KR20210051868A - Heating apparatus and heating method - Google Patents

Abstract

The present invention relates to a method of heating the inside of a container storing molten metal, which comprises: a process of generating a flame in an upper portion of the container; and a process of taking oxygen into a lower portion of the container. Therefore, according to an embodiment of the present invention, the heating device and the heating method take in the oxygen into the container through the lower portion of the container while the flame occurs in the upper portion of the container. Therein, heat inside the container circulates by a flow of the oxygen taking into the container, thereby uniformly dispersing the heat inside the container to uniformly heat the inside of the container.

Description

Heating apparatus and heating method {HEATING APPARATUS AND HEATING METHOD}

The present invention relates to a heating device and a heating method, and more particularly, to a heating device and a heating method capable of shortening the heating time of the container.

When the refining to control the concentration of the molten steel component in the converter is finished, the molten steel is fed from the converter. Then, the molten steel from the converter is taken with a ladle and then transferred to the next operation. However, while the molten steel is charged into the ladle and moved to the subsequent operation, the temperature in the ladle may decrease. Such a drop in the temperature of molten steel may cause delays in subsequent operations or product defects.

Therefore, before taking the molten steel from the converter, the ladle is heated to raise the temperature. That is, after the cover is disposed so as to face the upper opening of the ladle, the burner installed in the cover is operated, and fuel gas is supplied to the burner. Accordingly, as the fuel gas is combusted, a flame is generated under the burner, and the inside of the ladle is heated by the heat of the flame.

However, the method of heating the inside of the ladle with the heat of the flame has a problem that the inside of the ladle is heated unevenly. In addition, since heat descends from the top of the ladle, it takes a long time to heat up to the bottom of the ladle, and accordingly, there is a problem that the amount of fuel gas is excessively increased.

Korean Patent Registration KR0561064

The present invention provides a heating device and a heating method capable of shortening the heating time of the container and uniformly heating the interior of the container.

An embodiment of the present invention is a method of heating the inside of a container to take molten steel, the process of generating a flame toward the inside of the container from the top of the container; And a process of injecting oxygen into the lower portion of the container.

A process in which the flame generated from the top of the container is sprayed toward the lower side of the container; A process of injecting oxygen blown into the lower portion of the vessel toward the upper side of the vessel; And a process of circulating the gas in the container heated by the flame by the oxygen injected toward the upper side of the container.

The process of generating a flame at the top of the container may include operating a burner installed on the top of the container; And supplying the fuel gas to the burner, and in injecting oxygen into the lower portion of the container, it is preferable to inject the oxygen at a ratio of 0.03 to 0.1 of the supply amount of the fuel gas.

In injecting oxygen into the lower portion of the container, it is preferable to inject the oxygen in a ratio of 0.04 to 0.07 of the supply amount of the fuel gas.

In the process of injecting oxygen into the lower part of the container, the cover member is disposed to face the upper opening of the container so as to have a gap between the lower surface of the cover member and the upper end of the container.

Before the process of generating a flame at the top of the container, including the step of supporting the container on the support device, depending on whether the container is supported on the support device, whether or not the nozzle provided at the bottom of the container communicates Is regulated.

A heating device according to an embodiment of the present invention includes a support that is arranged to be spaced apart in one direction, and at least a part of a container to be heated is supported on each of the upper portions; A cover member movable from the upper side of the container so as to adjust the position and height in the horizontal direction; A burner installed to penetrate the cover member in an up-down direction to generate a flame in an inner direction of the container; And an oxygen transfer pipe for supplying oxygen into the container through a nozzle provided to pass through the lower part of the container.

The container includes a main body provided with a nozzle at the bottom, a protrusion protruding outwardly from an outer circumferential surface of the main body, and a gas supply pipe having at least a part installed in the protrusion, one end connected to the nozzle, and one surface of the protrusion of the container And a coupler that is installed in the support so as to be exposed to the upper surface of the support on which is supported, and operates so that the supply pipe and the oxygen transfer pipe are connected when the protrusion is supported on the upper surface of the support.

An upper portion of the support has a shape recessed inward, and a seating groove into which the protrusion can be inserted is provided, and the protrusion is supported on the bottom surface of the seating groove.

It is installed so that one surface of the coupler is exposed to the bottom surface of the seating groove.

The length of the support in the vertical direction is larger than the length between the protruding portion of the container and the lower surface of the main body.

It includes a fixing base for fixing and installing the support.

According to the heating apparatus and heating method according to an embodiment of the present invention, while generating a flame at the top of the container, oxygen is blown into the interior through the bottom of the container. At this time, heat inside the container is circulated by the moving flow of oxygen blown into the container, and thus, heat is uniformly spread inside the container, so that the inside of the container can be uniformly heated.

In addition, oxygen supplied to the container acts as an oxidizing agent that aids in combustion of the fuel gas, thereby promoting combustion of the combustion gas. Therefore, there is an effect of increasing the temperature of the flame, and thereby, the inside of the container can be heated to the target temperature at a high speed.

In addition, it is possible to reduce heat loss for heating nitrogen in the atmosphere as the rate of temperature increase inside the container increases. In addition, there is an effect of reducing the amount of fuel gas used, thereby reducing the cost due to the fuel gas.

1 and 2 are front views showing a container and a heating device according to an embodiment of the present invention
3 is a three-dimensional view showing a state in which a container is seated on a support device of a heating device according to an embodiment of the present invention.
Figure 4 is a side view showing a container and a support device according to an embodiment of the present invention and a container seated on the support device.
5 and 6 are diagrams for explaining the operation of a coupler according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in more detail with reference to the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, only the present embodiments make the disclosure of the present invention complete, and the scope of the invention to those of ordinary skill in the art It is provided to inform you. In order to describe the embodiments of the present invention, the drawings may be exaggerated, and the same reference numerals in the drawings refer to the same `limited element.

The present invention relates to a heating device and a heating method capable of improving the heating rate of a container.

1 and 2 are front views showing a container and a heating device according to an embodiment of the present invention. 3 is a three-dimensional view showing a state in which a container is seated on a support device of a heating device according to an embodiment of the present invention.

1 to 3, the heating device according to the embodiment of the present invention includes a support device 1100 (FIG. 3) for supporting a container 100 to be heated, and a container during operation of heating the inside of the container 100. A cover device that includes an oxygen supply unit 1200 for supplying oxygen to the inner and lower portions of the container 100 and a burner 1420 for generating a flame for heating the interior of the container 100, and is capable of covering the upper opening of the container 100 ( 1400).

In addition, the heating device 1000 includes an oxygen storage unit 1300 for providing oxygen to the oxygen supply unit 1200, a cover moving device 1600 for moving the cover device 1400 away from or close to the container, and a burner for generating a flame. It includes a fuel gas supply unit 1500 for supplying fuel gas to (1420).

First, the container 100, which is an object to be heated, will be described.

The container 100 has an inner space so as to accommodate the molten material therein, and has an open upper side. The container 100 according to the embodiment may be a ladle that receives molten iron or molten steel in an iron making operation.

The container 100 has an internal space, and includes a main body 110 provided with nozzles 140a and 140b capable of injecting gas at the bottom and gas supply pipes 150a and 150b supplying gas to the nozzles 140a and 140b. Includes.

In addition, the container 100 is formed to protrude outward from the outer surface of the main body 110, and the main body 110 from the lower side of the pair of locking portions 120 and the pair of locking portions 120 arranged to be symmetrical to each other. ) It is formed to protrude from the outer circumferential surface in an outward direction, and may include a protrusion 130 formed along the outer circumferential surface of the main body 110 or extending in the circumferential direction.

The main body 110 is made of a material containing refractory material so as to have heat resistance properties that are easy to treat hot molten steel. More specifically, the main body 110 may include a soft wire formed by constructing a brick including an iron skin and a refractory material forming an exterior surface on the inner surface of the iron skin.

The nozzles 140a and 140b may be formed to penetrate a portion of the bottom of the body 110 in the vertical direction. The nozzles 140a and 140b have a flow path through which gas can pass, and may be, for example, a plug type including a porous refractory material. Of course, the present invention is not limited thereto, and the nozzles 140a and 140b may be provided by inserting a pipe under the body.

The nozzles 140a and 140b may be provided as a pair, and may be provided symmetrically with respect to the center of the body 110 in the width direction or the diameter direction. More specifically, a pair of nozzles 140a and 140b may be arranged in one direction, for example, in the X-axis direction, as shown in FIGS. 1 and 2.

The pair of locking portions 120 is a means that can be fastened or connected with a means for moving the container 100. More specifically, the pair of locking portions 120 may be a means that can be fastened or caught with a hook of a crane device, which is a means for moving the container 100.

The protrusion 130 is a means for allowing the container 100 to be seated on the supporting device 1100 of the heating device 1000 to be described later. As described above, the protrusion 130 may protrude outward from the outer circumferential surface of the main body 110 and may have a shape extending along the outer circumferential surface or the circumferential direction of the main body 110.

In addition, the lower surface of the region seated on the support device 1100 in the extending direction of the protrusion 130 may have a shape that protrudes further downward compared to other regions. More specifically, the protrusion 130 protrudes outward from the outer circumferential surface of the main body 110 from the lower side of the pair of locking parts 120, and a first protrusion extending along the outer circumferential surface or in the circumferential direction The member 131 and each of the first protruding member 131 extend from a lower surface to protrude downward, and include a pair of second protruding members 132 disposed to face each other.

The gas supply pipes 150a and 150b are means for supplying gas to the nozzles 140a and 140b provided under the main body 110, and the gas supply pipes 150a and 150b have one end provided on the supports 1110a and 1110b to be described later. It may be connected to the couplers 1120a and 1120b, and the other end is connected to the nozzles 140a and 140b. The gas supply pipes 150a and 150b may be provided so that at least a portion of the gas supply pipes 150a and 150b is buried in the protrusion 130.

More specifically, some of the gas supply pipes 150a and 150b are located inside the protrusion 130, the other part is located outside the container 100, and the rest is inserted into the lower portion of the main body 110, so that the nozzles 140a, 140b ) May be connected to the structure. In other words, the gas supply pipes 150a and 150b are provided so as to be located inside the protruding part 130, and the first supply pipe provided so that one end is exposed to the lower surface of the second protruding member more specifically than the lower surface of the protruding part 130 ( 151), a second supply pipe 152 located outside the container 100, one end connected to the first supply pipe 151, and one end connected to the second supply pipe 152, and the other end connected to the nozzles 140a, 140b. It may be a configuration including a third supply pipe 153. Here, one end of the first supply pipe 151 is a portion connected to the pipe 1122 constituting the couplers 1120a and 1120b to be described later, and may be provided to have a diameter larger than that of the pipe 1122.

In addition, the gas supply pipes 150a and 150b may be provided in a pair so as to be respectively connected to a pair of nozzles 140a and 140b.

Figure 4 is a side view showing a container and a support device according to an embodiment of the present invention and a container seated on the support device. 5 and 6 are diagrams for explaining the operation of a coupler according to an embodiment of the present invention.

The heating apparatus 1000 according to an embodiment of the present invention is a device that generates a flame in the upper portion of the vessel 100 and injects oxygen from the lower portion of the vessel 100 to heat the inside of the vessel 100. Oxygen blown into the bottom of the container 100 circulates heat inside the container 100 so that the interior of the container 100 can be uniformly heated. In addition, the blown oxygen increases the temperature of the flame by promoting combustion of the fuel gas supplied to the burner 1420 to generate the flame, thereby increasing the temperature inside the container in a short time.

Hereinafter, each configuration of a heating device according to an embodiment of the present invention will be described with reference to FIGS. 1 to 6.

The support device 1100 is a device that supports the container 100 for heating or drying. The support device 1100 according to the embodiment is formed to extend in an arrangement direction (X-axis direction) of the pair of nozzles 140a and 140b, and a direction crossing the arrangement direction of the pair of nozzles 140a and 140b (Hereinafter, it is provided on any one of a pair of supports (1110a, 1110b) and a pair of supports (1110a, 1110b) arranged in a row in the Y-axis direction, and the container 100 is seated on the supports (1110a, 1110b) When configured, it includes couplers 1120a and 1120b for communicating or connecting between the gas supply pipes 150a and 150b of the container 100 and the oxygen supply unit 1200.

In addition, the support device 1100 may include a fixing rod for fixing the pair of support rods 1110a and 1110b on the floor or structure of an operation site. The fixing base is not particularly limited, and various means such as a clamping device capable of fixing each of the pair of supports 1110a and 1110b on the floor or structure of an operation site may be applied.

Hereinafter, among the pair of supports 1110a and 1110b, the support on which the coupler 1120a and 1120b is installed is referred to as a first support 1110a, and the other support is referred to as a second support 1110b.

Each of the first and second supports 1110a and 1110b extends in the arrangement direction of the pair of nozzles 140a and 140b as described above, and may have a plate shape having a predetermined height. In addition, a seating groove 1112 into which the second protruding member 132 of the container 100 may be inserted or accommodated may be provided at the upper portion of each of the first and second support 1110a and 1110b. That is, the seating groove may be provided in a shape recessed from the top of the supports 1110a and 1110b to the inside. Accordingly, the upper surface 1111 of each of the first and second supports 1110a and 1110b may have a shape having a height difference.

More specifically, the upper surface 1111 of each of the first and second supports 1110a and 1110b is a first surface 1111a parallel to the lower surface of the first protruding member 131 of the container 100, The first side (1111a) or the second side (1111b) and the first side (1111a) and parallel to the lower side of the second protruding member (132) of the container 100, the height is lower than that of the first side (1111a) It may include a third surface 1111c connecting the second surface 1111b. Here, the space partitioned by the second surface 1111b and the third surface 1111c is the seating groove 1112, and the first surface 1111a corresponds to the outer surface of the seating groove 1112.

As shown in FIGS. 3 and 4, the first and second supports 1110a and 1110b have their lower part fixed on the floor or structure of the operation site, and the protrusion 130 of the container 100 is seated at the upper part. , Is supported. That is, the lower surface of the first protruding member 131 of the container 100 is seated on the first surface 1111a of the upper surfaces of the supports 1110a and 1110b, and the second surface of the container 100 is placed in the seating groove 1112. The protruding member 132 is inserted, and the lower surface of the second protruding member 132 is seated on the bottom surface of the mounting groove 1112, that is, the second surface 1111b. Accordingly, the protrusion 130 of the container 100 is supported by the support device in a form that is mounted on the first and second supports 1110a and 1110b.

The seating structure as described above can be controlled by adjusting at least one of the depth of the seating groove 1112 and the vertical length (or the protruding length) of the second protruding member 132.

When the protrusion 130 of the container 100 is mounted on the first and second supports 1110a and 1110b, the bottom surface of the container 100 is the lower part of the first and second supports 1110a and 1110b. It should be separated from the floor or structure of the fixedly installed operation site. In other words, the bottom surface of the container 100 is supported on the support device 1100 so as to float. To this end, the vertical length, that is, the height of the first and second supports 1110a and 1110b is provided to be larger than the length between the protrusion 130 of the container 100 and the lower surface of the container 100. More specifically, the length between the first surface 1111a and the lower surface of the upper surfaces of the supports 1110a and 1110b is the length between the lower surface of the first protruding member 131 of the container 100 and the lower surface of the main body 110 It is prepared to be longer than that.

In this way, to be mounted or mounted on the first and second supports 1110a and 1110b so that the bottom surface of the container 100 is floating, the container 100 is mounted on the first and second supports 1110a and 1110b. When this is done, the couplers 1120a and 1120b provided on the first support 1110a are operated by the load applied to the support 1110a and 1110b from the container 100.

The oxygen supply unit 1200 is a means for supplying oxygen to the nozzles 140a and 140b of the container 100, and one end is connected to the oxygen storage unit 1300 and the other end is connected to the nozzles 140a and 140b. As a more specific example, the oxygen supply unit 1200 includes a pair of oxygen transfer pipes 1210a and 1210b respectively installed in the first support 1110a and connected to a pair of couplers 1120a and 1120b, and a pair of oxygen. It includes a connection pipe 1220 for connecting the transfer pipes 1210a and 1210b to the oxygen storage unit 1300, respectively. That is, the pair of oxygen transfer pipes 1210a and 1210b may have a shape branched from the connection pipe 1220.

The couplers 1120a and 1120b are provided inside the first support 1110a, and communicate or connect the first supply pipe 151 provided on the protrusion 130 of the container 100 and the oxygen transfer pipes 1210a and 1210b.

5 and 6, the couplers 1120a and 1120b according to the embodiment are the first to be located at the bottom of the seating groove 1112 of the first support 1110a, that is, at the lower side of the second surface 1111b. The body 1121 installed inside the support 1110a, a part is positioned to be accommodated in the body 1121, one end is connected to the oxygen transfer pipes 1210a, 1210b, and the other end is the body 1121 and the second side ( 1111b) is installed to surround the outer circumferential surface of the pipe 1122 and the pipe 1122 formed to protrude outward, the moving body 1123 and one end connected to the movable body 1123 and the other end is the lower part of the body 1121 It is connected to and includes a spring having an elastic force and a restoring force so that the moving body 1123 can descend and rise.

Hereinafter, the operation of the coupler will be described with reference to FIGS. 5 and 6.

When the protrusion 130 of the container 100 is in a state before being seated on the first support 1110a, the moving body 1123 of the couplers 1120a and 1120b is It is a state protruding upward from the bottom surface (the second surface 1111b).

Thereafter, as shown in FIG. 6, the second protruding member 132 of the protruding portion 130 of the container 100 is inserted to be accommodated in the seating groove 1112 provided in the first support 1110a, and the second protruding member 132 is brought into contact with the moving body 1123 of the couplers 1120a and 1120b, and the load is transmitted to the moving body 1123. Accordingly, the moving body 1123 of the couplers 1120a and 1120b descends downward, and at this time, the moving body 1123 is lowered so as not to protrude toward the bottom surface of the seating groove 1112.

In this way, when the second protruding member 132 of the container 100 is inserted into the seating groove 1112 so that the second protruding member 132 is pressing the moving body 1123, a coupler as shown in FIG. (1120a, 1120b) The other end of the pipe 1122 is inserted into the inside of one end of the first supply pipe 151. Accordingly, the first supply pipe 151 provided on the protrusion 130 of the container 100 and the pipe 1122 of the couplers 1120a and 1120b communicate with each other. Accordingly, oxygen provided from the oxygen transfer pipes 1210a and 1210b is supplied to the first supply pipe 151 through the pipe 1122 of the couplers 1120a and 1120b. Thereafter, oxygen is supplied to the nozzles 140a and 140b through the second supply pipe 152 and the third supply pipe 153.

In this way, when oxygen is blown into the nozzles 140a and 140b, it is blown at a ratio of 0.03 to 0.1, preferably 0.04 to 0.07 of the supply amount of the fuel gas.

On the other hand, for example, when the oxygen injection amount is less than 0.03 of the fuel gas supply amount, the effect of uniform heating inside the container by oxygen and promoting combustion of the fuel gas is insignificant. In addition, when the oxygen injection amount exceeds 1.0 of the fuel gas supply amount, the combustion of the fuel gas occurs excessively, and the temperature of the flame rises at an excessively fast rate, and there is a risk of explosion. In addition, if the temperature of the flame is too high, the refractory material constituting the container may be damaged.

The couplers 1120a and 1120b are not limited to the above-described example, and when the protrusion 130 of the container 100 is seated on the first support 1110a, the first supply pipe 151 provided on the protrusion 130 and the The pipe 1122 of the couplers 1120a and 1120b may be provided in various forms to be connected or communicated with each other.

The cover device 1400 includes a cover member 1410 capable of covering an upper opening of the container 100 and a burner 1420 mounted on the cover member 1410. In addition, the cover device 1400 is mounted on an upper portion of the cover member 1410 and includes a fastening part (hereinafter, a first fastening part 1430) that is fastened or connected to the cover moving device 1600 to be described later.

The cover member 1410 may be provided in a shape corresponding to the shape of the cross-section of the body 110, and may be provided to be equal to or larger than the cross-sectional area of the body 110.

The burner 1420 is for heating the container 100 by generating a flame, and may be a means including a spark plug (not shown) for igniting by high-pressure discharge by power applied from the outside. When a high voltage is applied to the spark plug of the burner 1420 and fuel gas is supplied into the burner 1420 from the fuel gas supply unit 1500 to be described later, a flame is generated as the fuel gas is burned.

The fuel gas supply unit 1500 includes a fuel gas storage unit 1510 in which fuel gas to be supplied to the burner 1420 is stored, and a fuel gas transfer pipe having one end connected to the fuel gas storage unit 1510 and the other end connected to the burner 1420 (1520).

In the fuel gas storage unit 1510, at least one of a gas (hereinafter referred to as COG gas) and LNG gas generated in a coke oven for heat-treating or drying coke may be stored as the fuel gas.

The fuel gas transfer pipe 1520 is a means for supplying fuel gas from the fuel gas storage unit 1510 to the burner, and may be a flexible pipe, that is, a hose.

The cover moving device 1600 is a means for moving the cover device 1400 close to the container 100 to face the upper opening of the container 100 or moving away from the container 100.

The cover moving device 1600 according to the embodiment has one end connected to the cover member 1410, a shaft 1610 capable of horizontal movement and height adjustment, a drive unit 1620 for moving the shaft 1610, and a shaft 1610. ) And fastened to the first fastening part 1430 installed on the cover member 1410 (hereinafter, the second fastening part 1630).

The shaft 1610 according to the embodiment has a bar shape extending in one direction, and may be inclined downward in the direction in which the support device 1100 is located.

The driving unit 1620 may be a means for moving the shaft 1610 through an unwinding and winding operation of the wire 1623. More specifically, the drive unit 1620 is a drive body 1622 providing a moving driving force to the shaft 1610, one end is connected to the drive body 1622 and the other end is connected to the shaft 1610, the drive body 1622 A wire 1623 that can be wound or unwound, a housing 1621 having an internal space to accommodate at least a portion of the shaft 1610, and a housing 1621 installed to be located at the rear of the shaft 1610 inside the housing 1621 and rotated Includes possible pulley 1624.

The driving body 1622 is a means for winding the wire 1623 or unwinding the wound wire 1623 by a rotation operation, and may be, for example, a winch capable of rotating operation. In addition, a motor for applying rotational power may be connected to the driving body 1622.

A plurality of pulleys 1624 may be provided, and a plurality of pulleys 1624 may be arranged in one direction inside the housing 1621 corresponding to the rear of the shaft 1610.

As described above, the wire 1623 has one end connected to the driving body 1622 and the other end connected to the shaft 1610. Among the wires 1623, the area between the driving body 1622 and the shaft 1610 is the housing 1621. ) It may be inserted through the inside and connected to the shaft 1610. In addition, the wire 1623 inserted into the housing 1621 may be supported on a plurality of pulleys 1624 installed in the housing 1621.

Hereinafter, the movement of the cover device 1400 by the driving body 1622 according to an embodiment of the present invention will be described with reference to FIGS. 1 and 2. At this time, a state in which the container 100 is supported on the support device 1100 will be described as an example.

When the drive body 1622 is rotated, for example, in a counterclockwise direction, the wire 1623 is wound around the drive body 1622. When the wire 1623 is wound around the driving body 1622, the shaft 1610 is pulled in the direction in which the driving body 1622 is located or in the direction opposite to the container 100 (reverse), and thus the shaft 1610 The connected cover device 1400 moves backward in a direction away from the container.

In addition, since the shaft 1610 is arranged to incline downward in the direction of the container 100, when the shaft 1610 is pulled in a direction away from the container 100, the other end of the shaft 1610 connected to the cover device 1400 The height is higher than before it was pulled. Accordingly, when the shaft 1610 is pulled away from the container 100, the cover device 1400 not only moves in the horizontal direction of the container 100 to move away, but also increases its height.

Conversely, when the driving body 1622 is rotated in the opposite direction, for example, in a clockwise direction, the wire 1623 wound around the driving body 1622 is released. The shaft 1610 advances in a direction opposite to the driving body 1622 or in the direction in which the container 100 is located by the operation of unwinding the wire 1623 from the driving body 1622, and thus the cover connected to the shaft 1610 The device 1400 moves forward so that it is close to the container 100.

In this way, when the shaft 1610 moves forward closer to the container 100, the height of the other end of the shaft 1610 connected to the cover device 1400 is lower than before the forward movement. Accordingly, when the shaft 1610 moves forward so as to be close to the container 100, the cover device 1400 moves not only in the horizontal direction of the container 100, but also moves downward, so that the height thereof is lowered.

The cover moving device 1600 is not limited to the above-described example, and various means capable of moving the cover device 1400 to or away from the container 100 may be applied.

Hereinafter, a method of heating a container using a heating device according to an embodiment of the present invention will be described with reference to FIGS. 1 to 6. Here, the container 100 may be a ladle to take molten steel that is poured out from the converter.

First, the empty container 100 is mounted on the support device 1100. That is, the protrusion 130 of the container 100 is mounted on the first and second supports 1110a and 1110b. More specifically, the lower surface of the first protruding member 131 of the container 100 is seated on the first surface 1111a of the upper surfaces of each of the first and second supports 1110a and 1110b, and the seating groove 1112 The lower surface of the second protruding member 132 is mounted on the bottom surface of, that is, the second surface 1111b. Accordingly, the main body 110 of the container 100 is seated between the first support 1110a and the second support 1110b. And at this time, the bottom surface of the container 100 is seated so that the lower portions of the first and second supports 1110a and 1110b are spaced apart from the floor or structure of an operation site where the lower portions of the first and second supports 1110a and 1110b are fixedly installed.

When the container is mounted on the first and second supports 1100a and 1100b so that the second protruding member 132 is inserted into the mounting groove 1112, the couplers 1120a and 1120b are operated, and thus the second protruding member The first supply pipe 151 provided at 132 and the pipe 1122 of the couplers 1120a and 1120b are interconnected or communicated with each other.

Then, when the container 100 is seated on the first and second supports 1110a and 1110b, first, as shown in FIG. 1, a flame is generated while the cover device 1400 is placed in a standby position. Here, the standby position of the cover device 1400 may be a position in which the center of the cover member 1410 in the width direction from the upper side of the container 100 does not coincide with the center of the width direction of the container 100. More specifically, at least 1/2 of the area of the cross section of the cover member 1410 may be located outside the container 100.

When the cover device 1400 is positioned in the standby position, the burner 1420 is operated, and at least one of a fuel gas such as COG and LNG gas is supplied to the burner 1420. In addition, when high-pressure discharge occurs by supplying power to the burner, the fuel gas is burned, thereby generating a flame.

When a flame is generated, the cover moving device 1600 is operated to move the cover device 1400 to be close to the container 100. That is, by rotating the drive body 1622 clockwise, the wire 1623 wound around the drive body 1622 is released. Accordingly, the shaft 1610 advances in a direction opposite to the driving body 1622 or in the direction in which the container 100 is located, and accordingly, the direction in which the cover device 1400 connected to the shaft 1610 approaches the container 100 Go to. At this time, since the shaft 1610 is disposed so as to incline downward in the direction of the container 100, when the shaft 1610 moves forward so as to be close to the container 100, the height of the other end of the shaft 1610 compared to before moving forward. Is lowered. Therefore, when the shaft 1610 moves forward so as to be close to the container 100, the cover device 1400 connected to the shaft 1610 not only approaches the container 100 in the horizontal direction, but also lowers its height. The vertical separation distance from the container 100 is reduced.

In this way, the cover moving device 1600 is operated to move the cover device 1400 to be close to the container 100 so that the cover member 1410 faces the upper opening of the container 100 as shown in FIG. 2. Move. More specifically, the cover device 1400 is moved so that the center of the cover member 1410 in the width direction is concentric with the center of the container 100 in the width direction.

In addition, in order to make the cover member 1410 face the upper opening of the container 100, a predetermined gap is provided between the cover member 1410 and the upper end of the container 100. That is, the height is adjusted so that the lower surface of the cover member 1410 does not contact the upper end of the container 100 and is spaced apart from each other. This is to prevent an operation accident from occurring due to an increase in pressure inside the container 100 by the flame and oxygen supplied thereafter.

While the cover member 1410 is moved to face the upper opening of the container 100, the fuel gas is continuously supplied to the burner 1420, and flames are continuously generated from the burner 1420.

When the cover member 1410 is positioned to face the upper opening of the container 100 as shown in FIG. 2, the flame generated from the burner 1420 installed in the cover member 1410 is sprayed downward in the container, and thus the container ( 100) The inside is heated. And, in the embodiment, when the cover member 1410 is positioned to face the upper opening of the container 100, oxygen, more specifically, begins to inject pure oxygen into the nozzles 140a and 140b provided in the lower portion of the container 100. do.

Here, the container is not completely closed by the cover member, and is disposed so as to have a predetermined gap with the container, so that the atmosphere can be introduced into the container. Further, since the fuel gas is supplied to the burner to burn the fuel gas, a gaseous reactant is generated by the combustion reaction of the combustion gas. Accordingly, heating the inside of the container by the flame may mean that the gas generated by combustion of the atmosphere, combustion gas, oxygen, and combustion gas introduced into the container is heated.

Oxygen blown through the nozzles 140a and 140b is injected upwards in the container 100. At this time, heat in the container 100 is circulated by the moving flow of the supplied oxygen. In other words, oxygen injected toward the upper side of the container circulates the gas in the container heated by the flame. In addition, heat is uniformly spread inside the container 100 by the circulation of heat by oxygen, so that the inside of the container 100 can be uniformly heated.

In addition, as described above, the fuel gas is burned to generate a flame. At this time, oxygen supplied to the container 100 acts as an oxidizing agent that helps combustion of the fuel gas, thereby promoting combustion of the combustion gas. Accordingly, there is an effect of increasing the temperature of the flame, and thus, the inside of the container 100 can be heated to a target temperature at a high speed.

In addition, conventionally, when the combustion gas supplied to the burner 1420 is combusted, oxygen in the atmosphere acts as an oxidizing agent to aid combustion of the combustion gas. However, the atmosphere contains nitrogen as well as oxygen, and nitrogen cannot function as an oxidizing agent, but rather, heat loss occurs in which nitrogen in the atmosphere is unnecessarily heated by the heat of the flame.

However, in the embodiment, by injecting pure oxygen into the container 100 to promote combustion of the combustion gas, the inside of the container 100 may be heated or heated at a high speed to the target temperature. Accordingly, heat loss for heating nitrogen in the atmosphere can be reduced. In addition, as the inside of the container 100 is heated at a high speed, there is an effect of reducing the amount of fuel gas used, thereby reducing the cost due to the fuel gas.

100: container 110: main body
130: protrusion 131: first protrusion member
132: second protruding members 140a, 140b: nozzle
1000: heating device 1100: support device
1100a, 1100b: support 1120a, 1120b: coupler
1200: oxygen supply unit 1410: cover member
1420: burner 1500: fuel supply

Claims (12)

As a method of heating the inside of a container to take molten steel,
Generating a flame from the top of the container toward the inside of the container; And
Injecting oxygen into the lower portion of the container;
Heating method comprising a. The method according to claim 1,
A process in which the flame generated from the top of the container is sprayed toward the lower side of the container;
A process of injecting oxygen blown into the lower portion of the vessel toward the upper side of the vessel; And
A process of circulating the gas in the container heated by the flame by the oxygen injected toward the upper side of the container;
Heating method comprising a. The method according to claim 1,
The process of generating a flame at the top of the container,
Operating a burner installed on the top of the container; And
Supplying fuel gas to the burner;
Including,
In blowing oxygen into the lower portion of the container, a heating method in which the oxygen is injected in a ratio of 0.03 to 0.1 of the supply amount of the fuel gas. The method of claim 3,
In blowing oxygen into the lower portion of the container, a heating method in which the oxygen is blown in a ratio of 0.04 to 0.07 of the supply amount of the fuel gas. The method according to claim 1,
In the process of blowing oxygen into the lower portion of the container,
A heating method in which the cover member is disposed so as to face the upper opening of the container so as to have a gap between the lower surface of the cover member and the upper end of the container. The method according to claim 1,
Before the process of generating a flame at the top of the container, including the process of supporting the container on the support device,
A heating method in which whether or not a nozzle provided at a lower portion of the container communicates is controlled according to whether or not the container is supported on the support device. A support that is arranged to be spaced apart in one direction, and at least a part of the container to be heated is supported on each of the upper portions;
A cover member movable from the upper side of the container so as to adjust the position and height in the horizontal direction;
A burner installed to penetrate the cover member in an up-down direction to generate a flame in an inner direction of the container; And
An oxygen transfer pipe for supplying oxygen into the container through a nozzle provided to pass through the lower part of the container;
Heating device comprising a. The method of claim 7,
The container includes a main body provided with a nozzle at the lower portion, a protrusion protruding outwardly from an outer circumferential surface of the main body, and a gas supply pipe having at least a portion installed in the protrusion, and one end connected to the nozzle,
A coupler is installed in the support so that one surface is exposed to the upper surface of the support on which the protrusion of the container is supported, and the supply pipe and the oxygen transfer pipe are connected to each other when the protrusion is supported on the upper surface of the support. Heating device. The method of claim 8,
The upper portion of the support has a shape recessed inward, and a seating groove into which the protrusion can be inserted is provided,
Heating device in which the protrusion is supported on the bottom surface of the seating groove. The method of claim 9,
A heating device installed such that one surface of the coupler is exposed to the bottom surface of the seating groove. The method of claim 8,
The length of the support in the vertical direction is larger than the length between the protruding portion of the container and the lower surface of the main body. The method of claim 7,
Heating device comprising a fixing base for fixing and installing the support.

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