WO2013031803A1 - Manufacturing method and manufacturing equipment for small diameter metal tube - Google Patents

Abstract

Small diameter metal tubes are manufactured with good precision and high production efficiency by using a large diameter roll in which rolls having diameters that are clearly larger than the outer diameter of the metal tube being manufactured are disposed. A pair of large diameter side rolls is used, the rolls being designed so that the outer diameter ratio φ₂/ φ₁ of the outer diameter φ₂ of the forming roll to the outer diameter φ₁ of the metal tube being manufactured is 10 or more, preferably 25 or more. After forming a metal band into a cylindrical shape in a single stand, the edges of the metal band are brought together and welded. A three roll-type or a four roll-type can be used for the large diameter side roll.

Description

Manufacturing method and manufacturing apparatus for small diameter metal pipe

The present invention relates to a method for manufacturing a metal pipe, particularly a weld pipe having a small diameter such that the outer diameter is less than 20 mm, and an apparatus therefor.

溶 接 Generally, a manufacturing method using a roll forming method is adopted for manufacturing a welded metal pipe. The roll forming method is a method in which a metal strip is supplied to a plurality of roll forming stands, for example, which are arranged in tandem and have 10 or more stages, and the metal strip is continuously formed into a cylindrical shape (for example, Patent Document 1). See). Thereafter, both side edges (that is, edge parts) of the metal strip formed into a cylindrical shape are brought into contact with each other and welded to produce a metal tube.

However, in the roll forming method, the production line is composed of a plurality of roll forming stands, that is, multi-stage stands as described above. There is a problem that the load increases. Moreover, since the downtime of a production line becomes long with a roll exchange operation | work, there also exists a problem that the production efficiency of a weld metal pipe will fall.

Furthermore, when manufacturing a small-diameter metal tube having an outer diameter of 20 mm or less, the above-described roll forming method may cause meandering, twisting, or other forming defects in the metal band unless strict adjustment is performed on each stand. There is a problem that the production efficiency of the metal pipe is significantly reduced.

Therefore, when manufacturing a small-diameter metal tube having an outer diameter of 20 mm or less, it is preferable to reduce the number of forming stands as much as possible in order to improve work efficiency and productivity, more preferably a single stand. It is to be.

Incidentally, as a method for producing a welded metal pipe, a die draw forming method is adopted in addition to the roll forming method described above. The die draw forming method is a manufacturing method in which a metal band is continuously formed into a cylindrical shape by supplying the metal band to a forming die and then pulling it out from the forming die (see, for example, Patent Document 2). In this manufacturing method, the forming die used for forming the metal strip into a cylindrical shape may be one stage. That is, only one molding stand is required.

However, in the die draw forming method, when the metal strip is supplied to and extracted from the forming die, friction is remarkably generated between the forming die and the metal strip. Then, in order to suppress such friction, it has been proposed to apply lubricating oil to the surface of the metal strip (see Patent Document 2).

However, even if lubricating oil is applied to the surface of the metal band, if the metal band is wrinkled during the process of manufacturing the metal band, the metal powder that has fallen from the wrinkle remains in the metal die while remaining on the metal band. There is a problem that the metal powder is brought into the forming die. When metal powder accumulates in the forming die, unless the inside of the forming die is frequently maintained, it may cause surface flaws on the metal tube. If it does so, surface polishing processing must be performed as processing of surface flaws after manufacture of a metal tube. That is, even if the die draw forming method is used, problems such as a decrease in productivity and an increase in production cost occur.

By the way, regardless of the roll forming method and the die draw forming method described above, a laser welding method is adopted as a method of abutting and welding the edge portions of a metal strip formed into a cylindrical shape. The laser welding method is suitable from the viewpoint of the productivity and workability of the weld metal pipe.

JP-A-6-134525 JP-A-8-267150

As described above, the roll forming method is not only a problem that the work load associated with roll replacement work and dimension adjustment increases, but also when manufacturing small diameter metal tubes, meandering due to slight adjustment mistakes in the roll forming stand. There is a problem that defects are likely to occur when the edges of the metal band are abutted against each other, such as twisting and twisting.

Also, in the die draw forming method, a large amount of lubricating oil is used to suppress friction generated between the metal strip and the forming die. Therefore, there is a problem that laser welding cannot be performed unless degreasing is performed after the metal tube is formed into a cylindrical shape.

The present invention has been proposed to solve such problems. That is, only a single roll having a diameter that is clearly larger than the outer diameter of the metal pipe to be manufactured, that is, a single-stand large-diameter roll is used. And, to provide a method and apparatus for manufacturing a small-diameter metal pipe which is formed into a cylindrical shape with high accuracy without using lubricating oil, and then welds and joins the edges of the metal band. Objective.

In order to achieve the object, the small diameter metal tube manufacturing method of the present invention has an outer diameter ratio φ ₂ / φ ₁ of the outer diameter φ ₁ of the metal tube to be manufactured and the outer diameter φ _{2 of the} roll of at least 10 or more. A large-diameter side roll is used, the large-diameter side roll is composed of at least a first large-diameter side roll and a second large-diameter side roll, and a metal strip is supplied to the large-diameter side roll, and the metal strip is cylindrical After being formed, the edge portion of the metal strip is welded.

The outer diameter ratio φ ₂ / φ ₁ is preferably 25 or more. Furthermore, as will be described later, in order to improve the butt shape at the time of welding, the metal band is supplied to the edge bend roll before the metal band is supplied to the large-diameter side roll, and the edge of the metal band in advance It is preferable to bend the part.

The large-diameter roll stand used by the execution of the present invention is preferably arranged in a three-way roll system composed of two large-diameter side rolls and one bottom roll (FIG. 8 (A )). FIG. 8A is a cross-sectional view showing the structure of a three-way roll type large-diameter side roll in which a bottom roll is arranged, as will be described later. Specifically, for the arrangement of the rolls, a pair of large-diameter side rolls are installed side by side so that their rotational axes are parallel and their outer peripheral surfaces face each other. Then, the bottom roll is disposed so that the outer peripheral surface of the bottom roll is positioned in the vicinity of the facing portion where the outer peripheral surfaces of the two large-diameter side rolls face each other. In the facing portion, the edge portions are brought into contact with each other when the metal tube is formed. Further, the rotation axis of the bottom roll is substantially orthogonal to the rotation axes of the two large-diameter side rolls. Further, the bottom roll is offset from the upstream side in the traveling direction of the metal strip (that is, the entry side of the production line) with reference to the line connecting the rotation axes of the pair of large-diameter side rolls. Preferably (see FIG. 10). FIG. 10 is a top view showing a more preferable installation position of the bottom roll used in the three-way roll type large-diameter side roll of the present invention, as will be described later. As described above, by arranging the bottom roll offset on the upstream side in the traveling direction of the metal strip, it is possible to further reduce the strain generated when the metal tube is formed.

In addition, in the above three-way roll method, a four-way roll method in which fin rolls are further arranged may be adopted (see FIG. 11). The fin roll is disposed at the facing portion so that the outer circumferential surface faces the outer circumferential surface of the bottom roll and the rotation axis is parallel to the rotation axis of the bottom roll. By arranging the fin rolls in this way, the position at which the edge portion of the metal band is abutted can be maintained with high accuracy.

Furthermore, a fin roll may be arranged on the upper part of the squeeze roll immediately before the edge of the metal strip is welded and joined at the position of the squeeze roll. By this fin roll, it is possible to suppress the twist of the butting position of the edge portion of the metal strip at the position of the fin roll (see FIG. 13). The fin roll used at this time is preferably provided with a fin and a concave surface having a radius of curvature larger than the radius of the metal tube to be manufactured. Because, by using the above-described fin roll, the fin accurately positions the butt portion at a preferred position for the next welding, and presses the edge portion of the metal strip by the concave surface to butt the edge portion. This is because the shape when hitting can be corrected. Thereby, a small-diameter metal tube with excellent forming accuracy can be obtained.

In the present invention, by using a side roll having an outer diameter that is clearly larger than the outer diameter of the metal tube to be manufactured, the metal strip can be formed into a cylindrical shape with a single stand, but has a small diameter with excellent surface properties. It is possible to manufacture a metal tube with high efficiency. In addition, by forming the metal strip into a cylindrical shape with a single stand, the total number of stands required for manufacturing the metal tube can be greatly reduced, and the work of roll replacement and dimension adjustment by the operator can be reduced. It is. Furthermore, it is possible to stably manufacture a small-diameter metal tube by appropriately using a fin roll.

(A) is a perspective view showing a positional relationship between a schematic structure of a large-diameter side roll used in the present invention and a welding machine that welds and joins a butt portion of an edge. (B) is an enlarged view which shows the groove part of a large diameter side roll. It is a figure which shows the relationship between outer diameter ratio (phi) ₂ / (phi) _1, and the equivalent plastic strain which arises in the edge part of a metal strip. It is the schematic of the manufacturing line used for manufacture of the small diameter metal pipe of this invention. It is sectional drawing which shows schematic structure of an edge bend roll. It is sectional drawing which shows schematic structure of a large diameter side roll. It is a figure which shows curving the edge part of a metal strip using two large diameter side rolls. It is a figure which shows the condition where a part of metal belt under deformation has produced a problem between two large-diameter side rolls. (A) is sectional drawing which shows the structure of the three-way roll system large diameter side roll which has arrange | positioned the bottom roll, (B) is an enlarged view which shows the positional relationship of two large diameter side rolls and a bottom roll. It is a top view which shows the installation position of the bottom roll used for the three-way roll system large diameter side roll of this invention. It is a top view which shows the more preferable installation position of the bottom roll used with the three-way roll system large diameter side roll of this invention. It is sectional drawing which shows the structure of the 4-way roll system large diameter side roll which has arrange | positioned the 1st fin roll to the 3-way roll system large diameter side roll of this invention. It is a figure explaining the condition of the metal belt at the time of arranging 1 stage of fin rolls. It is a figure explaining the condition of a metal belt at the time of arranging two stages of fin rolls. It is a figure explaining the shape of the edge part in the butt | matching part of a large diameter metal tube. It is a figure explaining the shape of the edge part in the butt | matching part of a small diameter metal pipe. It is a figure which shows the desirable shape of the 2nd fin roll arrange | positioned just before a squeeze roll.

¡Metal tube forming using the roll forming method is generally gently formed by multi-stage forming using ten or more roll forming stands arranged in tandem. For this reason, when changing the diameter of the metal tube to be manufactured, it is necessary to replace all the rolls arranged on the forming stand with ones corresponding to the outer diameter of the metal tube to be manufactured. Moreover, since much labor and time are required for the roll exchange, the productivity is reduced.

Therefore, the present invention has found a means for gently forming a metal strip into a cylindrical shape with a single stand and reducing the strain of the metal strip generated during roll forming. The details will be described below.

The large-diameter side roll used in the present invention will be described with reference to FIG. The large-diameter side rolls 42 and 44 (see FIG. 1A) according to the present invention have a considerably large ratio φ ₂ / φ ₁ of the outer diameter φ ₂ of the forming roll to the outer diameter φ ₁ of the metal tube to be manufactured. To design. The outer diameter ratio φ ₂ / φ ₁ is 10 or more, preferably 25 or more.

The large-diameter side rolls 42 and 44 designed so that the outer diameter ratio φ ₂ / φ ₁ is increased in this way can be regarded as a forming die used in the die draw forming method. That is, according to the present invention, when the metal strip 100 is formed into a cylindrical shape, it can be formed with a single stand instead of a multi-stage stand. However, the present invention does not require the lubricating oil used in the die draw forming process.

In addition, the manufacturing method of the metal tube by this invention is suitable for manufacturing the small diameter metal tube in which an outer diameter is less than 20 mm. This is because the metal tube manufacturing method according to the present invention requires a large-diameter side roll having a considerably large outer diameter ratio according to the outer diameter of the metal tube to be manufactured. That is, when manufacturing a small-diameter metal tube having an outer diameter of less than 20 mm, it is possible to use a large-diameter side roll having an actual diameter, but when manufacturing a metal tube having an outer diameter of more than 20 mm. This is not practical because it is necessary to prepare a large-diameter side roll having a considerably large diameter, and is disadvantageous in that the cost increases.

Here, a preferable relationship of the outer diameter ratio φ ₂ / φ ₁ between the outer diameter φ ₁ of the metal tube to be manufactured and the outer diameter φ ₂ of the forming roll will be described. By using a side roll having a large outer diameter ratio φ ₂ / φ _1, which is a ratio of the outer diameter φ ₂ of the forming roll to the outer diameter φ ₁ of the metal pipe to be manufactured, the metal band can be gently roll-formed. . That is, it can shape | mold, reducing the distortion which arises during shaping | molding.

FIG. 2 shows the relationship between the outer diameter ratio φ ₂ / φ ₁ and the equivalent plastic strain generated at the edge of the metal strip (see FIG. 2A). By setting the outer diameter ratio φ ₂ / φ ₁ to 10 or more, the metal band can be formed into a cylindrical shape in a state in which the strain generated particularly 0.25 mm inside from the edge portion of the metal band is even smaller (FIG. 2). (See (B)). Further, by setting the outer diameter ratio φ ₂ / φ ₁ to 10 or more, it is possible to form the metal strip with good cross-sectional shape when the edge portion is curved and without warping. On the side surface of the metal strip (see FIG. 2B), when the outer diameter ratio φ ₂ / φ ₁ is about 25, it becomes constant at a low level.

Therefore, the outer diameter ratio φ ₂ / φ ₁ is more preferably 25 or more. The upper limit of the outer diameter ratio need not be specified, but it is practical to set it to about 80. This is an upper limit that can be considered by the fact that the effect of reducing the strain generated at the edge of the metal strip is saturated at an outer diameter ratio φ ₂ / φ _{1 of} about 80, and considering the roll cost.

Prior to forming the metal strip 100 into a cylindrical shape using the single-sided large-diameter side rolls 42 and 44, the metal strip 100 is preferably supplied to the edge bend roll. Thereby, it becomes possible to bend the edge part of the metal strip 100 in advance, and to smoothly curve the edge part in the large-diameter roll.

The manufacturing method of the present invention will be described with reference to FIG. FIG. 3 shows an outline of a practical production line used for producing the small-diameter metal tube of the present invention.

The metal strip 100 is supplied to the edge bend roll stand 30 with both edges of the metal strip 100 being aligned by the guide 20 while being pressed by the plate presser 10. The metal strip 100 is curved at both edges by the edge bend rolls 34 and 32 according to the side end R of the edge bend roll, and then formed into a cylindrical shape at the large diameter side rolls 42 and 44 of the large diameter roll stand 40. The Then, the position accuracy of the butting position of the edge portion of the metal strip 100 is increased by the fin roll 80, and the metal strip 100 is supplied to the squeeze roll stand 50, and the butted portion is welded and joined by the welding machine 120. Through these steps, the metal pipe 70 is manufactured from the metal strip 100. Reference numeral 60 denotes a drawing device.

As shown in FIG. 4, the edge bend roll stand 30 includes a pair of upper and lower rolls, that is, a first edge bend roll 32 having a concave groove with a side end R attached to one edge bend roll, and the other edge. It is comprised from the 2nd edge bend roll 34 which has a protruding item | line with the side end R attached | subjected to the bend roll.

When the metal strip 100 is supplied to the edge bend roll stand 30, both edge portions of the metal strip 100 are curved according to the side end R of the edge bend roll. Further, the metal strip 100 is supplied to the large-diameter side roll stand 40 (see FIGS. 1 and 5) and formed into a cylindrical shape.

The metal strip 100 is formed into a cylindrical shape in the large-diameter side rolls 42 and 44 in such a manner that the metal strip 100 after being supplied to the edge bend roll is pressed by the pair of large-diameter side rolls 42 and 44 from the left and right. (See FIG. 6). Here, a gap is formed between one large-diameter side roll (first large-diameter side roll 42) and the other large-diameter side roll (second large-diameter side roll 44) (see P in FIG. 7). Is formed. When the metal strip 100 receives pressure from these large-diameter side rolls 42 and 44, a part of the metal strip 100 escapes into the gap P, and a defect may occur in the formed cylindrical shape (see FIG. 7).

In order to prevent a part of the metal strip 100 from escaping, a so-called “receiving portion” is provided at the position of the gap P formed between the first large-diameter side roll 42 and the second large-diameter side roll 44. "Is preferably arranged.

The “receiving part” will be described with reference to FIG. The first large-diameter side roll 42 and the second large-diameter side roll 44 have an inclination of about 30 degrees from the outermost side to the inner side in the radial direction at one of the axial ends. It has been cut so that. More specifically, as shown in FIG. 8, the metal band back surface side of the first large-diameter side roll 42 (that is, in FIG. 8) so that an inclination of about 30 degrees is formed from the radially outermost side to the inner side. The lower side of the paper surface is cut, and the back side of the metal band of the second large-diameter side roll 44 (that is, the paper surface of FIG. 8) so that an inclination of about 30 degrees is formed from the outermost side to the inner side in the radial direction. The lower side is cut so that an inclination of about 30 degrees is formed. A bottom roll 90 is disposed between the two large-diameter side rolls 42 and 44 that are inclined in this way (see FIG. 8A). The bottom roll 90 becomes a “receiving portion”. By arranging the bottom roll 90 on the large-diameter side roll stand 40, it is preferable to adopt a three-way roll system.

The arrangement of the bottom roll 90 will be described with reference to FIGS. 9 and 10. The center line O ′ of the bottom roll 90 is arranged so as to coincide with a line O (hereinafter referred to as “orthogonal line O”) that is substantially orthogonal to the respective rotation axes of the first and second large-diameter side rolls 42 and 44. In such a case (see FIG. 9), problems may occur when the metal strip 100 is formed into a cylindrical shape. This is presumably because if the orthogonal line O and the center line O ′ of the bottom roll 90 coincide with each other, the metal strip 100 is constrained in the circumferential direction, resulting in excessive distortion.

When the orthogonal line O of the large-diameter side rolls 42 and 44 and the center line O ′ of the bottom roll coincide with each other, the metal strip 100 is supplied to the two large-diameter side rolls 42 and 44 as described above. Before being supported by the bottom roll 90, the bottom of the metal strip 100 may slide downward and bend. The bottom of the bent metal strip 100 is then supported by the bottom roll 90 and lifted to be bent or bent back again. Thereby, it is estimated that the metal strip 100 is excessively strained to cause a defect.

Therefore, in the present invention, the bottom roll is on the opposite side of the traveling direction of the metal strip 100 (the traveling direction X of the production line) with respect to the orthogonal line O of the large-diameter side rolls 42 and 44 (that is, the upstream side of the production line). An offset is arranged (see Q in FIG. 10). As a result, an escape path is created without the entire circumference of the metal strip 100 being constrained, and excessive deformation due to bending or unbending is reduced, and the amount of strain generated can be greatly reduced. Thereby, the shape and quality of the molded metal strip 100 are greatly improved.

A metal tube is manufactured by abutting and welding the edge portions of the metal strip 100 formed into a cylindrical shape. As shown in FIG. 3, in a state where the metal strip 100 formed into a cylindrical shape is held by the squeeze roll stand 50, the edge portions are abutted and welded together by the welding machine 120. The welding method is preferably a laser welding method from the viewpoint of productivity and workability of the manufactured welded metal pipe.

The welding method is not limited to the laser welding method, and arc welding methods such as TIG welding and plasma welding may be used, and other high-frequency welding methods may be used.

Not only in the laser welding method, but when the edge portion of the metal strip 100 is butted and welded, the positioning accuracy of the butting position is high, and the butted portion extends in a straight line along the traveling direction X of the production line. preferable. In order to increase the positioning accuracy of the butting position, in the present invention, in the large-diameter side roll stand 40, in addition to the bottom roll 90, a first fin roll 80 is added to the butting portion side and roll forming is performed by a four-way roll method. It is preferable to do so (see FIG. 11).

By the way, even if the metal tube is roll-formed by providing the fin roll 80 on the metal band surface side of the large-diameter side rolls 42 and 44 (that is, directly above the large-diameter side roll in the paper surface of FIG. 11) (see FIG. 11). After the molding with the large-diameter side rolls 42 and 44, the metal strip 100 is twisted in the circumferential direction until it is conveyed to the squeeze roll stand 50, which may cause problems in welding (for example, see FIG. 12). ). This is considered to be due to the deviation of the centering position of the steel strip when feeding the metal strip 100 as the raw material into the production line and the deviation of the roll center such as a large-diameter side roll or squeeze roll. However, it is difficult to adjust such a shift manually, which leads to an increase in cost and is not realistic.

Therefore, in the present invention, as shown in FIG. 11, not only the first fin roll 80 is provided on the metal band surface side of the large-diameter side rolls 42, 44, but also the metal band 100 is formed as shown in FIG. Immediately before being supplied to the squeeze roll stand 50, a second fin roll 82 was provided on the side opposite to the metal band side with respect to the squeeze roll (that is, the upper side of the squeeze roll).

That is, by using the two fin rolls 80 and 82 at the same time, the butt position of the edge portion can be determined with high accuracy at two locations along the traveling direction X of the production line, so that the butt portion extends in a straight line. Is ensured. Thereby, more stable continuous welding is possible.

Furthermore, when the metal strip 100 is continuously roll-formed, the strain applied to each part of the steel strip is not uniform and is biased by various factors. Therefore, the shape of the edge portion of the metal strip 100 becomes unstable, and a difference in the edge position is likely to occur. Even when the step does not occur, for example, as shown in FIG. 15, the edge portion is likely to be poorly matched, and welding may be difficult.

This phenomenon becomes more prominent as the diameter of the metal tube to be manufactured becomes smaller. That is, as shown in FIG. 14, when the diameter of the metal tube to be manufactured is relatively large (see FIG. 14A), the shape of the butt between the edge portion 110a and the edge portion 110b is I-type. (See FIG. 14B), it is possible to butt and weld without problems. However, when the diameter of the metal pipe to be manufactured is reduced (see FIG. 15A), the shape of the abutting position between the edge portion 110c and the edge portion 110d is V-shaped as seen in FIG. 15B. And cause poor welding.

Therefore, in the present invention, immediately before the steel strip is supplied to the squeeze roll stand 50, the second side is opposite to the side of the metal strip 100 based on the squeeze roll (that is, the upper side of the squeeze roll). A fin roll 82 was placed (see FIG. 16). Specifically, the second fin roll 82 includes fins 82a and a pressing surface 88 having a radius of curvature larger than the radius of the metal tube to be manufactured. By using this second fin roll 82, the fin accurately positions the butt portion at a preferred position for the next welding, and presses the edge portion of the metal strip 100 by the concave surface to The shape of the butting position can be corrected.

Example 1;
An example of manufacturing a metal tube with an outer diameter of φ6.5 mm (φ ₁ ) using a ferritic stainless steel strip with a thickness of 0.5 mm having a composition of 18Cr-1Mo—Ti—low carbon and low nitrogen will be introduced.

The production line shown in FIG. 3 was used. As the edge bend roll, a roll having a shape shown in FIG. 4 was used. The large-diameter side rolls 42 and 44 have the shapes shown in FIGS. 5 and 7 (φ ₂ = 300 mm, outer diameter ratio φ ₂ / φ ₁ = 46). The bottom roll has an outer diameter of 62 mm, and the offset Q of the large-diameter side roll is 0 mm in the upstream direction of the production line with respect to the center line, and 12 mm, 14 mm, 15 mm, 16 mm, 18 mm and 20 mm. . The first fin roll 80 is disposed on the metal band surface side of the large-diameter side rolls 42 and 44 (that is, the upper side of the large-diameter side rolls 42 and 44). The squeeze roll stand 50 was not placed at the position immediately before.

The above material was passed through under the condition that the line speed was 4 m / min, and a metal tube was manufactured by fiber laser welding on a squeeze roll under conditions of an output of about 900 W and a beam diameter of 0.6 mm. No lubricant was used. As a result, when the offset Q was 0 mm, wrinkles were observed on the outer surface of the obtained metal tube, and the roundness was poor. On the other hand, when the offset was set, there was no wrinkle on the outer surface at any offset amount, and a metal tube with good roundness could be manufactured.

Example 2;
Next, a case where a metal tube having an outer diameter of φ3.7 mm (φ ₁ ) is manufactured from a ferritic stainless steel strip having a thickness of 0.3 mm having a composition of 16.5Cr—Ti—low carbon and low nitrogen will be introduced.

The production line shown in FIG. 3 was used. An edge bend roll having a diameter of 100 mm was used. Large- diameter side roll 42 and 44, the case where phi ₂ is used as a 100 mm, was performed in the case of using those 300 mm. The outer diameter ratio φ ₂ / φ ₁ is 27 and 81, respectively. Using a bottom roll with an outer diameter of 62 mm and using the orthogonal line O of the large-diameter side rolls 42 and 44 as a reference, the offset Q is 0 mm, 10 mm, 12 mm, 14 mm, 15 mm, and 16 mm on the upstream side in the traveling direction of the metal strip 100. , 18 mm and 20 mm. A metal tube was manufactured under the conditions of a line speed of 4 m / min, a fiber laser output of about 500 W, and a beam diameter of 0.6 mm. No lubricant was used.

In the fin roll, the first fin roll 80 is disposed above the large-diameter side rolls 42 and 44, and the second fin roll 82 is not disposed immediately before the squeeze roll stand 50. As a result, when the outer diameter ratio φ ₂ / φ ₁ was 27 or 81, when the offset Q was 0 mm, wrinkles were observed on the outer surface of the obtained metal tube, and the roundness was poor. It was. When the offset Q was set, there was no wrinkle on the outer surface at any offset amount, and a metal tube with good roundness could be manufactured.

Example 3;
Also introduced is a case where a metal tube with an outer diameter of φ6.5 mm (φ ₁ ) was manufactured using a ferritic stainless steel strip with a thickness of 0.3 mm, which also has a composition of 16.5Cr—Ti—low carbon and low nitrogen. To do.

The same production line, edge bend roll, large-diameter side rolls 42 and 44, and bottom roll as those in Example 1 were used. That is, the outer diameter ratio φ ₂ / φ ₁ is 46.

In Example 3, the offset Q of the bottom roll is set to 0 mm, 5 mm, 7 mm, 10 mm, 12 mm on the upstream side in the traveling direction of the metal strip 100 with reference to the orthogonal line O of the large-diameter side rolls 42, 44. There were 8 types of 15 mm, 18 mm and 20 mm. In either case, the fin roll 80 is disposed on the upper side of the large-diameter side rolls 42 and 44, and in this third embodiment, immediately before the squeeze roll stand 50, The fin roll 82 was installed on the opposite side (that is, the upper side of the squeeze roll). Two types of fin rolls 82 immediately above the squeeze roll stand 50 have a pressing surface with a radius of curvature of 5 mm and 10 mm. As a result, a total of 16 types of metal tubes were manufactured. No lubricant was used.

Then, the material steel strip was passed through under the condition that the line speed was 10 m / min, and fiber laser welding was performed on the squeeze roll under conditions of an output of about 1500 W and a beam diameter of 0.6 mm.

In each of the above manufacturing conditions, when the offset Q was 0 mm, wrinkles were observed on the outer surface of the obtained metal tube, and the roundness was poor. When the offset Q was set, there was no wrinkle on the outer surface at any offset amount, and a metal tube with good roundness could be manufactured.

Example 4;
In addition, an outer diameter φ6.5 mm (φ ₁ ) using a material obtained by applying aluminum plating on both sides of a 0.5 mm thick ferritic stainless steel strip having a composition of 16.5Cr—Ti—low carbon and low nitrogen. The metal tube was manufactured.

The same production line, edge bend roll, large-diameter side roll, and bottom roll as those in Example 1 were used. That is, the outer diameter ratio φ ₂ / φ ₁ is 46.

In Example 4, the offset Q of the bottom roll is 3 mm, 5 mm, 7 mm, 10 mm, 15 mm on the upstream side in the traveling direction of the metal strip 100 with reference to the orthogonal line O of the large-diameter side rolls 42, 44. It was. The fin roll was installed only on the upper side of the large-diameter side rolls 42 and 44, and was not installed on the upper side immediately before the squeeze roll stand 50.

Then, fiber laser welding was performed under the conditions of a line speed of 2 m / min, an output of about 580 W on a squeeze roll, and a beam diameter of 0.6 mm.

As a result, the above-mentioned aluminum-plated stainless steel strip can be used as a raw steel strip, and in each of the above manufacturing conditions, there can be no flaws on the outer surface at any offset amount, and a metal tube with good roundness can be manufactured. It was.

10 plate holder 20 guide 30 edge bend roll stand 32 first edge bend roll 34 second edge bend roll 40 large diameter side roll stand 42 first large diameter side roll 42a groove section of first large diameter side roll 44 first Second large-diameter side roll 44a Groove portion of second large-diameter side roll 50 Squeeze roll stand 60 Drawing device 70 Metal tube 70a Large-diameter metal tube 70b Small-diameter metal tube 80 First fin roll 82 Second fin roll 82a Fin 88 Press surface 90 Bottom roll 100 Metal strip 110a Edge part 110b Edge part 110c Edge part 110d Edge part 120 Welding device O Orthogonal line O 'Center line of bottom roll P Gap generated between two large-diameter side rolls Q Offset X Production line Direction of travel

Claims (16)

1. Using a large-diameter side roll whose outer diameter ratio φ ₂ / φ ₁ between the outer diameter φ ₁ of the metal tube to be manufactured and the outer diameter φ _{2 of the} roll is at least 10 or more,
   The large-diameter side roll comprises at least a first large-diameter side roll and a second large-diameter side roll,
   After the metal strip is supplied to the large-diameter side roll and the metal strip is formed in a cylindrical shape, the edge portion of the metal strip is welded and joined.
2. The method for manufacturing a metal tube according to claim 1, wherein a large-diameter side roll having an outer diameter ratio φ ₂ / φ ₁ of 25 or more is used.
3. The metal tube manufacturing method according to claim 1 or 2, wherein an edge portion of the metal strip is curved in advance by an edge bend roll before the metal strip is supplied to the large-diameter side roll.
4. The first large-diameter side roll, the second large-diameter side roll, and a bottom roll are arranged in a three-way roll method. The metal tube production according to claim 1, Method.
5. The bottom roll is a metal band back side of the first large-diameter side roll and the second large-diameter side roll, and a rotation axis of the first large-diameter side roll and the second large-diameter side roll. The metal pipe manufacturing method according to claim 4, wherein the metal tube is offsetly arranged on a side opposite to a supply direction of the metal strip with reference to a straight line connecting the two.
6. The metal tube according to claim 1, 4 or 5, wherein at least one fin roll is disposed on the metal band surface side of the first large-diameter side roll and the second large-diameter side roll. Manufacturing method.
7. At least one fin roll is disposed on the side opposite to the metal band side based on the squeeze roll that welds and joins the edge of the metal band after the metal band is formed in a cylindrical shape. The manufacturing method of the metal tube of Claim 1, 4 or 5.
8. A fin roll disposed on the side opposite to the metal band side based on the squeeze roll,
   It is provided with a fin and a pressing surface having a radius of curvature larger than the radius of the tube to be manufactured, and the pressing surface corrects the shape of the edge portion while pressing the edge portion of the metal strip. The manufacturing method of the metal tube of Claim 7.
9. A large-diameter side roll having an outer diameter ratio φ ₂ / φ ₁ of at least 10 or more between the outer diameter φ ₁ of the metal tube to be manufactured and the outer diameter φ ₂ of the roll is provided,
   The large-diameter side roll comprises at least a first large-diameter side roll and a second large-diameter side roll,
   A squeeze roll and a welding device are further provided downstream of the large-diameter side roll.
10. The method for producing a metal tube according to claim 9, wherein a large-diameter side roll having an outer diameter ratio φ ₂ / φ ₁ of 25 or more is used.
11. 11. The method of manufacturing a metal tube according to claim 9, wherein an edge bend roll for bending the edge of the metal strip is disposed before the metal strip is supplied to the large-diameter side roll.
12. The first large-diameter side roll, the second large-diameter side roll, and a bottom roll are arranged in a three-way roll method. The metal tube manufacturing according to claim 9, apparatus.
13. The bottom roll is offset from the supply direction of the metal strip with reference to a straight line connecting the rotation axes of the first large-diameter side roll and the second large-diameter side roll. The metal pipe manufacturing apparatus according to claim 12, wherein the apparatus is a metal pipe manufacturing apparatus.
14. The metal pipe according to claim 9, 12 or 13, wherein at least one fin roll is disposed on the metal band surface side of the first large-diameter side roll and the second large-diameter side roll. Manufacturing equipment.
15. At least one fin roll is disposed on the side opposite to the metal band side based on the squeeze roll that welds and joins the edge of the metal band after the metal band is formed in a cylindrical shape. The apparatus for manufacturing a metal tube according to claim 9, 12 or 13.
16. A fin roll disposed on the side opposite to the metal band side based on the squeeze roll,
    It is provided with a fin and a pressing surface having a radius of curvature larger than the radius of the tube to be manufactured, and the pressing surface corrects the shape of the edge portion while pressing the edge portion of the metal strip. The apparatus for manufacturing a metal tube according to claim 15.

Images