KR100775246B1 - An apparatus for centering drop sleeve of charging car - Google Patents

Abstract

A centering device is provided for adjusting the center between a drop sleeve installed in a charring car for charging coal in a coke oven and a carbonization chamber charging.

The drop sleeve centering device 1 is provided in the outer circumference of the drop sleeve 20, a plurality of sensor members installed in the drop sleeve 20 in accordance with the thermal deformation of the charging frame 12 ( Frame level sensing means 40 for activating 42; And sleeve support means 60 is installed to enable the rotation of the sleeve 20 in the lower end of the drop sleeve 20; And an actuating arm 82 installed at both ends of the lead lifting machine 20 to move back and forth to both sides, and the guide rod 22 installed at the drop sleeve 20 is quenched and dropped according to the operation of the sensor member 42. The sleeve 20 and the sleeve rotating means for adjusting the centering of the frame 12; 80 is configured.

Therefore, according to the present invention, it is to provide an excellent effect to prevent the contamination of the working environment by preventing dust and flame scattering in the carbonization chamber due to the gap caused by the center defect between the drop sleeve and the charging opening. .

Coke oven, carbonization chamber, carbonization chamber entrance, drop sleeve, sleeve centering device

Description

      Drop sleeve centering device of coke oven charging vehicle {AN APPARATUS FOR CENTERING DROP SLEEVE OF CHARGING CAR}             

1 is a schematic diagram showing a dust generation state generated when a lead lifting device for charging coal in a coke oven and a charging center defect of a drop sleeve of a charging vehicle in the related art

Figure 2 is a block diagram showing the overall configuration of the drop sleeve centering device for coke oven charging vehicle according to the present invention

Figure 3 is a schematic perspective view showing the level detection means and the support means of the lower side of the drop sleeve centering device of the coke oven charging vehicle of the present invention

Figure 4 is a plan view showing a sleeve rotating means in the drop sleeve centering device of the present invention coke oven charging vehicle

Figure 5 is a schematic diagram showing the overall operating state of the drop sleeve centering device of the present inventors coke oven charging vehicle

Explanation of symbols on the main parts of the drawings

1 .... drop sleeve centering device 10 .... charging

12 .... Frame 14 .... Lead

20 .... Charging drop sleeve 22 .... Guide rod                 

30 .... Lead Lifter 32 .... Moving Arm

34 .... Magnetic block 40 .... Frame level detection means

42 .. sensor element 44 .. fixed plate

46 .... Housing 48 .... Spring

50 .... moving rod 60 .... supporting means

62 .... support ring 64 .... guide ring

66 .... support roller 80 .... sleeve rotation means

82 .... working arm 82a .... 1st working arm

82b .... 2nd working arm 84 .... Cylinder

86 .... rotating piece 88 ....

90 .... Turnblock

The present invention relates to a drop sleeve (DROP SLEEVE) installed in a charging car (CHARGING CAR) for charging coal in the coke oven (COKE OVEN), in particular, the carbon supplied to the charging car through the hopper carbonization of the coke oven When the drop sleeve which is installed in the charging car and descends to the carbonization chamber entrance when charging indoors is not exactly centered on the carbonization chamber entrance frame part, the lead lifting device for moving the lid blocking the entrance frame is By rotating the sleeve as an installed rotation means to easily adjust the carbonization chamber charging center of the charging vehicle drop sleeve, it is possible to prevent dust and flame scattering in the carbonization chamber due to the gap generated by the center defect between the drop sleeve and the charging opening. A drop sleeve centering device for a coke oven charging vehicle is provided.

In general, coal used as raw materials for blast furnaces in steel mills is carbonized in coke ovens. The coals charged into the carbonization chambers of coke ovens are charged to charging cars through bin hoppers and webbing hoppers installed in coal mining rooms. Then, the charging car loads the coal into the carbonization chamber of the coke oven through the charging opening of the carbonization chamber. The coal working in the oven carbonization chamber using the conventional charging vehicle is shown in FIG.

That is, as shown in Fig. 1, when a certain amount of coal is mined from the WEIGHING HOPPER in the hopper COAL 110 of the charging vehicle, the feeder 120 and the hopper charging pipe 122 of the lower side Through the coal is to charge the coal into the carbonization chamber charge 140 through the drop sleeve 130 of the charging car.

At this time, the drop sleeve 130 has a cylinder 134 is connected to the sleeve ring 132 fixed to the outside to perform the entrance opening operation of the drop sleeve 130, and also the carbonization chamber charging hole ( The lid 142 which seals the lid 142 is normally covered, and the lid 142 of the charging port 140 is a lead lifting device 150 disposed to one side during coal mining through a charging vehicle. After the separation from the charging hole 140, the charging vehicle drop sleeve 130 is lowered as a cylinder 134 to closely enter the charging hole 140, and then coal mining operation is performed.

In addition, the lead lifting device 150 is a working arm (cylinder 158a) installed on the movable arm 156 which is moved back and forth and left and right by the horizontal movable cylinder 152 and the vertical movable cylinder 154 vertically connected thereto. 158b rotates the magnetic block 158 provided so as to rotate as a bolt at the tip of the movable arm 156, and the lead 142 is taken out as the magnetic block 158.

However, in the coaling operation of the carbonization chamber through the drop sleeve 130 of the charging vehicle as described above, the driver operates the equipment in the cab due to the high temperature by the carbonization chamber, as shown in FIG. When the frame 144 of the 140 is deformed by heat, that is, when the horizontal level is not kept constant, the lower end 130a of the drop sleeve 130 is the frame 142 of the charging hole 140. A poor centering condition is generated, which is not exactly matched with the cross-section, and a gap G is generated between the discharge end 130a of the drop rib 130 and the frame 144.

Therefore, a problem that considerably pollutes the working environment outside the carbonization chamber while scattering harmful gas or coal dust at high pressure generated during charging into the coaling chamber into the gap G.

Moreover, such fugitive fugitive gases are flammable, which includes a flame and an explosion hazard, which may cause serious safety accidents.

However, in the related art, when a center defect occurs between the drop sleeve 130 and the frame 144 of the carbonization chamber insert 140 as described above, the harmful gas and the flame are ejected through the gap G therebetween. In order to block, the operator directly performs the centering operation of the dispensing end 130a of the drop sleeve 130 and the frame 144 through manual work, but usually performs about 80 times of coal charging work in the carbonization chamber. The centering work between the dispensing end 130a of the drop sleeve 130 and the frame 144 of the carbonization chamber fitting 140 through such manual operation is considerably delayed, thereby reducing the overall productivity of the coke process. will be.

Therefore, if the drop sleeve is rotated by using the lead lifter to perform the centering adjustment work between the drop sleeve and the charging port, there is no need for a separate device installation space for easy installation and release of harmful gas and dust. It would be desirable to be able to block effectively.

The present invention is to improve the various problems as described above, an object of the present invention is to provide a gap caused by poor centering between the drop sleeve and the carbon charging chamber when charging the coal in the oven carbonization chamber through the drop sleeve of the charging car. It is to provide a drop sleeve centering device for a coke oven charging vehicle to effectively prevent the emission of harmful gas and coal dust.

In addition, another object of the present invention, as well as to quickly carry out the charge centering operation of the charging drop drop sleeve to prevent the release of harmful gas and dust from the charging in the carbonization chamber coal charging, the separation of the charging inlet Since the centering device is installed in the lead lifting device, there is no need for a separate installation space to provide a drop sleeve centering device for a coke oven charging vehicle that is easy to operate.

As a technical configuration for achieving the above object, the present invention, a charging drop for charging the coal in the carbonization chamber charging opening of the coke oven, and a lid for lifting the lid for opening and closing the frame installed in the charging opening In the coke oven coal charging equipment comprising a lifting device, a plurality of circumference is installed on the outer periphery of the drop sleeve, the frame level detection means for operating the sensor member installed in the drop sleeve in accordance with the thermal deformation of the charging frame; and,

Sleeve support means installed at a lower end of the drop sleeve to enable rotation of the sleeve; And,

Coke oven charging comprising a; operating arm is installed to move back and forth on both sides of the lead lifting device, the sleeve rotating means for adjusting the centering of the drop sleeve and the frame by quenching the guide rod installed in the drop sleeve in accordance with the operation of the sensor member; By providing a drop sleeve centering device for a car.

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

Figure 2 is a block diagram showing the overall configuration of the drop sleeve centering device of the coke oven charging vehicle according to the present invention, Figure 3 is a perspective view showing the level sensing means and the support support of the lower side of the centering device of the present invention, Figure 4 is a plan view showing the sleeve rotating means of the centering device, Figure 5 is a schematic diagram showing the overall operating state of the present centering device.

In FIG. 2, the entire configuration of the drop sleeve centering device 1 of the coke oven charging vehicle according to the present invention is illustrated, and the charge drop centering apparatus 1 of the present invention as described above is largely supported by the frame level detecting means 40. The means 60 and the sleeve rotation means 80, which are described in more detail each of the components 40, 60, 80 as follows.

First, as shown in FIG. 2 and FIG. 5, the charging drop drop sleeve 20 according to the present invention is installed on the charging car and the upper side of the charging opening 10 of the carbonization chamber 10a by a cylinder 21 connected thereto. Is moved up and down in this case, the charging hole 10 is installed in the refractory 10 side of the carbonization chamber (10a) is installed in the refractory and the inside is a rectangular block with an opening (12a), the opening (12a) portion is inward It is formed to be inclined.

In the frame opening 12a, the lid 14 is closed during the operation of the coal chamber, and when the coal is charged, the lid 14 is separated and moved by the lead lifting machine 30 shown in FIG. The lead lifting device 30 is performed as a magnetic block 34 installed on the bottom side of the end of the moving arm 32 which is moved by the horizontal and vertical moving cylinders 32a and 32b, which will be described later. 34 is rotatably installed for mounting the frame 12 of the lid 14, the connecting arm 21a horizontally fixed to the rod of the elevating cylinder 21 is installed on the outer peripheral surface of the sleeve 20 It is connected to move along the guide rail 21b.

Next, FIGS. 2 and 3 show the frame level detecting means 40 of the apparatus 1 of the present invention, and the frame level detecting means 40 of the present invention is the carbonization chamber 10a and the charging slot 10. Deformation of the frame is detected because the flame or coal dust is released by the gap generated when the drop sleeve 20 is not accurately seated in the charging hole when the frame 12 installed in the frame is deformed due to heat. To do that.

That is, as shown in Figure 3, the frame level detection means 40, a plurality of the outer periphery of the drop sleeve 20 is installed along the circumference, according to the thermal deformation of the charging frame 12 It is configured to operate the sensor member 42 installed in the drop sleeve 20.

By the way, the frame level detecting means 40 of the present invention, as shown in Figure 3, can be divided into the housing 46, the moving rod 50 and the moving roller 52, the housing 46 Is formed as a hollow housing 46 that is vertically fixed between the fixing plate 44 installed on the upper, lower side on the outer circumferential surface of the drop sleeve 20 which is raised and lowered as the cylinder 21.

In addition, the movable ball 50 is elastically supported by the spring 48 to the outside as a locking jaw (48a) formed in the center of the housing 46, the movable rod 50 passing through the fixing plate 44 The upper and lower ends 50a and 50b are installed to move up and down, and the moving roller 52 is installed on the lower end portion 50b of the movable rod and is provided on the upper surface of the frame 12 when the drop sleeve 20 descends. It comes in close contact.

On the other hand, as shown in Figure 3, since the movable rod 50 is installed at an interval of 90 degrees on the outer side of the drop sleeve 20, the movable roller 52 installed in the lower end of the movable rod 50 is the frame The four moving rods 50 respectively move up and down individually according to the level difference while contacting the four points of the upper surface of the 12 when the sleeve is lowered.

Next, as shown in Figure 3, the sensor member 42 is composed of a limit switch mounted on the upper side of the moving rod 52 of the frame level detecting means 40 on the outer peripheral surface of the drop sleeve 20 When the movable rod 52 is raised, it is operated by being quenched with its upper end 50a. At this time, the heat-resistant cover 42a for the thermal cutoff is covered on the outside of the limit switch 42 and fixed to the sleeve 20. .

Next, FIGS. 2 and 3 show the support means 60 of the device 1 of the present invention, wherein the support means 60 of the present invention has the sleeve 20 at the lower end of the drop sleeve 20. ) Is installed to allow the rotation of

That is, as shown in Figure 3, the sleeve support means 60 of the present invention is configured as a support ring 62, guide ring 64 and support roller 66 again, the support ring 62 is The lower end of the drop sleeve 20 is fixed to the upper portion of the dispensing end 20a, and a plurality of fixing grooves 62a are formed along the circumference thereof.

In addition, the guide ring 64 of the support end 60 is fastened to the fixing groove 62a of the support ring 62, and a plurality of fixing bolts 64a are fixed to the nut, and a plurality of droppings are installed thereon. The lower dispensing end 20a of the sleeve 20 passes.

In addition, the support roller 66 of the support means 60 is installed on the lower side of the guide ring 64 to enable the rotation of the guide ring 64 integrally with the sleeve 20 of the sleeve 20 When the dispensing end 20a is inserted into the opening 12a of the charging inlet frame 12, the bending is possible. As shown in FIG. 3, the support roller 66 is a universal joint box 66a. Since it is provided below the guide ring 64 via the above, the bending operation is possible.

Next, Figs. 2 and 4 show the sleeve rotating means 80 of the device 1 of the present invention, wherein the rotating means 80 of the present invention moves forward and backward to both sides of the lead lifting machine 20. With the operating arm 82 installed so as to adjust the centering of the drop sleeve 20 and the frame 12 by locating the guide rod 22 provided in the drop sleeve 20 in accordance with the operation of the sensor member 42. Consists of.

That is, as shown in Figures 2 and 4, the operating arm 82 of the sleeve rotating means 80 is composed of the first and second operating arms 82 again, such operating arms are the entire length Is connected to the turnbuckle 90 to precisely adjust it.

And, as shown in Figure 4, the first operating arm (82a) is connected to the cylinder 84 installed on the movable arm 32 of the lead lifting machine 30, the rotating piece to rotate the pivot (86a) One end is connected to both sides of the 86, and is connected to the magnetic block 34 provided at the front end of the movable arm 32.

In addition, the second operation arm (82b) is a U-shaped wrench piece 88 to quench the guide rod 22 installed vertically to the fixing plate 44 of the drop sleeve 20 is fixed to the connection, As shown in the main view, the second operation arm 82b is connected to the turnbuckle 90 by a connecting arm 83c having a spring 83b elastically supported in the box 83a, and screwing the quench piece ( One end portion 88 is inserted into and supported in the box 83a, which absorbs the impact when the quench piece 88 collides with the guide rod 22 vertically fixed to the fixing piece 44 installed in the drop sleeve 20. It is to.

On the other hand, the first operating arm (82a) connected to both ends of the rotating piece 86 is connected via the vertical bar 33 by the axial height of the movable arm 32 to be connected to the side of the magnetic block 34 It consists of the configuration.

Referring to the operation and effects of the present invention made in the above configuration in more detail as follows.

As shown in FIG. 2 and FIG. 5, in order to charge coal into the coke oven carbonization chamber 10a, first, a lid lifting lead 14 having abolished the frame 12 installed in the carbonization chamber charging opening 10 is lead-lifted. The magnetic block is installed at the bottom end of the moving arm 32 connected to the lower side of the moving beam by activating the horizontal and vertical moving cylinders 32a and 32b of the lead lifting machine 30. The lead 14 is separated and moved from the frame 12 at 34.

Next, when the charging vehicle is moved so that the drop sleeve 20 is positioned above the opening 12a of the frame 12, the drop sleeve 20 is lowered as the cylinder 21, and the frame 12 is opened to the heat. 5, the contact height of the moving roller 52 of the frame level detecting means 40 installed in the sleeve 20 is different depending on the frame deformation portion.

Therefore, the four moving rollers 52 of the sensing means 40 installed at intervals of 90 degrees on the outer circumferential surface of the sleeve 20 have a top portion 50a of the moving rod 50 at a portion where the frame is deformed and concave than the normal level. The moving rod 50 on the side of the moving roller which rises low and contacts the frame 12 of the other part goes up higher, so that the upper limit 50a of the moving rod 50 is in contact with the limit switch which is a sensor member operated. 42, only the movable rod 50 in which the lower moving roller 52 is installed on the frame 12 of the deformed portion has a different vertical movement amount, so that the limit switch 42 of one of the four limit switches 40 is not operated. will be.

As a result, when the heat deformation of the frame 12 is generated, the level state of the frame 12 is sensed by the moving rod 50, which is changed by the deformation width when the drop sleeve 20 descends, which is the next sleeve rotation operation. It is to make the centering adjustment operation through.

That is, as shown in FIGS. 2, 4, and 5, when the sleeve 20 is continuously lowered, the guide ring 64 is fastened as a bolt and a nut to the support ring 62 installed on the lower side of the sleeve 20. Support roller 66 is supported on the opening 12a side of the frame 12 to enable rotation of the sleeve 20 during the centering adjustment operation of the sleeve 20 described below, which is illustrated in FIG. As described above, the sleeve 20 moves along the guide rail 21b installed in the sleeve 20 so that the sleeve 20 is connected to the lower end of the cylinder 21 to enable the sleeve 20 to rotate. It is possibly connected to enable rotation of the sleeve 20.

Next, as shown in FIGS. 4 and 5, when the sleeve 20 is not seated correctly in the frame opening 12a without a gap, a cylinder installed on the movable arm 32 of the lead lifting machine 30 ( When the 84 is moved forward and backward, the rotary piece 86 connected thereto and pivoted 86a on the movable arm 32 rotates, and is connected to the vertical arm 33 to both sides of the rotary piece 86. The arm 82 is moved back and forth in the state in which the center portion thereof is connected to and supported by the magnetic block 34, and eventually the U-shaped quench piece 88 provided at the end of the working arm 82 is the sleeve fixing piece 44. The sleeve 20 is repeatedly rotated about 45 degrees while the guide rods 22 facing each other are guided among the guide rods 22 installed perpendicular to the guide rods 22.

Accordingly, as shown in FIGS. 3 to 5, the sleeve 20 is rotated while the connecting arm 21a is connected to the guide rail 21b on the upper side while being supported by the lower supporting means 60. While it is seated in the opening 12a side of the frame 12 by the flow of the rotation without gaps, the carbonization chamber charging of the coal is then carried out through a charging pipe connected on the sleeve 20.

On the other hand, as shown in Figure 3, when the sleeve 20 is seated in the frame opening 12a, the support roller 66 installed below the guide ring 64 of the support means 60 is a universal joint box The sleeve dispensing end 20a can be in close contact with the inner inclined surface of the frame opening 12a while being folded by the 66a.

And, as shown in Figure 4, the operating arm 82 is the first and second operating arms (82a, 82b) is connected to the turnbuckle 90, it is easy to adjust the overall length through this, operating arm The connecting rods 83c of which the springs 83b are elastically supported in the box 83a are formed so as to accurately perform the quenching of the guide bar 44 of the 82, and the turnbuckle 90 Since the screw piece 88 is in contact with the guide rod 22 that is vertically fixed to the sleeve fixing piece 44 in a state where the shock is absorbed.

Next, when the coal loading through the sleeve 20 is completed, the sleeve 20 is raised, the moving arm 32 of the lifting machine 30 is activated to lead 14 attached to the magnetic block 34 ) Is seated in the frame opening 12a to seal it. The magnetic block 34 is connected to a first operating arm 82a, which is operated back and forth during the operation of the cylinder 84, and flows left and right. The seating of frame 14 should be done without any gaps.

Thus, according to the drop sleeve centering apparatus of the coke oven charging vehicle of the present invention, when the coal charging of the oven carbonization chamber through the drop sleeve of the charging vehicle, the gap caused by the poor centering between the drop sleeve and the carbonization chamber charging zone caused by harmful gas and It effectively prevents coal dust emissions.

Therefore, the centering device of the lead lifting device for separating the inlet of the lead as well as quickly performing the charge centering operation of the charge drop drop sleeve to prevent the release of harmful gas and dust from the charge when charging carbon in the carbonization chamber. Because it installs, there is no need for a separate installation space is to provide an excellent effect to facilitate the operation of the facility.

While the invention has been shown and described with respect to specific embodiments thereof, it will be apparent to those skilled in the art that various changes and modifications can be made without departing from the spirit or scope of the invention as set forth in the claims below. I would like to know that those who have knowledge of this can easily know.

Claims (5)

Lead lifting for lifting the charging vehicle drop sleeve 20 for charging coal in the carbonization chamber charging opening 10 of the coke oven and the lid 14 for opening and closing the frame 12 installed in the charging opening 10. In the coke oven coal charging facility comprising a machine (30), Frame level sensing means installed in the plurality of circumference to the outside of the drop sleeve 20, the sensor member 42 installed in the drop sleeve 20 in accordance with the thermal deformation of the charging inlet frame 12 ( 40); and, Sleeve support means (60) installed at the lower end of the drop sleeve (20) to enable rotation of the sleeve (20); And, The lead lifting machine 20 is provided with an operation arm 82 installed to move back and forth on both sides, and according to the operation of the sensor member 42, the guide rod 22 installed in the drop sleeve 20 is quenched to provide a drop sleeve ( 20 and the sleeve rotating means for adjusting the centering of the frame 12; drop sleeve centering device of the coke oven charging vehicle, characterized in that consisting of According to claim 1, wherein the frame level detecting means 40, A housing fixed vertically between the fixing plate 44 installed on the outer circumferential surface of the drop sleeve 20 having a guide rail 21b to which the connecting arm 21a of the elevating cylinder 21 is connected so as to move. (46); and. A moving rod 50 installed as an upper and lower end portions 50a and 50b to move up and down through the housing 46 and the fixing plate 44 as a spring 48 elastically supported inside the housing 46; And, Drop sleeve centering device of the coke oven charging vehicle, characterized in that consisting of; moving roller 52 is installed on the lower side of the movable rod 50 and in close contact with the upper surface of the frame 12 when the sleeve is lowered According to claim 1, wherein the sensor member 42 is composed of a limit switch which is mounted on the outer circumferential surface of the drop sleeve 20 above the moving rod 52 of the frame level sensing means 40 of the moving rod 52 Configured to operate the quench on rise Drop sleeve centering device of the coke oven charging vehicle, characterized in that the outer of the limit switch 42 is covered with a heat-resistant cover 42a for the thermal cut-off is fixed to the sleeve 20 The method of claim 1, wherein the sleeve support means 60, A support ring 62 fixed to the lower end of the drop sleeve 20 and having a plurality of fixing grooves 62a formed along a circumference thereof; A plurality of fixing bolts 64a fixed to the fixing grooves 62a of the guide ring 62 are installed at an upper portion thereof, and a guide ring 64 into which the lower dispensing end 20a of the drop sleeve 20 is inserted. ; And, Drop-down sleeve of the coke oven charging vehicle, characterized in that consisting of; the support ring 66 is provided below the guide ring 64 to enable the rotation of the guide ring 64 integrally with the sleeve 20; Centering device According to claim 1, wherein the operating arm 82 of the sleeve rotating means 80, One end is connected to both sides of the rotating piece 86 which is connected to the cylinder 84 installed on the movable arm 32 of the lead lifting machine 30 and pivots 86a, and the leading end of the movable arm 32 A first actuating arm 82a connected to the magnetic block 34 installed on the first arm; And, And a second working arm 82b to which the U-shaped toothpiece 88 for fixing the guide rod 22 vertically installed on the fixing plate 44 of the drop sleeve 20 is connected and fixed. Drop sleeve centering device for a coke oven charging vehicle, characterized in that the first and second working arms 82a and 82b are connected to a turnbuckle 90 to enable length adjustment of the arms.

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