KR100812700B1 - Dust Scattering Prevention Apparatus for Weight Hopper - Google Patents

Abstract

In the apparatus for preventing the scattering of dust when charging the coal into the way hopper, at least Colbin bunker hopper 110, auxiliary chute 33, auxiliary hopper 50, the way hopper 120 and the motor control panel,

The colvin bunker hopper 110 is configured in the form of a hollow container, the bottom portion is configured to be connected to the outlet through the opening and closing means, the lower outer periphery is formed in a cylindrical shape, is installed in the auxiliary chute base 20 ,

The auxiliary chute 33 is formed in a tubular shape as a whole, and has a rotation driving means for allowing an upper portion thereof to rotate in place while being fitted snugly at the lower end of the colvin bunker hopper 110. It is installed in the auxiliary chute base 20,

The auxiliary hopper 50 is formed in a tubular shape as a whole, and its inner circumference is fitted to the outer circumference of the auxiliary chute 33 and its outer circumference or outer wall is fitted to the inner circumference or the inner wall of the hopper 120 up and down. It is provided with a lift drive means for moving, the bottom portion is composed of a lower gate 60, the lift drive means is installed in the auxiliary hopper base 40,

The way hopper 120 is formed in a tubular shape as a whole, and the auxiliary hopper 50 is formed and fixed so that the inner circumference or inner wall thereof is fitted to the outer circumference or outer wall of the auxiliary hopper 50.                 

According to this, the sealing structure is realized by the auxiliary chute 33, and the free fall distance can be reduced by the lowering operation of the auxiliary hopper 50, so that fine dust or powdered coal can be prevented from scattering around the hopper. Therefore, it is possible to prevent environmental pollution and to prevent deviation in basis weight.

Colvin, Wayhopper, Coke Oven, Dust

Description

Dust Scattering Prevention Apparatus for Weight Hopper

1 is an explanatory diagram illustrating a dust scattering phenomenon when using a conventional hopper;

Figure 2 is a perspective view of the auxiliary hopper of the device of the present invention in an elevated state,

Figure 3 is a perspective view of the auxiliary hopper of the device of the present invention in a lowered state,

4 is a plan view of a motor, a reducer, a driving unit and an auxiliary hopper of the present invention;

5 is a configuration diagram of the connection of the motor control panel of the present invention;

6 is a flow chart illustrating the operation of the present invention.

<Description of Symbols for Major Parts of Drawings>

10: upper gate 11: gate cylinder

11a: cylinder through hole 12: guide rail

20: auxiliary chute base 21: rack

22: primary pinion 22a, 23a: pinion shaft

23: 2nd pinion 24: auxiliary chute gear

24a: auxiliary chute gear fixing hole 25: auxiliary chute support roller

26: guide roller 27, 30: wire

28, 29, 31: sieve roller 32: weight                 

33: auxiliary chute 33a: auxiliary chute hanging jaw

34: auxiliary hopper locking hole 35: magnet lock

40: auxiliary hopper base 41: motor

41a: Motor magnet brake 42: Reducer

42a, 42b: reducer magnet brake 43: wire drum

44: drive shaft 45, 46, 47: bearing

48: pinion 49: auxiliary hopper rack

50: auxiliary hopper 60: lower gate

61: lower gate bar 62: gate link

62b: Pin 63: Bar Jam Jaw

64: cushion spring 100: gate

110: Colvin Bunker Hopper 120: Way Hopper

The present invention relates to a device for preventing dust from scattering to the outside of the coal mining equipment hopper in the coal mining, and more particularly to an apparatus for preventing or minimizing the generation of dust during coal mining by sealing while minimizing the drop of coal emissions. It is about.

In general, the coal mining facility of the coke process is a facility for supplying coal into an oven furnace where coke extrusion is completed, as shown in FIG. 1, and includes a hopper 120 capable of loading a predetermined amount of basis weight. .

Conventionally, when coal mining is carried out from the colvin bunker hopper 110 to the way hopper 120 during the coal charging operation, the drop distance of coal discharge is very large between the gate 100 and the bottom of the way hopper 120 (about 6 m). Degree), when the coal is discharged into the empty space of the hopper 120, the coal dust or fine dust contained in the coal due to the friction with the air to the upper hopper 120 due to the change in air pressure As it is pushed up, there is a problem that the dust is scattered around the outside of the hopper.

Therefore, as it was a factor that hindered the working environment, access to the coal mining room was possible only by wearing a mask, and there was a great concern of industrial accidents such as pneumoconiosis, and the working environment, equipment, and equipment were contaminated by dust. Problems causing business problems were occurring.

In addition, there is a problem that the cost of the raw material due to the scattered coal at the same time as the basis weight deviation error occurs because of the cost increase.

The present invention has been made in order to solve the above problems, a device that can prevent dust scattering by drastically reducing the free fall distance when charging the coal, and limiting the movement path of coal, coal, and dust in a certain sealed space. It is to provide.

In order to achieve the above technical problem, the apparatus of the present invention, as shown in the plan of FIG. 2 and FIG. 3 and the plan view of FIG. 4, the colvin bunker hopper 110, the auxiliary chute 33, the auxiliary hopper 50, Wayhopper 120 and the motor control panel as shown in Figure 5,

The colvin bunker hopper 110 is configured in the form of a hollow container so as to discharge the coal introduced into the upper inlet to the lower outlet, the bottom portion is configured to be connected to the outlet through the opening and closing means, the shape of the lower outer circumference is formed in a cylindrical shape Is installed in the auxiliary chute base 20,

The auxiliary chute 33 is formed in a tubular shape as a whole, and has a rotation driving means for allowing an upper portion thereof to rotate in place while being fitted snugly at the lower end of the colvin bunker hopper 110. It is installed in the auxiliary chute base 20,

The auxiliary hopper 50 is formed in a tubular shape as a whole, and its inner circumference is fitted to the outer circumference of the auxiliary chute 33 and its outer circumference or outer wall is fitted to the inner circumference or the inner wall of the hopper 120 up and down. It is provided with a lift drive means for moving, the bottom portion is composed of a lower gate 60, the lift drive means is installed in the auxiliary hopper base 40,

The way hopper 120 is formed in a tubular shape as a whole, the inner circumference or inner wall of the auxiliary hopper 50 is fitted to the outer circumference or the outer wall of the auxiliary hopper 50 is formed and fixed so as to move up and down is fixed. .

Hereinafter, the configuration and the embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2 and 3, the apparatus of the present invention includes a colvin bunker hopper 110, an auxiliary chute 33, an auxiliary hopper 50, and a way hopper 120. FIG. Comparing the conventional apparatus with the apparatus of the present invention, the lower outline of the colvin bunker hopper 110 is changed into a cylindrical shape, and an auxiliary chute (for the implementation of a sealed structure to prevent dust scattering and a rotating structure to prevent sticking coal generation) 33) and the auxiliary hopper 50 for the lifting structure to reduce the free fall distance.

The colvin bunker hopper 110 is configured in the form of a hollow container to discharge the coal introduced into the upper inlet to the lower outlet as in the conventional apparatus. In addition, the bottom portion is provided with opening and closing means, it is configured to open or close the connection to the outlet through it.

However, unlike the conventional apparatus, the opening and closing means, unlike the gate 100 of FIG. 1, is configured to not operate beyond the bottom width of the colvin bunker hopper 110, and the shape of the lower outer circumference is formed in a cylindrical shape. Is that there is. This is to ensure a smooth rotation operation of the auxiliary chute 33 to be connected to the bottom of the colvin bunker hopper (110).

In the embodiment of the present invention, as shown in Figure 2 and 3, the Colvin bunker hopper 110 is fixed to the auxiliary chute base 20, the opening and closing means is installed on the auxiliary chute base 20 It is composed of a gate 10, a gate cylinder 11 and a guide rail 12, the upper gate 10 is inserted in close contact with the colvin bunker hopper 110, the forward and backward movement of the gate cylinder 11 By operation, the upper gate 10 is configured to move forward and backward along the guide rail 12. Accordingly, when the upper gate 10 is fully retracted, the colvin bunker hopper 110 is opened to be completely connected to the auxiliary chute 33 and the auxiliary hopper 50 at the lower portion thereof, and when the upper gate 10 is fully advanced. The colvin bunker hopper 110 is closed and completely disconnected from the auxiliary chute 33 and the auxiliary hopper 50 thereunder.

In the above embodiment, the opening and closing means is described in the form of a sliding door, but may be in the form of a sliding door like the structure of the lower gate 60 to be described later. In addition, although the gate cylinder 11 is illustrated as the power of the opening and closing means, the present invention is not limited thereto, and the gate cylinder 11 may be implemented by a motor driving and driving by a rack and pinion combination.

An auxiliary chute 33 for implementing a sealed structure is installed under the colvin bunker hopper 110.

The auxiliary chute 33 is formed in a tubular shape as a whole. This is for sealing while rotating. Therefore, the upper part is installed in a state fitted snugly to the lower end of the colvin bunker hopper 110, and is provided with a rotation drive means to rotate in place in that state. The rotation drive means is fixed to the auxiliary chute base 20. This rotational operation is to prevent clogging due to the close coal inside the auxiliary hopper (50).

The rotation drive means may be configured by a combination of the rack and pinion horizontally installed as shown in Figures 2 and 3 showing an embodiment.

That is, the reduction gear 42 is connected to the shaft of the motor 41, and it is comprised so that two shafts may be rotated by the same rotation ratio by the gear coupling inside the reduction gear 42. FIG. And the wire drum 43 is inserted and fixed to one drive shaft 44 of the reducer 42, the wire 27 is connected and wound to this, the angled portion in the direction in which the wire 27 is bent The sieve roller 28 and the sieve roller 29 support, and these sieve roller 28 and the sieve roller 29 are being fixed to the auxiliary chute base 20. As shown in FIG. And the rack 21 is connected to the wire 27 is installed so as to move forward and backward by the four guide rollers 26, the hook of the rear end of the rack 21 is the weight 32 and the wire ( 30) to form an angle by the guiding of the sieve roller 31.

In addition, the primary pinion 22 engaged with the rack 21 converts the forward and backward motion of the rack 21 into a rotary motion, and the secondary pinion 23 increases the rotational force to solve the load received during rotation. It serves, and the auxiliary chute gear 24 is engaged with it serves to rotate the auxiliary chute (33). The load of the auxiliary chute 33 is supported by a plurality of auxiliary chute support roller 25 smoothly rotates while supporting the lower surface of the auxiliary chute gear 24.

At this time, when the wire drum 43 fixed to the drive shaft 44 is rotated via the reduction gear 42 by the drive of the motor 41, the wire 21 is wound or unrolled, and thus the rack 21 is linearly moved. When the auxiliary chute gear 24 engaged with the rack 21 by the linear motion of the rack 21 rotates, the auxiliary chute 33 on which the auxiliary chute gear 24 is fixed is rotated. .

In the above embodiment, the power is transmitted between the rack 21 and the auxiliary chute gear 24 via the primary pinion 22 and the secondary pinion 23, but the configuration or number varies depending on the deceleration rate. It's configurable and not essential.

In addition, the linear force of the rack 21 is applied to the attraction force by the driving force of the motor 41 on one side, and the attraction force by the weight 32 on the other side, instead of the motor is connected, for example The pinion which is present may be engaged with the motor 41, thereby allowing the motor 41 to linearly move. Then, the pinion rotates by the driving of the motor, and the rotational motion is transmitted to the motor 41 to be a linear motion, and the linear motion is again transmitted to the auxiliary chute gear 24 to be the rotational motion.

However, the rotation drive means for the rotational movement of the auxiliary chute 33 is not limited to the rack and pinion structure described in the embodiment, for example, except for the configuration except for the auxiliary chute gear 24 of Figs. It is also possible to remove and, instead, install a gear that meshes with the auxiliary chute gear 24, and then install and drive a separate motor directly on the gear. At this time, the gear is rotated by the driving of the motor, the rotational force is transmitted to the auxiliary chute gear 24 may implement a rotational movement of the auxiliary chute 33.

On the other hand, the auxiliary hopper 50 is formed in a tubular shape as a whole. This is to ensure smooth rotation of the auxiliary chute 33 that rotates while contacting the inner circumference. The outer circumference or outer wall does not need to be cylindrical because the outer circumference or outer wall is to be matched according to the shape of the inner circumference or inner wall of the way hopper 120 fitted in contact with the outer circumference or outer wall.

And the inner circumference is fitted to the outer circumference of the auxiliary chute 33 and the outer circumference or outer wall is provided with a lifting and lowering drive means to move up and down while being fitted to the inner circumference or inner wall of the hopper 120. The elevating drive means is fixed to the auxiliary hopper base 40.

According to an embodiment, the elevating driving means may be configured by a combination of a rack and a pinion installed vertically as shown in FIGS. 2 and 3. At this time, when the pinion 48 fixed to the drive shaft 44 is rotated via the reduction gear 42 by the driving of the motor 41, the auxiliary hopper rack 49 engaged thereto by the rotational movement is thus linearly moved. As a result, the auxiliary hopper 50, to which the auxiliary hopper rack 49 is fixed, moves up and down. The drive shaft 44 is fitted with a bearing 45 for smooth rotation.

However, the elevating driving means for the elevating movement of the auxiliary hopper 50 is not limited to the above embodiment, and for example, instead of the pinion 48 and the auxiliary hopper rack 49 of FIGS. By installing a cylinder (not shown), the lifting and lowering motion of the auxiliary hopper 50 may be implemented by driving the cylinder.

Since the auxiliary hopper 50 is very heavy, there may be a risk of malfunction or drop due to impact in the process of loading coal in a lifted state. Therefore, according to the embodiment, a plurality of auxiliary hopper locking holes 34 are formed on the sidewall of the auxiliary hopper 50, and the same number of magnet locks 35 are formed in the auxiliary hopper base 40 as a fixture. After installation, the magnet lock 35 may be moved forward and backward by a driver not shown.

According to this configuration, when the magnet lock 35 is advanced, the auxiliary hopper locking hole 34 is inserted and the auxiliary hopper 50 is fixed so that the coal hopper does not fall even when the coal is loaded, and the auxiliary hopper 50 When raising and lowering, when the magnet lock 35 is reversed and removed from the auxiliary hopper locking hole 34, the auxiliary hopper 50 can be freely raised and lowered.

In addition, the brake device is a mechanical brake, in which the motor magnet brake 41a is mounted on the motor 41 or the reducer magnet brake 42a is mounted on the reducer 42 to assist in case of failure. Can be. That is, by installing the motor 41 to support the load received before the magnet lock 35 of the auxiliary hopper 50, and by installing the reduction gear 42 at both shaft drives, the lower load of the auxiliary hopper 50 is increased. It's supporting.

However, the mechanical or magnetic brake device is not an essential component, and the configuration for achieving this object may be any other form. For example, a structure may be considered in which a groove is formed on the outer circumference of the drive shaft 44 in only one direction, and then a stopping jaw that is caught therein may be fastened and relaxed, and the auxiliary hopper base when the auxiliary hopper 50 is fully raised. The brake force may be obtained by applying one or more electromagnets to the outside of the position corresponding to the height of 40 and the inside of the auxiliary hopper base 40 opposite thereto, and then applying or releasing a strong magnetic force. In addition, when a piston is used as the elevating drive device, a separate brake device may not be necessary since the piston may support the dropping impact of coal by the support force of the piston.

The bottom of the auxiliary hopper 50 is composed of a lower gate (60). This is because the auxiliary hopper 50 stores the coal once the lower gate 60 is closed and descends to the bottom of the way hopper 120, and then the lower gate 60 is opened to release coal. 120 is a configuration for delivering in a small free fall state.

However, in order to open and close the lower gate 60, according to an embodiment, the lower gate 60 is coupled to the lower portion of the auxiliary hopper 50 so as to be movable by a shaft, and the gate to the lower gate 60. In the state in which the link 62 is integrally fixed, the lower gate bar 61 is coupled to the gate link 62 by the pin 62b, so that the hole of the auxiliary hopper base 40 and the cushion spring provided thereon. Through 64). A bar locking jaw 63 is provided at the upper end of the lower gate bar 61.

In this structure, when the auxiliary hopper 50 is raised to the end, the upper end of the bar latching jaw 63 contacts the lower surface of the auxiliary chute base 20 to close the lower gate 60 by pressing a force downward. When the auxiliary hopper 50 descends to the end, the lower gate 60 is opened by applying a force upward while the lower surface of the bar locking jaw 63 contacts the upper surface of the cushion spring 64.

However, the structure for the opening and closing operation of the lower gate 60 is not limited to the structure described in the above embodiment, and may be implemented by an operation of an independent motor or cylinder not shown for opening and closing the lower gate 60. Alternatively, a brake means not shown may be provided to maintain the closed state of the lower gate 60.

In addition, the way hopper 120 is formed in a tubular shape as a whole. The configuration and role thereof do not differ significantly from the way hopper 120 in the conventional apparatus. However, the shape of the inner circumference or the inner wall of the auxiliary hopper 50 should be formed in such a size that it does not interfere with the auxiliary hopper 50 moving up and down while being fitted to the outer circumference or the outer wall of the auxiliary hopper 50. The way hopper 120 is configured to be fixed so as not to rotate or move up and down.

The driving of the motor and the cylinder constituting each of the driving means and the brake means is controlled by the motor control panel of FIG. 5.

Hereinafter, the operation of the apparatus of the present invention having the above configuration will be described in detail with reference to the flowchart of FIG. 6.

First, the auxiliary hopper 50 is fastened to the auxiliary hopper locking hole 34 by advancing the magnet lock 35 in order to prevent vibration or shock in the state in which the auxiliary hopper 50 is raised to the end. Then, the motor magnet brake 41a, the speed reducer magnet brake 42a, and the speed reducer magnet brake 42b are walked and placed in the brake state.                     

Thereafter, the upper gate 10 is opened by the opening and closing means. In the exemplary embodiment, the bar latching jaw 63 is pressed downward while contacting the bottom surface of the auxiliary chute base 20 so that the lower gate 60 is closed.

Thereafter, the upper gate 10 is opened by other opening and closing means. In the case of the embodiment, the gate cylinder 11 is reversed to open by reversing the upper gate 10 along the guide rail 12.

Then, the coal of the colvin bunker hopper 110 is mounted in the auxiliary hopper 50.

When all the coal is loaded, a maximum level signal is generated. Then, the upper gate 10 is closed using the opening and closing means. In the embodiment, the gate cylinder 11 is advanced to close the upper gate 10. Therefore, coal is no longer emitted.

Then, the magnet lock 35 is reversed to separate from the auxiliary hopper locking hole 34 to release the brake. Then, the motor magnet brake 41a, the reducer magnet brake 42a, and the reducer magnet brake 42b are released to release the brake state. Then, the auxiliary hopper 50 is in a state capable of raising and lowering.

Thereafter, the rotation drive means and the lift drive means are operated.

When the rotary drive means is activated, the auxiliary chute 33 starts to rotate in place. The rotation lasts at least until the auxiliary hopper 50 descends to the end. In the embodiment, when the driving direction of the motor 41 is a direction in which the wire 27 is wound, the weight of the weight 32 is measured while the wire 27 is wound on the wire drum 43 by the driving of the motor 41. The rack 21 is moved to the left side of the drawing, whereby the auxiliary chute gear 24 and the auxiliary chute 33 rotate clockwise when viewed from above via the primary pinion 22 and the secondary pinion 23. Done.

In addition, the auxiliary hopper 50 starts to descend without rotation when the lift drive means is operated. In this case, the falling distance may be set until the lower end of the auxiliary hopper 50 becomes a predetermined distance from the bottom of the way hopper 120 in consideration of opening of the lower gate 60. In the embodiment, while the drive shaft 44 is rotated by the driving of the motor 41, the pinion 48 installed thereon rotates, and the auxiliary hopper rack 49 and the auxiliary hopper 50 engaged thereto are lowered. .

At this time, since the upper portion of the auxiliary hopper 50 is closed by the auxiliary chute 33, generation of dust is prevented.

Thereafter, when the lowering is completed, as shown in FIG. 3, the motor 41 stops operation, and when the lower gate 60 is opened, coal starts to be charged into the hopper 120. At this time, since the fall distance is small, the occurrence of dust is prevented. When the lower gate 60 is opened by the lower gate bar 61 as in the embodiment, the lower gate bar 61 is further lowered while the bar latching jaw 63 is caught by the cushion spring 64 tip. The lower gate 60 opens when it cannot. At this time, the shock when the lower gate bar 61 is lowered by the cushioning action of the cushion spring 64 is absorbed.

In order to load the next amount of coal again while completing the charging operation of the coal, the auxiliary hopper 50 is raised while rotating the auxiliary chute 33. Then all of the remaining coal in the upper portion of the auxiliary hopper 50 is completed loading in the way hopper 120. At this time, since the auxiliary chute 33 is rotated, it is possible to prevent the separation and generation of the coal attached to the inside of the auxiliary hopper 50, and also serves as a guide of coal discharge. According to the embodiment, by rotating the motor 41 in the reverse direction, it is possible to raise the auxiliary hopper 50 while rotating the auxiliary chute 33 in the opposite direction (counterclockwise direction).

That is, when the auxiliary hopper 50 is moved up or down by the start of the motor 41, the auxiliary chute 33 is also rotated at the same time, thus acting as a coal discharge guiding and adhering coal attached to the auxiliary hopper 50. Since the auxiliary chute 33 is inserted into the auxiliary hopper 50, the production of the auxiliary hopper 50 may be accompanied by an increase in the auxiliary hopper 50, thereby causing the coal to fall down.

When the auxiliary hopper 50 rises to the end, the lower gate 60 is closed by the opening and closing means. In the exemplary embodiment, the bar latching jaw 63 is pressed downward while contacting the bottom surface of the auxiliary chute base 20 so that the lower gate 60 is closed.

Thereafter, the motor 41 is stopped, and thus the rotation of the auxiliary chute 33 is also stopped, and the rise of the auxiliary hopper 50 is also stopped. Thus, it returns to the original coal loading operation.

And the coal filled in the way hopper 120 is discharged to the lower portion is used in the next process.

As described above, although the present invention has been described by way of limited embodiments and drawings, the present invention is not limited thereto, and the technical idea of the present invention and the following by those skilled in the art to which the present invention pertains. Various modifications and variations are possible without departing from the scope of the claims to be described in the following.

Applying the present invention as described above, the closed structure is realized by the auxiliary chute 33, by the lowering operation of the auxiliary hopper 50 can go down to the bottom of the way hopper 120 to discharge the coal drop distance It is possible to reduce the dust, thus preventing the scattering of fine dust or coal around the hopper, thus preventing environmental pollution, creating a pleasant working environment, and preventing the neglect of dust generation points. In addition, since the basis weight deviation error can be prevented, there is an indirect effect of reducing cost and improving coke production.

Claims (1)

In the apparatus for preventing the scattering of dust when charging the coal into the way hopper, at least Colbin bunker hopper 110, auxiliary chute 33, auxiliary hopper 50, the way hopper 120 and the motor control panel, The colvin bunker hopper 110 is configured in the form of a hollow container so as to discharge the coal introduced into the upper inlet to the lower outlet, the bottom portion is configured to be connected to the outlet through the opening and closing means, the shape of the lower outer circumference is formed in a cylindrical shape Is installed in the auxiliary chute base 20, The auxiliary chute 33 is formed in a tubular shape as a whole, and has a rotation driving means for allowing an upper portion thereof to rotate in place while being fitted snugly at the lower end of the colvin bunker hopper 110. It is installed in the auxiliary chute base 20, The auxiliary hopper 50 is formed in a tubular shape as a whole, and its inner circumference is fitted to the outer circumference of the auxiliary chute 33 and its outer circumference or outer wall is fitted to the inner circumference or the inner wall of the hopper 120 up and down. It is provided with a lift drive means for moving, the bottom portion is composed of a lower gate 60, the lift drive means is installed in the auxiliary hopper base 40, The way hopper 120 is formed in a tubular shape as a whole, the inner circumference or the inner wall of the auxiliary hopper 50 is fitted to fit the outer circumference or the outer wall is configured to be fixed and formed so as to move up and down Way hopper dust scattering device, characterized in that.

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