KR20190019327A - Scale discharge device - Google Patents

Abstract

Disclosed is a scale discharge device for easily discharging scale. The scale discharge device according to an embodiment of the present invention includes: a cover for covering an upper portion of a transferred steel plate; a front hood mounted on the cover in order to inhale and discharge scale; a rear hood mounted on the cover located at a position spaced apart in a transfer direction of the steel plate from the front hood in order to inhale and discharge scale; and blower units mounted at a discharge duct of the front hood and a discharge duct of the rear hood. The blower unit includes: a cylindrical body part connected with the discharge duct; an aerofoil type Coanda surface disposed along the inner circumference of a body part and having a curved inner surface; a lid part extending from the inner face of the body part located above the Coanda surface to cover the Coanda surface to be spaced apart from the Coanda surface, wherein the lid part has a nozzle part formed between the Coanda surface and the lid part in such a way that an outlet face the downstream side of the discharge duct and an inner passage formed in the lid part to have a cross section area smaller than the passage of the discharge duct; and an air supply passage disposed between a head part of the Coanda surface and the inner face of the lid part to be separated from the inner passage in order to receive air from an air supply source and supply the received air to a nozzle part.

Description

[0001] SCALE DISCHARGE DEVICE [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scale discharging device for sucking and discharging a scale dropped from a steel plate surface.

The hot-rolled steel sheet is usually subjected to finish rolling at a high temperature of 800 ° C or higher, so that a large scale (iron oxide) is generated on the surface. It is necessary to remove the scale before performing these processes because it damages the surface property of the product as well as the plating property and the paintability during cold rolling.

Mechanical and chemical methods are used together to remove scale of steel sheet. The mechanical method is to press the surface of the steel sheet with a scale breaker while conveying the steel sheet, causing a crack on the scale. The chemical method is to remove the scale by passing the steel plate that has been subjected to the mechanical method in a pickling bath. The scale on the surface of the steel sheet passes through the scale breaker and can be easily removed from the pickling bath because it is contained in the pickling bath in the state where the crack is formed.

The scales dropped from the scale breaker are mostly removed by the dust collecting means in the scale breaker. However, some of the scale may be discharged to the outside together with the steel plate in a state of being settled on the upper surface of the steel plate, and scattered into the air in the process of being transferred to the pickling vessel through the deflector roll.

An aspect of the present invention is to provide a scale discharge apparatus capable of easily discharging a scale discharged along a steel plate.

Another aspect of the present invention is to provide a scale discharge apparatus capable of increasing scale discharge effect by floating scale on the upper surface of a steel plate.

According to an aspect of the present invention, a cover for covering an upper portion of a steel sheet to be conveyed; A front hood installed on the cover for sucking and discharging the scale; A rear hood installed on the cover at a position spaced apart from the front hood in a conveying direction of the steel plate and sucking and discharging the scale; And a blower installed in each of the front hood exhaust duct and the rear hood exhaust duct, wherein the blower device has a cylindrical body portion connected to the exhaust duct, and a cylindrical body portion provided along the inner periphery of the body portion, And a nozzle portion extending from the inner surface of the body on the upstream side of the Coanda surface and covering the Coanda surface so as to be spaced apart from the Coanda surface so that the outlet faces the downstream of the exhaust duct A cover portion formed on an inner side of the inner duct to form an inner channel having a smaller cross sectional area than a channel of the air outlet duct, and an air supply unit provided between the inner surface of the inner cap and the inner surface of the cover to partition the inner duct, And a supply passage for supplying the air to the nozzle unit.

The lid part may have a shape in which the inner diameter of the lid part gradually decreases and then expands as the portion of the lid part covering the inner surface of the lid part forms a diffusing air flow toward the tail part of the surface of the lid .

Wherein the intake port of the front hood is narrowly formed in the width direction of the steel plate so as to absorb the scale with a stronger suction force than the rear hood and the suction port of the rear hood is formed to be wider than the suction port of the front hood, The scale can be sucked by the suction force.

The scale discharge device may further include an air knife provided on the cover at the rear of the rear hood and spraying air obliquely toward the lower front side to float the scale on the upper surface of the steel plate and to block leakage of scale.

Wherein the air knife includes an intermediate jet portion extending in the width direction of the steel plate behind the rear hood; And two lateral jet portions extending obliquely from both ends of the intermediate jet portion toward both front ends of the cover.

The air knife may further include an air guide extending from an inner surface of the cover in an air spraying direction to block the influence of the rear hood intake air flow.

The scale discharging device according to the embodiment of the present invention can easily suck and discharge the scale discharged along the steel plate because the spray air of the air knife floats the scale on the upper surface of the steel plate toward the suction port of the front hood.

The scale discharge device according to the embodiment of the present invention sucks and discharges a relatively large scale scale with a strong suction force of the front hood, sucks and discharges the scale floating up without being discharged by the front hood, Since the leakage of the scale is blocked, the scale emission effect can be increased.

Since the air discharged from the nozzle portion of the air blowing device forms a diffusing air flow toward the tail portion of the surface of the coil, the scale discharge device according to the embodiment of the present invention accelerates the inner flow velocity of the air blowing device and generates strong suction force . Therefore, the emission effect of the scale can be enhanced.

1 shows a scale removal apparatus to which a scale discharge apparatus according to an embodiment of the present invention is applied.
2 is a cross-sectional view of a scale discharge apparatus according to an embodiment of the present invention.
3 is a perspective view of a scale discharge device according to an embodiment of the present invention.
4 shows a blower installed in a front hood of a scale discharge apparatus according to an embodiment of the present invention.
5 is a detail view of part A of Fig.
Fig. 6 is a detailed view of part B of Fig. 2. Fig.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following embodiments are provided to fully convey the spirit of the present invention to a person having ordinary skill in the art to which the present invention belongs. The present invention is not limited to the embodiments shown herein but may be embodied in other forms. For the sake of clarity, the drawings are not drawn to scale, and the size of the elements may be slightly exaggerated to facilitate understanding.

1 shows a scale removal apparatus to which a scale discharge apparatus according to an embodiment of the present invention is applied.

1, the scale removing apparatus includes a scale breaker 20 provided on a conveying path of a steel plate 10, a scale breaker 20 provided on an outlet side of the scale breaker 20, for collecting a scale discharged together with the steel plate 10, A plurality of deflector rollers 30 for changing the conveying direction of the steel sheet 10 conveyed via the scale ejector device 100 and a plurality of deflector rollers 30, And a pickling bath 40 for removing the scale by immersing the steel plate 10 in an acidic solution.

The scale breaker 20 presses the upper surface and the lower surface of the steel sheet 10 to which the plurality of pressure rolls 21 are fed to cause a crack on the scale of the surface of the steel sheet 10, . The scale breaker 20 is in a state in which the outside is surrounded by the dust collecting cover 22, so that the scales dropped by the pressing rolls 21 can be prevented from scattering to the outside.

The scale removed from the steel plate 10 in the process of passing through the scale breaker 20 can be mostly removed by a separate dust collecting means (not shown) provided inside the dust collecting cover 22. [ However, some of the scale may be discharged to the outside together with the steel plate 10 through the outlet 24 in a state where the scale is settled on the upper surface of the steel plate 10 to be transported. This scale can be discharged by the scale discharging device 100 provided on the side of the outlet 24 of the scale breaker 20 to prevent the scale from scattering to the outside.

2 and 3, the scale discharging apparatus 100 according to the present embodiment includes a cover 110 covering an upper portion of a steel sheet 10 to be transported, a cover 110 disposed adjacent to the scale breaker outlet 24, A front hood 120 installed in the front hood 120 and sucking and discharging the scale on the upper side of the steel plate 10 and a cover 110 installed at a position spaced apart from the front hood 120 in the transport direction of the steel plate 10, And a cover 110 provided behind the rear hood 130. The scales on the upper surface of the steel plate 10 are floated by injecting air obliquely toward the lower front side of the rear hood 130, And an air knife 140 blocking the leakage of the scale.

The cover 110 may be in the form of a rectangular panel wider than the width of the steel sheet 10 to be conveyed, as shown in Fig. Both ends of the cover 110 can be connected to the side cover 112, which covers both sides of the conveying path of the steel sheet 10, respectively.

The front hood 120 is narrow and long in the width direction of the steel plate 10 and has a suction port 121 for sucking the scale with a stronger suction force than the rear hood 130. The inlet 121 of the front hood 120 may extend longer than the width of the steel plate 10 in the width direction of the steel plate 10. [

3, the front hood 120 includes three connecting ducts 122 connected to the inlet 121, three outlet ducts 123 connected to the respective connecting ducts 122, To generate a suction force for discharging the scale.

2 and 4, each fan 124 of the front hood 120 includes a cylindrical body 124a connected to the discharge duct 123, and a cylindrical body 124a provided along the inner circumference of the body 124a And an airfoil surface 124c extending from the inner surface of the body portion 124a on the upstream side of the Coanda surface 124c so as to be spaced apart from the coanda surface 124c, A nozzle portion 124d having an outlet directed to the downstream side of the discharge duct 123 and a lid portion 124b having an inner passage 124b having a smaller cross sectional area than the flow passage of the discharge duct 123, The nozzle unit 124 is provided between the head part 124c-1 of the coiled surface 124c and the inner surface of the lid part 124e so as to be partitioned by the inner flow path 124b and receives air from the air supply source 60, And a supply air flow path 124f for supplying the air supply flow path 124d.

The airfoil-type Coanda surface 124c may be in the form of a diffuser whose inner diameter gradually increases toward the downstream of the exhaust duct 123. The lid portion 124e is a portion that covers the cone inner surface 124c so that the air discharged to the outlet of the nozzle portion 124d forms a diffusing air flow directed toward the tail portion 124c-2 of the coanda surface 124c The inner diameter may gradually decrease from the upstream to the downstream and then expand again. That is, the lid portion 124e may be a curved surface corresponding to the shape of the Coanda surface 124c at the portion forming the nozzle portion 124d. The gap of the nozzle portion 124d may be 0.05 to 0.3 mm.

Since the air discharged from the nozzle portion 124d flows along the coanda surface 124c, the flow rate of the internal flow path 124b is increased by the coanda effect. This air flow causes the pressure of the inner flow path 124b to decrease while maintaining the flow toward the downstream side of the discharge duct 123 so that the air toward the inlet 121 of the front hood 120 can flow toward the outlet of the discharge duct 123.

The air blowing device 124 of the present embodiment is configured such that the air discharged from the nozzle portion 124d forms a diffusing air flow directed toward the tail portion 124c-2 of the Coanda surface 124c, So that a strong suction force is generated at the suction port 121. Therefore, the air and the floating scale below the cover 110 can be smoothly discharged to the dust collector 70 through the front hood 120.

The front hood 120 has a suction port 121 having a relatively small sectional area as compared with the rear hood 130 and three blowing devices 124 are connected to the suction port 121 as shown in FIG. Lt; / RTI > Therefore, the front hood 120 can suck and discharge the scale on the upper side of the steel plate 10 with a stronger suction force than the rear hood 130.

The rear hood 130 has a suction port 131 having a cross sectional area wider than the suction port 121 of the front hood 120. 3, the rear hood 130 includes one connecting duct 132 connected to the inlet 131, one outlet duct 133 connected to the connecting duct 132, and a discharge duct 133 connected to the outlet duct 133 And may include an installed fan device 134.

The air blowing device 134 of the rear hood 130 may be configured in the same manner as the air blowing device 124 of the front hood 120. Since the rear hood 130 has a suction port 131 having a relatively larger sectional area than the front hood 120 and one air blowing device 134 sucks air through the suction port 131, The scale floating on the steel plate 10 can be sucked with a weaker suction force. Therefore, a relatively large particle scale can be sucked by the front hood 120, and a relatively small particle scale not sucked by the front hood 120 can be sucked back by the rear hood 130. [

 3, the air knife 140 includes a jetting section 141 for jetting air obliquely from the cover 110 toward the upper surface of the front lower steel sheet 10, A distribution cover 142 covering the top of the jetting section 141 and an air tube 143 extending from the air source 60 to supply air to the distribution cover 142.

3, the jetting section 141 of the air knife 140 includes an intermediate jetting section 141a extending in the width direction of the steel plate 10 at the rear of the rear hood 130, And two lateral jetting portions 141b extending obliquely toward both front ends of the cover 110 from both ends of the front cover 141a. And the distribution cover 142 coupled to the upper portion of the jetting section 141 may be a corresponding form.

The air knife 140 generates a spray air stream 145 that floats the scale of the upper surface of the steel plate 10 and guides the air to the suction port 121 of the front hood 120 as shown in FIG. Since the spray air stream 145 is sprayed on the upper surface of the steel sheet 10 with a width larger than the width of the steel sheet 10, it functions as a blocking wall for preventing leakage of the scale. That is, the scale floating on the steel plate 10 is prevented from flowing and leaking in the conveying direction of the steel plate 10. The angle θ between the spray air stream 145 and the steel plate 10 may be 30 to 75 ° and the spray velocity of the spray air stream 145 may be 10 to 50 m / s.

3, the scale on both sides of the upper surface of the steel plate 10 is connected to the inlet of the front hood 120 by the lateral jetting portion 141b provided on both sides of the intermediate jetting portion 141a, To the suction port 131 of the rear hood 130 or the rear hood 130 to smooth the discharge of the scale.

The spray air stream 145 of the air knife 140 causes a swirling airflow below the suction port 131 of the rear hood 130 after colliding with the upper surface of the steel sheet 10 as shown in FIG. The spray air stream 145 of the air knife 140 reaches the suction port 121 of the front hood 120 and generates a swirling air current also below the suction port 131 of the front hood 130 to be conveyed along the upper surface of the steel hose ≪ / RTI > Therefore, the scale discharged along the upper surface of the steel plate 10 is sucked and discharged by the strong suction force of the front hood 120 up to a relatively large particle. The scale floating without being discharged by the front hood 120 reaches the suction port 131 of the rear hood 130 and is discharged by the spray air stream 145 of the air knife 140. The rear hood suction port 131), and is discharged by the rear hood (130).

The scale discharge device of the present embodiment discharges the scale along the steel plate 10 because the spray air stream 145 of the air knife 140 floats the scale on the upper surface of the steel plate 10 toward the suction port 121 of the front hood 120 The scale can be easily sucked and discharged.

The scale discharging device of this embodiment sucks a scale having a relatively large particle size by sucking and discharging the front hood 120 with a strong suction force and sucking the scale floating without being discharged by the front hood 120 by the rear hood 130 And the air knife 140 blocks the leakage of the scale, so that the scale discharge effect can be enhanced.

The air knife 140 includes an air guide 146 which extends from the inner surface of the cover 110 in the direction of spraying air to guide the spray air stream 145, as shown in Fig. The air guide 146 cuts off the influences of the suction airflow of the rear hood 130 and the spray air stream 145 of the air knife 140 is sprayed straight to the upper surface of the steel plate 10 so that the spray air stream 145 functions . Also, the flow rate of the intake airflow of the rear hood 130 is prevented from being lowered due to the jet airflow. When the speed of the air knife injection air stream 145 is 50 m / s and the air guide 146 is not provided, the air flow rate of the rear hood air inlet 131 is 15-30 m / s. The airflow speed of the rear hood suction port 131 is increased to 40 to 60 m / s. In other words, it was confirmed that the suction of the rear hood 130 is further facilitated by only installing the air guide 146 under the same condition.

The suction port 121 of the front hood 120 may include a curved inflow guide 126 provided on the rear side connected to the cover 110 as shown in FIG. The curved inflow guide portion 126 allows the airflow sucked into the suction port 121 of the front hood 120 to flow smoothly along the curved surface without congestion due to the Coanda effect. This facilitates the suction of the front hood 120 and improves the discharge effect of the scale.

10: steel plate, 20: scale breaker,
100: scale discharge device, 110: cover,
120: front hood, 121: inlet of the front hood,
124: blowing device of the front hood, 126: inflow guide,
130: rear hood, 131: inlet of the rear hood,
134: blowing device of the rear hood, 140: air knife,
141: jet opening, 142: distribution cover,
146: Air guide.

Claims (6)

A cover for covering an upper portion of the steel sheet to be conveyed;
A front hood installed on the cover for sucking and discharging the scale;
A rear hood installed on the cover at a position spaced apart from the front hood in a conveying direction of the steel plate and sucking and discharging the scale; And
And a blower installed in each of the front hood exhaust duct and the rear hood exhaust duct,
The air blowing device includes a cylindrical body portion connected to the exhaust duct, an airfoil-type Coanda surface provided along the inner circumference of the body portion and curved on the inner surface, and an airfoil-shaped Coandao surface extending from the inner surface of the body portion on the upstream side of the Coanda surface A lid part which forms a nozzle part with an outlet facing the downstream of the discharge duct between the lid part and the coanda surface so as to be spaced apart from the surface of the lid and forms an inner flow passage having a smaller cross sectional area than the flow path of the discharge duct, And an air supply passage provided between the inner surface of the Coanda surface and the inner surface of the lid to partition the inner flow path and supply air from the air supply source to the nozzle section. The method according to claim 1,
The lid part is formed in such a manner that the part of the lid part covering the surface of the nose forms a diffusing air flow toward the tail part of the surface of the nose part, the air exhausted to the outlet of the nozzle part gradually decreases in size from the upstream to the downstream, Device. The method according to claim 1,
The intake port of the front hood is formed to be narrow in the width direction of the steel plate so that the scale is sucked by a stronger suction force than the rear hood,
Wherein the suction port of the rear hood is formed to be wider in cross-sectional area than the suction port of the front hood, so that the scale is sucked by the suction force weaker than the front hood. The method according to claim 1,
And an air knife provided on the cover behind the rear hood and spraying air obliquely toward the lower front side to float the scale on the upper surface of the steel plate and to block the leakage of the scale. 5. The method of claim 4,
The air knife
An intermediate jet portion extending in the width direction of the steel plate behind the rear hood; And
And two lateral jet portions extending obliquely from both ends of the intermediate jet portion toward both front ends of the cover. 6. The method of claim 5,
Wherein the air knife further comprises an air guide extending in an air spraying direction from the inner surface of the cover to block the influence of the rear hood intake air flow.

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