KR102022201B1 - Scaffolding system - Google Patents

Abstract

According to one embodiment of the present invention, a scaffolding system includes: a plurality of support pillars installed in a direction adjacent to a building and vertical to the ground; furring strips respectively connected in a direction vertical to the longitudinal direction of the support pillars; and a rotating unit positioned between the furring strips and having a bucket moving from an upper end of the support pillar to a lower end thereof in a space between the building and the support pillar.

Description

Scaffolding System {SCAFFOLDING SYSTEM}

The present invention relates to a scaffolding system.

In general, scaffolding system is a construction installed to work in high places when constructing a building.It is a construction platform that allows workers to work in and out of industrial sites such as construction, building, or people, equipment, It means a temporary structure that can be used to work on materials. Such scaffolding systems are commonly used to renovate, repair, cement or paint the exterior walls of buildings.

A general scaffolding system is provided with a steel pipe scaffold that forms a frame using connecting members such as clamps or fasteners, and some components of the scaffold frame are completed, so that the scaffolding can be easily assembled or disassembled. System scaffolding and the like are used.

Steel scaffolding is usually installed with vertical materials, horizontal materials, handrails, crossbars, scaffolding, vertical protection nets, clamps and connecting pins as assembly members. Since it is standardized and assembled through, it is easy to assemble and relatively safe because it eliminates the process of lifting each subsidiary material from the ground to assemble in the air.

Materials used inside the building during the construction of the building are taken out to the outside. In general, when constructing a building, a material lifting zone is formed inside the building and the material is taken out, and then the material lifting zone is closed.However, when rebuilding, such as remodeling, a material lifting zone is placed inside the building. It cannot be formed, and materials are taken out to the outside using openings such as windows. At this time, the stability of the scaffolding system due to the material export, the dust generated from the material and the noise generated during the lifting of the material is needed to improve the situation.

Based on the technical background as described above, the present invention is to provide a scaffolding system that is easy to take out materials, and can reduce noise and dust.

According to one embodiment of the invention, a plurality of support pillars installed in a direction adjacent to the building and perpendicular to the ground; Strips each connected in a direction perpendicular to the longitudinal direction of the support pillar; And a rotating part positioned between the belts and having a bucket moving from the top to the bottom of the support pillar in the space between the building and the support pillar.

In addition, the rotating unit, the gear unit connected to the belt; A belt part extending from an upper end to a lower end of the support pillar and moving in contact with the gear part; And a connection part connected to the belt part to protrude in the building direction and connected to rotate the bucket.

In addition, the gear unit may be installed only in the belt seat located at the top of the scaffolding system and the belt seat located at the bottom of the scaffolding system.

In addition, the belt portion may be connected to the connecting portion and a plurality of fitting protrusions spaced along the longitudinal direction of the belt portion may be formed.

In addition, the bucket may include a fixing jaw perpendicular to the side surface and protruding toward the building.

The gear unit may rotate when the bucket reaches a set weight.

In addition, the base plate is located between the support pillar and the ground, and includes a guide member connected to the support pillar and an elastic member positioned inside the guide member to contact the lower portion of the support pillar to support the support pillar. can do.

The bottom plate may include an auxiliary bottom plate having an inclined surface inclined toward the ground.

Scaffolding system according to an embodiment of the present invention is easy to take out materials, it is possible to reduce noise and dust.

1 is a perspective view of a scaffolding system according to one embodiment of the invention.
FIG. 2 is a side view showing a rotating part of the scaffolding system shown in FIG. 1.
3 is a cross-sectional view of the bottom plate and the guide member shown in FIG.
Figure 4 is an exploded perspective view of the bucket and the connecting portion shown in FIG.
5 is a view illustrating a discharge state of the rotating unit illustrated in FIG. 1.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted for clarity, and like reference numerals designate like elements throughout the specification.

In this specification, terms such as "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described on the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, parts, or combinations thereof. In addition, when a part such as a layer, film, region, plate, etc. is said to be "on" another part, this includes not only when the other part is "right on" but also another part in the middle. Conversely, when a part such as a layer, film, region, plate, etc. is "below" another part, this includes not only the other part "below" but also another part in the middle.

1 is a perspective view of a scaffolding system according to one embodiment of the invention.

In the following description, as illustrated in FIG. 1, the direction of the window 3 is defined upward in the bottom plate 100, and the direction of the bottom plate 100 is defined downward in the window 3.

Referring to FIG. 1, the scaffolding system 1 is installed adjacent to a building along the outside of the building. In addition, the scaffolding system 1 may include a support pillar 10, a strip 20, and a rotating part 50.

The support column 10 may be formed in a cylindrical or prismatic shape extending in a direction perpendicular to the ground at a position adjacent to the building 2. A plurality of support pillars 10 are installed, the plurality of support pillars 10 may be spaced apart along the circumference of the building (2).

For example, the support pillar 10 may be provided in plural numbers, and may be installed in a twin line scaffolding structure arranged in two rows along the outer circumferential surface of the building. Through this, the overall durability and stability of the scaffolding system 1 can be improved.

On the other hand, the strip 20 may be formed in a cylindrical or prismatic form extending in the direction perpendicular to the longitudinal direction of the support column (10). In addition, a plurality of strips 20 are provided, each strip 20 is positioned between the plurality of support pillars 10 to support the coupling means (not shown), such as each support pillar 10 and the bracket or clamp It can be combined by mediation.

Through this, each strip 20 is to connect the plurality of support pillars 10 to each other, it is possible to improve the overall durability of the scaffolding system (1).

In addition, the belt 20 may be located between the support pillars 10 except for the most adjacent position with the window 3 of the building (2). That is, the belt 20 may form a space in which the rotating unit 50 is disposed and driven at the position closest to the window 3.

Meanwhile, the scaffolding system 1 may include one or more joists 30. The joist 30 may be formed in a prismatic or cylindrical form extending in a direction perpendicular to the outer surface of the building 2. In addition, one end of the joist 30 is coupled to the outer surface of the building 2, the outer surface of the joist 30 is in close contact with the outer surface of the support pillar 10 and the strip 20, such as clamp or bracket The coupling means may be connected to the strip 20 and the support pillar 10.

Through this, the scaffolding system 1 in which the support column 10, the strip 20 and the joist 30 are mutually coupled is adjacent to the building 2 via the joist 30 connected to the outer surface of the building 2. It can be fixed so as to improve the overall stability of the scaffolding system (1).

On the other hand, the footrest 40 may be located between the plurality of joists (30). The scaffold 40 may be formed in a plate shape disposed in a space composed of the strip 20 and the joist 30. In addition, some of the outer surface of the scaffold 40 is connected to the joist 30, the worker working on the outer wall of the building 2 can safely move inside the scaffolding system (1).

FIG. 2 is a side view showing a rotating part of the scaffolding system shown in FIG. 1.

1 and 2, the rotating unit 50 may be formed at a position adjacent to the window 3 of the building 2. In addition, the rotation part 50 may include a gear part 300, a belt part 600, a bottom plate 100, a connection part 500, and a bucket 400.

The gear unit 300 may be located between the windows 3 of the building 2 and a plurality of adjacent support pillars 10. For example, the gear unit 300 may be located on an outer surface of the belt 20 which is adjacent to the space where the belt 20 is not formed.

In this case, the gear unit 300 may be located only in the belt 20 which is located at the top of the scaffolding system 1 and the belt 20 which is located at the bottom of the scaffolding system 1. That is, the gear unit 300 may be located only at the upper and lower ends of the rotating unit 50.

The gear unit 300 may supply rotational energy to the belt unit 600, and support a portion of the inner surface of the belt unit 600 so that the belt unit 600 can be easily rotated. The plurality of belts 20 in which the gear part 300 is not formed may pass through the inner space of the belt part 600 to connect the support pillars 10 adjacent to the rotation part 50 to each other.

Through this, the gear unit 300 may be formed only at the upper and lower ends of the rotating unit 50 so that the rotating unit 50 may be driven without attenuating the structural rigidity of the scaffolding system 1.

Meanwhile, the gear unit 300 may include a roller 310 and a motor 330.

The roller 310 may be formed on the outer surface of the top strip 20 and the bottom strip 20 of the scaffolding system 1. In addition, the roller 310 may be provided to rotate in one direction. The roller 310 provided to rotate may allow the belt part 600 in contact with the outer surface to rotate together with the rotation of the roller 310.

In addition, the motor 330 is connected to the outer surface of the roller 310, it can apply a rotational force of the roller 310. For example, the motor 330 may be an electric motor having a coil and a magnet.

Through this, the motor 330 connected to the external power may apply a rotational force to the roller 310, such that the belt 310 and the belt portion 600 in contact with the outer surface of the roller rotate in one direction.

In addition, the degree of rotation of the motor 330 may be adjusted according to the magnitude of the external power. The worker may adjust the amount of building materials discharged per hour by adjusting the rotational speed of the motor 330 according to the amount and cycle of building materials to be discharged.

On the other hand, the belt unit 600 may be rotated in one direction in contact with the roller 310 of the gear unit 300. The belt unit 600 may be, for example, a conveyor belt or a mesh conveyor having elasticity or a chain conveyor connecting one or more metal or polymer resin plates to each other.

The belt part 600 is formed in a ring shape, and the inner side surface may contact the outer side surface of the roller 310 of the gear unit 300. When the roller 310 rotates in one direction, the belt part 600 may also rotate correspondingly thereto.

In this case, one or more fitting protrusions 610 may be formed on the outer surface of the belt part 600. The fitting protrusion 610 may be connected to the bucket 400 through the connection part 500.

Through this, the belt part 600 connected to the bucket 400 through the fitting protrusion 610 and the connecting part 500 rotates, and the connected bucket 400 may also be moved in correspondence with the rotation.

On the other hand, the bottom plate 100 may be located at the lower end of the support pillar 10 located adjacent to the rotating unit 50. In addition, the upper surface of the bottom plate 100 in contact with the support pillar 10 may be a guide member 110 having a hole formed in the center. The outer surface of the support pillar 10 is inserted into the hole of the guide member 110 to be guided in contact with the inner surface of the guide member 110, and the lower end may be inserted into the bottom plate 100.

Through this, the support column 10 is guided along the inner surface of the guide member 110 and can easily apply pressure to the bottom plate 100.

3 is a cross-sectional view of the bottom plate and the guide member shown in FIG.

The bottom plate 100 may be a pressure sensor 170 on the surface in contact with the lower end of the support pillar 10 inserted into the interior. The pressure sensor 170 may be a piezoelectric element (Piezoelectirc Device) including a crystal piezoelectric element such as Pb (Zr, Ti) O3, KNbO3 to convert an external pressure into an electrical signal, or a polymer piezoelectric element such as PVDF-TrFe. .

The pressure sensor 170 composed of a piezoelectric element may generate an electrical signal in proportion to the pressure applied by the support pillar 10 downward. For example, when the pressure of the support pillar 10 increases, that is, when the amount of construction materials contained in the bucket 400 increases, the pressure sensor 170 controls an electrical signal in response to the increased pressure. Will be sent to. The control unit operates by sending a signal to the motor 330 of the gear unit 300 when the magnitude of the supplied electrical signal is greater than or equal to a preset size, that is, when the amount of construction material is contained in the bucket 400. The motor 330, which is already in operation, may rotate more quickly.

On the contrary, when the magnitude of the pressure is less than or equal to the preset value, the discharge amount may be reduced by stopping the operation of the motor 330 or by slowing the rotation speed of the motor 330.

Through this, the scaffolding system 1 can operate more than the set value, and can efficiently discharge the construction materials.

On the other hand, the elastic member 150 may be formed along the inner surface of the guide member 110. For example, the elastic member 150 may be a spiral spring made of a metal material.

Correspondingly, the column end portion 11, which is the lower end portion of the support pillar 10, may have a narrower area so that the pillar end portion 11 may be inserted into the spiral elastic member 150.

The support pillar 10 into which the pillar end portion 11 is inserted into the elastic member 150 may reduce the magnitude of pressure applied to the pressure sensor 170 through the elastic member 150. Through this, the elastic member 150 may extend the life of the pressure sensor 170.

Figure 4 is an exploded perspective view of the bucket and the connecting portion shown in FIG.

1 and 4, the bucket 400 may include a bucket case 410 and a fixing jaw 430.

The bucket case 410 may be formed in a tubular shape in which a storage space 411 which is a hollow part is formed therein. For example, the bucket case 410 may be formed in the shape of a hexahedron cylinder corresponding to the rectangular space formed by the strip 20, the support pillar 10, and the joist 30.

In addition, the bucket case 410 may be formed so that the top surface is open. With the open upper surface of the bucket case 410, the worker can discharge the construction material inside the building to the storage space 411 of the bucket case 410 through the window.

The fixing jaw 430 may be located on the outer surface of the bucket case 410. In addition, the fixing jaw 430 may be made of a material having elasticity, such as synthetic rubber or natural rubber.

In the process of discharging the construction material to the bucket case 410 through the window, the fixing jaw 430 is in contact with the outer wall located below the window. The rubber fixing jaw 430 may improve the friction force between the outer wall of the building and the bucket 400, so that the bucket 400 may be supported on the outer wall of the building.

Through this, the fixing jaw 430 may improve the stability of the bucket 400 in the process of discharging the building material.

Meanwhile, a plurality of first coupling members 413 may protrude from the other side surface of the bucket case 410. The bucket 400 may be connected to the connection part 500 through the first coupling member 413 and rotate about the first coupling member 413 about its central axis.

In this case, the connection part 500 may include a first connection member 510 and a second connection member 530.

A plurality of first connecting members 510 may be provided, and each of the first connecting members 510 may be connected to an outer surface of the bucket case 410. In addition, the first connection member 510 may be formed in a plate shape extending upward.

A first coupling hole 511 may be formed on a surface of the lower end of the first connection member 510 facing the bucket case 410. For example, the first coupling member 413 of the bucket case 410 may be fitted into the first coupling hole 511 to connect the bucket case 410 and the first connection member 510.

In this case, the bucket case 410 may be rotated through the first coupling member 413 fitted into the first coupling hole 511. Through this, the bucket case 410 is rotated in the process of discharging or injecting the building material and can easily enter and exit the building material.

The second coupling member 513 may be formed at an upper end of the first connection member 510. For example, the second coupling member 513 may be formed in a pillar shape penetrating the side surface of the upper end of the first connection member 510. A second connection member 530 is coupled to the second coupling member 513, and the bucket case 410 and the first connection member 510 may be rotated according to the rotation of the belt part 600.

On the other hand, the second connection member 530 may include a reinforcement pillar 531 and a connection column 533.

The reinforcement column 531 may be positioned between the plurality of first connection members 510, and may be formed in a tubular shape in which both ends thereof are coupled to the second coupling member 513 of each first connection member 510. .

The reinforcement column 531 may rotate the second coupling member 513 about the central axis in a state of being fitted to the second coupling member 513. Through this, the bucket 400 may be easily rotated.

In addition, the reinforcement pillar 531 may support the upper end of the first connection member 510, thereby preventing the first connection member from bending.

When building materials are loaded into the bucket case 410, the bucket case 410 receives a continuous force toward the ground due to the weight of the building materials. This force is applied to the first connection member 510 connected through the first coupling member 413.

The first coupling member 413 continuously presses the inner side of the lower side of the first coupling hole 511 and acts as a torque in which the lower end of the first connection member 510 is rotated in the outward direction of the bucket case 410. Done. As a result, the first connection member 510 may be bent or damaged, and an accident in which the bucket case 410 falls to the ground may occur.

The reinforcing column 531 positioned at the upper end of the first connecting member 510 applies a torque to the inner surface of the first connecting member 510 in a direction opposite to the torque received by the first connecting member 510, thereby providing a first connection. The force received by the member 510 may be offset.

Through this, the reinforcement pillar 531 may prevent deformation and breakage of the first connection member 510, thereby improving stability of the rotation unit 50.

On the other hand, the connection column 533 may be located on the outer surface of the first connection member 510. One end of the connection column 533 may be combined with the fitting protrusion 610 of the belt unit 600 shown in FIG.

The worker may couple the bucket 400 and the connection part 500 and the belt part 600 by inserting the connection column 533 into the fitting protrusion 610 of the belt part 600. At this time, when the belt part 600 rotates in one direction due to the gear part 300, the connection part 500 and the belt part 600 also correspond to the belt part 600 to move in the same direction as the rotation direction of the belt part 600. .

In this case, the worker may couple the connection column 533 only to a part of the plurality of fitting protrusions 610 to adjust the number of buckets 400 connected to the belt part 600. If the amount of building materials to be discharged is large, by installing a plurality of buckets 400 can be easily discharged building materials.

Through this, the connection part 500 may adjust the number of buckets 400 connected to the belt part 600 to facilitate the process of discharging the building materials.

A second coupling hole 535 may be formed at one side of the connection column 533. The second coupling member 513 may have an end opposite to the end connected to the reinforcing column 531 to be fitted into the second coupling hole 535, and the first coupling member 413 and the connection pillar 533 may be connected to each other. have.

In addition, the connection column 533 may be provided to rotate in one direction in a state connected with the second coupling member (513).

5 is a view illustrating a discharge state of the rotating unit illustrated in FIG. 1.

Referring to FIG. 5, a scaffolding system 1 having a rotating unit 50 will be described for discharging building materials.

The truck 60 to discharge the building material 4 to the outside may be positioned adjacent to the scaffolding system 1 and the bottom plate 100 so that the cargo compartment 61 faces the rotary unit 50. In this case, the bottom plate 100 may further include an auxiliary bottom plate 130 having one side formed of an inclined surface.

At least a portion of the cargo compartment 61 of the freight vehicle 60 may be positioned on an upper surface of the bottom plate 100 through the auxiliary bottom plate 130 on which the inclined surface is formed. Through this, the auxiliary bottom plate 130 may allow the truck 60 to be easily moved to the top surface of the bottom plate 100.

Meanwhile, the discharge jaw 63 may be located at the rear of the cargo compartment 61. The discharge jaw 63 may be in contact with the bucket 400 to rotate the bucket 400 in one direction.

The bucket 400 loaded with the building material 4 through the window is moved in one direction corresponding to the rotation of the belt part 600. For example, it may move in a direction away from the building at the lower end of the rotating part 50 in a position adjacent to the building.

The bucket 400 moving in a direction away from the building at a position close to the building at the lower end of the rotating part 50 is in contact with the discharge jaw 63 of the cargo compartment 61. The bucket 400 in contact with the discharge jaw 63 rotates in one direction in contact with the discharge jaw 63 due to the movement of the connected connection part 500 and the belt part 600.

As the bucket 400 rotates, the building material 4 loaded therein is poured into the cargo compartment 61. Thereafter, when the belt part 600 and the connection part 500 are further moved, the contact between the bucket 400 and the discharge jaw 63 is released, and the bucket 400 is changed back to its original state.

Through this, the scaffolding system (1) is easy to take out the material, there is no need to throw building materials through the window to the ground as in the conventional manner, it is possible to reduce the noise and dust generated during the discharge process.

Although one embodiment of the present invention has been described above, the spirit of the present invention is not limited to the embodiments set forth herein, and those skilled in the art who understand the spirit of the present invention, within the scope of the same idea, the addition of components Other embodiments may be easily proposed by changing, deleting, adding, and the like, but this will also fall within the spirit of the present invention.

1: scaffolding system 2: building
3: window 4: building materials
10: support pillar 11: column end
20: Chapter 30: Joist
40: scaffold 50: rotating part
60: truck 61: cargo
63: discharge jaw 100: bottom plate
110: guide member 130: auxiliary bottom plate
150: elastic member 170: pressure sensor
300: gear unit 310: roller
330: motor 400: bucket
410: bucket case 411: storage space
413: first coupling member 430: fixing jaw
500: connecting portion 510: first connecting member
511: first coupling hole 513: second coupling member
530: second connecting member 531: reinforcing column
533: connecting column 535: second coupling hole
600: belt portion 610: fitting projection

Claims (8)

A plurality of support pillars adjacent to the building and installed in a direction perpendicular to the ground;
Strips each connected in a direction perpendicular to the longitudinal direction of the support pillar;
A rotating part positioned between the bands and including a bucket moving from an upper end to a lower end of the support pillar in a space between the building and the support pillar;
Located between the support pillar and the ground, the guide member is connected to the support pillar and the elastic member positioned in the guide member to contact the lower support pillar to support the support pillar and the bottom surface of the support pillar It is installed on the bottom plate includes a bottom plate having a pressure sensor for generating an electrical signal in proportion to the pressure according to the amount of construction materials contained in the bucket,
The rotating part,
A gear part connected to the strap;
A belt part extending from an upper end to a lower end of the support pillar and moving in contact with the gear part;
A pair of connecting members connected to the belt part and protruding in the building direction and connected to the inner surface of the bucket so that the bucket is rotated;
A reinforcement pillar rotatably installed between the pair of connection members;
A pair of connecting pillars each having one end connected to an outer surface of the pair of connecting members and the other end coupled to the belt part;
Scaffolding system including a control unit for controlling the moving speed of the bucket according to the magnitude of the electrical signal delete According to claim 1,
The gear unit,
And a scaffolding system installed only at the top of the scaffolding system and at the bottom of the scaffolding system. According to claim 1,
The belt portion,
A scaffolding system fitted with the connecting pillar and having a plurality of fitting protrusions spaced apart in the longitudinal direction of the belt part. According to claim 1,
The bucket is
A scaffolding system perpendicular to the side and comprising a fixed jaw protruding toward the building. According to claim 1,
The gear unit,
A scaffolding system that rotates when the bucket reaches a set weight. delete According to claim 1,
The bottom plate is,
A scaffolding system comprising an auxiliary bottom plate having an inclined surface inclined toward the ground.

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