JPH01249248A - Belt type metal strip continuous casting machine - Google Patents

Abstract

PURPOSE:To sharply reduce wears of pushing/sliding member and cooling water sealing member and to shorten maintenance time required to change the members by applying stainless coat on a belt surface of a sliding surface between a short side mold pushing block and the belt. CONSTITUTION:In cooling box 6 arranged at back face side of the belt 4 for cooling the belt 4 and cooling and solidifying molten metal, the cooling water is flowed at almost the same static pressure as the static pressure of the molten metal. The multiple pushing blocks 8 pushing the belt 4 in the cooling box 6 is arranged and these are composed of the sliding member 10, such as solid carbon, the fluororubber series sealing member 11 for sealing cooling water and a spring 9 for pushing these. In the range of L or LL, where the pushing block 8 slides at the back side of the belt 4, the stainless protecting coat 13 is applied. This projecting coat may be stuck with plating or graphite paper, etc. By this method, the wear of the member is reduced and the maintenance time is shortened and the productivity can be improved.

Description

DETAILED DESCRIPTION OF THE INVENTION Field of Industrial Application The present invention is directed to a
The present invention relates to a belt-type continuous casting machine that continuously produces metal ribbon from molten metal poured into a sump.

Conventional technology Recently, a series of technologies have been developed to directly produce metal thin strips with a thickness of approximately several tens of mm in shape close to the final shape from molten metal such as molten steel.
Casting machines are attracting attention. When this method is used, the conventional multi-step rolling process can be omitted, thereby simplifying the process and equipment. Furthermore, since the process of heating the material to the processing temperature between each process is unnecessary due to the quality of the wood, energy saving effects can also be expected.

One such continuous casting machine is a belt type machine.

FIG. 1 shows IΔ showing M@ of a twin-belt continuous casting machine among these belt-type continuous casting machines.

In the continuous casting machine shown in FIG. 1, the nozzle 2 also supplies the molten metal in the tundish l to the casting space.

As shown in FIG. 2, this casting space is constructed by partitioning the opposite sides of the gap between a pair of belts 4 made of heat-resistant material such as steel, which are run by a pulley 3, with a short-side mold 5. is formed by. The molten metal supplied to this casting space is cooled by a cooling box 6 to which cooling water is supplied, and is carried out as a metal ribbon 7. At this time, the belt 4
If there is a gap of 0.1 to 0.2 m between the short-side mold 5 and the short-side mold 5, molten metal will often be inserted into the gap, causing flashing.

Therefore, it is necessary to press the belt 4 against the short side mold 5 to achieve close contact, and as shown in FIG. 3(a), a pressing block 8 is pressed against the belt by a spring 9.

In addition, since the belt and the pressing block 8 slide on each other, a sliding member 10 is attached to the pressing block 8 in order to reduce sliding resistance.
A sealing material 11 is attached to prevent cooling water for cooling the belt 4 from leaking to both sides.

The sliding range in the ttJ direction of the belt 4 that slides on the pressing block 8 is the normal range, but in order to change the casting process as shown in FIG. Belt [L when movable in 11 directions
(Reference technology, Japanese Patent Application Laid-Open No. 61-99541).

Problems to be Solved by the Invention As described above, when the short-side mold 5 is pressed by the pressing block 8 via the belt 4, especially since the belt, the sliding member 10, and the cooling water sealing member IT are sliding, this problem occurs. Wear of sliding surfaces is unavoidable. Furthermore, belts are generally made of thin steel plates, and are susceptible to rust due to constant exposure to cooling water or repeated heating and drying, and are easily damaged by rough sliding.

As a result, the sliding member 10 and the sealing member 11 suffer from increased wear, which increases the frequency of complicated maintenance, greatly reducing productivity and increasing maintenance costs.

One way to solve this problem is to apply lubricant to the sliding surface of the belt 4 and the pressing block 8 in order to reduce the sliding resistance, but if too much lubricant is supplied, it can cause contamination of the cooling water. It is difficult to say that this is an appropriate method because the lubricant may adhere to the cooling water flow path and cause a low F of the cooling capacity.

The present invention has been made in order to reduce wear and tear on the sliding surface of the pressing block 8 (sliding member 10, sealing member ti) of the belt 4 and the sliding surface of the pressing blow 2 8 with the belt 4. The object of the present invention is to provide a belt type continuous casting machine that can withstand long-term use and does not have problems such as those caused by lubricant application.

Means for Solving the Problems The present invention injects molten metal into a pool formed by a pair of endless belts running opposite each other in a predetermined direction and a short mold, and cools and solidifies the metal to form a thin metal strip. In the belt-type continuous casting machine to be manufactured, a rust-proof protective coating is applied to the sliding surface of the belt on the back side of the belt that is pressed by a pressing block along the short side mold in order to make the short side mold and belt come into close contact with each other. This is a belt-type continuous metal ribbon casting machine that is characterized by the following features:

Hereinafter, the features of the present invention will be specifically explained using examples with reference to the drawings.

In the example shown in FIG. 3, in order to cool the belt 4 and solidify the molten metal during cooling, a cooling surface 6 provided on the back side of the belt 4 is provided with cooling water at a static pressure approximately equal to the static pressure of the molten metal. is flowing.

This cooling surface 6 is provided with a large number of pressing blocks 8 for pressing the belt 4, and the pressing blocks 8 have sliding parts such as solid carbon, for example, in order to contact and press the belt. It is composed of a sealing member 11 made of, for example, fluorine rubber for sealing, and a spring 9 for pressing them with a constant force. An anti-rust protective liquid 18!13 is applied to the back side of the belt 4 on which the pressing block 8 slides, or in the range LL.

The state of stress in the thickness direction in the cross section of the belt 4 to which this protective coating is applied will be explained with reference to FIG.

(A) in Figure 4(a) shows the stress distribution when belts of the required length are connected to form a loop, and almost no stress is generated.
Figures (a) and (B) show that when the belt 4 is tensioned while being wound along the pulley, a tensile stress σ is generated on the molten metal side (outside) and a compressive stress σ1 is generated on the cooling water side (inside). do.

Here, σr = EX (1/R)X (t/2) where E: Young's modulus, R: Boole radius, t: belt thickness.

(C) in FIG. 4(a) shows a state in which tension (D) is further applied to the belt to give stress σ2. As a result, as the belt rotates, stress within the belt is reduced at the pulley (C).
Stress shape (D) in the straight part! It keeps coming out. Therefore, the protective coating applied to the back side of the belt must withstand this repeated stress and not easily peel off due to the difference in thermal expansion coefficient with the belt.
In addition, it is necessary to select a material that minimizes wear and tear on the sliding member 1O and the sealing material 11 provided on the pressing block.

When the belt is made of iron, metals that satisfy such conditions as a protective coating are preferably Cr or Ni, and plating with good surface smoothness is preferred as a means for forming the coating.

Table 1 shows a comparison between the case where the belt is made of iron and the protective coating is formed with C plating and the case where it is formed with Ni plating.

From this table, it can be said that Cr plating with high hardness is superior in terms of abrasion resistance, but it is disadvantageous in terms of adhesion to the belt (Fe) for the following reasons, and it is easy to crack and peel, so it cannot be said that it is particularly suitable. It has difficult characteristics.

Figure 4(b) is a diagram qualitatively showing a comparison of the stress distribution in the thickness direction in the case of Cr and Ni (or Fe-Ni) as two-piece materials, and (a) shows the stress distribution on the outside of the belt and Inside temperature gradient, (a) is elongation rate, (tsu) is compressive stress, (1)
indicates tensile stress.

Here, since the coefficient of linear expansion is Cr<longitude, e~1, the thermal expansion coefficient is △1Ee>ΔtCr and ΔtN1, and Δtl:eX
J'Fe 〉Δtcrx le crΔtp, x gpe
: ΔtN, XJ” Ni.

However, Δ1. e=belt average temperature rise ΔjCr=temperature of chrome-plated portion−hiR ΔENi ”Temperature of nickel-plated portion.

Therefore, (A) and (T) in the same figure show the heat +1i tension due to the temperature gradient when no shear force acts between the belt and the coating. (5) and (6) indicate the belt and coating material. It shows the stress that occurs when the two are in close contact.

Furthermore, (7) and (8) show states in which tension σ2 is applied to the belt. It can be seen from this that Cr is subjected to greater stress than Xi.

Further, as shown in Table 1, Xi has excellent adhesive strength between the belt and the coating. It can be seen from this that Ni plating is superior as a coating. There is no rust compared to when only the belt is used.

From the comparisons in 1-12 below, by adopting Ni plating for the belt of the sliding portion of the pressing block, the wear of the pressing layered member can be significantly reduced.

In addition to plating, the protective coating may include Ni,
A thin film of Cr or a metal having properties similar to these metals may be bonded, or the material may be powdered and applied by thermal spraying or a binder.

Alternatively, it may be formed by adhering a material other than metal, such as graphite paper. The type of these protective coatings is appropriately selected depending on the material of the block that slides on the belt Z surface, the material of the belt, etc.

As described in detail, in the present invention, by applying a rust-proof coating to the sliding surface of the belt between the short-side mold pressing block and the belt, the pressing layer member and the cooling water seal can be sealed. Wear of parts is significantly reduced, and the maintenance time required to replace those parts can be shortened, contributing to improved productivity.

[Brief explanation of the drawing]

FIG. 1 is an explanatory side view showing an outline of a twin-belt continuous casting equipment in an embodiment of the present invention, FIG. 2 is a partially cutaway perspective view,
Figure 3 is a cross-sectional diagram Ij taken along the line ``x-x'' in Figure 1, and Figure 4 is an explanatory diagram of the temperature distribution in the thickness direction and the stress distribution in the thickness direction of the belt and the protective coating. 1-φO methane issue, 21111-nozzle, 3e@
Fist pulley, 4, @ medium belt, 511, short side mold, 6.
...Cooling box, 7 races...Metal thin strip, 8...ψ press block, 9...Spring, 10...Sliding member,! ! Eyelids - sealing material, ■2 Good luck Q loading and unloading, 13... film, 14-
-・Driving device.

Claims (1)

[Claims] Molten metal is injected into a pool formed by a pair of endless belts running opposite each other in a predetermined direction and a short-side mold, and then cooled and
In a belt-type continuous casting machine that solidifies and produces metal thin strips, in order to bring the short-side mold into close contact with the belt, the belt is pressed by a pressing block along the short-side casting on the sliding surface of the back of the belt with the pressing block. A belt-type continuous metal ribbon casting machine featuring a rust-resistant protective coating.