JP2018103234A - Cold roll forming machine and heater thereof - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a cold roll forming machine and a heater thereof, which can locally heat a portion to be roll formed of a material to be formed, thus enabling smooth roll forming, in cold roll forming.SOLUTION: A cold roll forming machine (1) according to an embodiment of the present invention includes multiple-stage roll forming stands (2) that are arrayed in a conveying direction, and which gradually cold roll form a material (6) to be formed. In at least one of two sets in each roll forming stand (2), one set comprising a lower roller (23) and a lower roll shaft (22), and the other set comprising an upper roller (25) and an upper roll shaft (24), at least one of the roll shafts (22, 24) have paths (22a, 22b; 24a, 24b), and at least one of the rollers (23, 25) have fluid collecting spaces (23e, 25e). Through the paths, heating fluid flowing in from one end of the roll shaft flows axially toward the other end of the roll shaft (22), and after that, flows outside in a substantially radial direction. Each fluid collecting space receives the heating fluid having flowed outside in the substantially radial direction, storing the heating fluid, and after that, the heating fluid is discharged.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a cold roll forming machine capable of performing smooth roll forming by locally heating a roll forming portion of a molding material in cold roll forming, and a heating apparatus therefor.

In cold roll forming, a metal forming material is sequentially bent between a plurality of stands each having a pair of rollers at room temperature, and is continuously bent to form a flat metal forming. This is a processing method for producing the desired shape steel, pipe material and sash material from the material. With cold roll forming, the processing speed is overwhelmingly faster with complex shapes compared to general press and bender processing, and it is possible to make long products with uniform shapes and cross-sectional accuracy. It produces good and beautiful surface properties, and produces effects such as significant cost reduction due to continuous production.

JP 2014-184453 A

By the way, in the cold roll forming machine of the said Unexamined-Japanese-Patent No. 2014-184453, in each shaping | molding stand 10, the metal plate material 7 is a pair of upper and lower forming rolls 2, 2 'reverse square shape, or a square-shaped shaping surface Thus, the molding process is performed. However, according to this, the metal plate 7 needs to be bent at a large angle at room temperature at a portion where it is bent at a reverse angle or a large angle, and the bending is insufficient. In some cases, the metal plate 7 was cracked by tensile stress and compressive stress generated on both sides of the metal plate 7.
Accordingly, an object of the present invention is to solve the above problems by at least one of an upper roller body (consisting of an upper roll shaft and an upper roller) and a lower roller body (consisting of a lower roll shaft and a lower roller). Heating a predetermined portion of the roller by drawing a heated fluid from one end of one roll shaft in the axial direction inside the roll shaft and then discharging it through the fluid pool space inside the roller, and then pulling An object of the present invention is to provide an apparatus which can perform a molding process of a material to be molded well by heating the material.

The cold roll forming machine of the present invention is
A cold roll forming machine (1) provided with a plurality of roll forming stands (2) arranged in the conveying direction and performing stepwise cold roll forming of a molding material (6), wherein the plurality of rolls Each stage of the molding stand (2) is arranged such that the axis (22, 24) direction thereof is arranged in a direction perpendicular to the conveying direction of the molding material (6) and rolls the molding material (6). A lower roll shaft (22) having a roller (23) and the lower roller (23) are disposed so as to sandwich the molding material (6), and the molding material (6) is placed together with the lower roller (23). An upper roll shaft (24) having an upper roller (25) for roll forming; and a driving means (11) for rotationally driving at least one of the lower roll shaft (22) and the upper roll shaft (24). Set of roller (23) and lower roll shaft (22), and upper roller In at least one of the set of the roller (25) and the upper roll shaft (24), the heated fluid that has flowed from one end of the roll shaft to the roll shaft (22, 24) is the other end shaft of the roll shaft (22). Are provided with passages (22a, 22b; 24a, 24b) that flow substantially radially outward after flowing in the direction, and the rollers (23, 25) receive the heated fluid flowing substantially outward in the radial direction. It is characterized by providing fluid reservoir spaces (23e, 25e) to be discharged after being stored.
Preferably, the passages (22a, 22b; 24a, 24b) are both in the set of the lower roller (23) and the lower roll shaft (22) and in the set of the upper roller (25) and the upper roll shaft (24). Each is provided in the set.
Further, preferably, the fluid reservoir space (23e, 25e) is provided in the vicinity of a part that is molded locally in the cross section of the material to be molded (6). Preferably, at least one of the lower roller (23) and the upper roller (25) is configured by combining a plurality of roller portions (23a-23c; 25a-25c).
Preferably, in at least one set of the lower and upper roll shafts (22, 24) and the rollers (23, 25), the roll shaft and the roller are integrally formed.
Preferably, the driving means (11) is connected to the lower roll shaft (22).
Preferably, a pair of stands (26, 27) that support the lower roll shaft (22) and the upper roll shaft (24) are provided, and at least of the lower roll shaft (22) and the upper roll shaft (24). An adjustment mechanism (32a) is provided that adjusts the distance between the two axes by bringing one of the two into contact with and away from the other.
Other heating devices of the cold roll forming machine of the present invention are:
A plurality of roll forming stands (2) arranged in the conveying direction and for cold roll forming the material to be molded (6) in stages, each stage of the plurality of roll forming stands (2) has its axis (22, 24) The lower roll shaft (22) having a lower roller (23) which is disposed in a direction perpendicular to the conveying direction of the molding material (6) and roll-molds the molding material (6). And an upper roll having an upper roller (25) which rolls the molding material (6) together with the lower roller (23). In the cold roll forming machine comprising a shaft (24) and a drive means (11) for rotationally driving at least one of the lower roll shaft (22) and the upper roll shaft (24), the lower roller (23) And set of lower roll shaft (22) and upper row In at least one of the set of (25) and the upper roll shaft (24), the heated fluid that has flowed from one end of the roll shaft into the roll shaft (22, 24) is in the direction of the other end of the roll shaft (22). Are provided with passages (22a, 22b; 24a, 24b) that flow substantially outward in the radial direction, and the rollers (23, 25) receive the heated fluid that flows out in the substantially radial direction. A heating apparatus for a cold roll forming machine, characterized in that a fluid pool space (23e, 25e) for discharging after storage is provided. Preferably, the passages (22a, 22b; 24a, 24b) are both in the set of the lower roller (23) and the lower roll shaft (22) and in the set of the upper roller (25) and the upper roll shaft (24). Each is provided in the set.
Further, preferably, the fluid reservoir space (23e, 25e) is provided in the vicinity of a part that is molded locally in the cross section of the material to be molded (6).
Preferably, at least one of the lower roller (23) and the upper roller (25) is configured by combining a plurality of roller portions (23a-23c; 25a-25c).
Preferably, in at least one set of the lower and upper roll shafts (22, 24) and the rollers (23, 25), the roll shaft and the roller are integrally formed.

The cold roll forming machine and its heating device of the present invention have the following effects.
(1) The heating device that stores the heated fluid in the fluid pool spaces (23e, 25e) of the rollers (22, 23) locally heats the part to be molded (6) in the vicinity thereof, which is to be molded. Therefore, the molding material can be satisfactorily molded without cracks or cracks.
(2) If the heating device is provided for each of the lower roller (23) and the upper roller (25), the molding process can be performed more satisfactorily.
(3) If the fluid pool space (23e, 25e) is provided in the vicinity of the locally processed portion of the material to be molded (6), the molding process can be further improved.
(4) At least any one of the lower roller (23) and the upper roller (25) is configured by combining a plurality of roller portions (23a-23c; 25a-25c), so that the fluid pool space (23e, 25e). Is easy to manufacture, and can be easily replaced when the individual roller portions are consumed, and is economical.
(5) Cost can be reduced by integrally forming the roll shaft and the roller with at least one set of the lower and upper roll shafts (22, 24) and the rollers (23, 25).
(6) The driving means (11) can stabilize the molding process by rotating the upper roll shaft and the lower roll shaft.
(7) In the pair of stands (26, 27) that support the lower roll shaft (22) and the upper roll shaft (24), at least one of the lower roll shaft (22) and the upper roll shaft (24) is in contact with or separated from the other. Thus, the adjustment mechanism (32a) for adjusting the inter-axis distance between the two shafts is provided, so that the present invention can be applied to the molding material (6) having various thicknesses.
(8) If necessary, in addition to the heating device pointed out in the above section (1), another heating device such as a high-frequency heating device is additionally arranged to form the molding material (6) into a desired shape. It can also be processed.

FIG. 1 is a plan view of the cold roll forming machine to which the heating device in the cold roll forming machine of the present invention is applied. FIG. 2 is a side view of the cold roll forming machine shown in FIG. FIG. 3 is a longitudinal front view of a roll stand showing a heating device in the cold roll forming machine of the present invention. FIG. 4 is a side view of the roll stand shown in FIG.

  Hereinafter, the heating device in the cold roll forming machine according to the present invention is applied to the cold roll forming machine shown in FIGS. 1 and 2 and the heating device applied to the cold roll forming machine shown in FIGS. 3 and 4. This will be specifically described based on the form. First, the cold roll forming machine 1 shown in FIG. 1 and FIG. 2 includes a central roll stand row 3, a molding material carrying conveyor 4 on the left side in the drawing, and a molding material carrying conveyor 5 on the right side in the figure. Have. In the roll stand row 3, a plurality of (11 in this case) roll stands 2a, 2b, 2c,... 2k are arranged in parallel, and the molding material 6 carried in from the left in the figure is a plurality of roll stands. 2a, 2b, 2c,... 2k are sequentially formed into rolls and processed into a desired final cross-sectional shape when leaving the final roll stand 2k.

  In FIG. 1, reference numeral 7 denotes an amplifier of a high-frequency heating device, whereby a workpiece 6 (steel plate, stainless steel plate, magnesium alloy plate, etc.) is formed by a work coil (not shown) provided at an appropriate location of the roll stand row 3. ) Heat the whole. Reference numeral 8 denotes a lubricant oil tank that stores lubricant oil, and includes a pair of temperature setting type heaters 9 that heat the lubricant oil to a predetermined temperature and a pump 10 that pumps the lubricant oil. Reference numeral 11 denotes a roll shaft drive motor, which rotationally drives a lower roll shaft 22 (see FIG. 3), which will be described later, of each roll stand 2 via the speed reduction mechanism 18. Of course, the upper roll shaft 24 may be rotationally driven by the motor 11, and in some cases, both roll shafts 22 and 24 may be rotationally driven. An inlet guide 12 guides the molding material 6 to the roll stand 2. Reference numeral 13 denotes a correction device that corrects warping, bending, twisting, and the like of the molded material 6 after roll forming that has left the roll stand 2. 14 is an air blower, which removes the anti-friction oil adhering to the molding material 6 with air. Reference numeral 15 denotes a drawing pinch roller that is rotationally driven by a motor 16, and draws and discharges the molding material 6 that has been molded. Reference numeral 17 denotes a control panel.

  Further, in FIG. 1, reference numeral 41 (41a, 41b, 41c) is a first plate guide, which is provided in the vicinity of each roll stand 2 of the first to third stages and has different material widths 6. In order to process the local processing position of the molding material at the same position when the workpiece is conveyed, the insertion position of the molding material 6 is regulated. Reference numeral 42 (42a, 42b,... 41g) is a second plate guide, which is provided in the vicinity of each roll stand 2 in the fourth to tenth stages, and the distance between the work coil and the material 6 to be molded. Is stabilized and the heating temperature of the molding material 6 is stabilized.

Next, one roll stand 2 is shown in FIG.3 and FIG.4. The roll stand 2 includes a pair of stands 26 and 27 arranged to face each other with the conveyance path of the molding material 6 interposed therebetween, and a direction orthogonal to the conveyance path via bearings 30 and 31 between the stands 26 and 27. A lower roll shaft 22 and an upper roll shaft 24, and a lower roller 23 and an upper roller 25 fitted and fixed to the roll shafts 22 and 24, respectively. The lower roll shaft 22 is fixed to the stand 26 via a block 32 that houses the lower bearings 30 and 31. The upper roll shaft 24 is attached to a groove 26a of the stand 26 through a block 33 that accommodates the upper bearings 30 and 31 so as to be slidable in the vertical direction, and is attached to a screw rod 34 that is threadably inserted into the stand 26. . Therefore, by manually rotating the screw rod 34, the vertical position of the upper roll shaft 24 can be finely adjusted by the indicator 35 attached to the block 33 and the scale 36 attached to the stand 26. A gap dimension t (see FIG. 3) of a gap 37 between the lower roller 23 and the upper roller 25 described later can be adjusted. In order to adjust the gap dimension t of the gap 37, not only the position of the upper roll shaft 24 but also the position of the lower roll shaft 22 may be adjusted, or the positions of both axes may be adjusted.
Next, in FIG. 3, a fluid flow passage 22a extending in the right axial direction from the center of the left end of the lower roll shaft 22 is provided, and this fluid flow passage 22a passes through a flow passage 22b extending radially outward near the right end of the shaft. The fluid reservoir space 23d of the lower roller 23, which will be described later, communicates with the fluid reservoir space 23d. A connector 28a into which the fluid from the tube 38a flows is attached to the left end of the lower roll shaft 22, and a gear 29a is attached to the right end. The lower roller 23 is a combination of three lower roller portions 23a, 23b, and 23c, and a fluid pool space 23d is formed on the inner periphery of the right lower roller portions 23b and 23c in the drawing. Similarly, the upper roll shaft 24 and the upper roller 25 (combined with the three upper roller portions 25a, 25b, and 25c) have an axial flow passage 24a, a radial flow passage 24b, a fluid pool space 25d, and an outflow passage 25e. The upper roll shaft 24 has a fluid inflow connector 28b and a gear 29b at both ends of the upper roll shaft 24. When the lower roll shaft 22 is rotationally driven, the upper roll shaft 29b is engaged through engagement of the gears 29a and 29b. Are also driven synchronously in the opposite direction. The reason why the lower roller 23 and the upper roller 25 are divided and combined is to enable the formation of the fluid pool spaces 23d and 25d inside the roll. It can be replaced and the cost can be reduced. However, as long as the fluid pool space can be formed, it is needless to say that the roll shaft and the roller may be integrally formed by machining, casting, or the like.
The heating device in the cold roll forming machine according to the present invention particularly includes the axial flow passages 22a and 24a, the radial flow passages 22b and 24b, which are connected to the anti-friction oil tank 8 through the tubes 38a and 38b, and the heating. It is composed of fluid reservoir spaces 23d and 25d.
Next, operation | movement of the heating apparatus in the cold roll forming machine of this invention is demonstrated with operation | movement of a cold roll forming machine.
1 and 2 from the left side, the molding material 6 carried in by the carry-in conveyor 4 sequentially passes through the 11-stage roll stands 2a, 2b, 2c,. By doing so, when it is sequentially roll-rolled so as to approach the desired cross-sectional shape and leaves the last roll stand 2k, it is processed into a product having the desired final cross-sectional shape. The product 6 is further discharged by the carry-out conveyor 5 after being subjected to predetermined processing by the correction device 13, the air blow device 14, and the drawing pinch roller 15.
Here, in FIG. 3, during the cold roll operation period, the heated fluid (heated lubricant oil) heated to a predetermined temperature from the lubricant oil tank 8 on the lower roll shaft 22 of the heating device is the tube 38a. To the axial flow passage 22a through the connector 28a of the lower roll shaft 22. This heated fluid further enters the lower fluid pool space 23d through the radial flow passage 22b, locally warms the portion around the space 23d of the lower roller 23, particularly the portion around the bent gap portion 37a, and flows out from the outflow passage 23e. .
At the same time, in the upper roll shaft 24, the heated fluid from the anti-friction oil tank 8 enters the upper fluid pool space 25d through the tube 38a, the axial flow passage 24a, and the radial flow passage 24b, and the space 25d of the upper roller 25. The peripheral portion, particularly the peripheral portion of the bent gap portion 37a, is locally warmed and flows out from the outflow passage 25e.
Here, the molding material 6 is molded in the gap 37 between the lower roller 23 and the upper roller 25. In particular, a portion corresponding to the bending gap portion 37a is locally roll-formed. Therefore, since the part 6 to be molded is locally heated, the molded material 6 can be molded satisfactorily without causing cracks, cracks, or the like.

  In FIG. 3, the part 6 to be molded is bent between the rollers 23 and 25 is only one bending gap portion 37a on the right side of the roll in FIG. Needless to say, may be provided in the center or on the left side, or may be provided in a plurality of locations so as to heat the entire sheet width direction of the molding material 6.

DESCRIPTION OF SYMBOLS 1 Cold roll forming machine 2 Roll stand 3 Roll stand row 4 Carry-in conveyor 5 Carry-out conveyor 6 Molding material 7 Amplifier of high frequency heating device 8 Anti-friction oil tank 9 Input type heater 10 Pump 11 Roll shaft drive motor 12 Inlet guide 13 Straightening device 14 Air blow device 15 Pull pinch roller 16 Pull pinch roller drive motor 17 Control panel 18 Deceleration mechanism 22 Lower roll shaft 24 Upper roll shaft 22a, 24a Axial flow passage 22b, 24b Radial flow passage 22a, 24a Axial flow passage 23 Lower roller 25 Upper roller 23a, 23b, 23c Lower roller portion 25a, 25b, 25c Upper roller portion 23d, 25d Fluid pool space 23e, 25e Outflow path 26, 27 Stand 28a, 28b Connector 29a, 29b Gear 30, 31 Bearing 32 , 3 block 34 the threaded rod 35 indicator 36 scale 37 the gap between the rolls 37a bent gap portion 41 emails plate guide

Claims (13)

A cold roll forming machine (1) provided with a multi-stage roll forming stand (2) arranged in the conveying direction to perform cold roll forming of the material to be molded (6) stepwise,
Each stage of the plurality of roll forming stands (2)
A lower roll shaft having a lower roller (23) in which the axis (22, 24) direction is arranged in a direction perpendicular to the conveying direction of the molding material (6) and rolls the molding material (6). 22)
An upper roll shaft (having an upper roller (25) which roll-forms the molding material (6) together with the lower roller (23), and is opposed to the lower roller (23) with the molding material (6) interposed therebetween. 24)
Drive means (11) for rotationally driving at least one of the lower roll shaft (22) and the upper roll shaft (24),
In at least one of the set of the lower roller (23) and the lower roll shaft (22) and the set of the upper roller (25) and the upper roll shaft (24), the roll shaft (22, 24) includes the roll shaft. There are provided passages (22a, 22b; 24a, 24b) through which the heated fluid flowing in from one end of the roll flows in the direction of the other end axis of the roll shaft (22) and flows outward in the radial direction, and the roller (23 25) is provided with fluid pool spaces (23e, 25e) for receiving and storing the heated fluid that has flowed outward in the substantially radial direction, and then discharging it. In the cold roll forming machine according to claim 1,
The passages (22a, 22b; 24a, 24b) are respectively connected to the set of the lower roller (23) and the lower roll shaft (22) and the set of both the upper roller (25) and the upper roll shaft (24). A cold roll forming machine, characterized in that it is provided. In the cold roll forming machine according to claim 1 or 2,
The cold pool forming machine characterized in that the fluid pool space (23e, 25e) is provided in the vicinity of a part that is particularly locally processed in the cross section of the material (6). In the cold roll forming machine according to any one of claims 1 to 3,
A cold roll forming machine characterized in that at least one of the lower roller (23) and the upper roller (25) is configured by combining a plurality of roller portions (23a-23c; 25a-25c). . In the cold roll forming machine according to any one of claims 1 to 4,
A cold roll forming machine characterized in that at least one set of the lower and upper roll shafts (22, 24) and the rollers (23, 25) is integrally formed with a roll shaft and a roller. . In the cold roll forming machine according to any one of claims 1 to 4,
The cold roll forming machine, wherein the driving means (11) is connected to the lower roll shaft (22). In the cold roll forming machine according to any one of claims 1 to 6,
A pair of stands (26, 27) for supporting the lower roll shaft (22) and the upper roll shaft (24) are provided, and at least one of the lower roll shaft (22) and the upper roll shaft (24) is in contact with the other. A cold roll forming machine characterized in that an adjusting mechanism (34) for adjusting the inter-axis distance between the two axes is provided. In the cold roll forming machine according to any one of claims 1 to 7,
In order to heat the said to-be-molded material (6), other heating apparatuses, such as a high frequency heating apparatus, are further provided, The cold roll forming machine characterized by the above-mentioned. A plurality of roll forming stands (2) arranged in the transport direction and performing cold roll forming of the material to be molded (6) in stages, each stage of the plurality of roll forming stands (2) includes:
A lower roll shaft having a lower roller (23) in which the axis (22, 24) direction is arranged in a direction perpendicular to the conveying direction of the molding material (6) and rolls the molding material (6). 22)
An upper roll shaft (having an upper roller (25) which roll-forms the molding material (6) together with the lower roller (23), and is opposed to the lower roller (23) with the molding material (6) interposed therebetween. 24)
In a cold roll forming machine comprising drive means (11) for rotationally driving at least one of the lower roll shaft (22) and the upper roll shaft (24),
In at least one of the set of the lower roller (23) and the lower roll shaft (22) and the set of the upper roller (25) and the upper roll shaft (24), the roll shaft (22, 24) includes the roll shaft. There are provided passages (22a, 22b; 24a, 24b) through which the heated fluid flowing in from one end of the roll flows in the direction of the other end axis of the roll shaft (22) and flows outward in the radial direction, and the roller (23 25) provided with fluid reservoir spaces (23e, 25e) for receiving and storing the heated fluid that has flowed outward in the substantially radial direction, and then discharging the heated fluid. . The heating device according to claim 9, wherein
The passages (22a, 22b; 24a, 24b) are respectively connected to the set of the lower roller (23) and the lower roll shaft (22) and the set of both the upper roller (25) and the upper roll shaft (24). A heating device, which is provided. In the heating device according to claim 9 or 10,
The heating device according to claim 1, wherein the fluid reservoir space (23e, 25e) is provided in the vicinity of a part that is particularly molded locally in the cross section of the material (6). The heating device according to any one of claims 9 to 11,
At least one of the lower roller (23) and the upper roller (25) is configured by combining a plurality of roller portions (23a-23c; 25a-25c). The heating device according to any one of claims 9 to 12,
The heating device, wherein at least one set of the lower and upper roll shafts (22, 24) and rollers (23, 25) is integrally formed with a roll shaft and a roller.