KR101100600B1 - Connecter and connecting method of sell of heat exchanger - Google Patents

Abstract

The present invention provides a cell mechanism in which a plurality of tubes are mounted, and a coupling mechanism capable of pulling one tube sheet of an outer cylinder in engagement of an inner cylinder and an outer cylinder that constitutes a cell portion in a heat exchanger in which a channel portion is coupled to both of the cell portions. Further, while the inner cylinder is suspended from the tube sheet side opposite to the coupling mechanism by the connecting rope to the crane, the coupling mechanism is connected to the inner cylinder sheet of the inner cylinder with a connecting chain, so that the coupling mechanism is a tube of the outer cylinder. The inner cylinder connected to the coupling mechanism gradually enters the outer cylinder by the interval movement of the coupling mechanism in close contact with the seat, thereby allowing the inner cylinder to be safely coupled to the outer cylinder without impact and without damaging the product. In addition, the present invention relates to a method of joining an outer cylinder and a joining structure thereof. In the combination of the inner cylinder and the outer cylinder constituting the cell portion in the heat exchanger, one tube sheet 41 of the outer cylinder 40 has a support frame 220 connected to the moving frame 210 and the space moving means 400. A fixing step of fixing the coupling mechanism 200 of the towing means; Positioning process so that the inner cylinder (30) from the other tube sheet 41 side of the outer cylinder (40) can be entered in the state of being connected to the crane 100 by the connection rope 110; A connection process of connecting the moving frame 210 of the coupling mechanism 200 and the tube sheet 41 of the inner cylinder 30 with a connection chain 300; A moving step of moving the inner frame 30 to the outer cylinder 40 by the moving frame 210 through the opening frame 220 by the operation of the gap moving means 400 of the coupling mechanism 200. In the coupling method of the inner and outer cylinders of the cell portion of the heat exchanger made, the coupling mechanism 200 which is the traction means is the support frame 220 is fixed to the tube sheet 41 of the outer cylinder 40, the support frame 220 The space moving means 400 is mounted between the moving frame 210 and the inner cylinder seat 31 of the inner cylinder 30 is connected to the moving frame 210 by a connection chain 300, and the space movement is performed. By the operation of the means 400 is characterized in that the inner cylinder 30 is pulled into the outer cylinder 40, the inner and outer cylinders of the cell portion of the heat exchanger to be coupled, the present invention is also characterized in that The support frame 220 and the moving frame 210 at intervals on the tube sheet 41, the interval moving means 400 therebetween Coupling mechanism 200 which is a towing means is mounted, the cell of the heat exchanger in which the inner cylinder seat 31 of the inner cylinder 30 is connected to the connection chain 300 to the moving frame 210 of the coupling mechanism 200 In the coupling structure of the inner and outer cylinders, the inner and outer cylinders of the cell part of the heat exchanger in which the chain stopper 500 capable of latching the connection chain 300 is formed on the moving frame 210 of the coupling mechanism 200. It is characteristic of the coupling structure.

Heat exchanger, cell part, inner cylinder, outer cylinder, tube sheet, inner cylinder sheet, coupling structure, coupling mechanism, gap moving means, supporting frame, moving frame, connecting chain, connecting rope, crane, gap moving means

Description

Connecting method of inner and outer cylinders of cell part of heat exchanger and its coupling structure {Connecter and connecting method of sell of heat exchanger}

The present invention relates to a method for coupling the inner and outer cylinders of the cell portion of the heat exchanger for coupling the inner and outer cylinders constituting the cell portion in a heat exchanger for recovering waste heat from the waste heat or waste water, and more specifically, And a coupling mechanism capable of pulling one tube sheet of the outer cylinder in the coupling between the inner cylinder and the outer cylinder constituting the cell portion in the heat exchanger in which the tube portion is coupled to the cell portion on which the tube of the tube is coupled, and the above-mentioned. While the inner cylinder is suspended from the tube sheet side opposite to the coupling mechanism by the connecting rope, the coupling mechanism is connected to the inner tube sheet of the inner cylinder with a connecting chain, and the coupling mechanism is in close contact with the tube sheet of the outer cylinder. In this state, the inner cylinder connected to the coupling mechanism gradually enters the outer cylinder by the interval movement of the coupling mechanism. , Relates to an inner tube with no impact on the external cylinder also the cell portion of a heat exchanger that can be securely bonded without damage to the product, the outer tube coupling method and a bonded structure.

In general, a heat exchanger for recovering waste heat from a tank or wastewater storing a fire-coating body is made of carbon steel or stainless steel, and the inner surface is press-molded with corrosion-resistant cladding materials such as titanium and zirconium. Make up a sieve.

The clad material prevents corrosion by the highly toxic fluid flowing into and out of the tank. As shown in Figs. 1A, B and C, the cylindrical body forms a cell portion 10 corresponding to the body of the heat exchanger 1. In addition, the cell portion 10 has a plurality of tubes (11) extending in the longitudinal direction, both sides are equipped with a tube sheet 41 that can support the plurality of tubes (11), and also can be fixed to the ground Pedestal 42 is installed.

In order to prevent corrosion of the tube of the heat exchanger, an inner surface of corrosion resistant materials such as titanium and zirconium are used. In addition, as shown in Figure 1c the channel portion 20 is coupled to both sides of the tube sheet 41 of the cell portion 10 to form a heat exchanger.

The tube sheet 41 of the cell portion 10 and the channel flange 21 of the channel portion 4 each have holes for fastening bolt nuts, so that the tube sheet 41 and the channel flange 21 are bolted. The cell portion 10 and the channel portion 20 are coupled by the fastening of the nut (not shown).

In addition, a gasket is mounted between the tube sheet 41 and the channel flange 21 to prevent leakage of the toxic fluid, and as the tube sheet and the channel flange are frequently separated to repair the tank and check the internal condition. Since the contact part is easily worn, a stronger material (Ti Gr. 7 or Gr. 11) than a base metal such as titanium and zirconium (Ti Gr. 1 or Gr. 2) is used.

As shown in FIG. 3, nozzles 60 are formed in the cell portion 10 and the channel portion 20 of the heat exchanger 1 to allow the chemicals to flow through the cell portion 10 of the heat exchanger 1. ) And the channel unit 20 exchanges heat of a fluid such as a chemical coagulant.

As shown in Figs. 2A and 2B, in the case of a large capacity, the heat exchanger 1 has a diameter of 6m to 10m in the cell portion of the heat exchanger. The cell unit 10 is manufactured by the outer cylinder 40 and the inner cylinder 30, respectively, by operations such as cutting shearing and roll forming.

The outer cylinder 40 is a cylindrical body of the nozzle 60, the pedestal 42 and the tube sheet 41, the components are welded to manufacture, and the inner cylinder 30 is a tube 11 to the tube holding plate 12 The inner cylinder sheets 31 are welded to both sides. In addition, the channel units 20 are also manufactured.

In addition, the outer cylinder 40 and the inner cylinder 30 constituting the cell portion 10 are manufactured, respectively, to couple the inner cylinder 30 to the outer cylinder 40, as shown in FIG. 42 is fixed to the concrete anchor bolt 70 of the ground, and also supports the tube sheet 41 to the fixture (2) that can be supported so that one side of the outer cylinder (40) is not pushed.

Then, the inner cylinder 30 connects the lifting rope 110 to the crane 100, lifts it up, and then supports the timber 3 on one side of the inner cylinder 30 to slowly rotate the inner cylinder 30 using the forklift 4. The inner cylinder 30 is coupled to the outer cylinder 40 by pushing.

Since the forklift 4 is pushed as described above, surface damage may occur in the inner cylinder 30 due to the impulse, and the tubes 11 of the inner cylinder 30 may be damaged, and at the same time, the outer cylinder 40 may be damaged by damage to the product. This can cause a decrease in the quality of the product.

In addition, there is a problem that the workability is inferior due to the work of fixing the outer cylinder 40 to the anchor bolt of the ground, and also the production cost is expensive due to the need to install the fixture (2) separately. .

In addition, since the inner and outer cylinders 30 and 40 are large structures, the inner cylinder 30 is pushed by the forklift 4 while the inner cylinder 30 is walked by the connecting rope 110 using the crane 100 and the moving distance of the crane 100. If the timing of the back is not correct, there is a risk of a safety accident.

The present invention is to solve the above problems, and after providing a coupling mechanism that can be pulled to one tube sheet of the outer cylinder in the engagement of the inner and outer cylinders of the cell portion of the heat exchanger, the opposite side of the coupling mechanism The inner cylinder is connected to the coupling chain with the coupling mechanism from the outer cylinder, so that the inner cylinder can be towed and moved by the coupling mechanism to the outer cylinder, so that the inner and outer cylinders can be entered and combined without being damaged by impact. In another aspect, the present invention is the coupling mechanism is formed of a support frame and a moving frame is formed between the supporting frame and the moving frame interval moving means capable of moving the moving frame at a predetermined interval, and also in the moving frame By connecting the inner cylinder sheet and the inner chain of the inner cylinder, the purpose is to be able to move the inner cylinder stably without impact into the outer cylinder can be combined. In another aspect, the present invention is equipped with a hydraulic cylinder as the interval moving means mounted between the supporting frame and the moving frame to drive the hydraulic drive source by the extraction of the rod of the hydraulic cylinder by the movement of the interval of the moving frame from the supporting frame to the inner cylinder into the outer cylinder. The purpose is to allow entry.

The present invention is a coupling mechanism of the traction means having a support frame connected to the moving frame and the space moving means in one tube sheet of the outer cylinder in the inner cylinder and the outer cylinder coupling of the shell portion in the heat exchanger to recover the waste heat from the waste co-carrier or waste water A fixing step of fixing the; A positioning step for allowing the inner cylinder to enter from the other tube sheet side of the outer cylinder in a state of being connected to the crane by a connection rope; A connecting step of connecting the moving frame of the coupling mechanism and the tube sheet of the inner cylinder with a connecting chain; In the coupling method of the inner and outer cylinders of the cell portion of the heat exchanger consisting of a movement step of moving the inner frame to the outer cylinder by the operation of the gap moving means of the coupling mechanism to move the inner cylinder to the outer cylinder in the opening operation from the support frame. Phosphorus coupling mechanism is the support frame is fixed to the tube sheet of the outer cylinder, the interval moving means is mounted between the supporting frame and the moving frame, the inner cylinder sheet of the inner cylinder is connected to the moving frame by a connecting chain, the interval moving means There is a feature of the inner and outer cylinder coupling method of the cell portion of the heat exchanger to be coupled by pulling the inner cylinder into the outer cylinder by the operation of.
In addition, the present invention is equipped with a coupling mechanism which is a towing means equipped with a space moving means between the support frame and the moving frame at intervals between the tube sheet of the outer cylinder, the inner cylinder sheet of the inner cylinder is connected to the moving frame of the coupling mechanism A coupling structure of an inner and outer cylinder of a cell part of a heat exchanger connected by a chain, the coupling structure of an inner and outer cylinder of a cell part of a heat exchanger having a chain stopper capable of latching a connecting chain in a moving frame of the coupling mechanism. There is this.

delete

delete

delete

delete

delete

As described above, the present invention can pull one tube sheet of the outer cylinder in the combination of the inner cylinder and the outer cylinder constituting the cell portion in which the plurality of tubes are mounted and the cell portion in the heat exchanger in which the channel portion is coupled to both of the cell portions. The coupling mechanism is connected to the coupling mechanism by connecting the coupling mechanism and the inner cylinder sheet of the inner cylinder to a connecting chain, while the coupling mechanism is installed and the inner cylinder is suspended from the tube sheet side facing the coupling mechanism by a connecting rope to the crane. When the inner cylinder connected to the coupling mechanism gradually enters the outer cylinder by the interval moving movement of the coupling mechanism in a state in close contact with the tube sheet of the outer cylinder, the inner cylinder can be safely coupled to the outer cylinder without impact and without damage to the product.

Detailed examples of the present invention will be described below with reference to the accompanying drawings.

Figures 1a, b, c is a schematic view of the outer and inner cylinders and the channel portion of the cell portion of the heat exchanger, and Figures 2a, b are schematic views of the state before and after the combination of the inner and outer cylinders of the heat exchanger, and Figure 3 is a heat exchanger Figure 4 is a schematic view of the combined state of the cell portion and the channel portion, and Figure 4 is an illustration of a method of coupling the inner and outer cylinders of the cell portion of a conventional heat exchanger, and Figures 5a, b, c, d, e is a heat exchange of the present invention It is an illustration of the coupling method of the inner and outer cylinders of the cell part of the group.

The present invention has been described in the related art with respect to the configuration of the heat exchanger, and description thereof will be omitted.

As shown in Figs. 5a, b, c, d, and e, in the coupling between the inner cylinder 30 and the outer cylinder 40 constituting the cell portion 10 in the heat exchanger 1 recovering waste heat from the fire-coating medium or waste water. In the present invention, the inner cylinder 30 is suspended from the connecting rope 110 of the crane 100, toward the other tube sheet 41 by the traction means installed on one tube sheet 41 side of the outer cylinder (40). Towed from, the inner cylinder 30 is to be coupled into the outer cylinder (40).

The towing means is to be coupled to the inner cylinder 30 into the outer cylinder 40 by a coupling mechanism 200 to be described later, the winding device to pull the inner cylinder 30 to the outer cylinder 40 in addition to the coupling mechanism 200. It can be done by. For example, after connecting the connection chain 300 to the inner cylinder 30, as the connection chain 300 is wound around the bobbin rotated by the drive source in the state in which the inner cylinder 30 is suspended on the connecting rope 110 , Can be towed into the outer cylinder 40 to be coupled.

The method of joining the inner and outer cylinders of the cell part of the heat exchanger of the present invention includes a fixing step, a position setting step, a connecting step, and a moving step.

In the fixing step, as shown in FIG. 5A, the base 42 of the outer cylinder 40 is placed on the sheet 50 of the ground, and the movable frame is placed on one tube sheet 41 (left side in the drawing) of the outer cylinder 40. The coupling mechanism 200 of the towing means having a support frame 220 connected to the 210 and the interval moving means 400 is fixed. At this time, the mounting is completed by placing the outer cylinder 40 on the sheet 50 on the ground without fixing the anchor bolt with an anchor bolt.

In addition, the position setting process is entered in a state in which the inner cylinder 30 is connected to the crane 100 by the connection rope 110 and maintained from the tube sheet 41 side of the other side of the outer cylinder 40 (right side in FIG. 5A). Set it to be possible.

Next, the connecting process connects the moving frame 210 of the coupling mechanism 200 and the inner cylinder sheet 31 of the inner cylinder 30 to the connection chain 300.

The support frame 220 of the coupling mechanism 200 is formed in a substantially 'c' shape and is fixed by fastening the bolt nut 43 to the screw hole (not shown) of the tube sheet 41 of the outer cylinder 40. .

In addition, the coupling mechanism 200 is connected to the interval moving means 400 which is installed between the support frame 220 and the moving frame 210 at intervals. And the interval moving means 400 is installed a cylinder 400 which is operated by a drive source (not shown) such as hydraulic equipment. One side of the cylinder 400 is fixed to the 'c' shaped support frame 220, and the other side of the rod 410 portion of the cylinder 400 is fixed to the moving frame 210.

In addition, a chain stopper 500 capable of latching the connection chain 300 is formed on the moving frame 210 of the coupling mechanism 200. The connection chain 300 is fixed to the chain stopper 500 of the moving frame 210 of the coupling mechanism 200, one side as shown in Figure 5a, and the other bolt of the inner cylinder sheet 31 of the inner cylinder 30 It is fixed to the bolt 32 fixed to the hole (omission). At this time, the connection chain 300 to the coupling mechanism 200 is penetrated through the through-hole 221 to the support frame 220 in a state fixed to the chain stopper 500 of the moving frame 210 of the inner cylinder 30 It is fixed to the seat 31.

Next, the moving process is driven by the operation of the gap moving means 400 of the coupling mechanism 200, the moving frame 210 to pull the inner cylinder 30 to the outer cylinder 40 by the separation operation from the support frame 220 to move. Let's do it.

That is, as the cylinder 400, which is the interval moving means of the coupling mechanism 200, is extended as shown in FIG. 5B by the operation signal of the controller (not shown), the inner cylinder 30 is towed to the outer cylinder 40. It can be pushed into). At this time, the crane 100 is moved and adjusted toward the outer cylinder 40 with the movement of the inner cylinder 30 gradually in the state of holding the inner cylinder 30 by the connecting rope 110.

When the inner cylinder 30 enters the outer cylinder 40 by the operation of the coupling mechanism 200 as described above, the rod 410 of the cylinder 400 which is a space moving means of the coupling mechanism 200 as shown in FIG. After entering 400, the rod 410 of the cylinder 400 is operated as shown in FIG. 5D so that the inner cylinder 30 is pulled and pushed back into the outer cylinder 40. When the inner cylinder 30 enters the outer cylinder 40 to some extent, the inner cylinder 30 in the outer cylinder 40 is gradually repeated by repeating the operation of allowing the rod 410 to enter the cylinder 400 as shown in FIG. 5E. ) Can be combined by towing.

Example

As shown in FIG. 5A, the base 42 of the outer cylinder 40 is placed on the sheet 50 of the ground.

Then, the coupling mechanism 200 of the towing means having a support frame 220 connected to the moving frame 210 and the space moving means 400 on one tube sheet 41 (left in the drawing) of the outer cylinder 40 Fix it.

In other words, the support frame 220 of the coupling mechanism 200 is fastened by fastening the bolt nut 43 to the screw hole (not shown) of the tube sheet 41 of the outer cylinder 40.

In addition, the inner cylinder 30 is connected to the crane 100 by the connecting rope 110 from the tube sheet 41 side of the side opposite to the coupling mechanism 200 of the outer cylinder 40 (right in FIG. 5A). Set to enter the state.

Then, the moving frame 210 of the coupling mechanism 200 and the inner cylinder sheet 31 of the inner cylinder 30 are connected to the connection chain 300.

The connection chain 300 is fixed to the chain stopper 500 of the moving frame 210 of the coupling mechanism 200, one side as shown in Figure 5a, and the other side of the inner cylinder seat 31 of the inner cylinder 30 It is fixed to the bolt 32 fixed to the bolt hole (number abbreviation).

Next, as shown in Figure 5b by the operation of the gap moving means 400 of the coupling mechanism 200, the moving frame 210 is opened from the support frame 220 to the inner cylinder 30 to the outer cylinder 40 Tow and move.

That is, as the cylinder 400, which is the interval moving means of the coupling mechanism 200, is extended as shown in FIG. 5B by the operation signal of the controller (not shown), the inner cylinder 30 is towed to the outer cylinder 40. Can be towed into. At this time, the crane 100 is moved and adjusted toward the outer cylinder 40 with the movement of the inner cylinder 30 gradually in the state of holding the inner cylinder 30 by the connecting rope 110. The chain stopper 500 of the moving frame 210 of the coupling mechanism 200 maintains the connection (300) fixed (holding) state.

In addition, the chain stopper 500 is released to maintain the connection chain 300 in a free state. As shown in FIG. 5C, the rod 410 of the cylinder 400, which is a space moving means of the coupling mechanism 200, is a cylinder 400. To enter. In addition, the inner cylinder 30 is to be maintained by changing the position of the connection rope 110 of the crane 100 in a horizontal state such as a forklift.

In this state again, the rod 410 of the cylinder 400 is operated as shown in FIG. 5D so that the inner cylinder 30 is pulled and pushed into the outer cylinder 40.

In addition, when the inner cylinder 30 enters the outer cylinder 40 to some extent, the inner cylinder 30 in the outer cylinder 40 is gradually repeated by repeating the operation of allowing the rod 410 to enter the cylinder 400 as shown in FIG. 5E. ) Can be combined by towing.

Therefore, as shown in FIG. 2B, the inner cylinder 30 may be coupled to the outer cylinder 40 to form the cell unit 10. Thereafter, by assembling the channel units 20 on both sides of the cell unit 10, the heat exchanger 1 can be manufactured as shown in FIG. 3.

1a, b, c are schematic views of the outer and inner cylinders of the cell portion of the heat exchanger and the channel portion;

Figure 2a, b is a schematic diagram of the state before and after the coupling of the inner and outer cylinders of the heat exchanger,

3 is a schematic diagram of a state in which the cell portion and the channel portion of the heat exchanger are coupled;

Figure 4 is an illustration of a method of coupling the inner and outer cylinders of the cell portion of a conventional heat exchanger,

Figure 5a, b, c, d, e is an illustration of a method of coupling the inner and outer cylinders of the cell portion of the heat exchanger of the present invention.

Explanation of symbols on the main parts of the drawings

1: heat exchanger 10: cell part

20: channel portion 30: inner cylinder

40: outer cylinder 100: crane

110: connecting rope 200: coupling mechanism

210: moving frame 220: support frame

221: through hole 300: connection chain

400: interval moving means (cylinder)

410: load 500: chain stopper

Claims (6)

delete delete In the combination of the inner cylinder and the outer cylinder constituting the cell portion in the heat exchanger for recovering the waste heat from the waste co-conductor or the waste water, one of the tube sheet 41 of the outer cylinder 40 is connected to the moving frame 210 and the interval moving means 400 A fixing step of fixing the coupling mechanism 200 of the towing means having the support frame 220; Positioning process so that the inner cylinder (30) from the other tube sheet 41 side of the outer cylinder (40) can be entered in the state of being connected to the crane 100 by the connection rope 110; A connection process of connecting the moving frame 210 of the coupling mechanism 200 and the tube sheet 41 of the inner cylinder 30 with a connection chain 300; A moving step of moving the inner frame 30 to the outer cylinder 40 by the moving frame 210 through the opening frame 220 by the operation of the gap moving means 400 of the coupling mechanism 200. In the method of joining the inner and outer cylinders of the cell portion of the heat exchanger, Coupling mechanism 200 which is the towing means is a support frame 220 is fixed to the tube sheet 41 of the outer cylinder 40, the space moving means 400 between the support frame 220 and the moving frame 210 ) Is mounted, the inner cylinder sheet 31 of the inner cylinder 30 to the moving frame 210 is connected to the connection chain 300, the inner cylinder 30 by the operation of the gap moving means 400 the outer cylinder ( 40) A coupling method of the inner and outer cylinders of the cell portion of the heat exchanger, characterized in that to be coupled by towing into. delete delete On the tube sheet 41 of the outer cylinder 40, the support frame 220 and the moving frame 210 are spaced apart and the coupling mechanism 200 which is a towing means equipped with a space moving means 400 therebetween, In the coupling structure of the inner and outer cylinders of the cell portion of the heat exchanger in which the inner cylinder sheet 31 of the inner cylinder 30 is connected to the connecting chain 300 to the moving frame 210 of the coupling mechanism 200, The coupling structure of the inner and outer cylinders of the cell unit of the heat exchanger, characterized in that the chain stopper 500 is formed to latch the connection chain 300 in the moving frame 210 of the coupling mechanism 200.

Images