CN111071524A

CN111071524A - Coiled plate binding device and utilization method thereof

Info

Publication number: CN111071524A
Application number: CN201911005827.0A
Authority: CN
Inventors: 李弘�; 郭勳伊; 赵正翼; 权五正; 崔贤润
Original assignee: Posco M Tech Co Ltd
Current assignee: Posco M Tech Co Ltd
Priority date: 2018-10-22
Filing date: 2019-10-22
Publication date: 2020-04-28
Anticipated expiration: 2039-10-22
Also published as: KR20200045301A; CN111071524B; KR102197608B1

Abstract

The invention discloses a rolling plate binding device and a utilization method thereof, and the rolling plate binding device according to one embodiment of the invention comprises the following components: a head bracket disposed at one axial side of a rolled sheet placed on a rolled sheet shifter and movable toward the rolled sheet for providing a binding band to an inner side of the rolled sheet; a chute bracket which is disposed on the other side in the axial direction of the rolled plate, is movable toward the rolled plate, and is used for leading out the tie from the inner side of the rolled plate and moving the tie to the head bracket along the outer side of the rolled plate; and a lifting unit respectively provided at the head bracket and the chute bracket for adjusting the height of the head bracket and the chute bracket.

Description

Coiled plate binding device and utilization method thereof

Technical Field

The invention relates to a rolling plate binding device and a utilization method thereof. More particularly, the present invention relates to a rolled sheet bundling apparatus for bundling rolled sheets of a metal sheet or the like with a bundling tape, and a method of using the same.

Background

The metal sheet and the like can be coiled into a coil after being made into a flat plate shape. For transport and storage, the rolled sheet may be bound with a binding tape to prevent the rolled sheet metal or the like from loosening again. For bundling the rolled plates, a bundling device for bundling the rolled plates may be used.

The rolled sheet may be wound around a hollow-shaped rolled core, the binding band may be arranged to extend through an inner side to an outer side of the rolled sheet and to surround one side of the rolled sheet in a diameter direction, and the rolled sheet bundling apparatus may be arranged to convey the binding band from the inner side to the outer side of the rolled sheet for bundling.

On the other hand, in the binding process of the rolled plates based on binding, the rolled plates can be lifted into the air by a rolled plate lifter and the like to be aligned with the rolled plate binding device, and the rolled plates aligned with the rolled plate binding device after being lifted can be bound by the rolled plate binding device.

However, since the rolled sheet lifted by the rolled sheet lifter belongs to a high-weight object, there is a safety risk such as accidental falling, and the rolled sheet lifter may seriously consume power in order to lift the high-weight rolled sheet, and also the volume occupied in the operation process and the setting cost are high.

Therefore, it has been an important subject in binding rolled sheets to simplify the equipment required for the operation of binding rolled sheets, to improve the rapidity and efficiency of the operation process, and to ensure the safety.

Disclosure of Invention

Technical problem

Embodiments of the present invention provide a rolled plate bundling apparatus and a method for using the same, which can simplify equipment in a rolled plate bundling process, shorten time required for operation to achieve efficient operation, and improve operation safety.

Technical scheme

A rolled sheet bundling apparatus according to an embodiment of the present invention includes: a head bracket (HEAD CARRIAGE) disposed on an axial side of a rolled sheet disposed on a rolled sheet displacer and movable toward the rolled sheet for providing a wrap to an inner side of the rolled sheet; a CHUTE bracket (channel CARRIAGE) disposed on the other axial side of the rolled sheet and movable toward the rolled sheet for guiding the wrap from the inside of the rolled sheet to the head bracket along the outside of the rolled sheet; and a lifting unit respectively provided at the head bracket and the chute bracket for adjusting the height of the head bracket and the chute bracket.

The lifting unit can adjust the heights of the head bracket and the chute bracket, so that the central heights of the head bracket and the chute bracket are consistent with the central height of the rolling plate by taking the axial direction as a reference.

The chute bracket may comprise: an inner diameter beam inserted into an inner side of the rolled sheet in an axial direction of the rolled sheet for moving the strap supplied from the head bracket; an outer diameter beam extending in the axial direction of the rolled sheet and disposed outside the rolled sheet for moving the binder passing through the inner diameter beam; and a chute base unit for coupling one ends of the inner diameter beam and the outer diameter beam, the inner diameter beam, the base unit and the outer diameter beam may have a guide line (GUIDELINE) through which the strap passes and be disposed to communicate with each other.

The head rest may include: a band drawing-out unit configured to face the other end of the inner diameter beam for supplying the band to the other end of the inner diameter beam; a band housing unit configured to face the other end of the outer diameter beam for receiving the band moved along the guide route of the inner diameter beam, the base unit, and the outer diameter beam to be drawn out from the other end of the outer diameter beam; and the head base unit is provided with the bandage leading-out unit and the bandage containing unit.

The guide path is formed with a movement space in which the strap moves, and a surface facing the rolled sheet is openable by a pressing force transmitted from the movement space.

A plurality of the outer diameter beams and the strap housing unit may be provided and disposed at intervals in an outer circumferential direction of the rolled sheet, respectively, and the inner diameter beam may have a plurality of guide paths communicating with respective guide paths of the plurality of outer diameter beams.

The head base unit and the chute base unit may be rotatable centering on a rotation shaft aligned in the axial direction in the inner diameter beam and the band drawing unit, respectively.

The chute holder and the head holder are spaced apart from a shift track (shift guide) as a moving path of the rolled sheet shifter in the axial direction, and an accommodation space capable of accommodating at least a portion of each of the chute base unit and the head base unit may be formed below each of the chute base unit and the head base unit.

The outer diameter beam may be provided to be adjustable in a diameter direction of the rolled sheet by a distance from the inner diameter beam.

The chute base unit may include a moving unit extending in the diameter direction of the rolled sheet, and the one end of the outer diameter beam moves in conjunction with the moving unit.

In another aspect, a method of using a rolled sheet bundling apparatus according to an embodiment of the present invention may include: a configuration step of adjusting each lifting unit of a head bracket disposed on one axial side of a rolled plate and a chute bracket disposed on the other axial side of the rolled plate, thereby adjusting the heights of the head bracket and the chute bracket based on the height of the rolled plate; a joining step of moving the head bracket and the chute bracket in the axial direction to join the head bracket and the chute bracket with the rolled sheet therebetween; and a binding step of introducing a binding band from the head bracket to the inner side of the rolled plate, and after the binding band is introduced from the inner side of the chute bracket, moving the introduced binding band to the head bracket along the outer side of the rolled plate.

In the joining step, a position of an outer diameter beam may be adjusted in a diameter direction of the rolled sheet so that the outer diameter beam disposed outside the rolled sheet on the chute bracket is in contact with an outer peripheral surface of the rolled sheet.

In the binding step, the binding position of the binding band on the rolling plate along the peripheral direction can be adjusted by rotating the sliding chute base unit combined with the inner diameter beam and the outer diameter beam on the sliding chute bracket.

In the binding step, at a rotation angle of the chute base unit according to a binding position on the rolled sheet, if the outer diameter beam is located below a moving path of a rolled sheet shifter supporting the rolled sheet, i.e., a shifting track, the position of the outer diameter beam may be adjusted in a diameter direction of the rolled sheet so as to move toward a center side of the chute base unit.

Effects of the invention

The embodiment of the invention can simplify equipment in the plate rolling and bundling process, shorten the time required by operation, realize effective operation and improve the operation safety.

Drawings

Fig. 1 is a view illustrating a rolled sheet binding apparatus according to an embodiment of the present invention.

Fig. 2 is a view of the rolled sheet binding apparatus of fig. 1 as viewed from the front.

Fig. 3 is a view showing a state in which a head bracket and a chute bracket are combined in the rolled sheet bundling apparatus of fig. 2.

Fig. 4 is a view showing an outer diameter beam of the chute bracket in a moving state in the rolled sheet bundling apparatus of fig. 3.

Fig. 5 is a view showing a state in which a chute base unit is rotated in the rolled sheet bundling apparatus according to one embodiment of the present invention.

FIG. 6 is a flow chart illustrating a method of utilizing a rolled sheet bundling apparatus in accordance with an embodiment of the present invention.

Detailed Description

Embodiments of the present invention will be described in detail below with reference to the accompanying drawings so that those skilled in the art to which the present invention pertains can easily practice the present invention.

However, the present invention can be implemented in various different ways, and is not limited to the following examples. In addition, in order to clearly describe the present invention, portions that are not related to the description are omitted in the drawings, and like reference numerals are used to refer to like portions throughout the specification.

A repetitive description of the same components is omitted in this specification.

Further, when a component is described in this specification as being "connected" or "coupled" to another component, it is to be understood that the component may be directly connected or coupled to the other component, but other components may also be present between the component and the other component. When a component is referred to in this specification as being "directly connected" or "directly coupled" to another component, it is understood that no other component is present between the component and the other component.

The terminology used in the description is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention.

Furthermore, in this specification, the singular forms are intended to include the plural forms as well, unless the context clearly indicates otherwise.

In addition, it should be understood that the terms "comprises" or "comprising," or the like, in this specification are intended to specify the presence of stated features, integers, steps, operations, elements, or components, or groups thereof, but do not preclude the presence or addition of one or more other features, integers, steps, operations, elements, components, or groups thereof.

Furthermore, the term "and/or" in this specification includes any and all combinations of one or more of the associated listed items. In the present specification, "A or B" may include "A", "B" or "A and B".

A rolled sheet bundling apparatus according to an embodiment of the present invention is shown in fig. 1, and a view of the rolled sheet bundling apparatus according to an embodiment of the present invention is shown in fig. 2 from the front.

As shown in fig. 1 to 2, a rolled sheet bundling apparatus according to one embodiment of the present invention includes: a head bracket 100 disposed at one axial side of a rolled sheet 10 disposed on a rolled sheet displacer 20 and movable toward the rolled sheet 10 for providing a binding band to an inner side of the rolled sheet 10; a chute bracket 200 which is disposed on the other axial side of the rolled sheet 10, is movable toward the rolled sheet 10, and is configured to draw out the wrap from the inside of the rolled sheet 10 and move the same along the outside of the rolled sheet 10 to the head bracket 100; and

lifting units

190, 290 respectively provided at the head bracket 100 and the chute bracket 200 for adjusting the heights of the head bracket 100 and the chute bracket 200.

The wrap (COIL) may be a shape in which a thin metal plate or the like is wound around a hollow winding core, and may be moved by a wrap SHIFTER (COIL SHIFTER). For example, as shown in FIG. 1, the rolled sheet 10 is supported above the rolled sheet displacer 20.

In addition, the rolled sheet displacer 20 moves along a displacer track (shift rod) so that the rolled sheet 10 can be disposed to the rolled sheet bundling apparatus according to an embodiment of the present invention. A rolled sheet displacer 20 is shown in fig. 1 moving along a displacer track 30 to a rolled sheet bundling apparatus.

The head rest 100 is disposed on one side with respect to the roll axis direction of the rolled sheet 10 mounted on the rolled sheet shifter 20. Fig. 2 shows a head bracket 100 disposed on one axial side of the rolled sheet 10.

The head rest 100 may be provided to be fixed to a floor or the ground or provided on a movable column unit. Further, the head bracket 100 is provided to be movable toward the rolled sheet 10 from one side in the axial direction of the rolled sheet 10.

That is, the head carriage 100 is movable in the axial direction of the rolled sheet 10, and the head carriage 100 may be moved as a whole or the head base unit 110 described below is movable in the axial direction of the rolled sheet 10. There may be a driving motor for moving the head carriage 100.

When the head base unit 110 of the head carriage 100 is moved, the head base may be configured to move in the axial direction of the rolled sheet 10 by the rack-and-pinion gear engagement structure, which may be performed by an operator directly operating the console or by the control unit.

Head bracket 100 provides a strap to the inside of rolled sheet 10. The ties may be made of iron or PET material and may be disposed around the inner and outer faces of rolled sheet 10.

The binding band supplied from the head bracket 100 is supplied in a strip form and is supplied to the chute bracket 200 through the inside of the rolled sheet 10 as described below, and then returns to the outside of the rolled sheet 10, and then both ends are connected, and the rolled sheet 10 can be bound.

On the other hand, as shown in fig. 1 to 2, the chute bracket 200 is provided on the other axial side of the rolled sheet 10. One side and the other side of the rolled sheet 10 correspond to opposite sides to each other centering on the rolled sheet 10, and the chute bracket 200 may be provided to move toward the rolled sheet 10.

The chute bracket 200 may be provided fixed to the floor or ground or provided on a movable column unit. Further, the chute holder 200 may be moved as a whole or a chute base unit 210 described below may be moved in the axial direction of the rolled sheet 10. There may be additionally a driving motor for moving the chute bracket 200.

When the chute base unit 210 is moved, the chute base may be provided to be moved in the axial direction of the rolled sheet 10 by the rack-and-pinion engagement structure or the hydraulic cylinder structure, which may be performed by an operator directly operating the console or by the control unit.

The leading end of the strap fed from the head bracket 100 is moved from one side to the other side inside the rolled plate 10 by the chute bracket 200, moved from the inside of the rolled plate 10 to the outside on the other side, and moved from the other side to the one side outside the rolled plate 10, so that the strap can be fed to the head bracket 100 again.

The rolled sheet 10 may be bundled by a banding operation by winding the band around the rolled sheet 10 in the diametrical direction of the rolled sheet 10 in the manner described above. Fig. 2 shows a state of the chute bracket 200 provided on the other side of the rolled sheet 10.

On the other hand, the lifting

units

190, 290 are provided at the head bracket 100 and the chute bracket 200, respectively. The head rest 100 and the chute rest 200 are changed in length in the height direction from the ground by the lifting

units

190 and 290 or at least the heights of the head base unit 110 and the chute base unit 210 described below are changed.

As shown in fig. 1 to 2, the elevating

unit

190, 290 may be disposed below the column unit of the head rest 100 and the chute rest 200 or at a joint portion of the column unit and the head rest 100 or the chute rest 200.

The lifting

units

190, 290 have a rack and pinion engagement structure or are provided in a hydraulic cylinder type so that the heights of the head bracket 100 and the chute bracket 200 can be adjusted. Accordingly, the head bracket 100 and the chute bracket 200 are adjusted in relative height to the rolled sheet 10 by the elevating

units

190, 290.

When the binding operation of the rolled sheet 10 is performed by a binding band around the inner and outer diameters of the rolled sheet 10, it is necessary to arrange the head bracket 100 and the chute bracket 200 for binding at the same height as the rolled sheet 10, and for this reason, a method of lifting the rolled sheet 10 to be consistent with the height of the head bracket 100 and the chute bracket 200 using a rolled sheet lifter may be employed.

However, in this case, a roll bending lifter for lifting the roll bending 10 needs to be provided, and therefore, the equipment for the bundling operation of the roll bending 10 increases, and the operation processes such as the lifting process of the roll bending 10 also increase.

In addition, because the rolled sheet 10 is lifted into the air, the rolled sheet 10 may accidentally fall, and thus there may be a safety risk.

Accordingly, one embodiment of the present invention, rather than lifting the rolled sheet 10, has lifting

units

190, 290 at the head bracket 100 where the band is provided and the chute bracket 200 where the band is moved, thereby aligning the height of the head bracket 100 and the chute bracket 200 with the rolled sheet 10, enabling efficient strapping operations.

An embodiment of the present invention may omit a roll plate lifter or the like for lifting the roll plate 10, thereby simplifying the operation equipment and shortening the operation process, and reduce power required for the binding operation, etc., thereby effectively reducing the risk of accidents.

On the other hand, fig. 3 shows a state in which the center heights of the head bracket 100 and the chute bracket 200 are aligned with the center height of the rolled sheet 10 by the elevating

units

190, 290 and the head bracket 100 and the chute bracket 200 are coupled to each other by moving toward the rolled sheet 10.

As shown in fig. 3, in one embodiment of the present invention, the

lifting unit

190, 290 may adjust the heights of the head rest 100 and the chute rest 200 such that the respective central heights of the head rest 100 and the chute rest 200 coincide with the central height of the rolled sheet 10 with respect to the axial direction.

The center height of the rolled sheet 10 is the height of the winding core axis relative to the ground, and the center heights of the head bracket 100 and the chute bracket 200 may correspond to the heights of the inner diameter beam 220 and the band drawing unit 120, as described below.

On the other hand, as shown in fig. 2 and 3, in one embodiment of the present invention, the chute bracket 200 may include: an inner diameter beam 220 inserted into the inner side of the rolled sheet 10 in the axial direction of the rolled sheet 10 for movement of the strap supplied from the head bracket 100; an outer diameter beam 230 extending in the axial direction of the rolled sheet 10 and disposed outside the rolled sheet 10 for moving the wrap passing through the inner diameter beam 220; and a chute base unit 210 for coupling one ends of the inner diameter beam 220 and the outer diameter beam 230, the inner diameter beam 220, the base unit, and the outer diameter beam 230 may have

guide lines

212, 222, 232 through which the twist ties pass and be disposed to communicate with each other.

The head bracket 100 may have a chute base unit 210 facing the rolled sheet 10. The chute base unit 210 may be provided with an inner diameter beam 220 and an outer diameter beam 230, and the inner diameter beam 220 and the outer diameter beam 230 may be provided in a shape in which one end of each is coupled to the chute base unit 210 and extends in the axial direction of the rolled sheet 10.

The inner diameter beam 220 may be inserted into the inside of the rolled sheet 10. That is, the inner diameter beam 220 may be located at a substantially central side on the chute base unit 210, and the binding tape provided from the head bracket 100 may pass through the inner side of the rolled sheet 10 along the inner diameter beam 220.

The outer diameter beam 230 may be disposed outside of the rolled sheet 10. The tie, which passes through the inside of rolled sheet 10 via inner diameter beam 220, is movable across the outside of rolled sheet 10 along outer diameter beam 230. That is, the twist tie provided from the head bracket 100 through the inner diameter beam 220 and the outer diameter beam 230 may be returned to the head bracket 100 again.

On the other hand, the inner diameter beam 220, the outer diameter beam 230, and the chute base unit 210 may have

guide paths

212, 222, 232 through which the strap moves, and the

guide paths

212, 222, 232 formed on the inner diameter beam 220, the outer diameter beam 230, and the chute base unit 210, respectively, may be provided to communicate with each other.

The guide lines 212, 222, 232 are provided in the inner diameter beam 220, the outer diameter beam 230, and the chute base unit 210 on the moving path of the binding band, and can prevent the binding band from being detached and guide the binding band to achieve stable binding. The guide lines 212, 222, 232 may be provided in the shape of a groove extending along the moving path of the band, or may be provided in the shape of a tunnel formed with the band passing through the inner moving space as shown in fig. 2 to 3.

Therefore, the leading end of the strap led out from the head rest 100 can be introduced into the open mouth of the guide route 222 provided to the inner diameter beam 220, and moved from the guide route 222 along the inner diameter beam 220, the chute base unit 210, and the outer diameter beam 230, so that it is possible to stably return to the head rest 100.

On the other hand, as shown in fig. 2 to 3, in a rolling plate binding apparatus according to an embodiment of the present invention, the head bracket 100 may include: a band drawing unit 120 disposed to face the other end of the inner diameter beam 220 for supplying the band to the other end of the inner diameter beam 220; a band housing unit 130 configured to face the other end of the outer diameter beam 230 for receiving the band drawn out from the other end of the outer diameter beam 230 moving along the

guide routes

212, 222, 232 of the inner diameter beam 220, the base unit, and the outer diameter beam 230; and a head base unit 110, the band drawing unit 120 and the band housing unit 130 being disposed on the head base unit 110.

The side of the head bracket 100 facing the rolled sheet 10 may have a head base unit 110. The head base unit 110 may be provided in a disk shape or a rod shape, and a center side as shown in fig. 2 and 3 may have a band drawing unit 120.

The band drawing unit 120 may be disposed to face the other end of the inner diameter beam 220, and may have a drawing port to draw the band. The tie exiting the exit can be directed to the guide path 222 of the inner diameter beam 220. In addition, the band drawing unit 120 may be provided to protrude from the head base unit 110 to facilitate coupling with the inner diameter beam 220.

The band housing unit 130 may house the band returned through the chute bracket 200. The band received in the band receiving unit 130 is combined with the side of the band drawing unit 120 so that the rolled sheet 10 can be bundled. The band housing unit 130 is disposed to face the other end of the outer diameter beam 230, but does not necessarily form a coupling relationship. Shown in fig. 2 and 3 is a head bracket 100 including a head base unit 110, a strap directing unit 120, and a strap receiving unit 130.

On the other hand, as shown in fig. 3, in the rolled sheet bundling apparatus according to one embodiment of the present invention, the

guide route

212, 222, 232 is formed with a moving space in which the banding band moves, and one surface 223 facing the rolled sheet 10 may be opened by a pressing force transmitted from the moving space.

In one embodiment of the present invention, the

guide lines

212, 222, 232 may be provided in a tunnel shape forming a moving space in which the band moves. One surface 223 of the

guide paths

212, 222, 232 facing the rolled sheet 10 (for example, the guide path 222 of the inner diameter beam 220 is an upper surface, the guide path 212 of the chute base unit 210 is a right side surface, and the guide path 232 of the outer diameter beam 230 is a lower surface in fig. 3) can be opened by the pressurizing force transmitted from the respective moving spaces.

The band, which is wound around one side of rolled sheet 10 along the tunnel-shaped

guide path

212, 222, 232 and returned to head bracket 100, needs to be separated from

guide path

212, 222, 232 to bundle rolled sheet 10. For this reason, one embodiment of the present invention may provide the

guide route

212, 222, 232 at the side 223 facing the rolled sheet 10 to be opened by the internal pressurizing force.

For example, when the leading end of the band returns to the head bracket 100 along the

guide path

212, 222, 232, the leading end of the band is fixed and the chute bracket 200 is moved again away from the rolled plate 10, and one side 223 of the

guide path

212, 222, 232 is opened by the pressure applied by the band, and the rolled plate 10 is bound by separating the band from the

guide path

212, 222, 232 through the opened side 223.

The open side 223 of the

guide path

212, 222, 232 may be provided in various ways. For example, this can be provided by including a hinge with a return spring at a corner attached to the other side.

On the other hand, as shown in fig. 2 and 3, the rolled sheet bundling apparatus according to one embodiment of the present invention may be provided with a plurality of outer diameter beams 230 and the band housing unit 130, respectively, and be spaced apart in the outer circumferential direction of the rolled sheet 10, and the inner diameter beam 220 may have a plurality of guide paths 222 communicating with the respective guide paths 232 of the plurality of outer diameter beams 230.

One embodiment of the present invention may provide multiple outer diameter beams 230 to achieve multiple lashing in one operation. In fig. 2 and 3, a chute bracket 200 is shown having two outer diameter beams 230 as one embodiment of the invention, so that the rolled sheet 10 has two binding sites in one binding operation.

The inner diameter beam 220 may have a plurality of guide paths 222 communicating with respective guide paths 232 of a plurality of outer diameter beams 230. For example, the inner diameter beam 220 may be arranged with a plurality of guide paths 222 in the outer circumferential direction.

The inner diameter beam 220 may have a plurality of guide paths 222 that are provided to communicate with the guide path 232 of any one of the outer diameter beams 230, respectively. In fig. 2 and 3, an inner diameter beam 220 having guide paths 222 at upper and lower portions, respectively, as one embodiment of the present invention is shown, and the inner diameter beam 220 has two guide paths 222 communicating with guide paths 232 of two outer diameter beams 230 located above and below, respectively.

On the other hand, fig. 4 shows a state where the outer diameter beam 230 moves toward the rolled sheet 10, and fig. 5 schematically shows the chute base unit 210 in a rotated state.

In one embodiment of the present invention, the head base unit 110 and the chute base unit 210 may be provided to be rotatable centering on the rotation axis aligned with the axial direction in the inner diameter beam 220 and the band drawing unit 120, respectively.

Referring to fig. 2, the head base unit 110 and the chute base unit 210 may be rotatably combined with a cylinder unit fixed to the floor, and the combination may have a motor for rotation.

In order to stably bind the rolled sheet 10, it is advantageous to perform a plurality of banding in the circumferential direction of the rolled sheet 10, but it may not be easy to provide the outer diameter beams 230 or the band housing units 130 corresponding to the number of predetermined banding portions 15 on the rolled sheet 10. The binding portion 15 is a portion of the rolled sheet 10 to be bound by a binding band.

In one embodiment of the present invention, a plurality of binding portions 15 are provided on the rolled sheet 10, and the head base unit 110 and the chute base unit 210 are rotatably provided so as to enable the outer diameter beams 230 and the strap housing unit 130 of the head base unit 110 and the chute base unit 210 to be located at the binding portions 15.

Therefore, even if the number of the binding portions 15 required for the rolled sheet 10 is more than the number of the outer diameter beams 230, a plurality of binding portions 15 can be formed by rotating the chute base unit 210 and the head base unit 110. In fig. 5 is schematically shown a chute base unit 210 according to one embodiment of the invention, which is rotated according to a certain position of the lashing 15.

On the other hand, fig. 1 to 5 show that the chute base unit 210 and a part of the head base unit 110 may be accommodated in the accommodation space 310 on the lower side of the shift gate as the moving path of the rolled sheet shifter 20.

In an embodiment of the present invention, the chute bracket 200 and the head bracket 100 are spaced apart from a displacement track, which is a moving path of the rolled sheet displacer 20, in the axial direction, and an accommodating space 310 capable of accommodating at least a portion of each of the chute base unit 210 and the head base unit 110 may be formed below each of the chute base unit 210 and the head base unit 110.

One embodiment of the present invention excludes lifting of the rolled sheet 10, and performs the binding operation of the rolled sheet 10 by moving the chute bracket 200 and the head bracket 100 in the height direction from the ground, while the rolled sheet 10 differs in thickness in the diameter direction according to the amount of rolled sheet metal or the like.

Therefore, when the thickness of the rolled sheet 10 is below a certain level, if the heights of the chute holder 200 and the head holder 100 are aligned with the central height of the rolled sheet 10 by the elevating

units

190, 290, there may occur a case where the lower end sides of the rotating chute base unit 210 and the head base unit 110 are located further below the shift lane where the rolled sheet shifter 20 is located.

In this case, an embodiment of the present invention may form an accommodating space 310 corresponding to a hollow space below the chute base unit 210 and the head base unit 110, so that at least a portion of the chute base unit 210 and the head base unit 110 may be located at a lower height than the displacement track.

The receiving space 310 may be formed in various ways. For example, as shown in fig. 1, the lowermost end portions of the chute holder 200 and the head holder 100 may be located lower than the displacement path and the chute holder 200 and the head holder 100 may be spaced apart from the displacement path to form the accommodation space 310, or the displacement path may be located higher than the ground where the lowermost end portions of the chute holder 200 and the head holder 100 are located and spaced apart from each other to form the accommodation space 310.

Fig. 5 schematically shows a state in which the chute base unit 210 is rotated so that at least a part of the chute base unit 210, that is, the bottom end of the chute base unit 210 is accommodated in the accommodation space 310 below the shifter passage 30.

On the other hand, fig. 4 shows a state where the outer diameter beam 230 of fig. 3 is moved toward the inner diameter beam 220. As shown in FIG. 4, in one embodiment of the present invention, the outer diameter beam 230 may be disposed to be adjustable in distance from the inner diameter beam 220 in a diameter direction of the rolled sheet 10.

The chute base unit 210 may be a disk-like or rod-like shape when viewed from the rolled sheet 10 side, and the outer diameter beam 230 may be provided movably in the diameter direction of the rolled sheet 10 on the chute base unit 210. That is, outer diameter beam 230 may be configured to adjust the separation distance from inner diameter beam 220.

As described above, since the rolled sheet 10 has different thickness in the diameter direction, that is, different diameter according to the amount of rolled metal sheet, the distance separating each rolled sheet 10 from the outer diameter beam 230 is different.

In the process of winding the band around the rolled sheet 10, if the outer diameter beam 230 is excessively spaced from the outer side surface of the rolled sheet 10, the winding tension of the rolled sheet 10 is reduced to cause the metal thin plate to be loosened or the amount of the band unnecessarily consumed for stable binding may be increased.

Accordingly, an embodiment of the present invention adjusts the spaced distance between the outer diameter beam 230 and the outer side surface of the rolled sheet 10 corresponding to the thickness variation of the rolled sheet 10, thereby applying pressure to the rolled sheet 10 during banding to prevent the metal thin sheet from loosening and making it possible to effectively use the band.

On the other hand, as described above, in the rotating state in which a part of the chute base unit 210 is accommodated in the accommodation space 310, the outer diameter beam 230 disposed to face the outer side surface of the rolled sheet 10 contacts the upper surface of the displacer passage 30 when the rotation angle of the chute base unit 210 is equal to or greater than a certain level, and the rotation of the chute base unit 210 is restricted.

One embodiment of the present invention adjusts the position of the outer diameter beam 230 according to the rotation angle of the chute base unit 210 during the banding of the rolled sheet 10 so that the chute base unit 210 can be allowed to rotate to the rotation angle.

For example, when the outer diameter beam 230 of the chute base unit 210 at a predetermined position is in contact with the displacer track 30 at a predetermined rotation angle, if the outer diameter beam 230 is moved toward the inner diameter beam 220 side, the outer diameter beam 230 is not in contact with the displacer track 30 at the predetermined rotation angle. That is, the closer the outer diameter beam 230 is to the inner diameter beam 220, the greater the amount of rotation angle allowed for the chute base unit 210 increases.

Therefore, when the chute base unit 210 is rotated corresponding to the predetermined binding part 15 as shown in fig. 5 to stably bind the rolled sheet 10, one embodiment of the present invention can adjust the position of the outer diameter beam 230 so as not to restrict the rotation of the chute base unit 210 due to the contact of the outer diameter beam 230 with the displacer track 30 at the rotation angle.

On the other hand, in one embodiment of the present invention, the chute base unit 210 may include a moving unit 218 extending in the diameter direction of the rolled sheet 10, and the one end of the outer diameter beam 230 moves in conjunction with the moving unit 218.

Referring to fig. 5, according to an embodiment of the present invention, a bar-shaped chute base unit 210 is provided, and a groove extending in a length direction of the chute base unit 210 is formed on the chute base unit 210, and a moving unit 218 coupled with one end of an outer diameter beam 230 moves along the groove.

The moving unit 218 may be moved by a motor or the like receiving a driving force, and as described above, the moving unit 218 may be moved in the diameter direction of the rolled sheet 10. Since the moving unit 218 moves on the chute base unit 210, the outer diameter beam 230 can maintain a stable structure and adjust a spaced distance from the inner diameter beam 220.

On the other hand, a flow chart of a method of utilizing a rolled sheet bundling apparatus according to an embodiment of the present invention is shown in fig. 6. Next, a method of using the rolled sheet bundling apparatus will be described, and the description overlapping with the rolled sheet bundling apparatus described above will be omitted as much as possible.

The utilization method of the rolling plate bundling device according to one embodiment of the invention comprises the following steps: a positioning step S100 of adjusting the

respective lifting units

190 and 290 of the head bracket 100 positioned on one axial side of the rolled sheet 10 and the chute bracket 200 positioned on the other axial side of the rolled sheet 10, thereby adjusting the heights of the head bracket 100 and the chute bracket 200 based on the height of the rolled sheet 10; a coupling step S200 of moving the head bracket 100 and the chute bracket 200 in the axial direction to couple the head bracket 100 and the chute bracket 200 with the rolled sheet 10 interposed between the head bracket 100 and the chute bracket 200; a binding step S300 of introducing a binding band from the head bracket 100 to the inner side of the rolled plate 10, and after the binding band is introduced from the inner side of the chute bracket 200, moving the introduced binding band to the head bracket 100 along the outer side of the rolled plate 10.

In the arrangement step S100, the elevating

units

190, 290 of the head bracket 100 and the chute bracket 200 are adjusted so that the center heights of the head bracket 100 and the chute bracket 200 are adjusted to be located at the center height of the rolled sheet 10. The center height of the head bracket 100 and the chute bracket 200 may be the same as the height at which the rotation axes of the head base unit 110 and the chute base unit 210 are located, and may be the same as the height of the inner diameter beam 220 and the strap drawing unit 120.

In the coupling step S200, the head bracket 100 and the chute bracket 200 are coupled. As shown in fig. 3, the band drawing unit 120 of the head bracket 100 is combined with the inner diameter beam 220 of the chute bracket 200, and the band housing unit 130 of the head bracket 100 may be connected with the outer diameter beam 230 of the chute bracket 200, respectively. At this time, the rolling plate 10 is penetrated by the inner diameter beam 220 in a hollow portion of the inner side, and when a plurality of outer diameter beams 230 are provided, the rolling plate 10 is surrounded by the plurality of outer diameter beams 230 and is located between the chute base unit 210 and the head base unit 110.

On the other hand, in the banding step S300, the band drawn out from the head bracket 100 is returned again to the head bracket 100 along the outer peripheral surface through the inner peripheral surface of the rolled sheet 10 by the chute bracket 200. When the leading end of the band returns to the head bracket 100, the leading end of the band is combined with the side of the band that has not yet entered the inner peripheral surface of the rolled plate 10 to bundle the rolled plate 10.

On the other hand, in the utilization method of the rolled sheet bundling apparatus according to one embodiment of the present invention, the position of the outer diameter beam 230 may be adjusted in the diameter direction of the rolled sheet 10 in the coupling step S200 such that the outer diameter beam 230 disposed outside the rolled sheet 10 on the chute bracket 200 is in contact with the outer circumferential surface of the rolled sheet 10.

By adjusting the position of the outer diameter beam 230, it is possible to prevent the occurrence of loosening of the metal sheet wound into the roll sheet 10 and the occurrence of restriction of rotation of the chute base unit 210.

On the other hand, in the binding step S300, the position of the rolled sheet 10 bound by the binding band in the circumferential direction can be adjusted by rotating the chute base unit 210 to which the inner diameter beam 220 and the outer diameter beam 230 are coupled to the chute bracket 200.

The rolled sheet 10 may be provided with a plurality of binding portions 15, and in one embodiment of the present invention, the chute base unit 210 and the head base unit 110 may be rotated corresponding to the plurality of binding portions 15 to perform a binding operation.

On the other hand, in the binding step S300 of one embodiment of the present invention, at the rotation angle of the chute base unit 210 according to the binding position on the rolled sheet 10, if the outer diameter beam 230 is located below the moving path of the rolled sheet displacer 20 supporting the rolled sheet 10, i.e., the shifting track, the position of the outer diameter beam 230 may be adjusted in the diameter direction of the rolled sheet 10 so as to be moved toward the center side of the chute base unit 210.

The more the outer diameter beam 230 moves toward the inner diameter beam 220 side, the less the rotational angle restriction of the displacer track 30, and therefore, one embodiment of the present invention can allow the rotation of the chute base unit 210 corresponding to the binding portion 15 by adjusting the position of the outer diameter beam 230 according to the rotational angle of the chute base unit 210.

Although the present invention has been described in connection with the specific embodiments and the accompanying drawings, it is apparent to those skilled in the art to which the present invention pertains that various modifications and changes can be made without departing from the scope of the technical idea of the present invention in the claims.

Description of the symbols

10: rolling a plate 15: binding part

20: roll plate shifter 30: shifting device channel

100: head bracket 110: head base unit

120: the tape drawing unit 130: ribbon accommodation unit

190. 290: the lifting unit 200: chute bracket

210:

chute base unit

212, 222, 232: guiding route

218: the mobile unit 220: inner diameter beam

230: outer diameter beam 310: containing space

S100: configuration step S200: combining step

S300: step of binding

Claims

1. A coiled sheet binding apparatus, comprising:

a head bracket disposed at one axial side of a rolled sheet placed on a rolled sheet shifter and movable toward the rolled sheet for providing a binding band to an inner side of the rolled sheet;

a chute bracket which is disposed on the other side in the axial direction of the rolled plate, is movable toward the rolled plate, and is used for leading out the tie from the inner side of the rolled plate and moving the tie to the head bracket along the outer side of the rolled plate; and

and the lifting units are respectively arranged on the head bracket and the chute bracket and are used for adjusting the heights of the head bracket and the chute bracket.

2. The rolled sheet binding apparatus according to claim 1,

the lifting unit adjusts the heights of the head bracket and the chute bracket so that the central heights of the head bracket and the chute bracket are consistent with the central height of the rolling plate based on the axial direction.

3. The rolled sheet binding apparatus according to claim 1,

the chute bracket comprises:

an inner diameter beam inserted into an inner side of the rolled sheet in an axial direction of the rolled sheet for moving the strap supplied from the head bracket;

an outer diameter beam extending in the axial direction of the rolled sheet and disposed outside the rolled sheet for moving the binder passing through the inner diameter beam; and

a chute base unit for coupling one ends of the inner diameter beam and the outer diameter beam,

the inner diameter beam, the base unit and the outer diameter beam are provided with guide routes through which the cable ties pass and are arranged to communicate with each other.

4. The rolled sheet binding apparatus according to claim 3,

the head bracket includes:

a band drawing-out unit configured to face the other end of the inner diameter beam for supplying the band to the other end of the inner diameter beam;

a band housing unit configured to face the other end of the outer diameter beam for receiving the band moved along the guide route of the inner diameter beam, the base unit, and the outer diameter beam to be drawn out from the other end of the outer diameter beam; and

the head base unit, the band leading-out unit and the band containing unit are arranged on the head base unit.

5. The rolled sheet binding apparatus according to claim 3,

the guide path is formed with a movement space in which the strap moves, and one surface facing the rolled sheet is opened by a pressing force transmitted from the movement space.

6. The rolled sheet binding apparatus according to claim 4,

a plurality of the outer diameter beams and the ribbon containing units are respectively arranged and spaced along the peripheral direction of the rolling plate,

the inner diameter beam has a plurality of guide paths communicating with respective guide paths of the plurality of outer diameter beams.

7. The rolled sheet binding apparatus according to claim 4,

the head base unit and the chute base unit are rotatable around a rotation axis aligned in the axial direction in the inner diameter beam and the band drawing unit, respectively.

8. The rolled sheet binding apparatus according to claim 7,

the slide groove bracket and the head bracket are axially spaced from a displacement path which is a moving path of the rolling plate displacer, and an accommodating space capable of accommodating at least a part of each of the slide groove base unit and the head base unit is formed below each of the slide groove base unit and the head base unit.

9. The rolled sheet binding apparatus according to claim 8,

the outer diameter beam can adjust the distance from the inner diameter beam along the diameter direction of the rolling plate.

10. The rolled sheet binding apparatus according to claim 9,

the chute base unit includes a moving unit extending in the diameter direction of the rolled sheet, and the one end of the outer diameter beam moves in conjunction with the moving unit.

11. A method of using a rolled sheet bundling apparatus, comprising:

a configuration step of adjusting each lifting unit of a head bracket disposed on one axial side of a rolled plate and a chute bracket disposed on the other axial side of the rolled plate, thereby adjusting the heights of the head bracket and the chute bracket based on the height of the rolled plate;

a joining step of moving the head bracket and the chute bracket in the axial direction to join the head bracket and the chute bracket with the rolled sheet therebetween; and

and a binding step, wherein a binding belt is introduced from the head bracket to the inner side of the rolling plate, and after the binding belt is introduced from the inner side of the sliding chute bracket, the introduced binding belt moves to the head bracket along the outer side of the rolling plate.

12. The rolling plate binding apparatus utilization method according to claim 11,

in the joining step, the position of the outer diameter beam is adjusted in the diameter direction of the rolled plate so that the outer diameter beam disposed outside the rolled plate on the chute bracket is in contact with the outer peripheral surface of the rolled plate.

13. The rolling plate binding apparatus utilization method according to claim 11,

in the binding step, the position of the rolled plate bound by the binding belt along the peripheral direction is adjusted by rotating a chute base unit combined with an inner diameter beam and an outer diameter beam on the chute bracket.

14. The rolling plate binding apparatus utilization method according to claim 13,

in the binding step, at a rotation angle of the chute base unit according to a binding position on the rolled sheet, if the outer diameter beam is located below a moving path of a rolled sheet shifter supporting the rolled sheet, i.e., a shifting track, the position of the outer diameter beam is adjusted in a diameter direction of the rolled sheet so as to move toward a center side of the chute base unit.