KR100803974B1 - Vibration control device of screen - Google Patents

Abstract

An apparatus for controlling vibration of a screen is provided to prevent the screen from being broken down and maintain more accurately the weight of ores flown into a weighing hopper by relieving an impact generated when the screen stops. An apparatus for controlling vibration of a screen comprises: a screen(30); a screen base part(34) mounted under the screen to support the screen; a vibration part mounted between a bottom part of the screen and a top part of the screen base part; a buffering part(60) mounted between the bottom part of the screen and the top part of the screen base part to buffer vibration of the screen vibrated according to driving of the vibration part; auxiliary buffering parts(70) respectively disposed at front, rear, left and right sides on the bottom part of the screen and respectively mounted between the bottom part of the screen and the top part of the screen base part, the auxiliary buffering parts including a body mounted on the screen base part, and an air cylinder having a rod mounted on the bottom part of the screen; and an air direction control valve(74) including an air circuit part connected to the respective auxiliary buffering parts to guide a flow of air, wherein the air direction control valve controls a flow of air supplied to the auxiliary buffering parts.

Description

Screen Vibration Control {VIBRATION CONTROL DEVICE OF SCREEN}

1 is a view schematically showing a screen equipment installed in a steel mill raw material factory.

2 is a view showing the configuration of a screen vibration control device according to an embodiment of the present invention.

Figure 3 is a schematic diagram showing the arrangement of the auxiliary buffer according to an embodiment of the present invention.

Figure 4 is a flow chart showing the operation flow of the screen vibration control device according to an embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

30; Screen 40; Way hopper

50; Motor 52; Vibrator

60; Shock absorbing portion 70; Auxiliary buffer

80; Control unit 90; First detector

100; Second detector

TECHNICAL FIELD The present invention relates to screen equipment, and more particularly, to an apparatus for damping screen vibrations.

Typically, sintered ore is used as the main ore used in the production of molten iron in a blast furnace. These sintered ores are stored in a sinter storage unit BIN configured in a blast furnace factory. The sintered ore stored in the sintering storage unit is separated by spectroscopy for sintering by the screen equipment.

1 is a view schematically showing a screen equipment installed in a steel mill raw material factory.

The screen facility vibrates the screen 14 by using the movement of the vibrator 17 linked to the driving of the motor 18, and performs a basis weight of the ore flowing into the WEIGHING HOPPER through the screen 14. Do it. The screen 14 functions to basis weight of the ore by a set amount, and also filters the spectral of 5 mm or less among the sintered ores to stabilize the blast furnace furnace air permeability.

When the screen equipment is in operation, the screen 14 is vibrated by the set amplitude of the vibrator 17, but when stopped, the screen 14 is impacted by the inertia, and the crack and basis weight of the screen equipment are reduced. .

According to the related art when using the above method, in order to increase the efficiency of the screen 14, the thinner the layer of ore on the top of the screen 14 mat, the lower the weight of the screen 14, the more impact when the screen 14 is stopped. It becomes bigger.

In addition, the amount of ore charged into the blast furnace is distributed basis weight, but the crack of the bottom plate (BOTTOM PLATE) of the screen 14 is frequently caused by the impact caused by the inertia generated when the screen 14 is stopped. Frequent breakage of the spring (SPRING) 12 supporting (14) increases the maintenance cost and lowers the operation rate of the screen 14, thereby increasing the load on other screens.

In addition, if the screen 14 is stopped after completion of the basis weight by the set amount of the way hopper, there is a problem in that the accuracy of the basis weight falls due to the overweight due to residual vibration.

An object of the present invention is to provide a screen vibration control device that can alleviate the shock generated during the screen stop to prevent the failure of the screen equipment, and more accurately maintain the basis weight of the ore flowing into the way hopper.

In order to achieve the above object, the present invention provides a screen, a screen base portion mounted on the bottom of the screen to support the screen, a vibration portion mounted between the bottom portion of the screen and the upper portion of the screen base portion, and mounted between the lower portion of the screen and the upper portion of the screen base portion. And, it is preferable to include a buffer for cushioning the vibration of the screen vibrated in accordance with the driving of the vibrating portion, the auxiliary buffer mounted between the lower portion of the screen and the base portion of the screen.

In the above configuration, the vibrator may include a motor for generating vibration power of the screen and a vibrator for vibrating the screen in conjunction with driving of the motor.

The shock absorbing portion may be composed of a spring.

The auxiliary buffer part may be configured of an air cylinder having a body mounted on the screen base part and a rod mounted on the bottom of the screen, and may be disposed at the front, rear, left, and right sides of the screen, respectively.

On the other hand, the embodiment of the present invention is connected to each of the auxiliary buffer portion constitutes an air circuit for guiding the flow of air, it may further include an air direction control valve for intermittent air flow supplied to the auxiliary buffer portion.

And an air flow rate configured to connect the forward and reverse pipes, the forward pipes, and the reverse pipes respectively connecting the forward connection part and the backward connection part of the auxiliary buffer part to adjust the air flow rate supplied to the forward pipe and the reverse pipe. It may further include a control valve.

In addition, the first detection unit and the first detection unit which is mounted on the way hopper that the ore filtered through the screen is introduced, the ore is discharged from the way hopper to detect the empty state inside the way hopper to generate a corresponding detection control signal The method may further include a controller configured to generate the screen vibration driving control signal if the inside of the way hopper is analyzed by analyzing the detected control signal.

The apparatus may further include a second detection unit mounted on the way hopper and detecting a state in which ore flows into the way hopper so that more than a predetermined amount of ore flows into the way hopper to generate a corresponding detection control signal.

In the above configuration, the controller analyzes the detection control signal input from the second detection unit, and blocks the screen vibration driving control signal when the ore flows in the way hopper more than a predetermined amount, and controls the air flow control valve to vibrate the screen. Buffer control operation can be performed.

On the other hand, an embodiment of the present invention is mounted to the sintered storage unit for storing the ore discharged to the screen, it may further include a gate for adjusting the amount of ore discharged according to the amount of opening and closing.

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. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention.

2 is a view showing the configuration of a screen vibration control device according to an embodiment of the present invention.

Referring to FIG. 2, the screen vibration control device includes a vibration unit, a buffer unit 60, an auxiliary buffer unit 70, and a controller 80.

The vibrator includes a motor 50 and a vibrator 52 and is mounted between the lower portion of the screen 30 and the upper portion of the screen base portion 34 that supports the screen 30.

The motor 50 is driven in response to the input of the drive control signal supplied from the controller 80 to generate vibration power of the screen 30.

The vibrator 52 functions to vibrate the screen 30 in association with the driving of the motor 50. The vibrator 52 may be installed as a cam, and may be connected and rotated through the belt 54 to receive the driving force of the motor 50.

Reference numeral 32 is a hood mounted on the top of the screen 30, the dust of the ore is collected when the screen 30 vibrates.

The shock absorbing part 60 is mounted at a position supporting the screen 30 between the lower part of the screen 30 and the upper part of the screen base part 34, and has a function of cushioning the vibration of the screen 30 vibrated by the driving of the vibrating part. Do it. The shock absorbing unit 60 is composed of a spring that both ends are supported by a bracket to damp the vibration of the screen 30, and a plurality of springs may be mounted in combination.

The auxiliary buffer part 70 is mounted between the lower part of the screen 30 and the upper part of the screen base part 34 separately from the buffer part 60, and supports the screen 30 and the screen 30 similarly to the buffer part 60. The damping function has a controllable configuration to damp vibrations.

3 is a schematic diagram showing an arrangement relationship of the auxiliary buffer unit 70 according to the embodiment of the present invention.

Referring to FIG. 3, the auxiliary shock absorbing unit 70 includes an air cylinder having a body mounted on the screen base 34 and a rod mounted below the screen 30. The rod is installed to move in the vibrating direction of the screen 30 at the bottom of the screen 30.

The auxiliary buffer unit 70 may be disposed at the front and rear left and right (four locations) at the bottom of the screen 30, respectively. By providing four air cylinders on the upper, lower, left, and right sides of the bottom of the screen 30, the shock generated when the screen 30 is stopped can be alleviated.

On the other hand, the embodiment of the present invention is connected to each auxiliary buffer unit 70 constitutes an air circuit for guiding the flow of air, the air direction control valve for intermittent air flow supplied to the auxiliary buffer unit 70 ( 74). The forward connection part and the backward connection part of each auxiliary buffer part 70 are connected to each other, and an air direction control valve 74 is installed in a line connecting the forward connection part and the backward connection part.

In addition, the air circuit unit includes a forward pipe and a reverse pipe connecting the forward connection part and the reverse connection part of the auxiliary buffer part 70, respectively.

The apparatus further includes an air flow rate control valve 76 connected to the forward pipe and the reverse pipe, respectively, to adjust air flow rates supplied to the forward pipe and the reverse pipe. According to the opening and closing degree of the air flow control valve 76, the air flow rate supplied to the forward pipe and the reverse pipe is adjusted to mitigate the front or rear impact of the screen 30.

The apparatus further includes a first detector 90 and a second detector 100.

The first detection unit 90 is mounted to the way hopper 40, the ore is discharged from the way hopper 40 to detect an empty state inside the way hopper 40 to generate a corresponding detection control signal.

The second detection unit 100 is mounted on the way hopper 40, the ore flows into the way hopper 40 to detect a state in which the ore more than a predetermined amount flowed into the way hopper 40 to detect a corresponding control signal. Occurs.

The first detection unit 90 and the second detection unit 100 may be mounted on the lower and upper portions of the way hopper 40, respectively, and include a sensor for detecting the presence of ore flowing into the way hopper 40. Can be.

The controller 80 controls the overall operation related to the vibration control of the screen 30 according to the embodiment of the present invention, and may be configured as a kind of microprocessor. The controller 80 analyzes the detection control signal input from the first detection unit 90 and generates a screen vibration driving control signal when the inside of the way hopper 40 is empty. Then, the detection control signal input from the second detection unit 100 is analyzed to block the screen vibration driving control signal when the ore flows in the way hopper 40 more than the set amount, and the air flow control valve 76 is closed. By controlling the vibration attenuation control operation of the screen (30).

Meanwhile, the embodiment of the present invention further includes a gate 22 mounted to the sintered storage 20 for storing the ore discharged to the screen 30. The gate 22 functions to adjust the amount of ore discharged according to the amount of opening and closing. The gate 22 may be opened and closed manually by an operator, and may be configured to be automatically opened and closed by receiving a control signal from the controller 80. In the above configuration, when the opening amount of the gate 22 is adjusted to a small amount and opened, the ore discharged to the screen 30 is weighed in the state where the ore layer is made as thin as possible on the screen 30 mat MAT. The filtration efficiency of 30) can be improved.

Figure 4 is a flow chart showing the operation flow of the screen vibration control device according to an embodiment of the present invention.

2 to 4, the operation of the screen vibration control device according to the embodiment of the present invention will be described.

When the ore is discharged from the way hopper 40 and the inside of the way hopper 40 becomes the empty space (EMPTY), the first detection unit 90 detects the inside of the way hopper 40 in an empty state to detect a corresponding control signal. To generate (S410).

The controller 80 analyzes the detection control signal input from the first detector 90 and performs a screen vibration driving control operation when the inside of the hopper 40 is empty (S420).

As the screen vibration driving control operation is performed, the air direction control valve 74 mounted on the air circuit part of each air cylinder constituting the auxiliary shock absorbing part 70 is opened, and the vibrating part is driven so that the ore flows into the screen 30. Start a basis weight.

That is, when the ore is discharged from the way hopper 40 and the inside of the way hopper 40 becomes empty, the motor 50 constituting the vibration unit is operated to drive the vibrator 52, and the ore is vibrated by the screen 30. While filtering the spectral of the ore to the basis of the ore to the hopper 40.

In addition, when the air direction control valve 74 is opened during the screen vibration driving control operation, a flow path is formed at the forward and backward sides of the air cylinder, and thus the rod of the air cylinder freely moves up and down. This operation continues until the basis weight of the ore is complete and the air cylinder does not resist the screen 30.

When the basis weight of the ore is completed in this state and the ore flows into the way hopper 40 or more, the second detection unit 100 detects a state in which the ore more than the set amount flows into the way hopper 40. A detection control signal is generated (S430).

The controller 80 analyzes the detection control signal input from the second detection unit 100 and blocks the screen vibration driving control signal when the ore flows in the way hopper 40 more than a predetermined amount, and controls the screen vibration attenuation control. Perform (S440).

As the screen vibration attenuation control operation is performed, driving of the vibrator is stopped and the air direction control valve 74 mounted on the air circuit part of the air cylinder is closed. When the air direction control valve 74 is closed, the flow path of the forward and backward sides of each air cylinder is blocked. Then, the forward and reverse side air inside the air cylinder is not discharged, the rod of the air cylinder is not moved, and the shock caused by the inertia generated when the screen 30 is stopped due to the buffering action of the air inside the air cylinder.

However, when the air direction control valve 74 is closed, the remaining vibration of the screen 30 can be corrected when the air inside the air cylinder is completely closed, but the inertia force is applied to both ends of the air cylinder (the screen 30 and the screen base portion). 34)) can cause problems. That is, when the screen 30 is stopped in the driving state, the amplitude of the screen 30 is increased by inertia, and the screen 30 is stopped while rattled for about 10 seconds.

At this time, by controlling the opening and closing degree of the air flow control valve 76 can be adjusted the force of inertia transmitted to both ends of the air cylinder.

As described above, the screen vibration control device according to the present invention can alleviate the shock generated when the screen is stopped to prevent cracking of the screen equipment and breaking of the spring.

In addition, it is possible to reduce the cost of maintenance of the screen equipment by minimizing the failure of the screen, increase the screen efficiency by improving the operation rate of the screen, and contribute to improving the ventilation of the furnace by minimizing the amount of injection in the furnace.

In addition, since the remaining vibration of the screen is reduced after the completion of the screen basis weight has the effect of improving the degree of basis weight.

Claims (10)

screen; A screen base part mounted below the screen to support the screen; A vibrator mounted between the bottom of the screen and the top of the screen base part; A buffer unit mounted between the lower portion of the screen and the upper portion of the screen base portion and configured to buffer vibrations of the screen vibrated by driving of the vibrating portion; An air cylinder having a main body mounted on the screen base part and a rod mounted on the bottom of the screen, respectively disposed between the lower part of the screen, the left and right sides of the screen, and mounted between the lower part of the screen and the upper part of the screen base part; An auxiliary buffer configured, and An air directional control valve connected to each of the auxiliary buffer parts to guide the flow of air; Screen vibration control device comprising a. The method of claim 1, The vibrating unit A motor for generating vibration power of the screen; And a vibrator for vibrating the screen in association with driving of the motor. The method of claim 1, The shock absorbing portion is composed of a spring screen vibration control device. delete delete delete The method of claim 1, A forward pipe and a reverse pipe constituting the air circuit part and connecting the forward connection part and the backward connection part of the auxiliary buffer part, respectively; And an air flow rate control valve connected to the forward pipe and the reverse pipe, respectively, to control the air flow rate supplied to the forward pipe and the reverse pipe. The method of claim 7, wherein A first detection unit mounted to a way hopper into which the ore filtered through the screen is introduced, the ore being discharged from the way hopper to detect an empty state inside the way hopper to generate a corresponding detection control signal; And a controller configured to analyze the detection control signal input from the first detection unit and generate a screen vibration driving control signal when the inside of the way hopper is empty. The method of claim 8, A second detection unit mounted to the way hopper and detecting a state in which ore flows into the way hopper and a predetermined amount of ore flows into the way hopper to generate a corresponding detection control signal, The control unit analyzes a detection control signal input from the second detection unit to block the screen vibration driving control signal when the ore flows in the way hopper more than a predetermined amount, and controls the air flow rate control valve of the screen Screen vibration control device for performing the vibration damping control operation. The method of claim 9, And a gate mounted on the sintered storage unit for storing the ore discharged to the screen, the gate adjusting the amount of the ore discharged according to the amount of opening and closing.

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