KR101220674B1 - Cooling return roller and belt cooling system of use it - Google Patents

Abstract

A cooling return roller and a belt cooling system using the same are disclosed. Cooling return roller according to an aspect of the present invention supports a return belt of the conveyor, a drum having a plurality of inner pipe in the longitudinal direction of the inner periphery; And an inlet or outlet configured to respectively be installed at both ends of the drum, and through one side of the drum, through which the cooling fluid flows in or out, and the other side of which is provided with a distribution passage provided with the inlet or outlet to communicate with the inner pipe. It includes.

Description

COOLING RETURN ROLLER AND BELT COOLING SYSTEM OF USE IT}

The present invention relates to a cooling return roller and a belt cooling system using the same, installed in a belt conveyor for continuously moving the carbonized coke and cooling the belt returned after moving the coke.

In general, the coke coke dried in the coke oven can be moved continuously through a conveyor facility after dry quenching (Dry Quenching).

At this time, the dried coke is made to move to a design temperature of about 200 ℃. By the way, operation | movement is progressing in the state in which a red coke exceeded about 200 degreeC which is a design temperature substantially about 20-30 degreeC by the operation conditions difference etc ..

Accordingly, in the related art, the belt of the conveyor equipment for moving the red coke can be easily damaged by the heat transferred from the red coke. Accordingly, the belt replacement cycle is shortened, resulting in operation loss and replacement of the belt. The administrative costs are increasing.

1 is a front view showing a belt conveyor device according to the prior art.

Referring to FIG. 1, a belt 30 for transporting red coke is provided on a stand 20 of the conveyor apparatus 10.

The stand 20 is installed on both sides along the moving line of the conveyed object, and the stand 20 is provided with a carriage roller 22 which rotates the belt 30 to move the conveyed object, for example, the dried coke coagulated.

In addition, the conveyor apparatus 10 transfers the red coke using the belt 30, and then collects and circulates the belt 30, thereby allowing continuous transfer operation.

Conveyor device 10 is provided with a return roller 24 for supporting the lower portion of the belt 30 is recovered for circulation of the belt (30).

On the other hand, the belt 30 is continuously exposed to the heat transferred from the red coke during the movement of the red coke, thereby receiving thermal damage, the durability can be reduced.

Therefore, the conventional conveyor apparatus 10 is provided with a belt cooling device for cooling the belt 30 is recovered to prevent thermal damage to the belt 30.

Figure 2 is a front view briefly showing a cooling system of the belt conveyor apparatus according to the prior art.

As shown in FIG. 2, the conventional belt cooling device 40 includes a pipe part 42 that is installed to be long in the width direction of the conveyor device 10, and the pipe part 42 is configured to spray coolant to the pipe part 42. The nozzle 44 is provided. The pipe 42 is connected to the cooling water supply pipe 46 for supplying the cooling water from the outside.

The belt cooling device 40 supplies coolant to the return roller 24 to cool the belt 30 in contact with the cooled return roller 24 or to supply coolant to the lower portion of the belt 30 at a specific point. Thereby cooling the belt 30.

However, in the conventional belt cooling device 40, the belt 30 passes the point where the coolant is supplied to the return roller 24 or the belt 30, and then water is returned to the return roller 24 or the belt 30 again. The cooling of the belt 30 is not performed during the process of returning to the spraying point, thereby reabsorbing the coke heat. In addition, in the prior art, water may get on the cooling process of the belt 30, and thus, coke dust is attached to the water on the belt 30 by suction, thereby falling during the movement of the belt 30, and the coke dropped as described above. Dust or the like is caught in the driving portion of the return roller 24 for moving the belt 30, thereby preventing the rotation of the return roller 25.

In addition, since the cooling water injected to the return roller 24 or the belt 30 is thrown out together with the dust and the like, the cooling water is wasted, which is a factor that increases the manufacturing cost. In addition, the cooling water including the dust is discharged by reprocessing the dust contained in the cooling water in order to prevent environmental pollution, there is a problem that the cost of reprocessing the pollutants.

An embodiment of the present invention is to provide a cooling return roller and a belt cooling system using the same, so that the return roller is cooled by the cooling water supplied to the inside to cool the continuously moving belt.

Cooling return roller according to an aspect of the present invention supports a return belt of the conveyor, a drum having a plurality of inner pipe in the longitudinal direction of the inner periphery; And an inlet or outlet configured to respectively be installed at both ends of the drum, and through one side of the drum, through which the cooling fluid flows in or out, and the other side of which is provided with a distribution passage provided with the inlet or outlet to communicate with the inner pipe. The distribution passage may include at least one first passage communicating any one of the inlet or the outlet and the inner pipe, and at least one second passage communicating the other two of the inner pipe.

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The drum may include a core member having an inner pipe formed on an outer circumferential surface thereof, and an outer shell installed outside the core member.

The inner pipe may be formed straight or spiral.

The cooling fluid may comprise any one of water, oil and gas.

According to another aspect of the present invention, a belt cooling system using a cooling return roller includes the above-described return cooling roller installed at a lower portion of a belt conveyor device to support a belt that is circulated; A circulation line communicating with the inlet and the outlet to form a closed cycle; A pump installed on the circulation line to circulate the cooling fluid; And a heat exchanger connected to the circulation line to cool the cooling fluid by heat exchange.

The apparatus may further include a sensor unit for measuring a returned temperature of the belt, and a controller configured to control an operation of the pump to adjust a circulation amount of the cooling fluid according to the returned temperature of the belt sensed by the sensor unit.

The inner pipe may be formed straight or spiral.

The cooling fluid may comprise any one of water, oil and gas.

According to one embodiment of the present invention, after transporting the dry digested red coke, the belt can be continuously cooled by allowing the cooling fluid to circulate inside the roller that contacts the returned belt. As the cooling of the belt is made in this way, the rollers can be minimized from being damaged by heat, thereby improving the durability of the belt, thereby increasing the service life. In addition, the cooling load of the cooling return roller can be adjusted according to the temperature of the belt, thereby preventing unnecessary operation. In addition, since the belt cooling system of the present embodiment is installed to form a closed cycle in which the cooling fluid continues to circulate, the cooling fluid can be reused to prevent waste of the cooling fluid and to prevent environmental pollution due to the discarded cooling fluid. have.

1 is a front view showing a belt conveyor device according to the prior art.
Figure 2 is a front view briefly showing a cooling system of the belt conveyor apparatus according to the prior art.
Figure 3 is a block diagram of a belt cooling system using a cooling return roller applied to the belt conveyor apparatus according to an embodiment of the present invention.
Figure 4 is an exploded perspective view showing a cooling return roller according to an embodiment of the present invention.
5 is a cross-sectional view of the cooling return roller according to an embodiment of the present invention.
6 is a cross-sectional view of a cooling return roller according to another embodiment of the present invention.
Figure 7 is an exploded perspective view showing a cooling return roller according to another embodiment of the present invention.
8 is a cross-sectional view of a cooling return roller according to another embodiment of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the accompanying drawings. The embodiments of the present invention can be modified into various other forms, and the scope of the present invention is not limited to the embodiments described below. The shape and the size of the elements in the drawings may be exaggerated for clarity and the same elements are denoted by the same reference numerals in the drawings.

3 is a block diagram of a belt cooling system using a cooling return roller applied to the belt conveyor apparatus according to an embodiment of the present invention.

Referring to FIG. 3, in the present embodiment, the belt conveyor device 110 may circulate the belt 130 to continuously move the conveyed material.

To this end, the belt conveyor apparatus 110 may be provided with a plurality of stands 120 along the line of movement of the conveyed material, and the stand 120 may be provided with a carriage roller 122 for the movement of the belt 130.

The carriage roller 122 is composed of a plurality of, for example, three, the carriage roller 122 located on both sides is inclined toward the center. Thus, as the carriage roller 122 on both sides faces the center, the belt is formed in a concave shape toward the center side. Accordingly, the conveying material, for example, the dry coke discharged after drying is completed, is concavely loaded. Can move stably.

In the present embodiment, the belt conveyor apparatus 110 may include a belt cooling system 140 for cooling the heated belt 130 in the process of moving the red coke.

In one example, the belt cooling system 140 may include a plurality of cooling return rollers 124 installed under the belt 130 that are circulated and returned to support the belt 130 that returns.

The cooling return roller 124 is provided to circulate the cooling fluid therein, and may lower the temperature of the belt 130 as it rotates in contact with the belt 130.

In addition, the belt cooling system 140 may include a circulation line 142 connected to the inlet and the outlet of the cooling return roller 124 to form a closed cycle.

In addition, a pump 144 for circulating a cooling fluid may be installed on the circulation line 142.

The power line for supplying power from the outside may be connected to the pump 144, and a control unit (not shown) may be provided for the operation thereof.

In this embodiment, the cooling fluid may include cooling water, cooling oil or refrigerant gas. The cooling fluid is circulated by the pump 144 to the cooling return roller 124 through the circulation line 142, and in this process, the belt 130 that is returned to come into contact with the cooling return roller 124 may be cooled.

In addition, a heat exchanger 146 that circulates the cooling return roller 124 to cool the cooling fluid that absorbs heat such as the belt 130 may be connected to the circulation line.

The belt cooling system 140 may be provided such that the circulation line 142 of the cooling fluid circulates forming a closed cycle.

In this embodiment, the cooling return roller 124 may be installed long in the width direction of the belt conveyor device 110. In addition, the cooling return roller 124 may be provided with a flow path to allow the cooling fluid to circulate therein.

In the present embodiment, each cooling return roller 124 may be provided with a control unit for controlling the pump 144 and its driving, it is also possible to supply a cooling fluid is connected to one pump 144 and the control unit. .

In addition, the belt cooling system 140 of the present embodiment may further include a sensor unit 148 for measuring the returned temperature of the belt 130. For example, the sensor unit 148 may be installed at one side of the stand 120, and measure the temperature of the belt 130 positioned at the front of the cooling return roller 124.

Meanwhile, the temperature of the belt 130 measured by the sensor unit 148 may be transmitted to the controller. In addition, the controller may control the operation of the pump 144 according to the temperature of the belt 130 sensed by the sensor unit 148.

For example, when the temperature of the belt 130 sensed by the sensor unit 148 is higher than the set temperature, the controller increases the output of the pump 144 to increase the circulation amount of the cooling fluid. In addition, the controller lowers the output of the pump 144 or stops the operation when the temperature of the belt 130 sensed by the sensor unit 148 is less than the set temperature.

In addition, the sensor unit 148 may be installed to measure only the temperature of the front side of the cooling return roller 124 installed at one side of the cooling return roller 124, for example, at the foremost, and the belt measured by the sensor unit 148. It is also possible to deliver the temperature of 130 to the control unit so that all pumps 146 operate under the same conditions.

4 is an exploded perspective view showing the cooling return roller according to an embodiment of the present invention, Figure 5 is a cross-sectional view of the cooling return roller according to an embodiment of the present invention.

As shown in FIG. 4 and FIG. 5, the cooling return roller 124 may include a drum 126 having a plurality of inner pipes 127 formed in a longitudinal direction around an inner side thereof.

And both ends of the drum 126 may be coupled to the shaft connecting portion 128 rotatably mounted to the stand 120. In addition, a distribution passage 129 connected to the internal pipe 127 may be formed in the shaft connection part 128.

Each shaft connection portion 128 may be formed to penetrate through the inlet port (128a) or the outlet port (128b) for the flow, out of the cooling fluid on one side. In one example, the inlet 128a or outlet 128b may be formed on the axis of rotation.

In addition, a circulation line 142 may be connected to the inlet port 128a or the outlet port 128b of the shaft connection unit 128.

In addition, in the present embodiment, the distribution channel 129 may include a channel expansion part connected to the inlet or the outlet. The flow path expansion part may be formed as a disc shaped space formed inside the other side of the shaft connection part 128, and is connected to the plurality of internal pipes 127 in common as the shaft connection part 128 is combined with the drum 126 to cool. It may be provided in a passage through which the fluid circulates.

Accordingly, the cooling fluid that enters the inlet port 128a of the shaft connection unit 128 through the circulation line 142 is supplied to the flow path expansion unit, which is the distribution channel 129, to form internal pipes 127 formed around the inner side of the drum 126. To distribute the cooling fluid.

In addition, the cooling fluid passing through the inner pipes 127 may be collected at the flow path expansion part which is the distribution flow path 129 again, and may be discharged back to the circulation line 142 through the outlet 128b of the shaft connection part 128. have.

In this embodiment, the inner pipe 127 may be formed in a straight line, thereby rapidly circulating the cooling fluid, it is possible to quickly cool the belt 130 in contact with the cooling return roller 124.

In this embodiment, the drum 126 and the shaft connecting portion 128 may be integrally coupled by welding, and may be coupled using a spiral portion formed by using each of the connecting portions. In addition, the drum 126 and the shaft connecting portion 128 may be provided so as to form a stepped portion in each connecting portion, and the stepped portion is fitted by an interference fit.

In addition, in this embodiment, the inner pipe 127 is described as being formed in a straight line inside the drum 126, but is not limited thereto, and the inner pipe 227 may be spirally formed as shown in FIG.

6 is a cross-sectional view of a cooling return roller according to another embodiment of the present invention.

Referring to FIG. 6, when the inner pipe 227 is formed in a spiral shape, the inner pipe 227 may be formed in a reverse direction with respect to the rotation direction of the drum 226, and thus the cooling fluid circulating in the spiral inner pipe 227. The contact area of the drum 226 can be increased to lower the temperature deviation of the drum.

In this embodiment, the drum 226 may be cylindrical. And the inner pipe 227 may be formed through the drum 226 directly.

On the other hand, the drum 226 may be formed in a separate type, thereby making it possible to more easily form the inner pipe 227.

For example, the drum 226 may include a core material 226a having an inner pipe 227 formed on an outer circumferential surface thereof. At this time, the inner pipe 227 may be processed in the form of a groove open to the outside of the core material 226a.

In addition, an outer shell 226b may be installed at an outer side of the core 226a to block the open inner pipe 227. Here, the shell 226b may be formed of a material having high surface strength to prevent surface damage due to contact with the belt 130.

As such, in the present embodiment, the shell 226b may be formed of various materials and shapes to improve the characteristic value of the cooling return roller 224. For example, the outer shell 226b may be provided to improve cooling characteristics as well as increase the surface strength, and for this purpose, the outer shell 226b may be formed of a material having a higher heat transfer efficiency than the core member 226a.

In addition, both ends of the drum 226 may be rotatably connected to the stand 130, the shaft connecting portion 228 having a distribution passage 229 connected to the inner pipe 227 of the drum 226 may be installed. .

In addition, the inlet 228a and the outlet 228b connected to the circulation line 142 may be formed in the shaft connection part 228.

In addition, a stepped portion 228c may be formed in the shaft connection portion 228 for coupling the drum 226 formed of the core member 226a and the outer shell 226b. The stepped portion 228c may maintain a constant distance at which the core member 226a and the outer shell 226b are spaced apart from the shaft connecting portion 228 when the shaft connecting portion 228 and the drum 226 are coupled to each other. The flow path area of 229 can be kept constant.

In addition, the core 226a of the drum 226 may be formed on the inner surface of the shaft connecting portion 228 to form a protrusion 226c for maintaining a constant flow path area with the distribution channel 229.

7 is an exploded perspective view showing a cooling return roller according to another embodiment of the present invention, Figure 8 is a cross-sectional view of the cooling return roller according to another embodiment of the present invention.

Referring to FIGS. 7 and 8, the cooling return roller 324 may include a drum 326 and shaft connectors 328 coupled to both ends of the drum 326.

The drum 326 may be formed with a plurality of inner pipe 327 formed in the longitudinal direction of the inner circumference.

On the other hand, one side of each shaft connection portion 328 may be formed through the inlet 328a or the outlet 328b for the flow, out of the cooling fluid.

For example, the inlet 328a or the outlet 328b may be formed on the rotation axis, so that the circulation line 142 is connected to the inlet 328a or the outlet 328b when the cooling return roller 324 rotates. It can rotate on the axis and maintain the connection.

In addition, a distribution passage 329 may be formed in the shaft connection part 328 to connect the inlet port 328a or the outlet port 328b with the inner pipe 327 of the drum 426.

In this embodiment, the distribution channel 329 is formed in the shaft connection portion 328 and at least one first channel communicating with any one of the inlet port 328a or the outlet port 328b and the internal pipe 327 of the drum 326. 329a and at least one second flow passage 329b communicating with the other two of the inner pipe 327.

That is, the distribution channel 329 may supply the cooling fluid supplied from the inlet 329a to the internal pipe 327 of the drum 326 through the first channel 329a formed at the inlet side shaft connection part 328. Then, the cooling fluid supplied to the inner pipe 327 is circulated back to the inlet side shaft connecting portion 328 through the other inner pipe 327 adjacent through the second flow path 329b of the outlet shaft connecting portion 328. Can be. In addition, the cooling fluid circulated to the inlet-side shaft connecting portion 328 is supplied to another adjacent inner pipe 327 through the second flow passage 329b and circulated to the inlet-side shaft connecting portion 328, and the inlet-side shaft connecting portion 328 It may be discharged to the outlet 328b through the first flow passage (329a) formed in the.

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 appended claims and their equivalents. It will be clear to those who have knowledge.

110: belt conveyor device 120: stand
122: carriage roller 124: cooling return roller
126: drum 127: internal piping
128: shaft connection 128a: inlet
128b: outlet 129: distribution channel
130: belt 140: belt cooling system
142: circulation line 144: pump
146: heat exchanger 148: sensor

Claims (10)

A drum supporting a return belt of the conveyor, the drum having a plurality of inner pipes formed in a longitudinal direction of an inner circumference thereof; And
It is provided at both ends of the drum, respectively, the inlet or outlet through which the cooling fluid flows in or out through the rotation axis is provided on one side, the other side is formed with a distribution passage provided so that the inlet or the outlet communicates with the inner pipe It includes a shaft connection portion;
At least one first passage communicating with any one of the inlet or the outlet and the inner pipe;
And at least one second flow passage communicating with the other two of the inner pipes.
delete delete The method according to claim 1,
The drum is a core material with the inner pipe formed on the outer circumferential surface,
Cool return roller comprising an outer shell provided on the outer side of the core material.
The method according to claim 1 or 4,
The inner pipe is a cooling return roller, characterized in that formed in a straight or spiral.
The method according to claim 1 or 4,
Cooling return roller, characterized in that the cooling fluid comprises any one of water, oil and gas.
A return cooling roller according to claim 1 or 4, which is installed at a lower portion of the belt conveyor device and supports a belt which is circulated;
A circulation line communicating with the inlet and the outlet to form a closed cycle;
A pump installed on the circulation line to circulate the cooling fluid; And
A heat exchanger connected to the circulation line to cool the cooling fluid by heat exchange;
Belt cooling system comprising a.
The method of claim 7,
Further comprising a sensor unit for measuring the returned temperature of the belt,
And a control unit for controlling the operation of the pump to adjust the circulation amount of the cooling fluid according to the returned temperature of the belt sensed by the sensor unit.
The method of claim 7,
The inner pipe is a belt cooling system, characterized in that formed in a straight or spiral.
The method of claim 7,
The cooling fluid is a belt cooling system, characterized in that it comprises any one of water, oil and gas.

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