KR102249972B1 - Heat reflective panel assembly and equipment for maintaining heat of rolling line including the same - Google Patents

Abstract

Disclosed is a reflective panel assembly and a rolling heat insulation facility including the same. A reflective panel assembly according to an embodiment of the present invention includes: a reflective panel covering an outside of a transferred heating material; A frame frame having a coupling groove installed along the edge of the reflective panel, receiving and supporting the edge of the reflective panel, and having a size to allow expansion and contraction by the heat of the reflective panel; A plurality of fastening members fastened to pass through the frame and the frame of the reflective panel entering the coupling groove; And a plurality of elongated holes formed in the reflective panel so that the fastening member passes therethrough and elongated in the stretching direction of the reflective panel.

Description

Reflective panel assembly and rolling heat insulation equipment including the same {HEAT REFLECTIVE PANEL ASSEMBLY AND EQUIPMENT FOR MAINTAINING HEAT OF ROLLING LINE INCLUDING THE SAME}

The present invention relates to a reflective panel assembly capable of preventing deformation of a reflective panel due to heat, and a rolling heat insulation facility including the same.

The material for rolling is heated to approximately 1300 ~ 1400°C in a heating furnace and then transferred to the rough rolling process. As the heated material goes through the rough rolling process, the temperature drops to 900 ~ 1100℃ due to the influence of cooling water or the atmosphere, and as the length increases, a temperature deviation in the longitudinal direction occurs.

The material that has gone through the rough rolling process is transferred to the finish rolling process along a transfer line (roller table) of approximately 100 meters. In this process, an additional temperature drop occurs due to air cooling of the material. In the finish rolling process, the temperature difference between the front end and the rear end of the material becomes larger based on the time of rolling. In the finish rolling process, the time difference between the time when the front end is rolled and the time when the rear end is rolled reaches tens of seconds, and when the rear end of the material is rolled, the temperature drops by approximately 50°C compared to the temperature when the front end is rolled. If the temperature at the rear end of the material decreases excessively at the time of rolling, the material of the rolled product may become uneven or twist.

In the rolling transfer line, in order to prevent the temperature drop of the heating material during the transfer process, an insulation panel or a reflective panel may be installed to cover the outside of the heating material to keep it warm. The heat preservation facility heats the heating material by absorbing the radiant energy of the heating material and then re-radiating or reflecting the radiant energy generated from the heating material.

However, the heat insulating panel or the reflective panel of such a heat preservation facility has a problem of being easily deformed because the heated material is heated by high heat while passing through the heat preservation facility and stretched and cooled and contracted after passing through the material. If used for a long time, the insulation panel or the reflective panel could be wrinkled or stretched and deformed into sagging shape, resulting in loss of function.

An aspect of the present invention is to provide a reflective panel assembly capable of preventing the reflective panel from being deformed by heat by allowing expansion and contraction of the reflective panel by heat, and a rolling heat insulation facility including the same.

According to an aspect of the present invention, a reflective panel covering the outside of the heating material to be transferred; An rim frame provided along the rim of the reflective panel, receiving and supporting the rim of the reflective panel, and having a coupling groove having a size to allow expansion and contraction by the row of the reflective panel; A plurality of fastening members fastened so as to penetrate the frame and the frame of the reflective panel entering the coupling groove; And a plurality of elongated holes formed in the reflective panel so that the fastening member passes therethrough and elongated in a stretch direction of the reflective panel.

According to another aspect of the present invention, a reflective panel covering the outside of the heating material to be transferred; An rim frame provided along the rim of the reflective panel, receiving and supporting the rim of the reflective panel, and having a coupling groove having a size to allow expansion and contraction by the row of the reflective panel; A plurality of fastening members fastened so as to penetrate the frame and the frame of the reflective panel entering the coupling groove; And a plurality of elongated holes formed in the rim frame so that the fastening member passes therethrough and elongated in the stretching direction of the reflective panel.

The reflective panel is provided as a square panel, and the frame frame includes a plurality of frame elements coupled to each side of the reflective panel, and the plurality of frame elements are stepped coupling portions provided at both ends to engage and couple with adjacent frame elements. Each can be included.

The plurality of fastening members may be installed in the middle between both ends of the two frame elements arranged in parallel with each other.

According to another aspect of the present invention, it includes a heat insulation cover for covering the outside of the material to be transferred along the transfer line to heat, wherein the heat insulation cover includes an upper frame provided on the transfer line; And a plurality of the above-described reflective panel assembly to be installed in succession under the upper frame may be provided.

The upper frame includes a plurality of horizontal frames extending in an arc shape in the width direction of the transfer line and spaced apart from each other in the length direction of the transfer line; And a plurality of vertical frames extending in the longitudinal direction of the transfer line and connecting the plurality of horizontal frames.

The reflective panel assembly may be installed in a lattice-shaped groove formed by the horizontal frame and the vertical frame, respectively.

In the reflective panel assembly according to an exemplary embodiment of the present invention, when the reflective panel is expanded or contracted by heat, the coupling groove of the frame frame allows the reflective panel to be expanded and contracted, so that deformation such as bending may be prevented in the reflective panel.

1 is a perspective view showing a rolling facility to which a heat retention facility is applied according to an embodiment of the present invention.
2 is an exploded perspective view of a heat insulation cover of a heat insulation facility to which a reflective panel assembly is applied according to an embodiment of the present invention.
3 is a perspective view of a reflective panel assembly according to an embodiment of the present invention.
4 is an exploded perspective view of a reflective panel assembly according to an embodiment of the present invention.
5 is a cross-sectional view taken along line V-V' of FIG. 3.
6 is a plan view of a reflective panel assembly according to an exemplary embodiment of the present invention, showing a state in which the reflective panel is contracted.
7 is a plan view of a reflective panel assembly according to an exemplary embodiment of the present invention, and shows an extended state of the reflective panel.
8 is a cross-sectional view showing a modified example of a fastening member and a long hole of a reflective panel assembly according to an embodiment of the present invention.
9 is a perspective view showing a modified example of a fastening member and a long hole of a reflective panel assembly according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. The following examples are presented in order to sufficiently convey the spirit of the present invention to those of ordinary skill in the art to which the present invention pertains, and may be embodied in other forms without being limited thereto. In the drawings, in order to clarify the present invention, the illustration of parts not related to the description may be omitted, and the size of the components may be slightly exaggerated to help understanding.

1 shows a rolling facility to which a heat retention facility is applied according to an embodiment of the present invention. Referring to FIG. 1, the rolling equipment includes a heating furnace 10 for heating a material for rolling, a rough rolling mill 30 for rolling the material 20 heated in the heating furnace 10, and a material 20 subjected to rough rolling. ) To the finish rolling mill 40, the material 20 is transferred from the heating furnace 10 to the coarse mill 30, and the transfer line 50 transfers from the coarse mill 30 to the finish mill 40, roller Table).

The heat retention equipment 100 may be installed in the transfer line 50 between the roughing mill 30 and the finishing mill 40. The heat retention facility 100 covers the outside of the material 20 transferred to the finish rolling machine 40 through the rough rolling machine 30 to prevent excessive drop in the temperature of the material 20 during the transfer process. This heat retention facility 100 reduces the temperature drop of the material 20 entering the finishing mill 40 so that the material 20 can be rolled on the rear end side to be satisfactorily performed in the finishing mill 40.

1 shows a case where the heat insulation equipment 100 is installed on the transfer line 50 between the roughing mill 30 and the finishing mill 40, but the installation location of the heat insulation equipment 100 is not limited thereto. The heat retention facility 100 may be installed at another location of the rolling facility for the purpose of preventing a temperature drop of the material 20.

1 and 2, the heat insulation equipment 100 is installed on the upper part of the transfer line 50, and covers the outside of the material 20 transferred along the transfer line 50 to heat insulation cover 101 And, it may include an opening and closing device 102 that can lift the heat insulation cover 101 and open the heat insulation cover 101 when necessary.

As shown in FIG. 2, the heat insulation cover 101 is on both sides of the upper cover part 110 so as to cover both sides of the upper cover part 110, the material 20 covering the upper part of the material 20. A first driving part that adjusts the spread of the first side cover part 120 by rotating the first side cover part 120, the second side cover part 130, and the first side cover part 120 respectively rotatably connected. (140), it may include a second driving portion 150 for adjusting the spread of the second side cover portion 130 by rotating the second side cover portion 130.

Each of the upper cover portion 110 and the first and second side cover portions 120 and 130 is provided in a circular arc shape. Therefore, the heat insulation cover 101 may form a tunnel having an arc-shaped cross-sectional structure by combining the upper cover portion 110, the first side cover portion 120, and the second side cover portion 130 to each other. The tunnel-type heat insulation cover 101 may increase the heat insulation effect of the material 20 by smoothly re-reflecting the radiant energy radiated from the material 20 toward the material 20.

The first side cover part 120 and the second side cover part 130 can be spread to both sides when a wide material is transferred to widen the heat retention area, and when a narrow material is transferred, the first side cover part 120 and the second side cover part 130 are rotated to fold inward. The heat retention area can be narrowed. That is, it is possible to increase the heat insulation effect by changing the shape of the heat insulation cover 101 according to the width of the material to be transferred. When the first and second side cover parts 120 and 130 are folded, the upper cover part 110 rises, and when the first and second side cover parts 120 and 130 are unfolded, the upper cover part 110 may descend.

The first and second driving parts 140 and 150 have one side connected to the upper cover part 110 and the other side connected to the first or second side cover parts 120 and 130, and the first or second side cover part by expansion and contraction. It may be a hydraulic cylinder that adjusts the angle by rotating (120, 130). In this embodiment, a first driving part 140 and a second driving part 150 for adjusting the angle by driving the first side cover part 120 and the second side cover part 130 respectively are provided, but the first side cover part 120 and the second side cover part 130 are respectively driven. The unit 120 and the second side cover unit 130 may be operated simultaneously by one driving unit. For example, power is transmitted from one driving unit installed on the upper cover unit 110 to the first and second side cover units 120 and 130 so that the first and second side cover units 120 and 130 rotate at the same time to be folded or unfolded. can do.

The upper cover part 110 is installed to be continuous in the width direction and the length direction to the upper frame provided by the combination of a plurality of horizontal frames 111 and a plurality of vertical frames 112, and the lower of the upper frame. ) It includes a plurality of reflective panel assemblies 200 covering the upper part.

The plurality of horizontal frames 111 may extend in an arc shape in the width direction of the transfer line 50 and may be disposed to be spaced apart from each other in the longitudinal direction (transfer direction of the material) of the transfer line 50. The plurality of vertical frames 112 extend long in the longitudinal direction of the transfer line 50 and connect a plurality of horizontal frames 111. The plurality of reflective panel assemblies 200 may be respectively installed under the lattice-shaped groove 113 formed by the combination of the horizontal frame 111 and the vertical frame 112. Each of the plurality of reflective panel assemblies 200 may cover the upper side of the transfer line 50 by fastening the rim portions to the binding members 115 installed on the horizontal frame 111, respectively.

The first side cover part 120 and the second side cover part 130 are arc-shaped side frames 121 and 131 rotatably connected to the end of the horizontal frame 111 of the upper cover part 110, and the side frames 121 and 131. ) Each of the side reflective panels 170 coupled to the lower portion may be included.

3 is a perspective view of a reflective panel assembly installed on the upper cover part 110, and FIG. 4 is an exploded perspective view of the reflective panel assembly of FIG. 3.

3 and 4, the reflective panel assembly 200 includes a reflective panel 210, an edge frame 220, a plurality of fastening members 230, and a plurality of long holes 240.

The reflective panel 210 is provided in a rectangular panel shape and may cover the outside of the material 20 transferred in a heated state to heat the material 20. The reflective panel 210 may be made of a material such as aluminum, aluminum alloy, zinc oxide, stainless steel, etc. that can reflect most of the radiant energy due to a very low emissivity of radiant energy.

The rim frame 220 is installed along the rim of the reflective panel 210. As shown in FIG. 4, the frame frame 220 includes a plurality of frame elements 221a, 221b, 221c, and 221d that are coupled to each side of the rectangular reflective panel 210, respectively. Both ends of the four frame elements 221a, 221b, 221c, and 221d provided in a bar shape are combined with adjacent frame elements to form a rectangular frame 220.

Each of the frame elements 221a, 221b, 221c, and 221d includes a coupling groove 222 that accommodates and supports the edge of the reflective panel 210 as shown in FIGS. 4 and 5. The edge portion of the reflective panel 210 is inserted into the coupling groove 222 to be coupled.

The coupling groove 222 is formed long in the longitudinal direction of the frame elements 221a, 221b, 221c, and 221d so that one side of the reflective panel 210 can enter and be supported, and when the reflective panel 210 is extended by heat It is formed to a depth that allows the extension of the reflective panel 210. That is, the coupling groove 222 is provided in a size that allows expansion and contraction by heat of the reflective panel.

As shown in FIG. 5, the depth d2 of the coupling groove 222 is the depth d1 of the portion where the edge of the reflective panel 210 enters the coupling groove 222 while the reflective panel 210 is contracted. ) Is formed deeper than that. Accordingly, after the reflective panel 210 is coupled, an extra space (Δd) capable of allowing the reflective panel 210 to be elongated is formed.

Each of the frame elements 221a, 221b, 221c, and 221d includes stepped coupling portions 223 formed in a shape corresponding to each other at both ends so that adjacent frame elements can be engaged and coupled to each other, as shown in FIG. 4. Both ends of the frame elements 221a, 221b, 221c, and 221d are rigidly connected without shaking by being fastened with a plurality of fixing screws 225 in a state in which the step-like coupling portion 223 is engaged and coupled with an adjacent frame element.

A plurality of fastening members 230, as shown in Figs. 3 and 4, so as to penetrate the rim portion and the rim frame 220 of the reflective panel 210 that has entered the coupling groove 222 of the rim frame 220. It is fastened, and the reflective panel 210 has a long hole 240 formed long in the extension direction of the reflective panel 210 at a position where the fastening member 230 is fastened. Specifically, the plurality of fastening members 230 are respectively coupled to opposite sides of the reflective panel 210 and may be installed at an intermediate portion between both ends of the two frame elements 221a and 221c disposed in parallel with each other. The plurality of elongated holes 240 are provided on the edge of the reflective panel 210 at positions corresponding thereto.

In such a reflective panel assembly 200, when the reflective panel 210 is stretched or contracted by heat, the coupling groove 222 of the frame frame 220 allows the reflective panel 210 to be stretched and contracted. It can prevent deformation.

As shown in FIG. 6, the reflective panel 210 is guided by the fastening member 230 in the contracted state, so that the four rims form an extra space (Δd) from the inside of the coupling groove 222. Are spaced apart and may be located at the center of the border frame 220. On the contrary, as shown in FIG. 7, when the reflective panel 210 is elongated by heat, elongation is guided by the fastening member 230, so that the four rims may be elongated so as to equally enter the inside of the coupling groove 222. Therefore, even if the reflective panel 210 repeats contraction and elongation, the reflective panel 210 may maintain a flat state without bending.

8 and 9 show a long hole 241 formed in the frame element 221c of the frame element 221c in which the fastening member 231 is fixed to the edge of the reflective panel 210 and is elongated in the stretching direction of the reflective panel 210. ) Is provided. Even in this case, when the reflective panel 210 is stretched, since the fastening member 231 moves in the stretch direction along the long hole 241 of the frame frame 220, it can be stretched and contracted in the same manner as in FIGS. 6 and 7. Therefore, even if the reflective panel 210 expands and contracts by heat, it is possible to prevent the reflective panel 210 from being curved.

The reflective panel assembly 200 may be mounted on the upper cover portion 110 of the heat insulating cover 101 in a state in which the frame 220 is assembled on the edge of the reflective panel 210 as in the example of FIG. 3. As shown in FIG. 2, a plurality of reflective panel assemblies 200 are continuously mounted on the upper frame of the upper cover part 110 in the width direction and the length direction, so that the material transferred in a heated state along the transfer line 50 ( 20) can be covered and kept warm.

Since the reflective panel 210 of each reflective panel assembly 200 has a low emissivity and high reflectance of radiant energy, most of the radiant energy radiated from the heated material 20 is quickly reflected toward the material, thereby the heat retention effect of the material 20 Can increase.

10: heating furnace, 20: material,
30: rough rolling mill, 40: finishing mill,
50: transfer line, 100: heat retention equipment,
101: heat insulation cover, 102: opening and closing device,
110: upper cover part, 111: horizontal frame,
112: vertical frame, 200: reflective panel assembly,
210: reflective panel, 220: frame frame,
221a, 221b, 221c, 221d: frame element, 222: coupling groove,
223: stepped coupling portion, 230: fastening member,
240: longevity.

Claims (6)

A reflective panel covering the outside of the transferred heating material to reflect radiant energy radiated from the heating material;
An rim frame installed along the rim of the reflective panel, receiving and supporting the rim of the reflective panel, and having a coupling groove in which the rim of the reflective panel is fitted, provided with a size that allows expansion and contraction by the row of the reflective panel;
A plurality of fastening members fastened so as to penetrate the frame and the frame of the reflective panel entering the coupling groove; And
A reflective panel assembly comprising a; a plurality of elongated holes formed in the reflective panel so that the fastening member passes therethrough and elongated in a stretch direction of the reflective panel. A reflective panel covering the outside of the transferred heating material to reflect radiant energy radiated from the heating material;
An rim frame installed along the rim of the reflective panel, receiving and supporting the rim of the reflective panel, and having a coupling groove in which the rim of the reflective panel is fitted, provided with a size that allows expansion and contraction by the row of the reflective panel;
A plurality of fastening members fastened so as to penetrate the frame and the frame of the reflective panel entering the coupling groove; And
A reflective panel assembly comprising a; a plurality of elongated holes formed in the frame frame so that the fastening member passes therethrough and elongated in the expansion/contraction direction of the reflective panel. The method according to claim 1 or 2,
The reflective panel is provided as a square panel,
The frame frame includes a plurality of frame elements coupled to each side of the reflective panel,
Each of the plurality of frame elements includes stepped coupling portions provided at both ends to engage and couple with adjacent frame elements. It includes a heat insulation cover that covers the outside of the material transferred along the transfer line to heat it,
The heat insulation cover,
An upper frame provided above the transfer line; And
Rolling heat insulation equipment comprising a reflective panel assembly of claim 1 or claim 2 as a plurality of consecutively installed under the upper frame. The method of claim 4,
The upper frame,
A plurality of horizontal frames extending in an arc shape in the width direction of the transfer line and spaced apart from each other in the longitudinal direction of the transfer line; And
Rolling heat insulation equipment comprising a; a plurality of vertical frames extending in the longitudinal direction of the transfer line and connecting the plurality of horizontal frames. The method of claim 5,
The reflective panel assembly is installed in each of the lattice-shaped grooves formed by the horizontal frame and the vertical frame.

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