KR101834420B1 - Distribution Apparatus - Google Patents

Abstract

The present invention relates to a raw material supplying device for charging a raw material into a container for processing a raw material, wherein the raw material supplying device includes: a first chute capable of moving toward a container; and a second chute capable of storing a raw material therein and installed in the first chute so as to be movable forward and backward, wherein the second chute is adjustable in the width of a part through which the raw material is discharged. Accordingly, the present invention is able to smoothly discharge and supply the raw material loaded on a chute to the inside of a container for processing the raw material.

Description

Distribution Apparatus

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a raw material supply apparatus, and more particularly, to a raw material supply apparatus capable of smoothly discharging and supplying a raw material loaded in a chute into a container for processing a raw material.

Generally, steelmaking consists of iron pre-treatment, converter refining, secondary refining, and continuous casting. During the conversion process, the process of filling the furnace with charcoal and blowing oxygen to remove the carbon in the charcoal is repeated. Before the charcoal is supplied to the converter, a charging chute can be used to charge scrap in the converter.

The charging chute is supported by the hoisting hook and the hoisting hook of the ceiling crane. In order to load the scrap iron into the converter, the scrap iron can be first loaded in the charging chute and then moved to the converter side. Then, when the charging chute is raised while the charging chute is inserted into the nose of the converter, the inclination of the charging chute is adjusted, and the scraper slides along the inclined surface to be charged into the inside of the converter.

However, some of the scrap metal that is loaded into the charging chute may remain in the charging chute without being charged into the converter. When the scrap iron is charged into the converter, the scrap iron is concentrated on the discharge port of the charging chute, and the scrap metal can not be discharged to each other.

Conventionally, when scrap iron is caught in a charging chute, vibration is generated in the charging chute, or a shock is applied to the charging chute. However, the charging chute may be damaged or deformed due to impact or the like, and if the vibration causes severe vibration, the charging chute may be detached from the ceiling crane and fall down.

Or, the bobbing hooks were raised higher to remove stuck scrapes to form steep slopes. However, there is a limit to the height for raising the bobbin hook, and if the bobbin hook is forcibly lifted, the charging chute may fall off from the ceiling crane, causing a crash.

KR 10-0726159 B KR 2002-0000999 A

The present invention provides a raw material feeding device capable of smoothly feeding a raw material loaded in a chute into a container.

The present invention provides a raw material supply device capable of preventing safety accidents and facilitating maintenance of equipment.

The present invention relates to a raw material supply device for charging a raw material into a container for treating a raw material, comprising: a first chute capable of moving toward the container; And a second chute capable of storing the raw material therein and capable of adjusting the width of a portion through which the raw material is discharged, the second chute being provided in the first chute so as to be able to move back and forth.

Wherein the first chute is supported to be adjustable in inclination and the second chute can be moved forward and backward according to the inclination of the first chute and the material of the second chute is discharged The width of the portion to be formed can be adjusted.

Wherein the second chute comprises: a body member forming a path through which the raw material moves on the upper surface; A guide member covering at least one portion of the body member and having one end in contact with or detachable from the body member; And a connecting member rotatably connecting the other end of the guide member to the body member.

The pair of guide members are provided at both sides of the body member, and the maximum distance at which one ends of the pair of guide members are spaced apart from each other is equal to or greater than the width of the first chute.

The second chute may further include an elongate shrinkable member which is elongate and contractible in a direction intersecting the direction of movement of the raw material, one end of which is connected to one end of the guide member and the other end of which is connected to the body member.

The second chute further includes a driving member capable of adjusting an interval between the body member and one end of the guide member.

The first chute may include a rail extending in the longitudinal direction of the body member and the second chute may be movably connected along the extending direction of the rail and fixed to the body member do.

And a separation preventing portion provided on at least one of the first chute and the second chute so as to limit the distance that the second chute moves outside the first chute.

The release preventing portion includes an elastic member capable of elongating and contracting in the moving direction of the raw material and having one end connected to the second chute and the other end connected to the first chute.

The departure prevention portion includes a stopper installed in the first chute to restrict movement of the moving member.

The first chute includes a side wall member capable of wrapping the side surface of the second chute, and a portion of the side wall member that the second chute enters and exits is tapered or processed to have a curvature.

The container includes a converter, and the first chute is supported by a ceiling crane.

According to the embodiment of the present invention, the raw material loaded in the chute can be easily discharged. Thus, it is possible to suppress or prevent the raw material supplied to the container from clogging the chute. Therefore, since the raw material can be easily supplied to the container for treating the raw material, the efficiency of the process using the raw material can be improved.

In addition, it is possible to suppress or prevent the raw material from being applied to the chute without impacting the chute. Thus, it is possible to prevent the chute from being damaged due to vibration or impact applied to the chute, and excessively adjusting the inclination of the chute, thereby preventing the chute from falling. Therefore, it is possible to prevent a safety accident caused by the chute, and the service life of the chute can be prolonged, so that the maintenance of the equipment can be facilitated.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing a structure of a raw material supply apparatus according to an embodiment of the present invention; FIG.
2 is a view showing a structure of a first suit according to an embodiment of the present invention;
3 is a view showing a structure of a second suit according to an embodiment of the present invention;
4 is a view showing a connection structure between a first chute and a second chute according to an embodiment of the present invention;
5 is a view showing a connection structure between a first chute and a second chute according to another embodiment of the present invention.
6 is a view showing the operation of the raw material supply apparatus according to the embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. To illustrate the invention in detail, the drawings may be exaggerated and the same reference numbers refer to the same elements in the figures.

FIG. 1 is a view showing a structure of a raw material supplying apparatus according to an embodiment of the present invention, FIG. 2 is a view showing a structure of a first chute according to an embodiment of the present invention, and FIG. 2 is a diagram showing a structure of a second shoot.

Referring to FIG. 1, a raw material supply apparatus 100 according to an embodiment of the present invention is a raw material supply apparatus for charging a raw material into a container for processing a raw material. The raw material supply apparatus includes a first chute 110, And a second chute 120 capable of storing the raw material therein and being adjustable in width within the first chute 110 so as to be capable of moving forward and backward and discharging the raw material.

Further, the raw material supply apparatus 100 further includes a departure prevention portion for limiting the distance that the second chute 120 moves outside the first chute 110. At this time, the container may be a converter, the raw material may include scrap metal, and the first chute 110 may be supported by a ceiling crane.

The first chute 110 serves to house the second chute 120. Referring to FIG. 2, the first chute 110 includes a bottom member 111 extending in a longitudinal direction (or forward and backward direction), a side member 111 extending from the side of the bottom member 111 to cover a side of the second chute 120, A rear wall member 113 connected to the rear end of the bottom member 111, Accordingly, the first chute 110 may be formed in an open shape with its top and front open.

The bottom member 111 may be formed in the shape of a rectangular plate. The lateral width of the bottom member 111 may be greater than or equal to the lateral width of the second chute 120. Thus, the second chute 120 can be positioned on the bottom member 111. [

At this time, the rails 114 may be provided on the first chute 110. For example, the upper surface of the bottom member 111 may have an insertion groove 111a extending in the longitudinal direction (or forward and backward direction), and the rail 114 may be installed in the insertion groove 111a have. The rail 114 may be formed to extend in the longitudinal direction (or in the forward and backward directions). Therefore, the second chute 120, which is movably installed on the rail 114, can move back and forth along the extending direction of the rail 114.

The front end of the rail 114 can be connected to the front inner wall in the insertion groove 111a and the rear end can be connected to the rear inner wall in the insertion groove 111a. The rails can be vertically spaced from the bottom surface of the insertion groove 111a. As a result, the second chute 120 connected to the rail 114 can be prevented from coming into contact with the bottom of the insertion groove 111a, and the second chute 120 can be prevented from coming into contact with the bottom of the insertion groove 111a Can be prevented.

Also, one or a plurality of rails 114 may be provided. As the number of the rails 114 increases, the second chute 120 can be stably supported on the rails 114 and move. However, the structure, shape, and the number of the rails 114 are not limited to these, and may vary.

The side wall member 112 may form a side wall of the first chute 110. The sidewall member 112 may be formed in the form of a plate. The sidewall member 112 extends in the front-rear direction and is formed to have a longer length in the vertical direction than the bottom member 111. Accordingly, the side wall member 112 may be formed in a shape protruding upward from the bottom member 111.

Further, the pair of side wall members 112 may be connected to both sides of the bottom member 111, respectively. The lateral spacing distance between the side wall members 112 is equal to or greater than the width of the second chute 120 in the lateral direction. Thus, the second chute 120 can be positioned between the side wall members 112, and the pair of side wall members 112 can cover both sides of the second chute 120, respectively.

In addition, the portion (or the front end) of the side wall member 112 through which the second chute 120 enters and exits can be tapered or processed to have a curvature. That is, the portion of the side wall member 112 that can come in contact with the second chute 120 can be processed. The front end forming the entrance of the second chute 120 of the side wall member 112 can be processed. For example, the width of the front end of each side wall member 112 may be narrowed from the rear toward the front. Alternatively, the width between the front end portions of the pair of sidewall members 112 may be widened toward the front. Thus, it is possible to suppress or prevent the rotation of the second chute 120 when the second chute 120 rotates at least partly as it moves forward, from being caught by the side wall member 112. Accordingly, at least a part of the second chute 120 can be easily rotated, and the width of the portion forming the raw material discharge port in the second chute 120 can be adjusted. However, the structure and shape of the sidewall member 112 are not limited thereto and may vary.

The rear wall member 113 may be formed in a plate shape. The rear wall member 113 is longer than the bottom member 111 in the vertical direction. Accordingly, the rear wall member 113 may be formed in a shape protruding upward from the bottom member 111. The rear wall member 113 may be connected to the rear end of the bottom member 111 and the side wall member 112. Thus, the rear surface of the first chute 110 can be clogged by the rear wall member 113. Therefore, the bottom member 111, the side wall member 112, and the rear wall member 113 can be connected to form a space in which the second chute 120 can be housed. However, the structure and shape of the first chute 110 are not limited to these, and may vary.

At this time, the first chute 110 can be supported by a ceiling crane. The hoistway hook 115 of the ceiling crane is formed on the side wall member 112 of the first chute 110 and the hoisting hook 115 of the ceiling crane is attached to the rear wall member 113 of the first chute 110 A catching hook 116 can be formed. Therefore, the first chute 110 can be supported by the ceiling crane and move.

Further, the first chute 110 can be inclined by a ceiling crane. For example, when the bobbin hook is moved upward from the main hook of the ceiling crane, the first chute 110 may be inclined with the rear end of the first chute 110 being raised above the front end. Accordingly, the second chute 120 housed in the first chute 110 moves forward by tilting, so that at least a part of the second chute 120 can protrude outside the first chute 110.

Alternatively, the first chute 110 may be inclined so that the front end of the first chute 110 is raised above the rear end of the first chute 110 by moving the main hoist hook upward than the hoisting hook of the ceiling crane. Thus, the second chute 120 can be completely housed in the first chute 110 while moving backward.

On the other hand, if the main hook of the ceiling crane and the auxiliary hook of the ceiling crane are positioned at the same height, the second chute 120 can be maintained in the first chute 110. Thus, when the raw material is loaded in the second chute 120, the state in which the raw material is loaded can be maintained. However, the method of adjusting the inclination of the first chute 110 is not limited to this, and may vary.

The second chute 120 serves to load the raw material therein. Referring to FIG. 3, the second chute 120 may move forward and backward according to the inclination of the first chute 110, and the material of the second chute 120 may be shifted The width of the discharged portion can be adjusted.

The second chute 120 covers at least any one of the body member 121 and the body member 121 that forms the path through which the raw material moves on the upper surface and has one end contacted with the body member 121 A detachable guide member 122 and a connecting member 123 for rotatably connecting the other end of the guide member 122 to the body member 121. [ The second chute 120 may further include a cover member 124, a moving member 125, and an elongate shrinking member 126.

The body member 121 may be formed in the shape of a rectangular plate. The body member 121 is formed to extend in the longitudinal direction (or front-back direction). Accordingly, the body member 121 has a predetermined area, and the upper surface may form a path through which the raw material moves, or the raw material may be loaded on the upper surface. At least a portion of the lower surface of the body member 121 may be in sliding contact with the upper surface of the bottom member 111. Therefore, the body member 121 can move back and forth on the bottom member 111. [

The cover member 124 may be formed in a plate shape. The cover member 124 is formed longer than the body member 121 in the vertical direction. Accordingly, the cover member 124 may be formed to protrude upward from the body member 121. The cover member 124 may be connected to the rear end of the body member 121. That is, the cross section where the body member 121 and the cover member 124 are connected may be formed in an L shape. Therefore, the rear portion of the body member 121 can be clogged by the rear wall member 113.

The shifting member 125 serves to support the body member 121 so as to be able to move back and forth. The moving member 125 is fixed to the lower portion of the body member 121 and is installed on the rail 114 so as to be movable along the extension direction of the rail 114. When the movable member 125 moves along the rail 114, the body member 121 advances. When the movable member 125 moves back along the rail 114, the body member 121 can also move backward.

For example, the moving member 125 may include one or a plurality of the number of the rails 114, and may be formed in a ring shape so as to surround the rails 114. Therefore, even if vibration occurs in the first chute 110, it is possible to prevent the second chute 120 from being separated from the first chute 110. However, the structure and shape of the movable member 125 are not limited to this, and the movable member 125 may not be provided unless the rail 114 is provided.

The guide member 122 may form a side wall of the second chute 120. The guide member 122 guides the raw material loaded on the body member 121 to move along the extending direction of the body member 121. The guide member 122 may be formed in a plate shape. The guide member 122 is formed to extend in the front-rear direction and has a longer length in the vertical direction than the body member 121. Accordingly, the guide member 122 may be formed in a shape protruding upward from the body member 121. The pair of guide members 122 may be disposed on both sides of the body member 121, respectively. Therefore, the body member 121, the guide member 122, and the cover member 124 can form an internal space in which the raw material can be loaded, and the upper and the front surfaces of the second chute 120 can be opened .

Further, the guide member 122 is installed such that at least a portion thereof can be brought into contact with or detached from the body member 121. [ That is, the outlet width of the raw material formed by the guide member 122 can be adjusted while increasing or decreasing. Alternatively, at least a part of the space between the guide member 122 and the body member 121 can be opened or closed. For example, the front end can be rotated about the rear end of the guide member 122. [

The maximum distance at which the front ends of the pair of guide members 122 can be spaced apart from each other can be equal to or greater than the width of the first chute 110 and the minimum distance at which the front ends of the pair of guide members 122 can be spaced from each other Or less than the width of the first chute 110. When the guide member 122 rotates its front end toward the body member 121, the distance between the guide members 122 can be reduced, and the distance between the guide members 122 can be reduced to less than the width of the first chute 110 The first chute 110 can be stably inserted into the first chute 110. When the front ends of the guide members 122 are rotated toward the outside of the body member 121, the spacing distance between the guide members 122 can be increased and the spacing distance can be increased up to more than the width of the first chute 110 The raw material can be smoothly discharged into the second chute 120.

When the front end of the guide member 122 rotates toward the body member 121, the gap between the guide member 122 and the body member 121 can be closed. Conversely, when the front end of the guide member 122 rotates toward the outside of the body member 121, the gap between the guide member 122 and the body member 121 can be opened. Therefore, even if the raw materials discharged to the front end of the second chute 120 are caught, the front end of the guide member 122 and the front end of the body member 121 are opened, and the raw material can be discharged smoothly.

In addition, the width of the portion where the raw material is discharged in the second chute 120 can be adjusted while the guide member 122 rotates. Accordingly, when the raw material is discharged, the space between the front ends of the guide members 122 is widened, so that the width of the portion where the raw material is discharged is widened, and the raw material can be discharged smoothly. After the raw material is discharged, the space between the front ends of the guide members 122 is narrowed, so that the width of the portion where the raw material is discharged is narrowed and can be stably inserted into the first chute 110.

The connecting member 123 rotatably connects the guide member 122 to at least one of the body member 121 and the cover member 124. The connection members 123 may be provided in pairs as many as the guide members 122 are provided. The connecting member 123 may be a rotating shaft or a hinge member and may connect the rear end of the guide member 122 to the rear end of the body member 121 or the side surface of the cover member 124.

For example, the connecting member 123 may include a rotation axis extending in the vertical direction. The rear end of the guide member 122 and the cover member 124 may be partially overlapped and the rotation axis may be connected to the body member 121 through the overlapping portion of the guide member 122 and the cover member 124 have. Accordingly, the guide member 122 can rotate at the front end with respect to the rotation axis passing through the rear end portion. Therefore, the guide member 122 can be rotatably supported.

3 (a), the elongate and contractible member 126 is elongate and contractible in a direction (or a left-right direction) intersecting with the direction of movement of the raw material, and one side is connected to the side surface of the guide member 122, May be connected to the side surface of the body member 121. The elongate shrinkable member 126 serves to spread the gap between the guide member 122 and the body member 121 or to reduce the impact between the guide member 122 and the body member 121. [

For example, the body member 121 may be formed with a space into which the elongate and contractible member 126 can be inserted, and the elongate and contractible member 126 may be a spring. The guide member 122 is folded by the side wall member 112 and is in contact with the body member 121 when the second chute 120 is completely positioned in the first chute 110. [ Thus, the elongate shrinkable member 126 is compressed, and the space between the guide member 122 and the body member 121 is closed so that the raw material can be stably loaded.

The guide member 122 can move to the outside of the side wall member 112 when the second chute 120 advances and protrudes outside the first chute 110. Therefore, the elongated shrinkable member 126 is stretched so that the gap between the guide member 122 and the body member 121 can be opened, and the material in the second chute 120 can be smoothly discharged. At this time, since the stretchable member 126 is stretchable, the guide member 122 can be prevented from being excessively stretched.

In addition, when the second chute 120 is retracted and retracted to the inside of the first chute, the guide member 122 that has been opened can be folded by the side wall member 112. Accordingly, the second chute 120 can be completely housed in the first chute 110 while the elongate and contractible member 126 is contracted. At this time, since the elongate shrinkable member 126 has an elastic force, the guide member 122 can be prevented from colliding with the body member 121 while colliding with the guide member 122, thereby preventing an impact from occurring. That is, the stretchable member 126 can absorb the impact. Thus, breakage of the body member 121 and the guide member 122 can be suppressed or prevented.

3 (b), the second chute 120 may include a driving member 127 instead of the elongate and contractible member 126. The driving member 127 serves to adjust the distance between the front end of the body member 121 and the front end of the guide member 122. For example, the driving member 127 may be a cylinder, and the rod portion of the driving member 127 may move in a direction (or a left-right direction) intersecting the moving direction of the raw material. One side of the driving member 127 may be connected to the body member 121, and the rod portion may be connected to the guide member 122.

For example, the body member 121 is formed with a space into which the driving member 127 can be inserted, and the rod portion of the driving member 127 can move from the body member 121 to the outside. When the rod portion of the driving member 127 moves to the outside of the body member 121, the front end portion of the body member 121 and the front end portion of the guide member 122 can be opened. Conversely, when the rod portion of the driving member 127 moves to the inside of the body member 121, the body member 121, the front end portion, and the front end portion of the guide member 122 can be closed. When the second chute 110 advances to the outside of the first chute 110, the rod portion of the driving member 127 is moved to the outside of the body member 121 and the second chute 110 moves to the outside of the first chute 110, The rod portion of the driving member 127 can be moved to the inside of the body member 121 when the backward movement is performed inward.

FIG. 4 is a view showing a connection structure between a first suit and a second suit according to an embodiment of the present invention, and FIG. 5 is a view showing a connection structure between a first suit and a second suit according to another embodiment of the present invention .

The departure prevention portion may be installed in at least one of the first chute 110 and the second chute 120 so as to limit the distance that the second chute 120 moves outside the first chute 110. The second chute 120 is prevented from colliding with the electric path or the like when the second chute 120 moves to the outside of the first chute 110 to prevent the first chute 110 from moving too much, It can be prevented that it is completely released to the outside. Accordingly, the second chute 120 can maintain the state connected to the first chute 110, and can control the operation of the second chute 120 while adjusting the inclination of the first chute 110. For example, as shown in Fig. 4, the departure prevention portion may include a stopper installed in the first chute 110 to limit the movement of the movable member 125. Fig.

A stopper (not shown) may be installed on the rail 114 of the first chute 110. Thus, the moving member 125 moves along the rail 114 and is blocked by the stopper so that the movement can be restricted. Therefore, by changing the position of the stopper on the rail 114, the distance by which the moving member 125 can move on the rail 114 can be made longer or shorter.

Alternatively, as shown in FIG. 5, the release preventing part may include an elastic member 131 which is stretchable and contractible in the moving direction of the raw material, one end of which is connected to the second chute 120, and the other end of which is connected to the first chute. For example, the elastic member 131 may be a spring that can be stretched or contracted in the anteroposterior direction.

The front end of the elastic member 131 may be connected to the rear surface of the cover member 124 of the second chute 120 and the rear end may be connected to the front surface of the rear wall member 113 of the first chute 110. Accordingly, when the second chute 120 advances to the outside of the first chute 110, the elastic member 131 is extended and the second chute 120 can advance. Then, when the elastic member 131 is extended to the maximum, the length of the elastic member 131 does not further increase, so that the second chute 120 connected to the elastic member 131 is stopped. Therefore, the second chute 120 can move only by a length that the elastic member 131 can be stretched. When the second chute 120 is retracted into the first chute 110, the elastic member 131 is contracted.

At this time, when the elastic member 131 is provided, the first chute 110 may not be provided with a rail. That is, since the movement of the second chute 120 can be limited only by the elastic member 131, it is not necessary to provide a rail or a stopper. However, the present invention is not limited thereto, and if various combinations are possible among the embodiments, movement of the second chute 120 can be restricted in various ways.

As described above, it is possible to suppress or prevent the raw material supply device 100 from being caught by the raw material supply device 100 without applying any additional shock. Thus, it is possible to prevent the chute from being damaged due to vibration or impact applied to the raw material supply device 100, and excessively adjust the inclination of the raw material supply device 100 to cause a fall of the raw material supply device 100 . Therefore, it is possible to prevent a safety accident by the material supply device 100, and the life span of the material supply device 100 can be extended, so that maintenance and repair of the equipment can be facilitated.

6 is a view showing the operation of the raw material supply apparatus according to the embodiment of the present invention. Hereinafter, the operation of charging the scrap iron into the converter by the raw material supply apparatus according to the embodiment of the present invention will be described.

The main hook 21 of the ceiling crane and the auxiliary hook 22 are hooked to the main hook 115 and the auxiliary hook 116 of the first chute 110, respectively. At this time, the second chute 120 is completely housed in the first chute 110, and the second chute 120 is placed in the first chute 110 at any time before, during, and after the ceiling crane is hooked to the first chute 110 120). ≪ / RTI >

Then, the first chute 110 can be lifted with the ceiling crane while maintaining the horizontal state of the first chute 110. The operation of the ceiling crane is controlled to move the first chute 110 to the position of the converter 10 as shown in FIG. 6 (a). Thus, the second chute 120 in the first chute 110 is also moved, so that it is possible to prepare for loading the scrap iron loaded in the inside of the converter 10.

6 (b), when the bobbin hook 22 is lifted upward while the main hook 21 is stopped, the front end of the first chute 110 is moved toward the inside of the converter 10 1 chute 110 can be inclined. Therefore, the scrap iron loaded on the second chute 120 can be charged into the converter 10 while the second chute 120 is also inclined.

Also, the second chute 120 can be advanced toward the inside of the converter 10 by the inclination formed by the first chute 110. That is, the second chute 120 can advance by its own weight. Accordingly, the scrap iron loaded in the second chute 120 can be easily discharged to the converter 10 by the force of the second chute 120 advancing.

The second chute 120 may protrude to the outside of the first chute 110 and may extend between the front end of the body member 121 of the second chute 120 and the front end of the guide member 122, Can be. The degree to which the guide members 122 are extended (or the width between the guide members 122) is adjusted according to the degree of advancement of the second chute 120. When the second chute 120 is moved in the first chute 110, The more the guide members 122 are opened. Thus, the body member 121 and the guide member 122 can be opened. If the space between the body member 121 and the guide member 122 is opened, the width of the outlet of the second chute 120 can be widened. Therefore, even if the scrap metals in the second chute 120 are discharged and hung together at the front end of the second chute 120, the scrap metal can be smoothly discharged into the converter 10 by widening the discharge port.

Further, between the guide member 122 and the body member 121 can be opened while the gap between the guide members 122 is opened. Accordingly, a part of the scrap iron loaded in the second chute 120 can be discharged through the space between the guide member 122 and the body member 121. Therefore, the scrap metal can be smoothly discharged into the converter 10 without being clogged.

6 (c), when the scrap metal loaded in the second chute 120 is completely charged into the converter 10, the main hook hook 21 can be raised upward have. Thus, the first chute 110 can be inclined while the rear end of the first chute 110 is positioned higher than the front end. Since the second chute 120 is supported by the first chute 110, the position of the rear end portion of the first chute 110 may be higher than the position of the front end portion. Accordingly, the second chute 120 can be backwardly moved into the first chute 110 along its inclination by its own weight.

The guide member 122 can contact the side wall member 112 of the first chute 110 when the second chute 120 is retracted. Thus, the guide member 122 can be folded and inserted between the side wall members 112. The guide members 122 of the second chute 120 may be completely folded and positioned in the first chute 110 when the second chute 120 is completely stored in the first chute 110. [

Then, when the main hook of the ceiling crane and the auxiliary hook of the ceiling crane are positioned at the same height, the first chute 110 and the second chute 120 can be supported in a horizontal state. The process of moving the first chute 110 with the ceiling crane to load the scrap iron into the second chute 120 and charging the scrap iron into the converter 10 can be performed again.

Since the raw material loaded in the raw material supply device 100 can be easily discharged, it is possible to suppress or prevent the raw material supply device 100 from being clogged. Therefore, since the raw material can be easily supplied to the equipment for treating the raw material, the efficiency of the process using the raw material can be improved.

Further, it is possible to suppress or prevent the raw material supply device 100 from being caught by the raw material supply device 100 without applying any additional shock. Thus, it is possible to prevent the chute from being damaged due to vibration or impact applied to the raw material supply device 100, and excessively adjust the inclination of the raw material supply device 100 to cause a fall of the raw material supply device 100 . Therefore, it is possible to prevent a safety accident by the material supply device 100, and the life span of the material supply device 100 can be extended, so that maintenance and repair of the equipment can be facilitated.

Although the present invention has been described in detail with reference to the specific embodiments thereof, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited by the described embodiments, but should be defined by the appended claims, as well as the appended claims.

100: raw material charging device 110: first suit
112: side wall member 114: rail
120: second suit 121: body member
122: side wall member 123: connecting member
124: cover member 126: elongated member

Claims (12)

A raw material supply device for charging a raw material into a container for processing the raw material,
A first chute capable of moving toward the container and being supported so as to be capable of tilt adjustment; And
And a second chute capable of controlling the width of the portion where the raw material is discharged according to the degree of back and forth, the second chute being capable of storing the raw material in the first chute and being adjustable in accordance with the inclination of the first chute in the first chute, And a raw material supply device. delete The method according to claim 1,
The second chute may include:
A body member for forming a path through which the raw material moves on the upper surface;
A guide member covering at least one portion of the body member and having one end in contact with or detachable from the body member; And
And a connecting member rotatably connecting the other end of the guide member to the body member. The method of claim 3,
Wherein the guide members are disposed on both sides of the body member,
Wherein a maximum distance at which one ends of the pair of guide members can be separated from each other is equal to or greater than a width of the first chute. The method of claim 3,
Wherein the second chute is capable of elongating and contracting in a direction intersecting with the direction of movement of the raw material and further includes an elongate shrinking member having one end connected to one end of the guide member and the other end connected to the body member. The method of claim 3,
Wherein the second chute further comprises a driving member capable of adjusting an interval between the body member and one end of the guide member. The method of claim 3,
And a rail extended from the first chute in the longitudinal direction of the body member,
Wherein the second chute is movably connected along an extension direction of the rail and is fixed to the body member. The method of claim 7,
Further comprising a departure prevention portion provided on at least one of the first chute and the second chute so as to limit the distance that the second chute moves outside the first chute. The method of claim 8,
Wherein the release preventing portion includes an elastic member capable of elongating and contracting in a moving direction of the raw material and having one end connected to the second chute and the other end connected to the first chute. The method of claim 8,
Wherein the departure prevention portion includes a stopper installed in the first chute to restrict movement of the moving member. The method according to any one of claims 1 and 3 to 10,
Wherein the first chute includes a side wall member capable of wrapping a side of the second chute,
And a portion of the side wall member in and out of the second chute is tapered or processed to have a curvature. The method according to any one of claims 1 and 3 to 10,
Wherein the container includes a converter, and the first chute is supported by a ceiling crane.

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