KR20130032051A - Deivce for removing particles of strainer in process pump for cooling furnace body - Google Patents

Abstract

PURPOSE: A foreign substance removal apparatus of a process pump for cooling a furnace body is provided to have a brush sweeping the sidewall surface of a filter to rip off the foreign substances sticking to the filter, and an air injection unit injecting the high-pressure air to discharge foreign substances collected on a screen mesh on the outside. CONSTITUTION: A foreign substance removal apparatus of a process pump for cooling a furnace body includes a screen mesh(40), a brush(50), a lift drive unit(60) and an air injection unit(71). The screen mesh is positioned inside a filter(20). The brush is fixed on the screen mesh and contacted to the inner surface of the filter. The lift drive unit is connected to the screen mesh to lift the screen mesh and the brush vertically. The air injection unit is installed on the lift drive unit to inject the air inside the filter to discharge foreign substances. [Reference numerals] (AA,BB) Cooling water;

Description

DEVICE FOR REMOVING PARTICLES OF STRAINER IN PROCESS PUMP FOR COOLING FURNACE BODY}

The present invention relates to a filter for a process pump for furnace cooling, and more particularly, to a foreign matter removal device of a filter for a process pump capable of periodically removing foreign matter inside the filter.

The lower part of the blast furnace, that is, the bottom part, is equipped with a duct (fire brick) around the molten metal to withstand the high temperature molten iron located therein. In order to protect the duct, the coolant is injected to the furnace shell (furnace) to cool the furnace shell. The cooling water used for cooling is sent to the refrigerator equipment (heat exchanger, etc.) by the process pump, cooled, and then fed back to the furnace shell to be used for cooling.

The process pump filters a variety of foreign substances contained in the coolant by installing a filter in front of the suction side for sucking the coolant. However, if a large amount of foreign matter accumulates in the filter during the continuous circulation of the cooling water, filter clogging occurs. In this case, the process pump does not normally supply the coolant at an appropriate flow rate for cooling the furnace, causing a problem in that the temperature of the bottom part rises due to the decrease in flow rate.

The present invention is to remove the foreign matter attached to the filter of the process pump to prevent the clogging of the filter, as a result of the foreign matter removal apparatus of the filter for the process pump for the furnace body cooling that can normally supply the coolant of the proper flow rate for the cooling of the furnace body. To provide.

According to one embodiment of the present invention, an apparatus installed in a filter for a process pump for furnace cooling to remove foreign substances in the filter, i) a screen mesh located inside the filter, and ii) a screen mesh fixed to the screen mesh. A brush in contact with the inner surface of the filter, iii) a lift drive unit which is combined with the screen mesh to raise or lower the screen mesh and the brush, and iii) an air injection that is installed in the lift drive unit to inject air for debris discharge into the filter. It provides a debris removal device of the filter for the process pump comprising a portion.

The screen mesh may include a bottom portion having a plurality of fine holes for air passage, and a cylindrical side wall connected to the bottom portion, and the brush may be fixed to the entire outer circumferential surface of the side wall.

The outer diameter of the side wall is formed to be smaller than the inner diameter of the filter, the height of the side wall is formed to be smaller than the height of the filter so that the screen mesh can occupy a portion of the inside of the filter.

The filter can be located inside the front side housing of the process pump. The elevating drive unit may include a rotation drive shaft penetrating the bottom of the screen mesh and positioned over the inside of the filter and the outside of the front end housing, and a drive motor engaged with the end of the rotation drive shaft outside the front end housing.

The elevating drive unit may further include a buffer bearing. The shock absorbing bearing is installed between the filter and the rotational drive shaft and between the front side housing and the rotational drive shaft and can seal the bottom center of the front side housing.

The rotary drive shaft may form a thread in a portion located inside the filter, and the screen mesh may be coupled to the thread to move up or down according to the rotation direction of the rotary drive shaft. A buffer stopper may be placed on top of the rotation drive shaft to limit the maximum lift height of the screen mesh.

The air inlet may include an air inlet through the buffer bearing to connect the inside and the outside of the front side housing, a blower connected to the air inlet through the air pipe to blow air, and an open / close valve installed in the air pipe. .

The foreign matter adhering to the filter of the process pump can be removed automatically, eliminating the problem of clogging the filter. As a result, the flow rate of the cooling water for the cooling of the furnace is sufficiently secured to facilitate the cooling of the furnace, and the rise of the temperature of the furnace can be prevented. In addition, the foreign matter of the filter is prevented from entering the heat exchanger to prevent the failure of the heat exchanger, it is possible to reduce the repair time even if the heat exchanger repair is necessary.

1 is a schematic diagram of a furnace cooling system including a process pump.
2 is a schematic cross-sectional view of a process pump equipped with a debris removing device according to an embodiment of the present invention.
3 is a perspective view of the filter shown in FIG.
4 is a perspective view showing a part of the foreign matter removing apparatus shown in FIG. 2.
5 is a schematic cross-sectional view showing an operating state of the foreign matter removing apparatus shown in FIG. 2.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

1 is a schematic diagram of a furnace cooling system including a process pump.

Referring to FIG. 1, the lower part of the blast furnace 10, that is, the bottom part, is provided with a soft wire 11 to withstand high temperature waste water, and sprays cooling water on the outer wall of the furnace 12 to protect the soft wire 11. Cool down. The coolant used for cooling is collected in the sump 13, and the coolant in the sump 13 is cooled by the process pump 14 through the heat exchanger 15 and then supplied to the outer wall of the furnace 12 again.

The temperature of the cooling water supplied to the outer wall of the furnace body 12 through the heat exchanger 15 may be about 17 ° C., and the temperature of the cooling water collected into the sump 13 after cooling the furnace body 12 is in the range of approximately 20 ° C. to 35 ° C. Can be.

FIG. 2 is a schematic cross-sectional view of a process pump equipped with a debris removing device according to an embodiment of the present invention, and FIG. 3 is a perspective view of the filter shown in FIG. 2.

2 and 3, the filter 20 is installed inside the front-side housing 30 of the process pump 14 to filter foreign matter contained in the cooling water. At this time, the front end side housing 30 means the suction side front end to suck the cooling water stored in the drain (13).

The front end side housing 30 is connected to the first pipe 31 into which the coolant is introduced, and the second pipe 32 through which the coolant from which foreign matter is filtered out. In addition, a cover 33 is installed on the upper side of the front side housing 30 to seal the inside of the front side housing 30.

The filter 20 includes a circular bottom 21 and a cylindrical side wall 22 connected to the bottom 21. Cooling water inlet 23 having the same size as the first pipe 31 is formed on the side wall 22 facing the first pipe 31, and the coolant is supplied into the filter 20 through the first pipe 31. . In addition, a plurality of fine holes are formed in the entire bottom portion 21 and the side wall 22 of the filter 20.

Therefore, the foreign matter contained in the cooling water remains in the filter 20 without passing through the micro holes, and the cooling water from which the foreign matter is removed is discharged to the second pipe 32. When foreign matters accumulate inside the filter 20 in the cooling water filtration process, fine holes are blocked by foreign matters, and thus clogging of the filter 20 in which the cooling water is not properly discharged occurs.

When the clogging phenomenon of the filter 20 is confirmed and the operation of the process pump 14 is stopped, the foreign material removing apparatus 100 according to the present embodiment operates to collect foreign matter accumulated in the filter 20 and discharge the foreign matters to the outside of the filter 20. .

4 is a perspective view showing a part of the foreign matter removing apparatus shown in FIG. 2.

2 and 4, the debris removing apparatus 100 includes a screen mesh 40 located inside the filter 20, a brush 50 fixed to the screen mesh 40, and a screen mesh 40. It is coupled to the lifting and lowering drive unit 60 for raising or lowering the screen mesh 40, and the air inlet unit 70 is installed in the elevating drive unit 60 to inject air into the filter 20.

The screen mesh 40 includes a bottom portion 41 and a cylindrical side wall 42 connected to the bottom portion 41, and the brush 50 is fixed to the entire outer circumferential surface of the side wall 42. A plurality of fine holes are formed in the bottom portion 41 of the screen mesh 40.

The outer diameter of the side wall 42 of the screen mesh 40 is formed to be smaller than the inner diameter of the side wall 22 of the filter 20 so that the screen mesh 40 is positioned inside the filter 20. In addition, the height of the side wall 42 of the screen mesh 40 is formed to be smaller than the height of the side wall 22 of the filter 20 so that the screen mesh 40 occupies a part of the filter 20.

The elevating drive unit 60 includes a rotation drive shaft 61 penetrating the center of the screen mesh 40, a drive motor 62 coupled to the rotation drive shaft 61 outside the front side housing 30, and a filter ( And a shock absorbing bearing 63 installed between the rotary drive shaft 61 and the front end housing 30 and the rotary drive shaft 61.

The rotation drive shaft 61 penetrates the center of the bottom portion 41 of the screen mesh 40 and is formed at a height greater than the height of the side wall 22 of the filter 20 so that the inside of the filter 20 and the front housing 30 are formed. Located across the outside). Threads are formed on the outer circumferential surface of the portion of the rotary drive shaft 61 located inside the filter 20. And the buffer stopper 64 is located in the uppermost part of the rotation drive shaft 61.

An opening for penetrating the rotation drive shaft 61 is formed at the center of the bottom portion 41 of the screen mesh 40, and a screw thread is formed on the inner wall of the opening to screw the rotation drive shaft 61. Therefore, the screen mesh 40 is raised or lowered according to the rotation direction of the rotation drive shaft 61.

The rotary drive shaft 61 may be coupled to the drive motor 62 through the gear box 65 outside the front side housing 30, or the end of the rotary drive shaft 61 may be directly coupled to the drive motor 62. . In FIG. 2, the rotary drive shaft 61 is coupled to the driving motor 62 through the gear box 65 as an example.

The shock absorbing bearing 63 supports the rotation of the rotary drive shaft 61 and at the same time, seals the front-side housing 30 so that the coolant does not leak when the process pump 14 is operated. An opening is formed in the center of the bottom 21 of the filter 20 and the center of the bottom of the front-side housing 30, and the shock absorbing bearing 63 is mounted in this opening.

The air inlet 70 includes an air inlet 71 passing through the buffer bearing 63, an air pipe 72 connected to the air inlet 71, a blower 73 connected to an end of the air pipe 72, and And an on-off valve 74 provided on the air pipe 72. The air inlet 71 passes through the buffer bearing 63 to connect the inside and the outside of the front-side housing 30.

When the process pump 14 is running, the screen mesh 40 and the brush 50 are located at the bottom of the inside of the filter 20 and remain stationary. The lifting and lowering drive unit 60 is also in a stopped state, and the opening / closing valve 74 closes the air pipe 72 to block air inflow.

5 is a schematic cross-sectional view showing an operating state of the foreign matter removing apparatus shown in FIG. 2.

2 and 5, when the clogging phenomenon of the filter 20 is confirmed and the operation of the process pump 14 is stopped, all of the coolant inside the front side housing 30 is discharged, and the worker releases the front side housing 30. Open the cover 33 of the front side to open the inside of the housing (30).

Subsequently, the rotation drive shaft 61 is rotated forward by the operation of the drive motor 62, the blower 73 is operated, and at the same time, the open / close valve 74 installed in the air pipe 72 is opened to draw air into the filter 20. Inflow. The screen mesh 40 rises along the rotation drive shaft 61 by the forward rotation of the rotation drive shaft 61, and the brush 50 is attached to the filter 20 by sweeping the inner surface of the side wall 22 of the filter 20. Scrape off debris.

In this process, the air introduced into the filter 20 rises above the screen mesh 40 through the minute holes formed in the bottom 41 of the screen mesh 40. As a result, the foreign substances scraped off by the brush 50 continuously rise or fall depending on the weight, and then fall onto the bottom 41 of the screen mesh 40.

When the screen mesh 40 continuously rises and touches the buffer stopper 64, the operation of the driving motor 62 is stopped, and the foreign matter accumulated on the screen mesh 40 by raising the air pressure is transferred to the outside of the front side housing 30. Eject all The buffer stopper 64 restricts the maximum lift height of the screen mesh 40 to prevent the screen mesh 40 from escaping from the rotation drive shaft 61.

After all the foreign matter inside the filter 20 is discharged by the operation of the screen mesh 40, the driving motor 62 is operated to reversely rotate the rotary drive shaft 61. As a result, the screen mesh 40 descends to the initial position, and the foreign matter discharge operation is completed.

While the present invention has been described in connection with what is presently considered to be practical exemplary embodiments, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, Of course.

10: blast furnace 11: yeonwa
12: nobody 13: sump
14: process pump 15: heat exchanger
20: strainer 30: shear-side housing
40: screen mesh 50: brush
60: elevating drive unit 61: rotary drive shaft
70: air inlet 71: air inlet

Claims (8)

In the apparatus for removing the foreign matter inside the filter installed in the filter for the process pump for the furnace body cooling,
A screen mesh located inside the filter;
A brush fixed to the screen mesh and in contact with an inner surface of the filter;
A lift driver coupled with the screen mesh to raise or lower the screen mesh and the brush; And
An air injection unit installed in the elevating driving unit and injecting air for discharging foreign matter into the filter;
Foreign material removal device of the filter for the process pump comprising a. The method of claim 1,
The screen mesh includes a bottom portion formed with a plurality of fine holes for passing air, and a cylindrical side wall connected to the bottom portion,
The brush is foreign matter removal apparatus of the filter for the process pump is fixed to the entire outer peripheral surface of the side wall. The method of claim 2,
The outer diameter of the side wall is formed to a size smaller than the inner diameter of the filter, the height of the side wall is formed to a size smaller than the height of the filter so that the screen mesh occupies a portion of the inside of the filter, foreign matter removal apparatus of the filter. The method of claim 2,
The filter is located inside the front side housing of the process pump,
The elevating drive unit,
A rotary drive shaft penetrating a bottom portion of the screen mesh and positioned inside the filter and outside the front side housing; And
A drive motor that engages with an end of the rotation drive shaft on an outer side of the front-side housing;
Foreign material removal device of the filter for the process pump comprising a. 5. The method of claim 4,
The elevating drive unit,
And a buffer bearing disposed between the filter and the rotational drive shaft and between the front-side housing and the rotational drive shaft to seal a center of a bottom portion of the front-side housing. The method of claim 5,
The rotary drive shaft is a screw thread formed in the portion located inside the filter, the screen mesh is coupled to the thread is foreign matter removal device of the filter for the process pump for raising or lowering in accordance with the rotation direction of the rotary drive shaft. The method of claim 5,
A debris removal device of a filter for a process pump, wherein a buffer stopper is positioned at the top of the rotary drive shaft to limit the maximum lift height of the screen mesh. 5. The method of claim 4,
The air injection unit,
An air inlet through the buffer bearing to connect the inside and the outside of the front-side housing;
A blower connected to the air inlet and blowing air through an air pipe; And
On-off valve installed in the air pipe
Foreign material removal device of the filter for the process pump comprising a.

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