KR830001326B1 - Improved vertical solubility - Google Patents

Abstract

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Description

Improved vertical solubility

1 is a front elevational view of the melting furnace of the present invention.

2 is a layout view of the branch pipe at the bottom of the melting furnace

Figure 3a or the flame preservation burner of the present invention

3b turning section of burner device

The present invention relates to a device which is useful for continuously dissolving vertical pieces and burner used therein, especially copper pieces used as cathodes.

Vertical gas furnaces for dissolving metals such as copper are already known in the art. Examples of such melting furnaces are described in US Pat. Nos. 3,199,977, 3,701,517, 3,715,203, 3,788,623 and the prior art patent publications cited above.

Generally these furnaces are cylindrical and extend in the vertical direction. Metals to be dissolved, such as electrolytic copper pieces with a low oxide content, are charged into the furnace at the top. The metal falls to the bottom of the furnace, which is equipped with a number of burners that dissolve the metal by injecting hot gas into the melting chamber.

Molten metal is discharged from the furnace through outlets near the bottom for continuous supply to cracking furnaces or casting operations. The burners are usually arranged in one or two rows around the bottom of the furnace, forming a melting chamber and attached directly to the furnace walls. Each of the plurality of burners, all fueled from one source, sprays an air mixture of fuel into the dissolution chamber to produce a hot flame to dissolve the metal around each burner. Fire-resistant tunnel burners are known as devices for providing high temperature flames in furnaces. Traditionally, the draw mix type burner does not cause problems such as back fire in the feed manifold, which is a common problem with premixed burners, or the isolation of combustion sperm, ie flame from combustion. Used in the furnace.

However, the known draw mixed burners were also defective. Draw-blown burners require very high flame speeds because they must mix fuel and air properly in the tight spaces allocated within the burners. This not only produces high operational noise, but also severely adversely affects the furnace and burner refractory. If this deterioration is reached to a certain extent, the operating efficiency of the burner and the furnace is significantly deteriorated, so that readjustment is inevitable. In particular, the deterioration results in spalling slagging, abrasion, and the like. Spoiling is known to physically destroy, deform or crush refractory due to thermal, mechanical or structural factors. Slacking causes destruction of the refractory due to chemical reactions occurring at high temperatures. Abrasion exacerbates the refractory surface by the friction of solids in contact with the refractory surface. The solid may be transported in combustion gas or formed in the combustion gas.

In the most effective form of fire resistant tunnel burners, the refractory has good insulation, high heat resistance and rough internal surface texture. After the burner is ignited, the refractory is heated and combustion continues. The roughness of the refractory surface slightly disturbs the gas flow in the vicinity, thus causing a catalytic effect and consequently accelerating the combustion process. However, refractories with good insulation and rough surfaces are less resistant to the abrasion of high-speed combustion gases and are therefore faster to wear than denser and smoother refractories such as silicon carbide. Have unpredictable effects when they are not mixed properly, and when they are not uniform before being injected into the furnace, especially when the molten copper is fed to the continuous casting system at different rates, will be.

In summary, the main problem encountered in vertical melting furnaces and burner combinations so far known is metallurgical when the combination is used to dissolve electrolytic copper and to supply molten copper to continuous casting and rolling processes to produce copper rods for electrical conductors. It is not successful. Some problems are the fact that molten copper is contaminated with impurities above acceptable levels. For example, oxygen and sulfur which are easily introduced into the molten metal in the combustion process adversely affect the process of rolling the cast copper into rods. Slag and metal impurities can also enter the melt, which adversely affects the quality or conductivity of the final product.

Therefore, vertical furnaces and various types of burners are already known in the art but significant improvements are made by the present invention.

It is therefore an object of the present invention to provide an improved vertical furnace and burner structure which is suitable for continuous melting of copper and in fact avoids the disadvantages of known furnaces and burners.

Another object of the present invention is to improve the chemical composition of the product by increasing the uniformity and predictability of the process, and to make more precise control.

It is a further object of the present invention to provide an improved fire resistant tunnel burner which improves the combustion and operating efficiency of a premixed combustible gas mixture and has a relatively low operating noise during its useful life.

The vertical melting furnace and burner device of the present invention forms a burner of a matrix disposed around the lower circumference of the furnace containing the refractory, which is a main component, a branch pipe and a combustible mixture for supplying the fuel and air mixture to the burner, It consists of a mixer to adjust.

FIG. 1 shows that the upper end is open to receive the metal to be dissolved, and the lower part shows a vertically long melting furnace which is closed by forming a furnace bottom. The outer metal wall is made of a fireproofing agent such as a firebrick that can withstand high temperatures above the temperature at which copper can be dissolved, and supports and controls the inner wall constituting the cylindrical melting chamber.

The bottom of the furnace is a "V" trough formed of refractory material, and as shown in FIG. 1, the molten metal flows through the face of the trough by gravity and the tab hole 10 is positioned to discharge the molten metal. The furnace is inclined to flow a sloped gutter to the lowest point on the floor.

Eight burners are generally equidistant around the furnace with two to three rows. These are connected to the dissolution chamber through the spout 20 through both walls and dissolve the metal by direct contact with the hot gas from the new burner.

The burner is attached to its outer container by bolts 21 or by welding and other methods. Their long axes are inclined at a slight angle from the horizontal, cross the long axis centerline of the furnace, and the bottom row of burners are positioned so that their fire resistant tiles are just above the bottom of the furnace.

In this form, the hot combustion products released from the bottom row of the burner continuously clean the furnace bottom to remove solidified metal and slag.

3a shows a cross section of a flame preserving burner of the present invention. Combustible gaseous fuel and air mixture is injected into the nozzle unit 30 under pressure. The nozzle 31 transfers the mixture ignited by the spark plug 32 into the combustion chamber and prevents backfire from the supply. A circular array of holes 33 formed through the nozzle lip is connected to the cutout space 34 surrounding the nozzle end downstream and serves to preserve the flame in the nozzle. The lip 35 extending from the cut out diameter to the point where the nozzle portion is slightly larger than the diameter of the combustion chamber 36 is suitable for preserving high speed flame.

The combustion chamber 36 is preferably formed of a refractory tile in a cylindrical straight line and completely combusts the mixture of fuel and air to discharge the combustion product from the combustion chamber to contact the metal of the melting chamber. Refractory tiles promote combustion to ensure complete combustion, making the dissolution process uniform and predictable, especially when a wide range of dissolution rates are required.

Due to the fact that fuel and gas are not mixed in the burner structure, the burners of the present invention are simple in shape and produce less disturbing flames than ordinary draw mixed burners and are derived from burners for mixing fuel with air. There is no special disturbance.

The branch pipe 11 carries premixed fuel and air to the burner, with a small number of burners per branch (preferably four burners per branch pipe) arranged to prevent backfire to the air and fuel mixture. do. To increase the size of the furnace, more branches or burners need to be added in the above numerical relationship.

A mixer (not shown) is provided for each branch pipe. Preferred are known Venturi mixers, where mixing takes place when the air passes through the venturi under pressure and the fuel is injected into the air stream at low pressure in the venturi draw. The mixing ratio is known in the art and is determined by a proportional inlet or valve of the fuel and air supply lines, which are preferably connected to the flow measuring device. The most suitable method of controlling the fuel mixture is described in the applicant's application number 879,034, filed February 21, 1978 to the inventor.

In a preferred embodiment, the furnace is operated with a fuel under some reducing conditions, ie, with a stoichiometric value greater than 5-10% controlled by the mixer. Since the burner device burns out completely in the combustion chamber, the dissolution chamber atmosphere can be kept in a reduced state to avoid excessive oxygen inflow.

Claims (1)

A refractory wall surrounding the melting chamber, a plurality of burners attached to the bottom of the wall for injecting heat to the metal pieces, and an improved vertical melting furnace with an outlet at the bottom of the chamber for continuously discharging the molten metal. A plurality of burners, each comprising a plurality of burners, each comprising a fire-resistant tile combustion chamber having a cylindrical cross-section, including a flame-resistant fire-resistant tunnel burner for combusting a premixed combustible gas mixture of fuel and air. A device for supplying a mixture of fuel and air to the burner, the branch engine of which is connected to be fed to a small number of burners to prevent the burner from flashing back, and each powder for mixing the fuel and air to a predetermined mixture Improved vertical furnace, characterized in that it consists of a number of remote mixers with one engine.

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