KR100941366B1 - Method for manufacturing drum for heat recovery steam generator using frequency-heat-treatment - Google Patents

Abstract

PURPOSE: A method for manufacturing a drum for a heat recovery device using a frequency heat treatment device is provided to reduce the manufacturing time of a drum. CONSTITUTION: A method for manufacturing a drum for a heat recovery device using a frequency heat treatment device is as follows: A steel plate(6) is penetrated through a frequency heat treatment device by a first transfer unit(1), and rapidly heated by the frequency heat treatment device. The heated steel plate is transferred to a banding machine(3). The steel plate is inserted into a main roller(31) and multiple auxiliary rollers(32), and rolled. The steel plate surrounds the main roller by a guide member. An auxiliary frequency heat treatment device(2) is installed between the auxiliary rollers, and continuously maintains the temperature of the heated steel plate.

Description

Method for manufacturing drum for heat recovery steam generator using frequency-heat-treatment}

The present invention relates to a method for manufacturing a drum to withstand high pressure for use in a waste heat recovery device, the drum used in the waste heat recovery device uses a thick steel plate to withstand high temperature and high pressure. In the present invention, the iron plate is heated by using a frequency heat processor, and the heated iron plate part is rolled into a complete drum form through a banding machine, and then the welding part is formed as a part (1 seam) against both ends of the rolled iron plate. It is about how to produce.

In various industries, waste heat is discharged in the form of waste gas, waste air, waste hot water, and waste steam.The amount of waste heat discharged by the main equipment is 8-20% for various boilers, 10-50% for various drying facilities, Large air conditioning facilities emit 30-50%.

Such waste heat may be difficult to recover economically, but the energy efficiency has been improved by the technology development of the waste heat recovery apparatus including the high pressure drum.

In general, a method of manufacturing a thick iron plate in the form of a drum has been adopted a method of welding two iron plates that are banded in a semicircle form.

In order to bend the steel plate in semi-circular form, first, the steel plate is heated and the heated iron plate is bent in two rounds, first and second, so that the steel plate is rolled into a semi-circular shape. The butt parts are welded to each other to form a drum.

Non-destructive inspection of the welded parts is then carried out to check whether the drum is manufactured correctly.

At this time, as a method for heating the iron plate is heated using an electric furnace or a gas burner.

In particular, when the furnace is heated for about 1 hour when the furnace is used, the furnace temperature is 300 ° C., and when the iron plate is placed in the furnace for 3 to 4 hours, the entire iron plate is about 300 ° C.

As described above, the heating method of the iron plate by the existing electric furnace and gas burner takes a considerable time to heat the iron plate, and also because the welding of the two parts (2seam) to withstand the high pressure due to the half-circle of the iron plate to meet Due to the nature of the container, there are increasing costs for welding and non-destructive testing as well as problems with safety.

The present invention has been made to solve the problems described above, and by reducing the heat treatment and the cost of heat treatment by the frequency heat treatment in place of the existing furnace or burner.

The welding process and non-destructive inspection are performed by making the welding part become one part by heating the iron plate by the primary transfer means and simultaneously heating the iron plate into the banding machine to form a complete drum. Its purpose is to reduce the number of times to reduce the production cost of high pressure drum, and to make the drum with stability, and also to make the heated iron plate straight inside the banding machine to have the safety and efficiency of the work site. .

The drum manufactured according to the present invention has only one part of a welded part (1seam), so that the existing welded part has two parts (2seam), so that the safety of the characteristics of the high-pressure vessel can be increased, and the iron plate using a frequency heat processor By adopting the heating method, the heating time can be shortened and the manufacturing time of the drum can be shortened, and the iron plate heated by the frequency heat treatment machine is directly introduced into the bending machine to roll the iron plate. You can work in a safe place.

The present invention relates to a method for manufacturing a drum for a waste heat recovery apparatus, and more particularly, a primary transfer means for transferring a thick iron plate having a thickness of 80 mm or more, a frequency heat processor for heating the iron plate, and a bending machine for a rolling operation. Secondary transport means for transporting the rolled iron plate to the place for welding, and a control box for controlling the series process, by the primary transport means to gradually enter the iron plate with a thickness of 80mm or more into the frequency heat processor At the same time, the heated iron plate immediately after passing through the frequency heat processor enters the inside of the banding machine and rolls to make the iron plate in the form of a drum, and is directly welded to prevent the rolled iron plate from spreading. Iron rolled in the form of a drum by transferring to a position where the steel plate rolled in the form of a drum can be welded by the vehicle transport means. It relates to a drum manufacturing method for a waste heat recovery device using a frequency heat processor characterized in that the iron plate is produced in a drum form by welding both ends of the plate abutment.

The method for producing a drum for waste heat recovery apparatus using the frequency heat processor of the present invention having the above-described purpose will be described in detail with reference to the accompanying drawings.

1 is an exemplary view showing a welding method according to a conventional drum manufacturing method.

As shown in FIG. 1, the conventionally manufactured drum is formed by rolling the iron plate 100 in a semi-circular shape, and thus, the welded portion becomes two parts, so that the safety of the drum used in the waste heat recovery apparatus that has to withstand high pressure is a concern for safety. there was.

1 and 7 denotes a welded portion.

Figure 2 is a perspective view showing a facility for producing a drum for waste heat recovery apparatus of the present invention, Figure 3 is a schematic diagram showing the inside of the bending machine.

As shown in Figure 2 in order to manufacture the drum for the waste heat recovery apparatus of the present invention, the primary transfer means (1) for transferring a thick iron plate (6) of thickness 80mm or more, and a frequency heat processor for heat treatment of the iron plate (6) (2), a banding machine (3) for rolling work, a secondary conveying means (4) for transferring the rolled steel plate (6a) to a place for welding, and a control box (5) for controlling the series of processes ) Is configured.
For the sake of convenience, the iron plate of the rectangular shape is marked with 6 and differentiated by the iron plate 6a.

When the iron plate is formed in a drum form by the above-described device, the process of heating the iron plate 6 having a thickness of 80 mm or more by the primary transfer means 1 gradually enters and heats the frequency heat processor 2 and at the same time the frequency heat treatment. The heated iron plate 6 immediately after passing through the machine 2 enters the inside of the bending machine 3 and is rolled to make the iron plate 6 into a drum shape, and to the secondary conveying means 4. It is characterized in that the iron plate (6a) rolled in the drum form to the position that can be welded by the final welding of both ends of the iron plate (6a) rolled in the drum form to make the iron plate (6) in a drum form.

At this time, in order to prevent the rolled iron plate 6a from being stretched or deformed during the transfer by the secondary transport means 4, the iron plate 6 is rolled into a drum form in the bending machine 3 and then immediately welded or Primary welding shall be carried out by attaching fixed brackets at both ends.

In addition, it is preferable that the interval between the frequency heat processor 2 and the bending machine is configured without being spaced so that the iron plate 6 passing through the frequency heat processor 2 is not cooled in the air.

Reference numerals 2a and 2b denote portions for heating the upper and lower surfaces of the iron plate 6 in the frequency heat processor 2, respectively.

The frequency heat processor (2) uses a medium frequency, which is to minimize the deformation of the iron plate (6) by uniformly heating the internal and external temperature of the iron plate (6) when heating the iron plate (6) 80 mm or more in thickness, The higher the frequency, the more rapidly the temperature changes only on the surface of the iron plate 6, so that it is easy to become thermally deformed due to the change of the internal and external stresses of the iron plate 6, while the low frequency can be gradually heated to the inside, while induction heating This is because the heating takes a long time due to the characteristics of.
Therefore, the frequency band used for the frequency heat processor 2 can be used in the general medium frequency range of 500 to 5000 Hz.

Usually, the heating of the iron plate 6 by the frequency heat processor 2 is about 30 minutes-1 hour.

The steel plate 6 used in the drum is usually made of A516 and SA302B. A516 is carbon steel, and is generally divided into four grades of 55, 60, 65 and 70. The tensile strength is about 380 to 620 MPa.

3 is a diagram showing the internal configuration of the bending machine 3 in FIG. 2, and omitting the external form of the bending machine 3. As illustrated in FIG. 3, the bending machine 3 of the present invention has an iron plate 6 drawn therein. ) And the main roller 31 in the circumferential direction of the main roller 31 and the main roller 31 to determine the size of the inner diameter of the iron plate (6a) rolled in the drum form in order to produce a roll in the drum form Auxiliary rollers 32 are arranged to have a distance spaced apart.

The number of the auxiliary rollers 32 is preferably at least two or more auxiliary rollers 32, as shown in Figures 5 and 6 to be described later.

On the other hand, one side of the central axis 311 formed on both ends of the main roller 31 to rotate is bound to the inner surface of the bending machine (3) so that the main roller 31 rotates relative to the central axis (311). The central axis 311 of the other side is not tied.

A groove 312 is formed in the end surface of the central shaft 311 of the main roller 31 which is not bound to the bending machine 3, and when the iron door 34 for opening and closing the outlet is completely closed on the exit side. A binding member 341 for binding with the central shaft 311 has a configuration in which the groove 312 is coupled, so that the load and load applied by the main roller 31 in the process of rolling and rolling the iron plate 6. It can support.

In general, the main body of the transfer in the bending machine (3) is the auxiliary roller 32, the main roller 31 is rotated by the friction of the iron plate (6) by the rotation of the auxiliary roller (32).

It is possible to automatically control the opening and closing of the iron door 34 and the binding member 341 from the central shaft 311 by the control box 5, but to manually open and close the iron door 34 in case of emergency. An auxiliary handle 343 is configured to allow the main handle 342 and the binding member 341 to be separated from the groove 312 formed in the central axis.

In addition, the hydraulic cylinder 33 is configured on the other side of the outlet side, it is possible to push the rolled iron plate (6a) to the secondary transfer means 4 through the outlet.

Instead of the hydraulic cylinder 33, other types of devices may be used.

The outlet is, of course, a portion which is opened and closed by the iron door 34 and has not been designated by the reference numeral.

FIG. 4 is an exemplary view showing a process in which the iron plate is transferred into the banding machine while passing through the frequency heat processor by the primary transfer means, and FIG. 5 is an exemplary view showing a state in which the iron plate is rolled inside the bending machine. Figure 7 is a working example showing the appearance of the rolled iron plate is discharged from the bending machine.

4, 5, and 7 show a series of processes for manufacturing the drum for the waste heat recovery apparatus of the present invention. As shown in FIG. 4, the iron plate 6 has a frequency by the primary transfer means 1. Immediately after passing through the heat treatment unit (2) is transferred to the bending machine (3) configured on the rear of the frequency heat processor (2).

As shown in FIG. 5, the frequency heat processor 2 can heat the upper and lower surfaces of the iron plate 6 simultaneously in the up and down directions so that the iron plate 6 having a thickness of 80 mm or more can be heated more quickly. have.

And the iron plate (6) passing through the frequency heat processor (2) is configured in the circumferential direction of the main roller 31 and the main roller 31 from the heated portion in the frequency heat processor (2) as shown in FIG. The iron plate 6 is subjected to a rolling operation while being drawn in between the auxiliary rollers 32.

At this time, the interval between the main roller 31 and the sub-roller 32 depends on the thickness of the rolled drum, the iron plate 6 is the diameter of the drum produced because rolling the heated metal has a ductility in the characteristics of the heated metal In order to fit the iron plate 6 should be of an appropriate length by applying the elongation.

In other words, it is preferable that the length of the iron plate 6 be as small as the length to which the elongation is applied.

And by configuring the primary transport means (1) to extend to the inner main roller 31 of the bending machine (3) while being transported between the main roller 31 and the auxiliary roller 32, the central axis of the main roller 31 ( The iron plate 6 that rotates 360 ° based on 311 can be rotated more easily by the forcing force of the auxiliary roller 32 and the primary transport means 1.

In addition, a guide member having a curved guide surface between the first auxiliary roller 32 and the second auxiliary roller 32 constituted around the main roller 31 and the second auxiliary roller 32 to be rolled in a circular shape. By constructing 35, the iron plate 6 rotates 360 ° while wrapping the main roller 31, thereby preventing any deviation from the direction when the iron plate 6 is rolled.

The guide member 35 is even more iron plate 6 in the bending machine (3) equipped with a minimum auxiliary roller 32, as shown in Figure 6 is another working example showing the appearance that the iron plate is rolled inside the bending machine. By guiding the rolling direction of) will be able to exhibit its function.

On the other hand, by configuring the auxiliary frequency heat processor 36 between the plurality of secondary rollers 32 is configured to keep the temperature of the heated iron plate 6 is continuously maintained more easily to roll the iron plate (6).

The iron plate (6a) rolled in the drum form is discharged to the outside by the hydraulic cylinder 33 configured in the bending machine (3) as shown in Figure 7, the final welding operation is carried out via the secondary transfer means (4) To get to where it is.

At this time, the welding or bracket welding of the rolled steel plate 6a to prevent the deformation of the drum form or the rolled iron plate 6a to be deformed before being transferred to the place where the final welding operation is performed by the secondary transport means 4. This should be done right away.

Since the rolled iron plate 6a has an almost complete drum shape, there is only one portion of the welded portion where both ends of the rolled iron plate 6a abut.

Since the welding part is often expressed as seam, the welding of the rolled iron plate 6a according to the present invention may be referred to as 1 seam.

8 is a front view of the secondary conveying means.

As shown in FIG. 8, the secondary conveying means 4 is composed of a plurality of cylindrical rollers 4a, while the cylindrical rollers 4a support the weight of the iron plate 6a rolled in the form of a drum. It may be desirable to configure the rolled iron plate 6a to have a relatively long length rather than the outer diameter of the rolled iron plate 6a as a roller whose diameter gradually decreases from both ends to the middle point so as not to roll sideways.
4 denotes the overall configuration of the secondary conveying means, and 4a indicates a cylindrical roller in the secondary conveying means.

Even more preferably, the side shape of the cylindrical roller 4a, which is the secondary conveying means 4, may have a curved shape of the quadratic equation.

1 is an exemplary view showing a welding method according to a conventional drum manufacturing method.

Figure 2 is a perspective view showing a facility for producing a drum for waste heat recovery apparatus of the present invention.

Figure 3 is a schematic diagram showing the inside of the bending machine.

Figure 4 is an operation example showing a process in which the iron plate is transferred into the banding machine while passing through the frequency heat processor by the primary transfer means.

Figure 5 is an exemplary work showing the appearance that the iron plate is rolled inside the bending machine.

Figure 6 is another working example showing the appearance that the iron plate is rolled inside the bending machine.

7 is an embodiment showing a state that the rolled iron plate is discharged from the bending machine.

8 is a front view of the secondary conveying means.

<Code Description of Main Parts of Drawing>

1. Primary conveying means 2. Frequency heat processor 3. Banding machine

4. Secondary transport means 5. Control box 6. Steel plate

31. Main roller 32. Auxiliary roller 33. Hydraulic cylinder

34. Iron gate 35. Guide member 36. Auxiliary frequency heat processor

100. Iron plate

311.Center 312.

341. Fastening members 342. Main handle 343. Secondary handle

Claims (11)

In the method for producing a drum for waste heat recovery device, Primary conveying means (1) for conveying a thick iron plate (6) having a thickness of 80 mm or more, a frequency heat processor (2) for heat treatment of the iron plate (6), a bending machine (3) for rolling work, and a rolled iron plate Secondary conveying means (4) for conveying (6a) to the place for welding, and a control box (5) for controlling the series of processes, by the primary conveying means (1) iron plate of 80mm or more in thickness By gradually entering (6) into the frequency heat processor (2) and heating it, the heated iron plate (6) immediately after passing through the frequency heat processor (2) immediately enters into the bending machine (3) and rolls to work. The iron plate 6 is in the form of a drum, and immediately welds both ends of the rolled iron plate 6a to a position where the iron plate 6a rolled in the form of a drum can be welded by a secondary transfer means. Drum welding the iron plate 6 by final welding both ends of the iron plate 6a rolled in the drum form. The manufacturing method of the drum for waste heat recovery device to be put into production Using a frequency characteristic of the heat treatment. The method of claim 1, The interval between the frequency heat processor (2) and the banding machine (3) is characterized in that the iron plate (6) passing through the frequency heat processor (2) is configured without a space to prevent cooling in the air using a frequency heat processor Drum manufacturing method for waste heat recovery device. The method of claim 1, The frequency heat processor (2) is a drum manufacturing method for a waste heat recovery device using a frequency heat processor, characterized in that to heat the upper and lower surfaces of the iron plate (6) at the same time in order to quickly heat the thick iron plate (6) of 80mm or more. delete The method of claim 1, The bending machine (3) is the main roller 31 and the main roller to influence the size of the inner diameter of the iron plate (6a) rolled in the drum form in order to produce the iron plate (6) drawn into the drum form At least two sub-rollers 32 are arranged in the circumferential direction of the main roller 31 to be spaced apart from the main roller 31 by a distance between the main roller 31 and the sub-roller 32. Method for producing a drum for waste heat recovery apparatus using a frequency heat processor, characterized in that the iron plate (6) is rolled in the form of a drum by the (6). The method of claim 5, Between the first sub-roller 32 and the second sub-roller 32 configured in the circumferential direction of the main roller 31 of the bending machine 3 to guide the iron plate 6 to be rolled in the form of a drum Drum manufacturing method for a waste heat recovery device using a frequency heat processor characterized in that the guide member having a 35. The method of claim 5, The auxiliary frequency heat processor 36 for maintaining the heated iron plate 6 in a heated state is provided between the auxiliary rollers 32 arranged in at least two or more in the circumferential direction of the main roller 31. Drum manufacturing method for waste heat recovery apparatus using a frequency heat treatment. The method of claim 5, The main roller 31 is one side of the central shaft 311 formed in the center of both ends is bound to the inner surface of the bending machine 3 so that the main roller 31 rotates about the central axis 311 as a reference axis. A drum manufacturing method for the waste heat recovery apparatus using the frequency heat processor, characterized in that the other center axis (311) is not bound. The method of claim 1, One side of both sides of the bending machine 3, the hydraulic cylinder 33 is configured to push the iron plate (6a) rolled in the inside of the bending machine 3 to the outside through the outlet side configured on the other side Drum manufacturing method for the waste heat recovery apparatus using a frequency heat processor. The method according to any one of claims 8 and 9, The exit side of the bending machine (3) is composed of an iron door 34 for opening and closing the exit, the inner side of the configured iron door 34 is bound with the inner side of the bending machine (3) when the iron door 34 is completely closed A method for producing a drum for waste heat recovery apparatus using a frequency heat processor, characterized in that a binding member (341) for engaging with the central axis of the main roller (31) not on the side is formed. The method of claim 1, The secondary conveying means (4) is composed of a plurality of cylindrical rollers (4a) having a relatively long length than the outer diameter of the rolled iron plate (6a), the cylindrical roller (4a) is rolled in the form of a drum In order to prevent the iron plate (6a) is rolled to the side, the diameter of the waste heat recovery device drum manufacturing method characterized in that it is configured in the form gradually decreases toward the middle point from both ends.

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