KR101234834B1 - Method for making the long neck flange - Google Patents

Abstract

PURPOSE: A long neck flange manufacturing method is provided to reduce the time and the costs for processing by separately forming inner hollow holes. CONSTITUTION: A long neck flange(10) manufacturing method is as follows. One plane of a round plate(100) is processed so that a projected end portion(102) having a step is formed. A round bar(200) is positioned at a position corresponding to the projected end portion on a perpendicular direction of the plane of the round plate so that the round plate and the round bar are fixed. The round rod is tightly pressed when the round plate is rotated at a high speed. A side surface of the round rod and a surface of the projected end portion are closely adhered to each other, thereby generating friction heat. Friction surfaces are fused by friction heat generated by the friction of a side surface of the round rod and a surface of the projected end portion of the round plate so that the round rod and the round plate are welded. Through-holes(30) passing through the round plate and the round rod are formed.

Description

Method for making the long neck flange

The present invention relates to a method for manufacturing a long neck flange, and more particularly, a long neck flange, in which a connection part of a relatively long hollow tube is coupled to a flange portion of a disc shape, is simplified in a low cost and a small time. It relates to a long neck flange manufacturing method for manufacturing.

Pipes are generally used for the delivery of fluids. These pipes require continuous connection of pipes due to their length limitations or to change their orientation.

Flange generally refers to the edge portion of the joint connecting the tubular body is coupled to one end of the tubular body to be connected to each other to be coupled to each other against the flange of the corresponding portion.

In particular, the long neck flange is a flange in which the connection portion of the elongated hollow tube shape is integrally coupled to the flange portion. 'Long neck flange' is a flange widely used in pipe joints of power plants, shipyards, chemical plants, etc., and means a flange when the length of the hollow tube type connection is quite long, and the water pipe to be connected to the long neck flange is a considerable distance. It is used when you are away. It is also called 'long welding neck flange' in the sense that 'long neck flange' is connected by water pipe and (manual) welding.

Figure 1 is a perspective view and a cross-sectional view for explaining the general shape of the long neck flange of FIG.

Referring to Figure 1, the long neck flange (long neck flange) is a state in which the connection portion 20 of the elongated hollow tube is integrally coupled to the disk-shaped flange portion 10. When the flange portion 10 is connected to the flange and the flange is formed with a plurality of fastening holes 12 for inserting the bolt, the connection portion 20 formed with a hollow hole 30 therein is cylindrical, long neck flange The length of the connection part is approximately 100 mm or more, as well as the long neck flange having a connection part of 300 mm, 400 mm, 500 mm, 700 mm which are used in general, as well as a long neck flange of 1000 mm, 1500 mm, 2000 mm, 3000 mm or more may be used.

As a method of manufacturing a long neck flange, a method of directly cutting the round bar itself and a method of cutting the part after forging one side of the round bar are widely used.

The method of cutting round rods is a method of directly cutting round rods having an outer diameter corresponding to the outer diameter of the flange portion to produce long neck flanges, except in the case where the material cost of the round rods is extremely high or forging is impossible or unreasonable. Is applied.

In general, the method of forging is widely used, a method of using a round bar corresponding to the outer diameter of the connecting portion, forging a side of the round bar to form a disk shape, and then to produce a long neck flange by cutting. .

However, such a forging method has a disadvantage in that the connection part is very long, or in the case of a material that is difficult to forge or a material that is deformed in the forging. In the case of a long neck flange of about 500 mm or more in length, the bending part of the round bar (connecting part) may be bent during forging, or a crack may be generated at the joining part (between the flange part and the connecting part) and the defective product may be mass produced. Forging process cost is determined that the sugar processing cost is excessively consumed. In addition, forging molding cannot be used even when forging molding is difficult, or when forging molding is difficult due to deformation of a material or generation of bubbles or cracks during forging molding. If such a forging method is impossible or unreasonable, there is no choice but to use a method of directly cutting a round bar that requires a huge material cost (material cost).

In addition to such a general method, a new method has been proposed as a method of manufacturing a long neck flange (Korean Patent Registration No. 0688066). The method of this patent is shown in FIG. 2.

According to the method of the patent, the through hole 18 is formed in the center of the flange portion 10, and the coupling hole 12 having an oblique angle of inclination around the through hole is formed, and in the connection portion 20 also the through hole ( After forming 28 in advance, a side line 22 having an oblique inclination angle is formed at the end, and the connecting portion 20 is coupled to the flange portion 10 while rotating at a high speed to manufacture a long neck flange.

However, the conventional method according to FIG. 2 combines the engagement tool 12 and the side line 22 with the primary machining of individually perforating the through holes 18 and 28 in the flange portion 10 and the connecting portion 20, respectively. The second processing is to be carried out separately, so processing time and processing cost are excessively consumed, and it is difficult to accurately grasp the position where the connection part 20 should stop when consolidating the connection part 20 to the flange part 10. In case of making a long neck flange with a long length, it is also not easy to rotate the connector by biting the connector with a chuck. There was a drawback of considerable.

Therefore, there is a need for a long neck flange manufacturing method of a new method that can solve all the above problems.

The present invention is to solve the above problems, an object of the present invention is to reduce the cost of the product by reducing the loss of material costs, to reduce the processing time and processing costs consumed by forming the respective hollow holes, flange portion The product is secured by the tight coupling between the connector and the joint, and the rotation of the flange alone prevents safety accidents during the manufacturing process. It is to provide a method of manufacturing a long neck flange that can be easily applied.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood from the following description.

The present invention is to achieve the above object, the manufacturing method of a long neck flange according to a preferred embodiment of the present invention, the step of forming a protruding end stepped by processing one plane of the disc; Fixing the disc and the round bar, respectively, by positioning the round bar in the vertical direction of the disc plane at a position corresponding to the protruding end of the disc; Consolidating the round bar while rotating the disc at high speed to melt the friction bar by frictional heat due to the adhesion between the side surface of the round bar and the surface of the protruding end of the round plate to weld the disc and the round bar; And

And forming a through hole 30 having a predetermined size passing through the disc and the round bar.

According to a preferred embodiment, the projecting end of the disc is formed such that the central portion is higher than the edge.

According to a preferred embodiment, the protruding end of the disc has a circular shape, the outer diameter of the protruding end is formed to be equal to the size of the outer diameter of the round bar.

As described above, the long neck flange manufacturing method of the present invention is a high-speed rotation of the disk in the disk state without the through-hole is formed inside the flange portion, and the round bar without the through-hole formed in the connection portion, Friction welding and coupling the disc and the round bar, and subsequently to form a through-hole integrally penetrating the center of the disc and the round bar.

The method of the present invention can reduce the processing time and processing cost by not having to form through holes in the disc and the round bar, respectively, and secure the product safety by the tight coupling of the disc and the round bar, and the combination of the disc and the round bar The circular rod is not rotated at a time, but the original plate rotates at a high speed to prevent a safety accident that may occur in the related art, and even when the length of the connecting portion where the forging process is impossible is more than 2000 mm or the hardness of the material is strong, Since the long neck flange can be manufactured by applying the manufacturing method, it is possible to drastically reduce the loss of material costs, and the work process can also be drastically reduced.

1 is a perspective view (a) and a cross-sectional view (b) of a general long-length flange.
Figure 2 is a perspective view according to the conventional method for manufacturing a long rack flange.
Figure 3 is a flow chart of a long neck flange manufacturing method according to a preferred embodiment of the present invention.
Figure 4 is a schematic cross-sectional view for explaining the manufacturing process according to the long neck flange manufacturing method according to an embodiment of the present invention.

Hereinafter, a method of manufacturing the long neck flange of the present invention with reference to the accompanying drawings will be described in more detail.

3 is a flowchart of a long neck flange manufacturing method according to a preferred embodiment of the present invention, Figure 4 is a schematic cross-sectional view for explaining the manufacturing process according to the long neck flange manufacturing method.

In the method of manufacturing a long neck flange of the present invention, a flange portion of a disc state in which a through hole is not formed at the center and a connecting portion in a round bar state in which a through hole is not formed at the center thereof are joined to each other by friction welding, and a flange portion and a connection portion are later formed. The technical feature is to form a through-hole penetrating the center of the.

Looking at the manufacturing process in detail with reference to Figures 3 and 4, first, to prepare a disc 100 having a predetermined outer diameter size. The size and thickness of the disc should be slightly larger than the outer diameter or thickness of the final flange, taking into account the part lost by the cutting process. This is of course the same in the case of round bar.

The disc 100 is a portion corresponding to the flange portion 10 when the long neck flange is finally completed. One side of the prepared disk is processed to form a protruding end 102 having a step (S10). (See Figure 4 (b))

The protruding end 102 is a part that is engaged with the round bar 200 during friction welding, and protrudes convexly with a step with respect to one side plane of the disc. The reason why the protruding end is formed is that the slag is formed on the side of the round bar during friction welding with the round bar 200 so that the disc and the round bar are friction welded smoothly.

 The protruding end 102 has a circular shape protruding from the disc 100, so that the round bar 200 corresponds to the protruding end 100 during friction welding. That is, preferably the outer diameter (d1) of the projecting end has the same size as the size (d2) of the outer diameter of the round bar coupled in the vertical direction to the disc.

On the other hand, the protruding end of the disc is formed so that the center portion is higher than the edge (h2> h1), which allows the round bar and friction welding to be sequentially joined from the center portion to prevent bubbles from being generated at the welding surface. In order to prevent the occurrence of cracks and thereby perform a friction welding of excellent quality.

Next, by placing the round bar 200 in the vertical direction of the disk plane at a position corresponding to the projecting end of the disk, the disk and the round bar is fixed respectively (S20).

The disc 100 is fixed by using the chuck to be rotated at high speed during friction welding, and the round bar 200 is firmly fixed to the hydraulic press because it must be advanced in the vertical direction of the disc.

Next, the round bar is compacted while melting the round bar to be melted by frictional heat to weld the round plate to the round bar (S30). That is, the step of welding the flange portion of the disc state and the connecting portion of the round bar state by friction welding.

In the state in which the disc 100 rotates at a high speed of about 350 to 400 rpm, the round bar 200 is advanced in the vertical direction of the disc plane by the force of the hydraulic press. As the round bar 200 moves forward, the projecting end 102 of the disc 100 is consolidated, and the disc 100 and the round bar 200 are melted by frictional heat due to adhesion between the side of the round bar and the surface of the protruding end of the disc. Welded.

In the present invention, since the disk is rotated at a high speed by the disk is chucked, it can be said to be considerably safer than the method of rotating the connection portion of the hollow tube in the prior art (Fig. 2). That is, in the conventional technique of FIG. 2, the connection part 20, which is a hollow tube, rotates at a high speed, and thus, in the manufacturing process of the long neck flange having a very long connection part, the flange part 10 is in a state in which the connection part 20 is rotating at a high speed. When the chuck does not catch the shake due to the high-speed rotation of the connection portion 20, the connection part is separated from the chuck can lead to a very dangerous situation. The high speed of the connection breaks out into a very dangerous weapon, much like a deadly weapon.

However, in the present invention, since the disk is rotated at a high speed by biting the disk, which is a relatively small size, in the long neck flange, the possibility that the disk is separated from the chuck is considerably low, thereby preventing a safety accident as in the prior art.

In this method, even if the length of the connecting part (round bar) of the long neck flange is very long, 2m, 3m or more, the disk and the bar can be welded to any number of times. Coupling has a strong bonding force that can not be compared with the manual welding method, and will have a coupling force that does not fall at all compared to the forging method.

4 (d) shows a state in which the disc and the round bar are joined by friction welding.

Since the protruding end is formed in the disc, it can be confirmed that molten slag is formed at the side of the round bar when the disc and the round bar are combined. The molten slag is the part where the melt at the joint portion comes out of the side during friction welding and hardens.

Next, in a state where the disc and the round bar are coupled, the through-hole 30 penetrating the disc and the round bar is integrally formed (S40). The through hole 30 may be formed using a U drill. In the state where the disc and the round bar are coupled to the chuck by being rotated at high speed, the through hole 30 is formed by penetrating the center of the disc and the round bar using a U drill. However, instead of rotating the product in which the disc and the round bar are combined, the U drill may rotate to form a through hole penetrating the disc and the round bar. Of course, the size of the through hole depends on the size of the outer diameter of the U drill.

Next, by processing the outer surface of the long neck flange, by forming a desired number of fastening holes in the disc (flange portion), the long neck flange as shown in Figure 1 is finally completed (S50).

Formation of the outer surface cutting and fastening holes for the long neck flange is a well known processing method, and thus a detailed description thereof will be omitted.

It is preferable that the through-hole is formed in the long neck flange and the outer surface of the long neck flange is formed later, and that the through-hole is formed, but the through-hole may be formed after the outer surface processing or the formation of the fastening hole. Will belong to the range.

The long neck flange manufacturing method of the present invention as described above will be referred to as a breakthrough method to improve the manufacturing method by the conventional forging process.

In the forging process, if the length of the connecting part is more than 2000mm, bending may occur in the connecting part or crack may occur in the flange part. Therefore, forging method that applies strong external pressure to one side cannot be applied. It was difficult to apply the method. However, the method of the present invention can be applied to all the cases even if it is impossible by the forging method can be produced a long neck flange, it is possible to significantly reduce the loss of material costs, there is an advantage that the work process can also be significantly reduced.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention may be embodied otherwise without departing from the spirit and scope of the invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the scope of the present invention, but are intended to be illustrative, and the scope of the present invention is not limited by these embodiments. The scope of protection of the present invention should be construed according to the following claims, and all technical ideas within the scope of the claims should be construed as being included in the scope of the present invention.

10: flange part
12: fastener
20: Connection
30: through hole
100: disc
102: protrusion
200: round bar

Claims (3)

In the manufacturing method of the long neck flange,
Processing one plane of the disc to form a stepped protrusion;
Positioning the round bar in the vertical direction of the disc plane at a position corresponding to the protruding end of the disc to fix the disc and the round bar respectively;
Consolidating the round bar while rotating the disc at high speed to melt the friction surface by frictional heat due to the adhesion between the side surface of the round bar and the protruding end surface of the disc to weld the disc and the round bar to each other; And
And forming a through hole of a predetermined size passing through the disc and the round bar. The method of claim 1,
Protruding end of the disc is a manufacturing method of a long neck flange, characterized in that the central portion is higher than the edge. The method of claim 1,
The protruding end has a circular shape, the outer diameter of the protruding end is a method of manufacturing a long neck flange, characterized in that the same as the size of the outer diameter of the round bar.

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