KR200301639Y1 - Deformation prevention structure of heat insulation heat insulation board - Google Patents

Abstract

The present invention is installed between the ROUGHING MILL and FINISHING MILL process of a steel mill's hot rolling mill to prevent the slab from cooling, and the heat-resistant cover heat-resistant plate minimizes heat deformation and cracks caused by high temperature. The present invention relates to a deformation preventing structure of a heat-resistant cover heat resistant plate, which is installed at upper and lower portions of a plurality of transfer rolls installed on a transfer table for moving a bar to prevent the bar from being cooled while moving a rolled bar from a rough mill to a finishing mill. In the heat retaining cover, the bending direction is perpendicular to the heat-resistant plate on the circumferential surface of the heat-resistant plate in order to alleviate the thermal stress generated in the heat-resistant plate that is installed on one surface of the heat cover and directly exposed to the heat generated from the bar To make a plurality of slit grooves at equal intervals on the parts to minimize tearing of the plate due to crack prevention Thermal cover structure.

Description

Deformation prevention structure of heat insulation heat insulation board

The present invention is installed between the ROUGHING MILL and FINISHING MILL process of a steel mill's hot rolling mill to prevent the slab from cooling. It relates to a deformation preventing structure of the heat insulation cover heat insulating plate.

In general, as shown in FIG. 1, in a hot rolling mill, a slab (SLAB) of about 200 mm thickness is heated to a high temperature of about 1100 ° C. in a heating furnace 1 to undergo a rough rolling and finishing rolling, etc. To prepare a hot rolled coil having.

The slab (S) heated in the heating furnace (1) is first rolled into a plate (hereinafter referred to as 'Bar') (3) having a thickness of 40-50mm around 1050 ℃ while passing through the rough mill (2) The conveying table 5 is moved by the transfer table 5 to the rolling mill 4, and in this process, the temperature of the bar 3 drops by about 60-70 ° C while air-cooling.

If the temperature of the slab (S) drops a lot before reaching the finishing mill (4) it may be hot rolled at a temperature lower than the hot rolling temperature, thereby affecting the surface quality of the final product hot rolled coil to heat the slab (S) The cost of heating energy is excessively consumed.

Therefore, if the temperature drop (Drop) during the transfer of the slab (S) is not large, the initial heating temperature of the slab (S) can be lowered by that much, not only can reduce the manufacturing cost by saving heating energy, but also reduce the deterioration of equipment. And since it is possible to extend the service life of the slab (S) in order to minimize the temperature drop during the transfer of the use of the thermal cover is common.

Conventionally, as shown in FIG. 2, the heat retaining cover 6 is disposed on the upper and lower portions of the bar 3 to cover the upper and lower portions of the bar 3 between the plurality of feed rolls 5a provided to move the bar 3. The top cover is about 880mm × 730mm × 100mm size and about 180 pieces are attached, and the bottom cover is about 244 pieces of 552mm × 366mm × 100mm size.

Inside the heat insulating cover 6, a heat insulating material 8 is built-in, and a heat resistant plate 9 exposed to a heated bar 3 is installed on one surface thereof, and the heat insulating material 8 and the heat resistant cover 9 are provided. It is fixed to the heat retaining cover 6 by a fixing bolt (7), and the coupling portion of the heat retaining cover (6) and the heat-resistant plate (9) bends the circumferential surface of the heat-resistant plate (9) as shown in FIG. It is supposed to be passed down.

The heat retaining cover 6 is installed on the upper and lower surfaces of the bar 3 guided to the feed roll 5a to prevent the bar 3 from cooling and the heat-resistant plate 9 installed on the heat retaining cover 6. The temperature of) rises up to 750 ℃ as the bar (3) proceeds and falls to around 450 ℃ as the bar (3) exits. Since it is made repeatedly, the heat-resistant plate 9 is subjected to enormous thermal fatigue and site-specific stress.

Therefore, the cracks are generated from the edges that receive a lot of thermal stress and are torn as the process progresses, which shortens the service life of the heat-resistant plates. Therefore, nickel-based alloys are widely used as commercially available heat-resistant plates. In the same harsh conditions, the material itself is difficult to withstand.

Therefore, even if a new heat-resistant plate is inserted, deformation occurs within a few weeks, and it is not tolerated thermal stress and is torn due to crack generation from the edge of the heat-resistant plate. There was a need to fix the heat-resistant plate material so as not to be separated from the thermal cover.

The present invention is designed to solve the above problems to provide a deformation preventing structure of the heat insulation cover heat resistant plate that can minimize the thermal deformation caused by high temperature by forming a plurality of slits on the edge of the heat resistant plate installed in close proximity to the high temperature bar. The purpose is.

The present invention for achieving the above object is in the thermal cover installed in the upper and lower portions between the plurality of transfer rolls installed in the transfer table for moving the bar to prevent the bar is cooled while moving the rolled bar in the rough mill to the finishing mill And a plurality of slit grooves are formed at equal intervals on the bent surface bent on the circumferential surface of the heat-resistant plate in order to alleviate the thermal stress generated in the heat-resistant plate directly exposed to the heat generated from the bar is installed on one surface of the thermal cover By bending the edge of the heat-resistant plate vertically to be caught on the heat cover, the structure is designed to minimize the deformation of the plate even in the expansion and contraction of the heat-resistant plate due to heating and cooling.

1 is a perspective view showing a general rolling process,

2 is a cross-sectional view showing a state where a conventional heat cover is installed;

3 is an enlarged cross-sectional view 'A' part of FIG.

4 is a perspective view showing a heat-resistant plate according to the present invention,

5 is a cross-sectional view of the circumferential surface of the heat insulating cover heat insulating plate according to the present invention,

Figure 6 is a cross-sectional view showing a heat retaining cover is installed a heat-resistant plate according to the present invention.

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

1: heating furnace 2: roughing mill

3: bar 4: finishing mill

5: Transfer Table 5a: Feed Roll

6: heat insulation cover 8: heat insulation

9: heat-resistant plate 9a: bending surface

20: slit groove

Hereinafter, the present invention will be described in detail with reference to FIGS. 4 to 6.

Figure 4 is a perspective view showing a heat-resistant plate according to the present invention, Figure 5 is a cross-sectional view of the heat insulation cover heat insulating plate edge according to the present invention, Figure 6 is a cross-sectional view showing a heat insulation cover is installed heat-resistant plate according to the present invention, Inside the heat insulating cover 6 of the present invention, a heat insulating material 8 is built-in, and a heat resistant plate 9 exposed to a heated bar 3 is installed on one surface of the heat insulating material 8 and the heat resistant plate 9. The fixing bolt 7 is fixed to the heat retaining cover 6.

On the other hand, the circumference of the heat-resistant plate 9 is bent inwardly to give a firm fixing force when combined with the heat retaining cover 9, and the plurality of slit grooves 20 are formed at equal intervals in the bent surface 9a. And they are coupled to maintain close contact force as shown in FIG. 6.

Therefore, in order to prevent the bar 3 guided to the feed roll 5a from cooling, the heat cover 6 is installed at the upper and lower portions of the bar 3 so that the heat generated from the bar 3 is retained. Since the heat-resistant plate 9 and the heat insulating material (8) of (6) is heated, it is possible to minimize the cooling of the bar (3).

When the heat retaining cover 6 is heated by the heat generated by the bar 3, the heat retaining material 8 embedded in the heat retaining cover 6 is heated, as well as the temperature of the heat-resistant plate 9 installed in close proximity to the bar 3. The change is most severe.

This temperature change causes thermal stress in the heat resistant plate 9, which is relaxed by a plurality of slit grooves 20 formed on the circumferential surface of the heat resistant plate 9 to minimize deformation and breakage due to thermal stress. do.

On the other hand, the edge of the heat-resistant plate material is bent vertically with the heat-resistant plate 9 to be engaged with the heat retaining cover 6 can effectively prevent the edge sagging due to thermal deformation.

As described above, the present invention is generated by heating the heat-resistant plate which is installed in close proximity to the bar when the thermal cover is installed at the upper and lower portions of the bar running between the roughing mill and the finishing mill to prevent the bar from being cooled. As the thermal stress is alleviated, the service life is extended and the maintenance cost can be minimized.

Claims (1)

In order to prevent the bar 3 from cooling while moving the rolled bar 3 from the roughing mill 2 to the finishing mill 4, a plurality of transfers are provided on the transfer table 5 for moving the bar 3. In the heat retaining cover 6 provided in the upper and lower parts between the rolls 5a, A circumferential surface of the heat resistant plate 9 which is installed on one surface of the heat cover 6 and bent to alleviate thermal stress generated in the heat resistant plate 9 which is directly exposed to heat generated from the bar 3; Thermal stress due to expansion and contraction of the heat-resistant plate 9 is severely acted to prevent tearing at an unspecified site due to crack generation, a plurality of slit grooves 20 to maintain a constant depth and spacing to relieve thermal stress Deformation-resistant structure of the heat insulation cover heat-resistant plate comprising a.