KR100987663B1 - Fly away preventive apparatus for blast furnace - Google Patents

Abstract

The present invention relates to a prevention device for preventing the scattering of molten iron discharged from the blast furnace exit.

The present invention, the blast furnace provided with a discharge port to discharge the molten iron, shielding cover to shield to prevent the scattering of the molten iron discharged to the outlet of the blast furnace; An elevating cylinder connected to an electric means to elevate the shielding cover to open the exit; It is composed of a fixed frame installed on one side of the blast furnace to fix the lifting cylinder.

Therefore, the present invention blocks the scattering of the molten iron discharged to the tap opening while automatically lifting the shield cover automatically, there is an effect that can prevent the safety accident in advance.

Blast furnace, exit, molten iron, scattering, shielding cover, lifting cylinder, rotating shaft.

Description

Scattering prevention device for blast furnace exit {FLY AWAY PREVENTIVE APPARATUS FOR BLAST FURNACE}

The present invention relates to a scattering prevention device for the blast furnace outlet, more specifically, for the blast furnace outlet that can be expected to increase the work efficiency while preventing safety accidents by preventing the scattering of molten iron discharged through the outlet of the blast furnace. It relates to a scattering prevention device.

As is well known, iron is produced by reducing the iron oxide component of iron ore into fossil fuels such as coke or coal. Such a manufacturing method includes a method of manufacturing a furnace for reducing iron ore with CO gas generated at this time using coke as a fuel. There are various methods such as steelmaking using electric energy, rotary kiln method for producing reduced iron, and fluidized bed method using spectroscopy.

In the process of pig iron manufacturing, the blast furnace steelmaking method is the mainstream in the world, and the other methods are used in small areas in some regions depending on the resources and regional characteristics.

Here, the furnace is a kind of shaft furnace and is derived from the German hoch ofen and is widely referred to as a blast furnace.

Looking at the above-described steelmaking method of the furnace, after charging the iron ore and coke in the interior of the furnace, and supplying hot hot air to the lower portion of the furnace to produce molten iron by melting and reducing the iron ore and coke.

However, the molten iron produced in this way uses high-pressure oxygen in the process of being discharged through the blast furnace outlet port, which not only causes the molten iron to be scattered to all sides of the outlet port, but also generates high-temperature radiant heat, causing and producing safety accidents. There was a problem of delaying the process.

The present invention has been made to solve the conventional problems as described above, the object of the present invention is to block the scattering of the molten iron discharged through the exit port to prevent safety accidents in advance and at the same time to increase the work efficiency. The present invention provides a scattering prevention device for a blast furnace exit.

The present invention for achieving the above object, in the blast furnace provided with a discharge port to discharge the molten iron, shielding cover to prevent the scattering of the molten iron discharged to the outlet of the blast furnace; An elevating cylinder connected to an electric means to elevate the shielding cover to open the exit; It consists of a fixed frame installed on one side of the blast furnace to fix the lifting cylinder.

Here, the transmission means, a lifter connected to elevate the shield cover, one side is connected to elevate the lifter by rotation and the other side is connected to the elevating cylinder to be rotated by the elevating operation, the rotating shaft, It includes a drive sprocket provided to rotate integrally with the rotary shaft, a driven sprocket provided in the fixed frame to transfer the driving force of the drive sprocket, a connecting chain connecting the driven sprocket and the drive sprocket, the cylinder rod of the lifting cylinder Is connected to the connecting chain.

The transmission means further includes a slider connected to the elevating cylinder and the connection chain to drive the connection chain according to the operation of the cylinder rod, and a first guide rail installed in the fixed frame to guide the vertical sliding of the slider. At this time, the upper and lower portions of the slider are provided along the first guide rail of the fixed frame to prevent the front and rear flow of the slider is provided with a first flow prevention roller.

In addition, the rotating shaft is provided with an electric sprocket for transmitting the driving force of the driving sprocket, one end of the electric chain connected to the electric sprocket is connected to the lifter and the other end is connected to the weight balance to adjust the horizontal balance.

In addition, both sides of the lifter is provided with a second anti-flow roller, the fixed frame is provided with a second guide rail to guide the vertical sliding of the second anti-flow roller to prevent the left and right flow of the lifter.

In addition, the shielding cover is provided with a hook bar to be detachably coupled to the hook groove provided at the tip of the lifter.

Alternatively, the present invention for achieving the above object, in the blast furnace provided with a discharge port to discharge the molten iron, shielding cover to prevent the scattering of the molten iron discharged to the outlet of the blast furnace; An elevating cylinder connected to both sides of the shielding cover by electric means, and elevating the shielding opening by elevating the shielding cover; It is composed of a fixed frame installed on both sides of the exit port of the blast furnace to fix the two lifting cylinders.

At this time, the transmission means, the lifter is connected to lift the shield cover, one side is connected to elevate the lifter by rotation and the other side is connected to the elevating cylinder, the rotary shafts respectively installed on both sides of the fixed frame, the both side shaft The first interlocking sprockets respectively provided in the second interlocking sprockets respectively provided on both fixed frames to transfer the driving force of the first interlocking sprockets, and the interlocking bodies connecting the first and second interlocking sprockets respectively to each other; It is preferable to include a balance joint connected to the two interlocking sprockets to adjust the rotational balance according to the driving force transmission.

According to the present invention implemented by the above means, by automatically raising and lowering the shielding cover automatically to block the scattering of the molten iron discharged to the exit port, it is possible to prevent safety accidents at the same time and increase the work efficiency. This is a very useful effect.

In addition, the present invention is to lift by using the lifting cylinder on both sides of the shield cover, there is an effect that can improve the stability of the operation.

In addition, according to the present invention, the shield cover is detachably coupled to the lifter, thereby providing convenience for installation and disassembly and management of the shield cover.

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described in detail.

The present invention provides a shielding cover 150 for shielding the molten iron discharged from the tap-hole A of the blast furnace to prevent scattering, and a lifting cylinder for lifting the tap-hole A of the blast furnace by lifting the shielding cover 150. 130 and a fixed frame 110 for fixing the lifting cylinder 130.

The shielding cover 150 is formed of a rectangular plate having an appropriate width and vertical length to block the molten iron discharged through the exit A of the blast furnace in all directions, such a shielding cover 150 is shown in FIG. As shown in Fig. 4, it is preferable to maintain a proper distance d from the tap opening A to form a working space for the float treatment. And the hook bar 151 is horizontally provided on the upper portion of the shielding cover 150 to be detachably coupled to the hook groove 141 of the lifter 140 to be described later, the reinforcing bar 152 in the lower portion of the hook bar 151 ) Is provided to prevent and reinforce the deformation of the shield cover 150 and the hook bar 151 due to heat generated at the outlet A.

In addition, the inner surface of the shielding cover 150 is provided with a refractory material (not shown) to prevent the melting and damage of the shielding cover 150 due to the molten iron flying from the outlet (A) in advance, such a fire-resistant It is preferable to implement a castable widely used at workability and ultra-high temperature.

The fixed frame 110 forms a frame of the present invention, and is installed at both sides of the outlet A of the blast furnace as shown in FIGS. 4 and 5 to firmly secure the lifting cylinder 130 and the transmission means. And the fixed frame 110 is preferably installed on each of the upper both sides of the exit port (A). For example, as shown in Figure 6 showing another embodiment of the present invention, the fixed frame 110 is to be installed on each of the upper both sides of the outlet (A) to be disposed on both sides of the shield cover 150. Optionally, it is noted that the fixed frame 110 may be arranged in a single center in the shield cover 150.

Lifting cylinder 130 is connected to the transmission means to elevate the shield cover 150 to open or shield the exit (A) of the blast furnace through the shield cover 150, such lifting cylinder 130 is The cylinder rod 131 is vertically fixed to one side of the fixed frame 110 to move up and down. Such a lifting cylinder 130 may be implemented as a pneumatic cylinder or a hydraulic cylinder.

The power transmission means is a means for connecting the lifting cylinder 130 and the shielding cover 150 so as to transfer the power generated in the lifting cylinder 130 to the shielding cover 150, such a transmission means for lifting the shielding cover 150 It is roughly divided into a lifter 140 and a rotary shaft 114 which is connected to the lifter 140 and the lifting cylinder 130 and rotates to lift the lifter 140.

Rotating shaft 114 is rotatably installed on the upper portion of the fixed frame 110 to raise or lower the lifter 140 by rotation, the rotary shaft 114 is fixed frame 110, as shown in FIG. It is rotatably supported by bearings 114a provided on both sides of the upper part of the.

3, the driving sprocket 113 is provided at the right end of the rotating shaft 114 to be integrally rotated, and the fixing frame 110 in the vicinity of the lower side of the driving sprocket 113 is provided. The driven sprocket 112 is rotatably installed to transmit the driving force of the driving sprocket 113, and the connecting chain 113a connecting the driven sprocket 112 and the driving sprocket 113 has a cylinder of the lifting cylinder 130. The rod 131 is connected to rotate the driving sprocket 113 and the driven sprocket 112 according to the operation of the cylinder rod 131.

Here, the cylinder rod 131 and the connecting chain 113a of the lifting cylinder 130 are connected to the slider 120, and the first guide rail 111 is vertically installed on the fixed frame 110 to the slider 120. The upper and lower sliding guide, wherein the upper and lower portions of the slider 120 is provided with a first anti-flow roller 121 is preferably sliding in a rolling motion along the first guide rail 111, accordingly the slider 120 is prevented from flowing in the front and rear direction.

In addition, the center of the rotary shaft 114 is provided with an electric sprocket 115 is rotated integrally, the front end of the electric chain 116 that is caught by the electric sprocket 115 is connected to the lifter 140, the electric chain ( The rear end of the 116 is the weight balance 117 is connected.

Accordingly, the slider 120 moves up and down by the operation of the cylinder rod 131, and the driving sprocket 113 and the driven sprocket 112 are rotated while the connecting chain 113a connected to the slider 120 is driven. Accordingly, the rotating shaft 114 rotates the electric sprocket 115, and thus, the electric chain 116 moves to lift or lift the lifter 140 upward or downward.

At this time, the weight balance 117 not only adjusts the horizontal balance of the shielding cover 150 having a constant weight, but also lowers by its own weight when the lifting cylinder 130 malfunctions due to power failure, while lifting the lifter 140 and the shielding cover 150 ) And do not cause trouble for the starting process of blast furnace.

A hook groove 141 is formed at the top of the tip of the lifter 140 so that the hook bar 151 of the shielding cover 150 is detachably coupled thereto, whereby the installation and disassembly and management of the shielding cover 150 is performed. It becomes even easier. The support 142 is formed at the lower end of the lifter 140 to support the reinforcing bar 152 of the shielding cover 150 described above.

In addition, the rear end of the lifter 140 is provided with a second flow preventing roller 140b is slid up and down along the second guide rail 111a provided perpendicular to the fixed frame 110, thereby lifting the lifter 140 As shown in FIG. 3, the flow is prevented in the left and right directions when the elevator is lifted.

In addition, the rear end of the lifter 140 is provided with a third flow preventing roller 140a to slide up and down along the second guide rail 111a of the fixed frame 110, whereby the lifter 140 is shown in FIG. As shown in the drawing, the flow is prevented in the front-rear direction during the ascent.

Here, the second guide rail 111a is formed to guide the lifting of the lifter 140 while guiding the sliding of the second and third flow preventing rails 140b and 140a.

Meanwhile, the driving sprocket 113, the driven sprocket 112, the electric sprocket 115, and the first and second interlocking sprockets 160 and 161 may be implemented as pulleys. In addition, the connection chain 113a, the electric chain 116, the interlock chain 162 may be implemented as a belt.

The overall operating relationship of the present invention configured as described above will be described in detail with reference to FIGS. 4 and 5.

As shown in FIG. 4, the shield cover 150 is normally maintained in a state where the outlet A of the blast furnace is opened.

However, in the process of discharging the molten iron through the tap opening A, when the cylinder rod 131 is pulled downward by the operation of the lifting cylinder 130 to drive the connecting chain 113a in the direction of the arrow of FIG. The sprocket 113 and the rotary shaft 114 are integrally rotated.

By the rotation of the rotary shaft 114, the electric sprocket 115 is also integrally rotated to drive the electric chain 116, thereby lowering the lifter 140 and the shielding cover 150 connected to the electric chain 116. As shown in FIG. 5, since the shielding port A of the blast furnace is shielded, the molten iron discharged through the outlet port A is blocked from scattering in all directions by the shielding cover 150.

Unlike this, in order to open the tap-hole A of the blast furnace, when the cylinder rod 131 is pushed upward by the operation of the lifting cylinder 130 to drive the connecting chain 113a in the direction opposite to the arrow in FIG. As the sprocket 113, the rotary shaft 114, and the electric sprocket 115 are integrally rotated, thereby driving the electric chain 116 caught by the electric sprocket 115 to raise the shielding cover 150, The shielding cover 150 opens the exit hole A of the blast furnace as shown in FIG. 4.

On the other hand, Figure 6 is a front view showing another embodiment of the present invention, another embodiment of the present invention, the shield cover 150 to shield to prevent the scattering of molten iron discharged to the outlet (A) of the blast furnace And a lift cylinder 130 connected to both sides of the shield cover 150 by a transmission means to lift the shield cover 150, and a fixed frame 110 to fix the lift cylinder 130 respectively. do.

Another embodiment of the present invention is characterized in that the fixing frame 110 and the lifting cylinder 130 is installed corresponding to both sides of the exit port (A) of the blast furnace, wherein the transmission means is a lifter 140 and the rotary shaft ( 114), the first and second interlocking sprockets 160 and 161, the interlocking chain 162 and the balance joint 163 are further included.

The first interlocking sprockets 160 are respectively provided at corresponding ends of the rotary shafts 114 installed on both side fixing frames 110 to be integrally rotated with the rotary shafts 114 and to the lower portion of the first interlocking sprockets 160. The second interlocking sprocket 161 is rotatably installed in the vicinity of the fixed frame 110 to be transferred to the driving force of the first interlocking sprocket 160, and the first and second interlocking sprockets 160 and 161 on both sides. ) Are connected to the interlocking chain 162, respectively.

And the second interlocking sprocket 161 on both sides is connected to the balance joint 163 to adjust the rotational balance according to the driving force transmission. That is, when the driving speeds of the first and second interlocking sprockets 160 and 161 are different, the balance joint 163 adjusts the balance of the driving speeds of the first and second interlocking sprockets 160 and 161. To adjust.

In another embodiment of the present invention configured as described above, the rotary shaft 114 and the first and second interlocking sprockets 160 and 161 are integrally rotated by the lifting cylinder 130 connected to both sides of the shielding cover 150. As a result, a more stable shielding cover 150 can be raised and lowered, and a balance joint 163 adjusts the left and right balance according to the rotational speeds of the two rotation shafts 114.

The above descriptions are merely illustrative of preferred embodiments of the present invention, and the present invention is not limited to the above-described embodiments, and can be variously modified within the scope of the appended claims.

1 is an exploded side view showing an exploded state of the shield cover according to an embodiment of the present invention.

Figure 2 is a side view showing a coupling state of the shield cover according to an embodiment of the present invention.

3 is a front view according to an embodiment of the present invention.

4 and 5 is an operation diagram according to an embodiment of the present invention.

6 is a front view according to another embodiment of the present invention.

♠ Explanation of symbols on the main parts of the drawing ♠

110: fixed frame 114: rotating shaft

115: electric sprocket 120: slider

130: lifting cylinder 140: lifter

150: shield cover A: exit port

Claims (10)

In the blast furnace equipped with a tap hole to discharge the molten iron, A shielding cover for shielding to prevent scattering of the molten iron discharged to the outlet of the blast furnace; An elevating cylinder connected to an electric means to elevate the shielding cover to open the exit; A fixing frame installed at one side of the blast furnace to fix the lifting cylinder; Scattering prevention device for blast furnace outlet characterized in that it comprises a. In the blast furnace equipped with a tap hole to discharge the molten iron, A shielding cover for shielding to prevent scattering of the molten iron discharged to the outlet of the blast furnace; An elevating cylinder connected to both sides of the shielding cover by electric means, and elevating the shielding opening by elevating the shielding cover; A fixed frame installed at both sides of the exit of the blast furnace to fix the two lifting cylinders; Scattering prevention device for blast furnace outlet characterized in that it comprises a. The method according to claim 1 or 2, The transmission means, A lifter connected to lift and lower the shield cover; One side is connected to elevate the lifter by the rotation and the other side is connected to the elevating cylinder to be rotated by the elevating operation, the rotation shaft installed in the fixed frame; Scattering prevention device for blast furnace outlet characterized in that it comprises a The method according to claim 3, The transmission means, A drive sprocket provided to rotate integrally with the rotary shaft; A driven sprocket provided in the fixed frame to transfer the driving force of the driving sprocket, It includes a connection chain for connecting the driven sprocket and the drive sprocket, The cylinder rod of the elevating cylinder is a scattering prevention device for blast furnace exit, characterized in that connected to the connection chain. The method according to claim 4, The transmission means, A slider connected to the elevating cylinder and the connecting chain to drive the connecting chain according to the operation of the cylinder rod, Scattering prevention device for blast furnace exit characterized in that it further comprises a first guide rail installed in the fixed frame to guide the vertical sliding of the slider. The method according to claim 5, Scattering prevention device for blast furnace opening, characterized in that the upper and lower portions of the slider is provided with a first flow preventing roller to slide along the first guide rail of the fixed frame to prevent the front and rear flow of the slider. The method according to claim 4, The rotating shaft is provided with an electric sprocket so that the driving force of the drive sprocket is transmitted, One end of the electric chain connected to the electric sprocket is connected to the lifter and the other end is connected to the weight balance so as to adjust the horizontal balance. The method of claim 7, On both sides of the lifter is provided with a second flow preventing roller, The fixed frame has a second guide rail to prevent the drift of the lifter by guiding the vertical sliding of the second flow preventing roller to prevent the blast furnace opening scattering device. The method according to claim 3, The shielding cover is a scattering prevention device for blast furnace exit characterized in that the hook bar is provided to be detachably coupled to the hook groove provided at the tip of the lifter. The method according to claim 2, The transmission means, A lifter connected to lift and lower the shielding cover; One side is connected to elevate the lifter by rotation and the other side is connected to the elevating cylinder rotating shafts respectively installed on both sides of the fixed frame, First interlocking sprockets respectively provided on both side rotation shafts; Second interlocking sprockets provided on both side fixed frames so as to transfer the driving force of the first interlocking sprocket, Interlocking chains connecting the first and second interlocking sprockets on both sides, A balance joint connected to the second interlocking sprockets on both sides to adjust a rotational balance according to driving force transmission; Scattering prevention device for blast furnace outlet characterized in that it comprises a.

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