter in Concrete. The method of claim 1 or 3, The concrete crack progress measuring device, characterized in that a predetermined buzzer is connected to any one of the sensor terminals so as to sound an alarm when the crack is wider than the set width.