KR102041364B1 - Safety Diagnostics Unit for Checking the Crack Length of Structures - Google Patents

Abstract

The present invention relates to a safety diagnosis device for checking a crack length of structures, comprising: a measurement unit (10) for performing a safety diagnosis by photographing a crack of a structure with a camera (12); a housing (32) installed on the camera (12) side of the measurement unit (10) to prevent inflow of rainwater by finishing a gap between the measurement unit (10) and the structure, and preventing the inflow of rainwater by finishing the gap between the measurement unit (10) and the structure; a sealing unit (100) installed on an edge of the housing (32); a waterproof unit (30) including a vacuum pump (38) installed in a drain pipe (36) connected to a drain hole (34) formed in the housing (32); an elevating unit (50) for performing a safety diagnosis on an upper part of the structure which a worker does not reach by elevating the measurement unit (10); a wireless communications unit (80) for transferring an operation signal of the worker to the measurement unit (10) such that the worker grabbing a lower end of the elevating unit (50) can drive the measurement unit (10); a vacuum providing unit (110) for preventing inflow of rainwater to a measurement space between the housing (32) and the structure by providing a vacuum pressure to a sealed space between the housing (32) and an outer wall of the structure which the housing (32) is in close contact with; and a fluid supply unit (130) for allowing an end of the housing (32) and the outer wall of the structure to come in close contact with each other by supplying the vacuum pressure discharged from the measurement space between the housing (32) and the structure to the sealing unit (100).

Description

Safety Diagnostics Unit for Checking the Crack Length of Structures}

The present invention relates to a safety diagnosis device for checking the crack length of a structure, and more particularly, the operator can easily carry and carry out the measurement work by moving easily to the location out of reach of the operator and perform the measurement work in the rain. The present invention relates to a safety diagnosis device for checking the crack length of a structure that can prevent malfunctions in which accurate crack measurement cannot be made by rainwater, and prevent rainwater from entering the gap between the outer wall of the building and the measuring device. .

In general, the cause of the cracking of the structure is caused by various causes, such as dry shrinkage of the structure, excessive stress or material problems.

Some of these cracks do not affect the structural safety of the structure, but some cracks cause structural defects in the structure and eventually result in collapse of the structure.

Therefore, in order to ensure the safety of the structure, it is necessary to investigate the occurrence of cracks, and in particular, the cracks in progress must be observed precisely and carefully.

However, there are many places where concrete-related facilities have insufficient lighting facilities such as the underground or access by using auxiliary equipment, such as ladders, rather than in a convenient location. After holding the cracker and the magnifying glass in both hands, the lighting is inconvenient for work such as attaching to the hat or using a separate lighting device, and the volume of the equipment is not easy to carry. There was a problem that the follow-up work was not systematic when the visual inspection was conducted without a rough outline.

Background art of the present invention is disclosed in Republic of Korea Patent Publication No. 10-0788230 (December 26, 2007, the name of the invention: portable crack measuring device for structure inspection).

The crack measuring device according to the prior art is difficult to accurately photograph the cracks as the rain passes between the cracks and the measuring device when the measurement work is made in rainy weather, and the operator separates the cracks when the crack is located at a high position out of reach of the worker. There is a problem that should be performed after the installation of the structure of the measurement.

Therefore, there is a need for improvement.

The present invention can be easily carried by the operator to easily move to a location out of reach of the operator to perform the measurement work and can prevent malfunctions that do not make accurate crack measurement by excellent when performing the measurement work in rainy weather. The purpose of the present invention is to provide a safety diagnosis device for checking the crack length of a structure that can prevent the rainwater from entering the gap between the outer wall of the building and the measuring device.

The present invention, the measurement unit 10 for performing a safety diagnosis by photographing the crack of the structure with the camera 12; It is installed on the camera 12 side of the measuring unit 10 to close the interval between the measuring unit 10 and the structure to prevent the rain flows and closes the interval between the measuring unit 10 and the structure Housing 32 to prevent rainwater from entering; A sealing part 100 installed at an edge of the housing 32; A waterproof part 30 including a vacuum pump 38 installed in the drain pipe 36 connected to the drain hole 34 formed in the housing 32; Lifting unit 50 for elevating the measuring unit 10 to perform a safety diagnosis on the upper part of the structure that the operator's hands do not reach; A wireless communication unit 80 which transmits an operator's operation signal to the measurement unit 10 so that an operator who holds the lower end of the elevating unit 50 can drive the measurement unit 10; Vacuum providing unit for providing a vacuum pressure to the sealed space between the outer wall of the structure and the housing 32 that the housing 32 is in close contact with the housing 32 and the measurement space between the housing 32 and the structure ( 110); It includes a fluid supply unit 130 for supplying a vacuum pressure discharged from the measurement space between the housing 32 and the structure to the sealing unit 100 so that the end of the housing 32 and the outer wall of the structure is in close contact with each other. It features.

In addition, the lifting unit 50 of the present invention, the first pillar portion 52 which is detachably supporting the measurement unit 10 is formed long in the vertical direction and the rack portion 56 is formed; And a second pillar 54 slidably inserted into the first pillar 52 and rotatably installed by the lever member 58 with a pinion 57 gearably connected to the rack 56. Characterized in that.

In addition, the wireless communication unit 80 of the present invention is generated from the second operation unit 84 provided at the lower end of the first operation unit 82 or the second column 54 provided in the measurement unit 10. A wireless transmitter 86 for transmitting an operation signal; And a wireless receiver 88 which receives an operation signal transmitted from the wireless transmitter 86 and transmits a driving signal to the measurement unit 10.

In addition, the edge of the housing 32 of the present invention is formed with a recess groove 112 in a concave inward direction from the front, the edge of the housing 32 is the outer wall portion 114 by the spacer groove 112. And an inner wall portion 116, and an installation groove 117 is formed at an end of the outer wall portion 114 and an end of the inner wall portion 116, respectively, so that the sealing portion 100 is installed. .

The safety diagnosis device for checking the crack length of a structure according to the present invention includes a waterproof part for maintaining a vacuum state between the measuring part and the structure, so that the measuring part is generated while rain is passed between the measuring part and the structure when measuring the crack. Malfunctions can be prevented and there is an advantage that accurate crack measurement can be performed in rainy weather.

In addition, the safety diagnosis device for checking the crack length of the structure according to the present invention, by the driving of the lifting unit can be measured by raising the measuring unit to a high position where the crack is placed, it is easy to perform the crack measurement without installing a separate structure There is an advantage to that.

In addition, the safety diagnosis device for checking the crack length of the structure according to the present invention, by providing a vacuum between the building outer wall and the waterproof portion is provided with a vacuum providing portion to be in close contact with the outer wall of the building, and is discharged by the operation of the vacuum providing unit Since the fluid is supplied to the sealing part provided in the waterproof part, the waterproof part is in close contact with the outer wall of the building, thereby preventing the rainwater from flowing into the measurement space, thereby providing more accurate crack measurement.

1 is a perspective view showing a safety diagnosis device for checking the crack length of a structure according to an embodiment of the present invention.
2 is a perspective view illustrating a waterproof part, a sealing part, a vacuum providing part, and a fluid supply part of the safety diagnosis device for checking crack length of a structure according to an exemplary embodiment of the present invention.
3 is a block diagram showing the waterproof portion, the vacuum providing portion and the fluid supply portion of the safety diagnosis device for checking the crack length of the structure according to an embodiment of the present invention.
4 is a cross-sectional view showing a waterproof part, a vacuum providing part, a cylinder part, and a fluid supply part of the safety diagnosis device for checking crack length of a structure according to an exemplary embodiment of the present invention.
5 is a block diagram showing a safety diagnosis device for checking the crack length of the structure according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of the safety diagnosis device for checking the crack length of the structure according to the present invention.

In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description.

In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or custom.

Therefore, the definitions of these terms should be made based on the contents throughout the specification.

1 is a perspective view showing a safety diagnosis device for checking the crack length of the structure according to an embodiment of the present invention, Figure 2 is a waterproof portion of the safety diagnosis device for checking the crack length of the structure according to an embodiment of the present invention, 3 is a perspective view showing a sealing part, a vacuum providing part, and a fluid supply part, and FIG. 3 is a block diagram showing a waterproof part, a vacuum providing part, and a fluid supply part of a safety diagnosis device for checking a crack length of a structure according to an exemplary embodiment of the present invention. to be.

4 is a cross-sectional view illustrating a waterproof part, a vacuum providing part, a cylinder part, and a fluid supply part of a safety diagnosis device for checking crack length of a structure according to an exemplary embodiment of the present invention, and FIG. 5 is an embodiment of the present invention. The safety diagnosis device for checking the crack length of the structure according to the block is shown.

1 to 5, the safety diagnosis device for checking the crack length of the structure according to an embodiment of the present invention, the measurement unit 10 for taking a safety diagnosis by photographing the crack of the structure with a camera 12, It is installed on the camera 12 side of the measuring unit 10 to close the gap between the measuring unit 10 and the structure to prevent the rain flows and closes the gap between the measuring unit 10 and the structure to enter the rainwater Vacuum pump is installed in the housing 32, the sealing portion 100 is installed on the edge of the housing 32, and the drain pipe 36 connected to the drain hole 34 formed in the housing 32 to prevent The lifting portion 50 including the waterproof portion 30, the lifting portion 50 for elevating the measuring portion 10 to perform a safety diagnosis on the upper part of the structure which is not reachable to the operator, and the lifting portion 50 The operator's operation signal is transmitted to the measuring unit 10 so that the operator who catches the lower end can drive the measuring unit 10. Is to provide a vacuum pressure in the sealed space between the outer wall of the structure and the housing 32 is in close contact with the wireless communication unit 80 and the housing 32 to prevent rainwater from entering the measurement space between the housing 32 and the structure. The fluid supply unit for supplying a vacuum pressure discharged from the measuring space between the vacuum providing unit 110 and the housing 32 and the structure to the sealing unit 100 to the end of the housing 32 and the outer wall of the structure ( 130).

Since the lens of the Carrera is installed on the front surface of the measurement unit 10, the camera 12 may be operated by arranging the measurement unit 10 so that the cracks face the front surface of the measurement unit 10, and then operating the first operation unit 82. The cracks are measured while the technical configuration of the measuring unit 10, etc. is driven.

In the case of measurement in rainy weather, the housing 32 is placed in close contact with the structure, and then the first operation part 82 is operated to drive the waterproof part 30 to drain air and moisture at a distance between the structure and the reds. After discharging through the hole part 34, a crack measuring operation is performed.

Therefore, the rainwater is prevented from passing between the lens and the crack of the camera 12, thereby suppressing a malfunction in which the crack is not accurately measured by the rainwater.

The lifting unit 50 is detachably supporting the measuring unit 10 and is formed to be elongated in the vertical direction, and is slidable to the first column 52 and the first column 52 where the rack unit 56 is formed. The pinion 57, which is inserted into the rack and is connected to the rack 56, includes a second pillar 54 that is rotatably installed by the lever member 58.

In the case of measuring a crack in a high place out of reach of an operator, the pinion 57 rotates when the lever member 58 is rotated after the measuring part 10 is press-fitted to the upper end of the first pillar part 52. While raising the rack portion 56 connected to the gear to the upper side as the first pillar 52 is raised to increase the measuring unit 10.

As described above, when the operator operates the second manipulation unit 84 provided at the lower end of the second pillar 54 after raising the first pillar 52, the operation signal is generated by the operation of the wireless communication unit 80. Since it is transmitted to the measuring unit 10 and the waterproof unit 30, it is possible to measure the crack of the high position out of reach of the operator.

The wireless communication unit 80 transmits an operation signal generated from the second operation unit 84 provided at the lower end of the first operation unit 82 or the second column 54 provided in the measurement unit 10. 86 and a wireless receiver 88 which receives an operation signal transmitted from the wireless transmitter 86 and transmits a drive signal to the measurement unit 10.

Therefore, the operation signal generated by the second operation unit 84 is received by the wireless receiving unit 88 by the wireless transmitting unit 86, and according to the driving signal transmitted from the door forwarder unit of the measuring unit 10 and the waterproof unit 30 The vacuum pump 38 is driven to perform the measurement as described above.

In the present proposal, the measuring unit 10 is detachably installed at the upper end of the first pillar 52 by the detachable unit 70, and the detachable unit 70 is perpendicular to the lower end of the measuring unit 10. The guide groove portion 72 is formed to be long, the hook member 74 is installed so as to emerge from the guide groove portion 72 in the inward direction of the measuring portion 10, and formed on the other end of the hook member 74 and the measuring portion ( 10) the lever member 75 disposed to be protruded to the outside, the elastic member 76 interposed between the hook member 74 and the inner wall of the measuring part 10, and the guide groove portion on the upper end of the first pillar portion 52. It includes a rail 77 is formed to be inserted when sliding to the 72, and the locking groove 78 is formed on the rail 77, the hook member 74 is engaged.

Accordingly, when the measuring unit 10 is coupled to the upper end of the first pillar 52, the upper end of the first pillar 52 is inserted into the lower end of the measuring unit 10 so that the rail 77 guides 72. While pressing along the inclined surface formed on the hook member 74 while being inserted along the compression of the elastic member 76, when the rail 77 is fully inserted along the guide groove 72, the hook by the restoring force of the elastic member 76 As the member 74 protrudes, the member 74 is inserted into the locking groove 78 to engage the measurement unit 10 and the first pillar 52.

Since the sealing part 100 is installed at the edge of the housing 32 of the present proposal, when the vacuum pump 38 is driven after the housing 32 is in close contact with the wall of the structure, the structure, the measuring part 10 and the housing 32 By discharging both air and moisture from the inside of the space formed by this, accurate crack measurement can be performed.

A gap groove 112 is formed in the edge of the housing 32 in a concave direction from the front side, and the edge of the housing 32 is divided into an outer wall portion 114 and an inner wall portion 116 by the gap groove portion 112. The installation grooves 117 are formed at the ends of the outer wall 114 and the ends of the inner wall 116, respectively, and the sealing unit 100 is installed.

The sealing part 100 of the present proposal includes a first tube 102 protruding from the installation groove 117 formed in the outer wall 114 and an installation groove 117 formed in the inner wall 116. And a second tube 104 protruding from the housing, and the fluid discharged from the inside of the housing 32 by the operation of the fluid supply part is filled in the first tube 102 and the second tube 104, (32) It protrudes outward, and the vacuum pressure is provided to the gap between the first tube 102 and the second tube 104 by the operation of the vacuum providing unit 110, so that the edge of the housing 32 is formed on the outer wall of the structure. While being in close contact with each other, it is possible to effectively prevent rainwater from flowing into the housing 32.

The vacuum hose 118 is connected to the inner end of the installation groove 117 to drive rain and air from the space between the outer wall 114 and the inner wall 116 by driving the vacuum pump 38. By discharging to provide a vacuum pressure to close the housing 32 edge to the outer wall of the structure.

The fluid supply unit 130 of the present proposal is installed in a drain pipe extending from the vacuum pump 38 to discharge rainwater, the valve member 132 for converting the discharge direction of the discharged fluid to the sealing unit 100 side, and the valve And a circulation supply pipe 134 extending from the member 132 and connected to the first tube 102 and the second tube 104.

The circulation supply pipe 134 includes a first supply pipe 136 connected to the first tube 102 and a second supply pipe 138 connected to the second tube 104, so that the gap groove part is formed by the vacuum pump 38. Rainwater and air discharged from the 112 are filled in the first tube 102 and the second tube 104 along the first supply pipe 136 and the second supply pipe 138 through the valve member 132 and the housing. (32) A pair of tubes protrude outwardly from the rim to maintain a spacing, whereby rain and air are expelled from the gap between the pair of tubes to provide a vacuum pressure in which the pair of tubes adhere to the outer wall of the structure. Done.

As a result, the operator can easily carry and easily move to a position out of reach of the operator to perform the measurement work, and can prevent malfunctions that do not make accurate crack measurement by rain when performing the measurement work in rainy weather, It is possible to provide a safety diagnosis device for checking the crack length of the structure that can prevent the rainwater from entering the gap between the outer wall of the building and the measuring device.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and various modifications and equivalent other embodiments are possible to those skilled in the art. Will understand.

In addition, the safety diagnosis device for checking the crack length of the structure has been described as an example, but this is merely exemplary, and the safety diagnosis device of the present invention may be used in other products other than the safety diagnosis device for checking the crack length of the structure.

Therefore, the true technical protection scope of the present invention will be defined by the claims below.

10: measuring part 30: waterproof part
50: lifting unit 70: detachable
80: wireless communication unit 100: sealing unit
102: first tube 104: second tube
110: vacuum providing unit 112: gap groove
114: outer wall portion 116: inner wall portion
117: mounting groove 118: vacuum hose
119: vacuum pump 130: fluid supply
132: valve member 134: circulation supply pipe
136: first supply pipe 138: second supply pipe

Claims (4)

Measuring unit 10 for taking a safety diagnosis by photographing the crack of the structure with the camera 12;
It is installed on the camera 12 side of the measuring unit 10 to close the interval between the measuring unit 10 and the structure to prevent the rain flows and closes the interval between the measuring unit 10 and the structure Housing 32 to prevent rainwater from entering;
A sealing part 100 installed at an edge of the housing 32;
A waterproof part 30 including a vacuum pump 38 installed in the drain pipe 36 connected to the drain hole 34 formed in the housing 32;
Lifting unit 50 for elevating the measuring unit 10 to perform a safety diagnosis on the upper part of the structure that the operator's hands do not reach;
A wireless communication unit 80 which transmits an operator's operation signal to the measurement unit 10 so that an operator who holds the lower end of the elevating unit 50 can drive the measurement unit 10;
Vacuum providing unit for providing a vacuum pressure to the sealed space between the outer wall of the structure and the housing 32 in which the housing 32 is in close contact with the housing 32 and the measurement space between the housing 32 and the structure ( 110);
And a fluid supply unit 130 supplying a vacuum pressure discharged from the measurement space between the housing 32 and the structure to the sealing unit 100 so that the end of the housing 32 and the outer wall of the structure are in close contact with each other.
The lifting unit 50,
A first pillar portion 52 detachably supporting the measurement portion 10 and extending in the vertical direction and having a rack portion 56 formed thereon; And
The pinion 57 slidably inserted into the first pillar portion 52 and gear-connected with the rack portion 56 includes a second pillar portion 54 rotatably installed by the lever member 58. ,
The wireless communication unit 80,
A wireless transmitter (86) for transmitting an operation signal generated from a first operator (82) installed at the measurement unit (10) or a second operator (84) installed at a lower end of the second pillar (54); And
And a radio receiver 88 which receives an operation signal transmitted from the radio transmitter 86 and transmits a driving signal to the measurement unit 10.
An interval groove portion 112 is formed in the edge of the housing 32 in a concave direction from the front surface, and the edge of the housing 32 is formed by the outer groove portion 112 and the inner wall portion 116 by the interval groove portion 112. The crack length check of the structure, characterized in that the installation grooves 117 are formed at the end of the outer wall portion 114 and the end of the inner wall portion 116, respectively, and the sealing portion 100 is installed. Safety diagnostic device. delete delete delete

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