KR101012841B1 - Cooling Apparatus For Bearing Block Of Strip Roll For Annealing Furnace - Google Patents

Abstract

Strip roll 10 inside the annealing furnace; Bearing blocks 300 provided at both ends of the strip roll 10; And a supply line 120 coupled to the end of the bearing block 300 by a strip roll 10 and supplied with a cooling fluid, a flow path 142 is formed, and a strip roll from the flow path 142. 10 is a bearing block cooling apparatus 100 of the annealing furnace strip roll including a cooling plate 100 in which a spray nozzle 144 is formed such that a cooling fluid is injected into the cooling fluid. According to the cooling device 100, the cooling fluid can be injected to the strip roll side through the injection nozzle to prevent the hot gas of the annealing furnace from penetrating to the bearing block side in advance.

Description

Cooling Apparatus For Bearing Block Of Strip Roll For Annealing Furnace}

The present invention relates to a bearing block cooling apparatus of annealing furnace strip roll for protecting the bearing block of the strip roll guiding the strip in the annealing furnace from the high heat of the annealing furnace.

The annealing process of the strip refers to the process of heating the strip sufficiently and cooling it slowly to bring the material into a stable state as shown in the equilibrium diagram. In the annealing furnace, the strip is transferred and heated by using a plurality of strip rolls. In general, the heating operation is performed by burning COG gas in a radian tube to raise the temperature, and the supplied gas (nitrogen, oxygen, etc.) Maintain the atmosphere. The hot gas temperature in the annealing furnace is about 400 to 900 ° C.

The strip of the annealing furnace is conveyed through a strip roll, which consists of a roll portion and a shaft. Bearing blocks for supporting the shaft are coupled to both ends of the strip roll, and a plurality of roller bearings are provided on the inner side of the bearing block to smoothly rotate the shaft. Hereinafter, a bearing block cooling apparatus of a conventional annealing strip strip will be described with reference to FIG. 1.

1 is a cross-sectional view of a bearing block cooling apparatus of a conventional annealing strip strip, in which the shaft 12 of the strip roll 10 is positioned and rotated inside the bearing block 30. The bellows 50 is installed in the bearing block 30 so that the bearing block 30 is stably coupled to the shaft 12. In order to smoothly rotate the shaft 12, a bearing 32 is provided inside the bearing block 30. In addition, the packing 36 is provided on the outside of the bearing block 30 to prevent the hot gas of the annealing furnace from penetrating into the bearing 32 inside the bearing block 30. However, when the strip roll 10 is used for a long time, the hot gas of the annealing furnace penetrates into the bearing 32 side due to the aging of the packing 36, and the bearing 32 is also aged so that the stable rotation of the strip roll 10 is not achieved. do. In order to prevent this phenomenon, a cooling water flow path 34 is formed inside the bearing block 30, and cooling water flows through the flow path 34 to cool the bearing block 30, thereby degrading the bearing 32. Water-cooled cooling was used to prevent burning out.

However, in the case of water-cooled cooling, it was not possible to prevent the high-temperature gas infiltrate into the bearing, and there was a problem that a large maintenance cost is required to maintain the cooling temperature of the cooling water and to provide a steady circulation power.

In addition, in order to replace the packing during the aging of the packing to stop the process, there was a problem that the degradation of productivity was inevitable.

The present invention has been proposed to solve such a problem, and its object is to fundamentally block the high temperature gas of the annealing furnace from penetrating to the bearing block side, thereby preventing deterioration and damage of the packing of the bearing block and the bearing.

Bearing block cooling apparatus of the annealing furnace strip roll according to the present invention for achieving the above object, the strip roll is installed to guide the strip from the inside of the annealing furnace; Bearing blocks provided at both ends of the strip roll to smoothly rotate the strip roll; And a supply line coupled to the end of the bearing block by a strip roll and supplying a cooling fluid from an outer circumferential surface to an inner circumferential surface, and a flow path is formed so that the supplied cooling fluid circulates around the inner circumferential surface. It includes; a cooling plate formed with a spray nozzle so that the cooling fluid is injected into the strip roll.

A plurality of injection nozzles may be formed along the inner circumferential surface of the cooling plate.

The cooling plate may be formed into a plurality of divided parts and then coupled to the bearing block.

According to the bearing block cooling apparatus of the annealing furnace strip roll having the structure as described above, the cooling gas is introduced through the cooling plate coupled to the bearing block, the cooling gas is injected to the strip roll through the injection nozzle to the flow path High temperature gas in the annealing furnace can be prevented from penetrating to the bearing block side in advance.

It is possible to prevent high temperature gas from penetrating the bearing block to prevent deterioration of the packing of the bearing block, the bearings and other parts, and to obtain a high cooling effect at a lower cost than the conventional water-cooled cooling.

Hereinafter, with reference to the accompanying drawings looks at the bearing block cooling apparatus of the annealing furnace strip roll in accordance with a preferred embodiment of the present invention.

Figure 2 is a cross-sectional view showing a bearing block cooling device of the annealing furnace strip roll of the present invention and Figure 3 is a perspective view of the cooling plate of the cooling device. The bearing block 300 supports both ends of the strip roll 10 in the annealing furnace and includes a bearing 320 inside the shaft 12 of the strip roll 10 so as to stably rotate. The bearing 320 is provided to surround the shaft 12 to help smooth rotation of the shaft 12. One end of the bearing block 300 is equipped with a bellows (50) to provide a close contact with the bearing block 300 to be stably coupled to the strip roll (10). Bearing block cooling device 100 of the annealing furnace strip roll of the present invention is largely of the cooling plate 100 is provided between the strip roll 10 and the bearing block 300 and the bearing block 300 and the bellows (50) It consists of three parts.

Bearing block cooling device of the annealing furnace strip roll, the bearing block cooling device 100 of the annealing furnace strip roll is a strip roll (10) installed to guide the strip from the inside of the annealing furnace; Bearing blocks 300 provided at both ends of the strip roll 10 so that the strip roll 10 rotates smoothly; And a supply line 120 coupled to the end of the bearing block 300 by a strip roll 10 and supplying a cooling fluid from an outer circumferential surface to an inner circumferential surface, and the supplied cooling fluid circulates around the inner circumferential surface. And a cooling plate 100 in which a flow path 142 is formed, and a spray nozzle 144 is formed such that a cooling fluid is injected from the flow path 142 to the strip roll 10. The cooling plate 100 may be coupled to the roll portion of the strip roll 10 or the shaft 12 side. In general, since the bearing block 300 is coupled to the shaft 12 of the strip roll 10, the cooling plate 100 is coupled to the shaft 12 side to be in close contact with the bearing block 300.

In addition, the cooling plate 100 is preferably formed of a plurality of divided parts to be coupled to the bearing block 300. For example, when the cooling plate 100 is divided into two, the divided cooling plate 100 is inserted between the bellows 50 and the bearing block 300 and then fastened to the bearing block 300 to form an annealing process. Detachable without interruption. If the cooling plate 100 is integrally formed and coupled to the shaft 12, the ineffective operation of removing the bearing block 300 and coupling the cooling plate 100 after the annealing process is stopped is performed.

Specifically, the cooling plate 100 is composed of a disk 110 and the protrusion 140 of the inner peripheral surface side of the disk 110, such as the disk of the bearing block 300. The disk is tightly coupled to the bearing block 300. An injection line 120 is formed inside the disk 110 and a cooling fluid flows through the injection hole 122. As the cooling fluid, it is preferable to use nitrogen gas at room temperature. The nitrogen gas is preferably used in part of the nitrogen gas supplied to the annealing furnace. Since the hot gas of the annealing furnace is a high temperature of 400 ~ 600 ℃, there is no problem in cooling even if using the gas at room temperature, and when using the nitrogen gas before heating supplied to the annealing furnace, there is no need to establish a separate supply line.

The disk 110 of the cooling plate 100 penetrates the strip roll 10, and a protrusion 140 protruding to surround the shaft 12 of the strip roll 10 is formed on the inner circumferential surface side of the disk 110. do. The illustrated protrusion 140 is one embodiment formed on the shaft 12 side of the strip roll 10. A flow path 142 is formed around the shaft 12, and the flow path 142 is connected to the injection line 120 to circulate the cooling fluid supplied through the injection line 120. . In addition, the flow path 142 is formed with a plurality of injection nozzles 144 surrounding the shaft 12 on the inner circumferential surface of the disk 110 so that the cooling fluid circulating in the flow path 142 includes the shaft 12 of the strip roll 10. To be sprayed to the side. The cooling fluid (shown in solid line) injected to the shaft 12 side blocks the high temperature gas (shown in dashed line) of the annealing furnace from entering the bearing block 300 in advance. In addition, a plurality of coupling holes 112 are formed in the cooling plate 100 to be attached to and detached from the coupling holes 360 of the bearing block 300 through the coupling holes 112.

As shown in FIG. 4, a packing 340 and a bearing 320 contacting the shaft 12 of the strip roll 10 are mounted inside the bearing block 300. The packing 340 and the bearing 320 are not deteriorated from the hot gas of the annealing furnace by the cooling fluid injected through the injection nozzle 144.

Referring to Figure 5 looks at another embodiment of the cooling plate (100). In this case, the protrusion 140 is integrally molded without protruding from the disc 110. The cooling fluid (shown in solid line) injected through the injection nozzle 144 of the protrusion 140 proceeds to the annealing path side by the shaft 12, and at the same time, moves toward the inside of the bearing block 300. By forming such a cooling atmosphere along the circumference of the strip roll 10 to the coupling of the bearing block 300, the hot gas of the annealing furnace is blocked from directly approaching the bearing 320. Therefore, deterioration and burnout of the packing 340 and the bearing 320 are prevented and durability of the part is improved.

While the present invention has been particularly shown and described with reference to specific embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the following claims It will be apparent to those of ordinary skill in the art.

1 is a cross-sectional view showing a bearing block cooling apparatus of a conventional annealing strip strip roll.

Figure 2 is a cross-sectional view showing a bearing block cooling apparatus of the annealing strip strip in accordance with an embodiment of the present invention.

Figure 3 is a perspective view showing a cooling plate of the bearing block cooling device of the annealing furnace strip roll shown in FIG.

Figure 4 is a perspective view showing a bearing block cooling device of the annealing furnace strip roll shown in FIG.

Figure 5 is a cross-sectional view showing the injection nozzle of the bearing block cooling apparatus of the annealing furnace strip roll shown in FIG.

<Description of the symbols for the main parts of the drawings>

10: strip roll 12: shaft

50: bellows 100: cold plate

110: disk 112: coupling hole

120: injection line 122: injection hole

140: protrusion 142: flow path

144: injection nozzle 300: bearing block

320: bearing 340: packing

Claims (3)

A strip roll 10 installed to guide the strip inside the annealing furnace; Bearing blocks 300 provided at both ends of the strip roll 10 so that the strip roll 10 rotates smoothly; And A supply line 120 is coupled to the inner end of the bearing block 300 by a strip roll 10 and is supplied with a cooling fluid from an outer circumferential surface to an inner circumferential surface, and the supplied cooling fluid circulates around the inner circumferential surface. An annealing furnace strip roll including; a cooling channel (100) having a flow path (142) formed thereon, and a cooling nozzle (144) formed therein so that a cooling fluid is injected from the flow path (142) to the strip roll (10) on the inner circumferential surface side thereof. Bearing block chiller. The method according to claim 1, The injection nozzle 144 is a bearing block cooling device of the annealing furnace strip roll, characterized in that a plurality is formed along the inner peripheral surface of the cooling plate (100). The method according to claim 1, The cooling plate 100 is formed of a plurality of divided parts, the bearing block cooling apparatus of the annealing strip strip roll, characterized in that coupled to the bearing block (300).

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