KR100832427B1 - An Apparatus Keeping Temperature of Probe Nozzle - Google Patents

Abstract

The present invention completely blocks and seals the immersion nozzle (NOZZLE) 20 and the molten steel 90 in the mold 30 from the atmosphere during the initial start of the casting operation and the casting operation, and passes through the immersion nozzle 20 to the mold 30. The present invention relates to an immersion nozzle thermal insulation device capable of continuously casting by minimizing a temperature drop of injected molten steel 90 to prevent nozzle clogging and uncompleted.

The configuration of the present invention for achieving the above object, the weight 40 is the immersion nozzle 20 is coupled by the jig 50, and the central shaft 7 is located on the upper surface portion of the mold 30 The mold cover 60 is installed, the hollow shaft 6 is moved up and down about the center shaft 7 and one side is coupled to the protective cover 1, and the shaft 6 and A protective cover 1 connected to the nozzle inserting groove 2 and the flux inlet 3 and a flux supply line inserting groove formed between the protective cover 1 and the mold cover 60 and formed on one side thereof. (12) is characterized in that the auxiliary cover 11 is configured to be inserted into the flux supply line 70.

Description

An Apparatus Keeping Temperature of Probe Nozzle

1 is a perspective view of the present invention,

2 is a cutaway view of the present invention,

3 is an operation of the present invention,

4 is an installation of the present invention,

5 is a conventional casting operation diagram,

6 is an initial START operation diagram.

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

1. Cover 2. Slot for inserting nozzle

3. Flux inlet 4. Support plate

5. Gas supply hose 6. Shaft

7. Shaft for the center 8. Rest rest

9. 9a Quick Coupling 10. Floating Pin

11. Auxiliary Cover (COVER) 12. Flux Supply Line Insertion Groove

13. 13a Gas Supply Line 20. NOZZLE

30.MOLD 40.Weight

50. Jig 60. Mold Cover                 

70. Flux Supply Line 80. Flux

90. Molten steel 100. Dummy bar

110.Tundish

The present invention completely blocks and seals the immersion nozzle (NOZZLE) 20 and the molten steel 90 in the mold 30 from the atmosphere during the initial start of the casting operation and the casting operation, and passes through the immersion nozzle 20 to the mold 30. The present invention relates to an immersion nozzle thermal insulation device capable of continuously casting by minimizing a temperature drop of injected molten steel 90 to prevent nozzle clogging and uncompleted.

Injecting the molten steel 90 in the tundish 110 into the mold 30 in the continuous casting process for the purpose of preventing oxidation and improving the quality of the molten steel 90 (NOZZLE) ( 20) Assemble and use. In addition, the flux 80 is introduced into the molten steel 990 in the mold 30 to prevent oxidation of the molten steel 90 injected into the mold 30 and lubrication with the insulating copper plate.

The immersion nozzle 20 has a length of about 600 mm and has a molten steel 90 injection path in the middle portion of about 30 mm, which is used for billet production of a small section (160 × 160).

However, since the molten steel injection path of the nozzle 20 has a small diameter (30 mm) and a length of about 600 mm, it shows a very sensitive reaction to the temperature of the molten steel 90. Very bad. As a result, the continuous casting process is interrupted due to blockage and uncompleted STRAND-type nozzle 20, and serious defects due to central segregation occur, which greatly affects productivity and quality.

In order to prevent oxidation and insulation of the molten steel 90 injected into the mold 30, and to prevent fusion of the molten steel 90 and the copper plate of the mold 30, the flux 80 is introduced into the molten steel 90 in the mold 30. (Figure 5).

However, the flux 80 is scattered by the gas (Gas) ejected in the molten steel 90 in the form of fine powder or granules, which causes trouble and environmental pollution of equipment requiring precision, and protects workers. For this purpose, more than 20% of the input is lost by scattering through the use of a large fan.

Due to the problems described above, a certain amount (approximately 3000 m) of ultra-thin casts are processed by cutting scrap (SCRAP) due to the generation of pin holes due to the inflow of oxygen in the mold 30 at the initial start, and the initial molten steel 90 is injected. There are various problems, such as a high risk of burn injury and equipment damage caused by the municipal steel spatter 120.

The present invention has been made to solve the above problems, the initial start and casting operation during the immersion nozzle (NOZZLE) 20 and the molten steel 90 in the mold 30 completely blocked and sealed from the atmosphere and the immersion nozzle ( By minimizing the temperature drop of the molten steel 90 injected into the mold 30 through 20), it is possible to prevent continuous nozzle casting and blockage of nozzles, thereby contributing to productivity improvement and cost reduction, and initial START oxygen (O ₂ ) and It can prevent quality problems and burns caused by pinholes by blocking molten steel scattering 120.Blocking flux 80 prevents immersion nozzle thermostats for cost reduction and environmental pollution prevention. In providing.

The configuration of the present invention for achieving the above object, the weight 40 is the immersion nozzle 20 is coupled by the jig 50, and the central shaft 7 is located on the upper surface portion of the mold 30 The mold cover 60 is installed, the hollow shaft 6 is rotated about the center shaft 7 and one side is coupled to the protective cover 1, and the shaft 6 and A protective cover 1 connected to the nozzle inserting groove 2 and the flux inlet 3 and a flux supply line inserting groove formed between the protective cover 1 and the mold cover 60 and formed on one side thereof. (12) is characterized in that the auxiliary cover 11 is configured to be inserted into the flux supply line 70.

In addition, the hollow shaft 6 has a support 8 and an argon gas injection quick coupling 9 formed at an end thereof, and a gas supply hose for supplying gas into the protective cover 1 at the other end thereof. (5) is provided, the hollow shaft (6) is coupled to the support plate (4) connected by the protective cover (1) and the floating pin (10), the quick coupling (9) Is characterized in that it is detachable from the quick coupling (9a) of the gas supply line (13a).

Referring to the configuration and operation of the present invention as described above in more detail with reference to the accompanying drawings as follows.

As shown in Figure 1 (COVER) (1) is a rectangular iron plate, the upper part of the lower circle is open in a square model, the lower surface of the square model flux inlet (3) is installed.

Inserting groove (2) in the nozzle (LOZZLE) is engraved in a circular shape on the top of the cover (COVER) (1) and the flux inlet (3) is engraved on one side of the bottom (COVER).

Support plate (Plate) (4) is assembled to the shaft (6) is assembled by connecting the upper portion of the cover (COVER) (1) by a flow pin (PIN) (10).

The shaft 6 is a pipe model in which an inner space is formed, and is assembled at the upper end of the center shaft 7 of the triangular model, and a weight 40 and a settable 8 are fixed to the distal end.

The coupling male and female 9a is assembled to the gas supply line 13a, and the gas supply line 13a is assembled in a bending form, partly to the shaft 6, and partly to a cover of the mold 30. 60) assembled and fixed.

Auxiliary cover 11 is a square model is engraved with a square groove on the inside and the flux supply line (Line) insertion groove is engraved on one side.

As shown in Figure 4, the cover (COVER) 1 part of the present invention is inserted into the copper plate of the mold (MOLD) 30 and the shaft 6 and the central shaft (7) is the top of the mold cover 60 Install on.

When the tundish raises the tundish 110 using a lifting device before moving, the preheated immersion nozzle 20 is assembled to the tundish 110 lower nozzle, and the weight 40 is increased. To the jig (50), the immersion nozzle 20 is fixed.

When the tundish 110 moved to the casting position is lowered, the immersion nozzle NOZZLE 20 assembled in the lower portion enters the inside of the mold MOLD 30 copper plate of each strand. end))

As the tundish 110 descends, the weight 40 assembled to the jigs 50 of the respective strands transfers the load to the rest 8 of the present invention. 30) The cover (1) inserted into the copper plate slowly rises, and the coupling (9 ♀) assembled at the bottom of the shaft (6) closely adheres to the coupling (90♂) assembled to the mold cover (60). Inert gas (Ar) is supplied to the cover 1 and the inside of the copper plate. The lowering of the tundish 110 and the raising of the cover 1 are completed at the same time (FIG. 3 (b)). As such, the immersion nozzle 20 and the space between the tundish 110 and the mold 30 are sealed and initially Sealing with inert gas (Ar) at the start to remove oxygen (O ₂ ) inside the copper plate at the start to prevent the occurrence of pin hole and burn injury due to the molten steel (90) emergency, equipment damage, etc. It can be prevented.

When casting is completed and the tundish 110 is raised, the weight of the weight 40 applied to the settable 8 decreases, and the cover 1 gradually enters the inside of the copper plate of the mold 30, and the shaft 6 and The couplings 9 9a are separated and returned to their original assembled state (Fig. 3 (a) (b) and Fig. 4). Upon completion of the casting start, the above operation is repeated.

The present invention is expected to improve productivity, quality, etc. by continuous casting by preventing the center segregation, unblocked nozzle clogging by minimizing the temperature drop of the molten steel 90 is injected into the mold 30 through the immersion nozzle 20 Reduction of refractory consumption by non-improving can contribute to cost reduction.

In addition, by blocking and recycling the scattered flux 80 (the scattered flux falls into the copper plate while hitting the top of the cover), it is possible to prevent deterioration and troubles of the surrounding facilities and improve the cost environment.

Claims (4)

The immersion nozzle 20 is coupled to the weight 40 by the jig 50, A mold cover 60 located on an upper surface of the mold 30 and provided with a central shaft 7; A hollow shaft (6) rotatably moved about the center shaft (7) and one side coupled to the protective cover (1); A protective cover (1) connected to the shaft (6) and having a nozzle insertion groove (2) formed at an upper end thereof and a flux inlet (3) formed at one side of the lower end thereof; Located between the protective cover 1 and the mold cover 60, characterized in that consisting of the auxiliary cover 11, the flux supply line 70 is inserted into the flux supply line insertion groove 12 formed on one side. Immersion nozzle thermostat. The method of claim 1, The hollow shaft 6 has a support 8 and an argon gas injection quick coupling 9 formed at an end thereof, and a gas supply hose 5 for supplying gas into the protective cover 1 at the other end thereof. Immersion nozzle thermostat, characterized in that is installed. The method of claim 1, The hollow shaft 6 is an immersion nozzle warming device, characterized in that coupled to the support plate (4) connected by a protective cover (1) and the flow pin (10). The method of claim 2, The quick coupling (9) is an immersion nozzle warming device, characterized in that detachable from the quick coupling (9a) of the gas supply line (13a).

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