The present invention relates to a manufacturing apparatus and method of a spiral duct including an elbow, and more specifically, to a manufacturing apparatus and method of a spiral duct including an elbow, which cuts a metal plate member into a wave shape and winds the cut metal plate member into a cylindrical shape to form a spiral duct including an elbow.
In general, spiral ducts are widely used in air handling units, pipelines for transferring particles and so on.
An apparatus for manufacturing a spiral duct has a plurality of pressing rollers arranged in a plurality of lines. While a thin metal plate member wound around a reel stand passes through the pressing rollers, both ends of the metal plate member are bent away from each other. Then, as the metal plate member is pressed by the pressing rollers while the bent portions of both ends of the metal plate member are coupled to each other, the metal plate member is formed into a cylinder. At this time, as the metal plate member is guided while being supported by three to five projecting guide rods installed along the circumferential direction of the cylinder, a cylindrical spiral duct is formed. When the spiral duct is formed to have a proper length, it is cut by a circular cutter.
In the process of manufacturing the spiral duct, the pressing rollers for bending both ends of the metal plate member, and the pressing rollers for pressing both ends of the metal plate member, are driven by a plurality of gears or chains.
Such a representative spiral duct manufacturing apparatus is disclosed in Korean Unexamined Utility Model No. 1999-5329 (hereinafter, referred to as “related art 1”). Referring to
As shown in
On a second table 12, a forming unit 3 is installed, including a bolt 32 which adjusts a pressing force for coupling the bent portions 18a and 18b of the metal plate member 18 supplied from the transfer unit 2, a pair of pressing rollers 31 to which the distal end of a lever 33 having the bolt 32 fastened thereto is coupled, and a circular frame 34 which guides a duct which is formed in a cylinder shape while passing through the pressing rollers 31.
The circular frame 34 has a spiral guide groove 35 formed on the inner circumferential surface thereof, the spiral guide groove 35 serving to guide the duct.
Under the forming unit 3, a cutting unit 4 is installed on the second table 12.
The cutting unit 4 includes an operating plate 41 which slides on the second table 12, a bracket 46 which is installed on the distal end of the operating plate 41 so as to connect the circular saw blade 42, a motor 43 for rotating the circular saw blade 42, and a cylinder 44 which adjusts the height of the circular saw blade 42.
On the second table 12, a cylinder 47 for moving and returning the cutting unit 4 is installed. The first and second tables 11 and 12 are connected through a guide plate 5.
The spiral duct manufacturing apparatus according to the related art winds a metal band, supplied at an oblique angle, into a cylindrical shape, thereby manufacturing a spiral duct.
The spiral duct manufacturing apparatus can manufacture a spiral duct formed in a straight line, but cannot manufacture a spiral duct having an elbow which is bent at a predetermined angle depending on a place where the spiral duct is installed.
Further, a spiral duct manufacturing apparatus and method is disclosed in Korean Patent Laid-open Publication No. 2006-28859 (hereinafter, referred to “related art 2”) filed by the present applicant.
As shown in
The spiral duct manufacturing apparatus can manufacture not only a straight spiral duct but also a spiral duct having an elbow. Since the elbow is formed in such a manner that the outer circumference thereof is set in a straight line, the elbow is not formed in a gently curved line, but in a straight line which is bent several times at various angles.
In order to solve the foregoing and/or other problems, it is an objective of the present invention to provide a manufacturing apparatus and method of a spiral duct including an elbow that manufacture a duct and an elbow for connecting a duct to another duct.
It is an objective of the present invention to provide a manufacturing apparatus and method of a spiral duct including an elbow that cut a metal plate member wound around a reel into a wave shape and bend the projecting wave portions of the metal plate member to manufacture a spiral duct having an elbow.
In one aspect, the invention is directed to a manufacturing apparatus of a spiral duct including an elbow, comprising: a wave bending unit that upwardly bends projecting wave portions of metal plate members supplied in a state where the metal
plate members are cut in such a manner that a straight line and waves are formed; a transfer unit that transfer the metal plate members having the bent wave portions; and a forming and cutting unit that forms the metal plate members transferred from the transfer unit into a cylindrical spiral shape, presses the metal plate members to form an elbow, and then cuts the metal plate members.
In another aspect, the invention is directed to a manufacturing method of a spiral duct including an elbow, comprising: bending projecting wave portions of metal plate members upward by a ball caster, the metal plate members being cut in such a manner that a straight lines and waves are formed; transferring the metal plate members using a pair of transfer rollers which are rotated by a first motor installed in a manufacturing apparatus of a spiral duct including an elbow; pressing a single folded portion and a double folded portion of the metal plate members using upper and lower pressing rollers while the transferred metal plate members are rolled into a circular shape by a joint jig; and cutting the elbow formed by the manufacturing apparatus using upper and lower cutters.
The foregoing and other objects, features and advantages of the invention will be more apparent from the more particular description of preferred embodiments of the invention, as illustrated in the accompanying drawings. The drawings are not necessarily to scale, emphasis instead being placed upon illustrating principles of the invention.
Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.
Around the uncoiler 100, the metal plate member for forming a spiral duct is wound. As shown in
Since the wave cutting unit 200 is disclosed in Korean Patent Application No. 2006-28859, filed by the present applicant, it will only be briefly described here. The wave cutting unit 200 includes a first edge forming roll. The first edge forming roll includes a first inclination forming roll 210 which flattens the metal plate member supplied from the uncoiler 100, a second inclination forming roll 220 which slightly bends the edge of the metal plate member downward, and a third inclination forming roll 230 which bends the downward-bent edge of the metal plate member upward so as to form a double folded portion.
The wave cutting unit 200 includes a line scribing roll 240 which scribes a wave-shaped line on the metal plate member and a vertical forming roll 250 which vertically forms the inclined edge of the metal plate member.
Further, the wave cutting unit 200 includes a partitioning roll 260 which cuts the metal plate member along the longitudinal direction into two parts, and an inward inclination forming roll 270 which bends the vertically-erected edge of the metal plate member inward. The partitioning roll 260 forms an L-shaped single folded portion on the edge of the metal plate member while cutting the metal plate member into a wave shape.
The wave cutting unit 200 includes a second edge forming roll 280 which bends the edges of the wave-shaped portions of the metal plate members so as to form a single folded portion, and a guide roll 290 which guides and discharges two of the metal plate members. Next to the wave cutting unit 200, the first transfer unit 300 formed of a conveyor is installed so as to stably transfer the cut metal plate members.
The manufacturing apparatus according to the present invention includes the wave bending unit 400, the second transfer unit 500, and the forming and cutting unit 600. As shown in
As shown in
The wave bending unit 400 includes a ball caster 420 which partially bends the projecting wave portions of the separated metal plate members into a round shape. The ball caster 420 is installed so as to be moved by a linear guide 421, as shown in
The ball caster 420 is composed of an upper ball caster 422 and a lower ball caster 423. As shown in
Next to the ball caster 420, the second transfer unit 500 is installed to pull and transfer the metal plate members.
As shown in
The transfer rollers 530 of the second transfer unit 500 are installed in such a manner that the height thereof is adjusted depending on the thickness of the supplied metal plate members or the supply height of the metal plate members. On the top surface of an upper frame 531, a first adjusting lever 532 for adjusting the height of the transfer rollers 530 is installed.
The forming and cutting unit 600 forms the metal plate members, which are supplied in a state where both sides thereof are bent, into cylindrical spiral elbows and cuts the formed elbows. As shown in
Further, as shown in
As shown in
The second gear 621 is geared with a third gear 623 provided above the second gear 621. The third gear 623 has an upper pressing roller 624 installed thereon such that the upper pressing roller 624 is adjacent to the lower pressing roller 622, the upper pressing roller 624 pressing the connection portion of the spiral duct against the distal end of the shaft.
The lower and upper pressing rollers 622 and 624 serve to press the double folded portion and the single folded portion formed on the edge of the metal plate member, and the lower pressing roller 622 has a concave groove formed thereon.
As shown in
As shown in
The first moving portion 644 has a vertical guide rail 645 erected on the distal end thereof, and a second moving portion 646 is coupled to the vertical guide rail 645 so as to vertically move. Under the vertical guide rail 645, the joint jig 650 is installed, which forms the supplied metal plate members into a cylindrical spiral shape.
As shown in
Further, cylinders 653a and 653b are installed in both sides of the divided pieces 651 such that the length of the divided pieces 651 is adjusted. Among the divided pieces 651, a divided piece positioned in the upper side is fixed to the second moving portion 646 coupled to the vertical guide rail 645 of the fixing device 640.
The cylinders 653a and 653b are coupled to self-aligning bearings.
The joint jig 650 has a moving plate 654 fixed to one surface thereof, and the moving plate 654 is bent toward the inner curve of the joint jig 650 such that the metal plate members are transferred in a state where they are held.
As shown in
As shown in
The link 665 has a first cylinder 666 installed thereon, the first cylinder 666 advancing and retreating the link 665.
The lower cutter 662 has a rail 667 which is vertically installed under the lower cutter 667. As shown in
Further, the manufacturing apparatus also include a controller which generally controls the elbow manufacturing apparatus so as to form the spiral duct.
In the manufacturing apparatus constructed in such a manner, the metal plate member wound around the uncoiler 100 is continuously supplied.
First, an operator manually fixes the metal plate member to the ball caster 420, the transfer rollers 530, and the joint jig 650 through the wave cutting unit 200 and the first transfer unit 300.
When installation of the metal plate member is completed by the operator, the metal plate member wound around the uncoiler 100 is pulled by the wave cutting unit 200 so as to be continuously supplied (step S1O).
Both edges of the metal plate member supplied to the wave cutting unit 200 are bent by the guide roll 290 installed in series from the first inclination forming roll 210, and the central portion thereof is cut into a wave shape. Further, the edges of two cut metal plate members are bent (step SI1).
In this case, the metal plate member is cut into predetermined lengths of line and wave shapes depending on the size of an elbow which is to be manufactured by the elbow manufacturing apparatus. That is, the center of the metal plate member is cut into a straight line with a predetermined length, and the metal plate member is then cut into a continuous wave shape so as to be formed into a cylindrical spiral shape. The number of waves of the cut plate metal plate members is properly set by an equation established depending on the diameter and length of the elbow.
As shown in
The detection sensor 410 installed in the wave bending unit 400 detects from the straightly-cut metal plate members that the wave-cut portions of the metal plate members enter. That is, the detection sensor 410 detects that the wave-cut portions of the metal plate members enter and then sends a detection signal to the encoder 615, and the encoder 615 accurately measures the length of the transferred metal plate members. Next, the metal plate members are supplied to the ball caster 420 of the wave bending unit 400. In this case, the straightly-cut portions of the metal plate members pass through the ball caster 420 as is. When the wave-cut portions of the metal plate members are supplied, the cam 425 is retreated by the projecting wave-cut portions of the metal plate members, as shown in
The retreated cam 425 is lifted along an inclined plate 425 installed at the right side of the drawing. Since the retreated state of the cam 425 is maintained until the projecting wave-cut portions of the metal plate members pass, the wave-cut portions of the metal plate members are bent upward in a state where the lower ball caster 423 is lifted.
When the wave-cut portions of the metal plate members pass, the cam 425 is lowered along the inclined plate 425, and the lowered state of the cam 425 is maintained at the straightly-cut portions of the metal plate members. Therefore, only the projecting wave-cut portions of the metal plate members are bent upward.
When the projecting wave-cut portions of the metal plate members enter, the cam 425 is lifted along the inclined plate 424 such that the wave-cut portions of the metal plate members are bent upward. As the metal plate members are bent, curved portions of elbows are formed at a gentle angle when the elbows are formed (step S14).
As shown in
The metal plate members transferred in such a manner are supplied to the joint jig 650, the single folded portion and the double folded portion of the metal plate members are pressed by the upper and lower pressing rollers 622 and 624 installed at the lower end of the joint jig 650, and the elbow of the pressed spiral duct is rocked along the curved line of the wave-cut portions.
The upper cutter 661 is installed to project forward from the joint jig 650, but is lifted. Therefore, the upper cutter 661 can be prevented from interfering with the spiral duct which is rocked while being formed.
At this time, the lifted state of the upper cutter 661 is maintained by the first cylinder 666. As the first cylinder 666 retreats, the link 665 is rotated about one of its sides. As the link 665 is rotated, the frame 663 is lifted upward with respect to the hinge shaft 664, so that the upper cutter 661 is lifted.
The lower cutter 662 is lowered along the rail 667 as the second cylinder 669 and the link 668 retreat. The upper and lower cutters 661 and 662 are separated from each other while the elbow of the spiral duct is manufactured by the joint jig 650.
The metal plate members supplied in such a manner are formed in an elbow shape by the joint jig 650. As shown in
When the elbow is formed, the encoder measures the length of the metal plate members separately from the length of the portion cut by the wave bending unit 200. When the elbow is formed with the length of an elbow which is to be formed, the elbow is cut by the cutter installed in front of the joint jig 650.
When formation of the elbow is completed, a boss is formed in a straight line. Then, to cut the elbow, the upper and lower cutters 661 and 662 are engaged with each other, and the rotating device 670 rotates so as to cut the elbow in a straight line.
The rotation angle of the rotating device is calculated depending on specifications of the elbow. For example, the angle is properly controlled in the range of 0-33 degrees, depending on the size of the elbow.
The rotation of the rotating device 670 is performed as follows: the driving gear 672 is rotated by power applied to the servo motor 673, and the driven gear 671 geared with the driving gear 672 is rotated, so that the entire frame 663 is rotated. As the rotating device 670 rotates, the upper and lower cutters 661 and 662 are rotated. In a state where the upper and lower cutters 661 and 662 are rotated by a predetermined angle, the elbow is cut into a straight line (step S16).
After the elbow is cut, the metal plate member is continuously supplied from the uncoiler 100. The process of forming the elbow is repeatedly performed.
According to the present invention, the projecting wave portions of the metal plate members are bent so as to form the elbow. Therefore, it is possible to manufacture an elbow which is curved at a gentle angle. Accordingly, fluid can flow smoothly along the curved portion of the elbow.
Further, as the elbow is formed by consecutive processes, it is possible to increase productivity.
While the invention has been shown and described with reference to certain exemplary embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims.
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/KR08/02852 | 5/22/2008 | WO | 00 | 11/19/2010 |