CN114101609A - Jet casting and rolling high-performance 6XXX aluminum alloy thin strip and preparation method thereof - Google Patents

Abstract

A jet-cast high-performance 6XXX aluminum alloy thin strip and a preparation method thereof are disclosed, the aluminum alloy thin strip comprises the following components by mass percent: 0.5-1.5% of Si, 0.1-2.0% of Mg, 0.1-1.0% of Fe, 0.05-0.5% of Mn, 0.02-0.2% of Cu, 0.01-0.08% of Ti, 0.001-0.008% of B, and the balance of Al and other unavoidable impurities, wherein the content of single impurity is less than or equal to 0.05%, and the content of total impurities is less than or equal to 0.15%. Compared with the existing 6XXX aluminum alloy, the 6XXX aluminum alloy thin strip cast-rolled by the spray deposition combined double-roll thin strip casting-rolling process has the advantages that the strength is higher than 30%, and the formability is higher than 40%; compared with the steel plate for the automobile, the light weight of more than 50 percent can be easily realized. The aluminum alloy thin strip can be widely applied to the field of automobile application, such as parts of automobile engine covering parts, fenders, automobile doors, roofs, trunk lids and the like, and provides a wide space for the automobile industry in terms of light weight, energy consumption reduction and fuel economy improvement.

Description

Jet casting and rolling high-performance 6XXX aluminum alloy thin strip and preparation method thereof

Technical Field

The invention relates to the field of aluminum alloy preparation, in particular to a jet-cast high-performance 6XXX aluminum alloy thin strip and a preparation method thereof.

Background

The thin strip continuous casting technology is a leading technology in the metallurgy field at present, and the idea was originally proposed by Henry Bessemer in 1865 (US Patent: 49053). The continuous casting of the thin strip integrates the procedures of continuous casting, rolling, even heat treatment and the like, so that the produced thin strip blank can be formed into an industrial finished product at one time through subsequent rolling, the production procedure of the aluminum alloy thin strip is greatly simplified, the production period is shortened, and the production flow of the aluminum alloy thin strip is more compact, more continuous, more efficient and more environment-friendly; meanwhile, the production cost is obviously reduced, and the quality and the performance of the produced thin strip product are not inferior to or even superior to those of the traditional process.

The weight reduction of automobiles has become a major concern of countries in the world, and in recent years, technologies and innovations for realizing the weight reduction of automobiles are continuously emerging. The light weight is to reduce the net quality of the whole automobile as much as possible on the premise of ensuring the strength and the safety performance of the automobile, so as to improve the dynamic performance of the automobile and reduce the energy consumption of the automobile in the running process, thereby achieving the purposes of energy conservation and emission reduction. The net quality of the whole automobile is reduced by 10%, and the fuel efficiency can be improved by 6-8%; when the whole vehicle mass is reduced by 100kg, the fuel consumption per hundred kilometers can be reduced by 0.3-0.6L. Nowadays, energy conservation and emission reduction are global tasks, and automobiles are indispensable necessities in modern life, so that the light weight of the automobiles becomes the development trend of the automobiles in the world.

At present, the average energy consumption of Chinese automobiles is about 7.5L/100km, and has a certain gap with developed countries, and the national planning aims to reach 4.5L/km in 2020, is equal to the European standard and exceeds the standard set by the United states. To achieve this, it is necessary to accelerate the weight reduction of the automobile. The european automobile manufacturing industry is advancing "ultra light automobile engineering", and the united states has made a striding progress in automobile aluminization, aiming to reduce the mass of the automobile by 30% on the basis of the existing price.

Aluminum was the first material to be used as a substitute for steel, and the average amount of aluminum used for U.S. passenger cars was 28.6kg in 1960, and increased to 109kg in 1999, and reached about 160kg in 2015, and was estimated to be more than 285kg in 2025, and the body frame and cover of Audi A8 produced by Audi car company in 1994 were all made of extruded aluminum and sheet materials of the U.S. aluminum company, which was the pioneer of all aluminum passenger cars. The current data show that replacing steel with aluminum in automobile manufacturing can reduce the automobile quality by 30-40%, and if using the second generation aluminum alloy, the weight reduction effect is more excellent. Aluminum is second only to the use of steel and cast iron in automobile manufacture, while in all aluminum passenger cars the amount of aluminum rises to the second place. In addition, the new energy automobile is a new branch market for automobile industry development, and the new energy automobile is different from the traditional automobile in that the battery is adopted as power to drive the automobile to run, and the new energy automobile is limited by the weight of the power battery and the endurance mileage of the power battery, so that the requirement of light weight of an automobile body is more urgent in the aspects of vehicle design and material application. In the aspects of application technology, operation safety, cyclic recycling and the like, the aluminum alloy material with mature technology has great advantages and becomes the first choice of new energy vehicles and enterprises.

At present, automobile body sheets (ABS for short) are divided into two types, namely an inner plate and an outer plate. ABS has high requirements for the performance of an outer plate, is difficult to produce, and must have good formability, strong surface smoothness, good weldability and excellent baking hardening property.

The ABS aluminum alloy can be divided into two generations according to the performance and the production process of the ABS aluminum alloy, the first generation is generally the conventional wrought aluminum alloy produced by an ingot casting-hot rolling method, the final aluminum alloy thin strip product is obtained by subsequent cold rolling and heat treatment, the production period is longer, about 20 days are generally needed, 27 enterprises and workshops which are built globally at present are totally built, and the enterprises and workshops belong to the first generation.

The second generation ABS is generally considered to be a deformed aluminum alloy plate which is prepared by a short-flow new process and has obviously improved performance. Typical short-flow new processes include a Hatzerland (Hazelett) continuous casting and rolling process, a twin-roll thin-strip continuous casting and rolling process and the like. However, the traditional horizontal twin-roll strip continuous casting and rolling process can only produce rolled aluminum foil strips and simpler 1XXX and 3XXX series alloy thin strip products, and cannot produce high-end 6XXX series aluminum alloy covering piece thin strip products for automobiles. And the traditional horizontal twin-roll casting machine has a slow speed which is usually only 1-3m/min, and the production efficiency is low.

In recent years, many famous manufacturers of twin roll casting machines for thin aluminum alloy strips have made many developments in increasing casting speed and width of thin aluminum alloy strips, aiming at improving production efficiency and wider application. The more well-known companies include FataHunter, Italy and Puji, France, Speedcaster developed by FataHunter^TMThe ultrathin high-speed casting and rolling machine is characterized in that: the double rollers are driven by double drives, the inclination is 15 degrees, the diameter of the casting roller is 1118mm, the plate width reaches 2184mm, the rolling force is 3000t, the maximum casting speed can reach 38m/min, and the thickness can reach 0.635mm at the thinnest. The Junbo3CM casting and rolling machine developed by Puji corporation is characterized in that: the rolling force is 2900t, the plate width reaches 2020mm, the cast-rolling thickness is 1mm at the thinnest, and the maximum cast-rolling speed is 15 m/min. However, these devices still cannot produce high-end thin strip products of 6XXX series aluminum alloy cladding for automobiles.

Disclosure of Invention

The invention aims to provide a high-performance 6XXX aluminum alloy thin strip produced by jet casting and rolling and a preparation method thereof, the aluminum alloy thin strip can realize the combined improvement of strength, elongation and formability, and compared with the existing 6XXX aluminum alloy, the obtained 6XXX aluminum alloy thin strip has the advantages that the strength is higher by more than 30 percent, and the formability is higher by more than 40 percent; compared with the steel plate for the automobile, the weight is reduced by more than 50%; the composite material can be widely applied to the field of automobile application, particularly can be used for automobile engine covering parts, can also be used for parts such as fenders, doors, roofs, trunk lids and the like, and provides a wide space for the automobile industry in terms of light weight, energy consumption reduction and fuel economy improvement; moreover, the aluminum alloy thin strip of the invention can be smoothly formed by a mold which is common with a steel plate, can be more easily deformed into a complex shape, and does not need to additionally design a mold.

In order to achieve the purpose, the technical scheme of the invention is as follows:

a high-performance 6XXX aluminum alloy thin strip is cast and rolled by spraying, and comprises the following components in percentage by mass: si: 0.5-1.5%, Mg: 0.1-2.0%, Fe: 0.1 to 1.0%, Mn: 0.05 to 0.5%, Cu: 0.02 to 0.2%, Ti: 0.01-0.08%, B: 0.001-0.008% and the balance of Al and other inevitable impurity elements, wherein the content of single impurity is less than or equal to 0.05%, and the content of total impurities is less than or equal to 0.15%.

The aluminum alloy thin strip can realize yield strength of 160-240MPa, tensile strength of 240-320MPa, elongation of 28-37% and forming limit test (test under the specification of thickness of 1.0 mm) FLD (flash deformation) under the natural aging condition, namely T4 or T42₀In the range of 28-38%.

The aluminum alloy thin strip can realize yield strength of 180-₀In the range of 25-35%.

After the aluminum alloy thin strip is subjected to paint baking, the yield strength of 260-300MPa, the tensile strength of 340-380MPa and the elongation of 23-30% can be realized.

In the composition design of the high-performance 6XXX aluminum alloy thin strip provided by the invention:

si: the silicon-based alloy is a main component for improving the flow property of the aluminum alloy, can greatly improve the casting property of the aluminum alloy, and can improve the tensile strength, the hardness and the corrosion resistance of the aluminum alloy by adding a certain content of Si; however, addition of high Si content causes Si-containing hard particles in the aluminum alloy, which increases alloy brittleness and deteriorates machinability. Therefore, the Si content is controlled in the range of 0.5 to 1.5% in the present invention.

Mg: can improve the strength of the aluminum alloyHardness, heat resistance, corrosion resistance and machinability, but adding a large amount of Mg tends to cause hot shortness, cracking of the alloy, and formation of Mg₂Si can embrittle the alloy. Therefore, the Mg content is controlled in the range of 0.1 to 2.0% in the present invention.

Fe: FeAl is formed in the aluminum alloy₃、Fe₂The Al or Al-Si-Fe has a plate-like or needle-like structure which reduces mechanical properties and also causes the alloy to have a reduced fluidity and an increased tendency to be thermally cracked, and therefore, the Fe content is controlled in the range of 0.1 to 1.0% in the present invention.

Mn: the harmful effect of Fe can be reduced in the aluminum alloy, the sheet-shaped or needle-shaped structure formed by Fe in the aluminum alloy can be changed into a fine crystal structure, Mn can organize the recrystallization process of the aluminum alloy, the recrystallization temperature is increased, and recrystallized grains can be obviously refined; too high Mn causes segregation and also lowers the thermal conductivity. Therefore, the Mn content is controlled in the range of 0.05 to 0.5% in the present invention.

Cu: cu is dissolved in the aluminum alloy in a solid solution manner, so that the strength, the hardness, the heat resistance and the cutting performance can be improved, and the casting flow performance can be improved; however, too high a Cu content affects the corrosion resistance and plasticity of the aluminum alloy and increases the tendency to hot cracking. Therefore, the Cu content is controlled in the range of 0.02 to 0.2% in the present invention.

Ti: the grain structure can be obviously refined by adding a trace amount of Ti into the aluminum alloy, the mechanical property of the alloy is effectively improved, and the hot cracking tendency of the alloy is reduced; however, the addition of too much Ti not only increases the alloy cost, but also affects the conductivity. Therefore, the Ti content is controlled in the range of 0.01 to 0.08% in the present invention.

B: b is added into the aluminum alloy through the aluminum boron intermediate alloy, a small amount of the aluminum boron intermediate alloy is added into the alloy solution, then a large amount of high-melting-point particles can be generated, the aluminum boron intermediate alloy can be used as an external crystal nucleus to refine the grain structure when the alloy is solidified, and the effect of improving the strength and the plasticity of the aluminum alloy can be achieved. In addition, the conductivity and corrosion resistance of the aluminum alloy can be increased. Therefore, the content of B is controlled in the range of 0.001 to 0.008% in the present invention.

The invention selectively adds in 6XXX aluminum alloyThe Ti element can obviously refine the grain structure, effectively improve the mechanical property of the alloy and reduce the hot cracking tendency of the alloy. Cu is selectively added, so that Cu is dissolved in the aluminum alloy in a solid mode, the strength, the hardness, the heat resistance and the cutting performance are improved, and the casting fluidity can be improved; in addition, the CuAl precipitated by aging₂Has obvious aging strengthening effect.

The B element of the aluminum-boron intermediate alloy is introduced into the aluminum alloy, a small amount of the aluminum-boron intermediate alloy is added into the alloy solution, so that a large amount of high-melting-point particles can be generated, the aluminum-boron intermediate alloy can be used as an external crystal nucleus to refine the grain structure when the alloy is solidified, and the strength, the plasticity, the conductivity and the corrosion resistance of the aluminum alloy can be improved.

The invention relates to a preparation method of a jet casting and rolling high-performance 6XXX aluminum alloy thin strip, which comprises the following steps:

1) smelting

Smelting according to the component requirements;

2) standing, degassing, and filtering

Introducing the smelted aluminum alloy liquid into a standing furnace for standing, conveying the aluminum alloy liquid to a front box through a runner, and then degassing and filtering; the temperature of the aluminum alloy liquid introduced into the standing furnace is 780-850 ℃;

3) spray deposition, continuous casting

Atomizing aluminum alloy liquid into fine molten drops by adopting inert gas, depositing the molten drops on the surface of a double roller, and continuously casting a thin strip by adopting the double roller to obtain an aluminum alloy casting strip with the thickness of 2-6mm and the width of 1000-2200 mm; the pressure of inert gas is 0.8-2.0MPa, the temperature of the aluminum alloy cast strip is 550-600 ℃, the diameter of a crystallization roller is 400-800mm, water is introduced into the crystallization roller for cooling, and the casting speed of the casting machine is 20-80 m/min;

4) cooling down

The aluminum alloy casting strip is cooled to 410-510 ℃ through water quenching after coming out of the casting machine;

5) first hot rolling

Sending the cooled aluminum alloy cast strip to a rolling mill after pinch roll and crop end treatment for primary hot rolling; the first hot rolling temperature is 380-480 ℃, and the first hot rolling reduction rate is less than or equal to 50%;

6) cooling and second hot rolling

Carrying out air cooling or water cooling on the aluminum alloy thin strip subjected to the first hot rolling, and then carrying out second hot rolling;

the second hot rolling temperature is 280-420 ℃, and the second hot rolling reduction rate is less than or equal to 60%; the thickness of the aluminum alloy thin strip after the second hot rolling is 0.3-4mm, preferably 0.5-3 mm;

7) coiling

Conveying the aluminum alloy thin strip subjected to the second hot rolling to a coiling machine through a pinch roll for coiling, wherein the coiling temperature is 200-370 ℃;

8) post-treatment

And (3) after the aluminum alloy thin strip is coiled, sequentially carrying out solution heat treatment and quenching.

Preferably, in step 3), the inert gas is one or two of nitrogen and argon.

Preferably, in step 3), the molten drop is in a solid, semi-solid or liquid state.

Further, after quenching in the step 8), aging and baking finish procedures are sequentially carried out.

Preferably, the aging is artificial aging or natural aging plus artificial aging, wherein the artificial aging temperature is 90-200 ℃, the time is 25-120min, and the natural aging time is 25-35 days.

Preferably, the baking varnish temperature is 150-220 ℃, and the duration is 20-50 min.

And performing additional artificial aging after the paint baking, wherein the temperature of the additional artificial aging is 90-200 ℃, and the time is 25-120 min.

Preferably, in the step 8), the temperature of the solution heat treatment is 500-560 ℃, and the time is 8-50 min.

Preferably, in the step 8), the temperature of the aluminum alloy thin strip after quenching is between room temperature and 120 ℃.

Preferably, before the post-treatment process of the step 8), one or more of off-line cold rolling, tension straightening, edge cutting, flattening, surface inspection and plate shape inspection can be carried out on the aluminum alloy thin strip.

Preferably, in step 3), the nozzle used for spray deposition is a slit linear nozzle.

Preferably, in the step 3), a vertical casting machine or a horizontal casting machine is used for the continuous casting.

Preferably, in the step 3) continuous casting process, the crystallizing roller is a copper roller, and the surface of the crystallizing roller is provided with textures, grooves or embossments.

Preferably, the surface of the crystallization roller is subjected to chromium electroplating treatment, and the thickness of the chromium plating layer is 0.05-0.10 mm.

The aluminum alloy liquid smelted by the method is led into a standing furnace for standing, one smelting furnace is generally used for 2-3 standing furnaces, the smelting capacity of the smelting furnace is greater than that of the standing furnace, so that the aluminum alloy liquid is fully supplied, and the temperature of the aluminum alloy liquid flowing into the standing furnace is controlled to be 780-850 ℃. And conveying the aluminum alloy liquid from the standing furnace to the front box through a launder, degassing, filtering and flowing into a tundish.

During spray deposition, aluminum alloy liquid is fed into a slit type linear nozzle having a slit parallel to the center line of the roll shaft of a twin roll caster in an inert gas (e.g., N)₂Ar) under the action of inert gas pressure of 0.8-2.0MPa, atomizing the aluminum alloy liquid flowing into the slit type linear nozzle into fine molten drops to be deposited on the surface of the double rollers, and generating thermal conduction or thermal radiation and other thermodynamic behaviors with the outside in the flying process of the molten drops, wherein the molten drops can be in a solid state, a semi-solid state or a liquid state; and then continuously casting the aluminum alloy strip by a double-roller thin strip casting machine to obtain the aluminum alloy cast strip with the thickness of 2-6mm and the width of 1000-2200 mm.

The spray deposition and double-roller thin strip casting and rolling process combines the atomization, spray deposition and double-roller casting and rolling of aluminum alloy liquid into one process, and can economically and efficiently prepare the aluminum alloy thin strip with uniform fine grain structure and excellent comprehensive performance.

Compared with the traditional horizontal double-roller casting and rolling, the technology combining the spray deposition and the double-roller thin strip casting and rolling has the following obvious advantages:

(1) the produced aluminum alloy thin strip has the microstructure characteristic of rapid solidification, almost has no macrosegregation and almost no anisotropy, has fine equiaxed crystal structure, and the mechanical property is greatly improved after heat treatment;

(2) the density of the produced aluminum alloy thin strip is high, the density of the aluminum alloy thin strip can easily reach 97-99% after the aluminum alloy thin strip is subjected to spray deposition and twin-roll thin strip casting rolling, and the cracking problem in the subsequent rolling process is avoided;

(3) the production efficiency is high, and the casting and rolling speed can reach more than 3 times of that of the traditional horizontal double-roller casting and rolling;

(4) the surface quality is excellent, and the problem of uneven cooling of the upper surface and the lower surface of the traditional horizontal double-roller casting can be avoided;

(5) the range of aluminum alloy varieties which can be produced is greatly widened, the aluminum alloy varieties which can be produced by the traditional horizontal double-roller casting and rolling are few, and the process can produce some alloys with wider solidification temperature intervals, such as 2XXX, 6XXX, 7XXX and the like, because the aluminum alloy liquid is atomized, sprayed and deposited on the surface of the crystallizing roller to form uniform fine crystal structures.

The aluminum alloy cast strip after water quenching and cooling enters a four-roll mill for first hot rolling after being cut by a pinch roll, the hot rolling temperature range is 380-480 ℃, and the reduction rate is less than or equal to 50%. In order to ensure that the aluminum alloy cast strip does not deviate and ensure the smooth production, the pinch roll has the functions of deviation rectification and centering.

Although the method of the present invention is described in the above embodiment as having two stands in the rolling step to achieve the target thickness, one skilled in the art can contemplate other embodiments, such as using any suitable number of hot rolling and subsequent cold rolling stands in the rolling step to achieve the appropriate product target thickness.

The post-treatment process in the step 8) comprises the processes of solution heat treatment, quenching, aging, varnish baking and the like.

After coiling, the aluminum alloy thin strip may be solution heat treated and quenched, solution heat treatment temperature: 500 ℃ and 560 ℃, time: 8-50 min; the temperature range of the aluminum alloy thin strip after quenching is between room temperature and 120 ℃.

After the solution heat treatment and quenching, artificial aging treatment can be carried out, wherein the artificial aging temperature is as follows: 90-200 ℃, time: and 25-120 min. The condition of the aluminum alloy product after solution treatment and artificial aging is referred to as the T6 condition, which means that the final product has been solution heat treated, quenched and artificially aged.

The preparation method can select other processes before the post-treatment in the step 8), including off-line cold rolling, tension straightening, trimming, leveling, surface inspection, plate shape inspection and the like, and then can perform solid solution heat treatment and quenching after reaching the final specification.

If necessary, after the solution heat treatment and quenching, the aluminum alloy strip may be subjected to natural aging, the natural aging standing time is generally 25 to 35 days, and the state after the solution heat treatment and the natural aging to be substantially stable is called a T4 state or a T42 state. After natural aging, the coiled aluminum alloy product is shipped to a customer for use.

After natural aging, the aluminum alloy thin strip can be artificially aged according to requirements to generate precipitation hardening. Artificial aging temperature: 90-200 ℃, time: and 25-120 min. The artificial aging is generally carried out after the aluminum alloy thin strip is formed into an automobile part, and then the aluminum alloy thin strip may be subjected to baking finish (bake hardening), wherein the baking finish temperature range: 150 ℃ and 220 ℃, time: 20-50 min. The extra artificial aging after the paint baking can be completed according to the requirement, and the extra artificial aging temperature is as follows: 90-200 ℃, time: and 25-120 min.

The twin roll casting machine for continuous casting according to the present invention may be in the form of a vertical type or a horizontal type. The crystallizing roller for twin-roll strip casting is copper roller, and the surface of the crystallizing roller is processed into grains, grooves or embossing, etc. to raise the heat conducting efficiency of the interface and thus raise the strip casting speed. After the surface appearance of the crystallization roller is processed, the chromium electroplating treatment is needed, the thickness of the chromium coating is controlled to be 0.05-0.10mm, the surface hardness and the wear resistance of the crystallization roller can be greatly improved through the chromium electroplating treatment, and the service life of the crystallization roller is prolonged.

The aluminum alloy thin strip is coiled in a double-coiling mode, and also can be coiled in a carrousel coiling mode, so that the continuous production of the aluminum alloy thin strip is ensured. The coiling machine reel has an automatic centering function so as to ensure good coil shape when the aluminum alloy thin strip is coiled and ensure smooth production.

The invention is distinguished and improved from the prior art:

the existing thin strip continuous casting production aluminum alloy products do not adopt Ti and B added improved aluminum alloy components, and the preparation of the 6XXX aluminum alloy thin strip by using the spray deposition and the twin-roll thin strip continuous casting process according to the invention has not been directly reported.

Chinese patent CN106164308A discloses an aluminium alloy product and a method for its production, which aluminium alloy has at least 0.8 wt% Mn, at least 0.6 wt% Fe, the near surface of the aluminium alloy strip contains small particles with an equivalent diameter <3 μm, with a volume fraction of at least 0.2%, the composition of the product is not related to elements such as Ti, B, etc., nor to spray deposition and twin roll strip casting processes.

Chinese patent CN103119184B discloses "an improved 6XXX aluminum alloy and method of producing the same" that can be produced by preparing an aluminum alloy body for post-solutionizing cold work, cold working by at least 25%, and subsequent heat treatment, and that can achieve improved strength and properties, without regard to elements such as Ti, B, etc., in the composition of the product, or to spray deposition, etc.

Chinese patent CN104284745A discloses "an improved 6XXX aluminum alloy and method for making the same", wherein the aluminum alloy body has a "sandwich" structure with two outer regions plus an inner region, and the inner region contains particles at a concentration greater than that of the outer regions, and the product composition of the patent does not involve B elements, nor spray deposition, etc.

Chinese patent CN200810098094 discloses "a continuous casting process of an aluminum alloy thin strip blank", and proposes that 5052 aluminum alloy can be produced by adopting a vertical twin-roll thin strip continuous casting process, and the patent does not relate to measures such as spray deposition and the like, and does not relate to 6XXX aluminum alloy.

The invention has the beneficial effects that:

1. according to the invention, Ti is selectively added into the 6XXX aluminum alloy, so that the grain structure can be obviously refined, the mechanical property of the alloy is effectively improved, and the hot cracking inclination of the alloy can be reducedAnd (3) direction. According to the invention, Cu element is selectively added into the 6XXX aluminum alloy, so that Cu is dissolved into the aluminum alloy in a solid solution manner, the strength, the hardness, the heat resistance and the cutting performance are improved, and the casting fluidity can be improved; in addition, the CuAl precipitated by aging₂Has obvious aging strengthening effect.

2. The B element is introduced into the aluminum alloy through the aluminum-boron intermediate alloy, a small amount of the aluminum-boron intermediate alloy is added into the alloy solution, so that a large amount of high-melting-point particles can be generated, the aluminum-boron intermediate alloy can be used as an external crystal nucleus to refine the crystal grain structure when the alloy is solidified, and the strength, the plasticity, the conductivity and the corrosion resistance of the aluminum alloy can be improved. Meanwhile, the content of the B element can be further improved to 0.008 percent due to the combination of a double-roller thin strip continuous casting sub-rapid solidification process.

3. The spray deposition and double-roller thin strip casting and rolling process combines the atomization, spray deposition and double-roller casting and rolling of aluminum alloy liquid into one process, and can economically and efficiently prepare the aluminum alloy thin strip with compact and uniform fine grain structure and excellent comprehensive performance.

4. Compared with the traditional aluminum alloy production process, the invention has the following advantages:

a) short flow, investment saving, low cost and low energy consumption: the double-roll thin strip casting and rolling equipment can replace the traditional DC casting machine, heating furnace and hot rolling mill, and the equipment cost is greatly reduced; the occupied area is only 1/4 of the traditional flow (casting and hot rolling workshop), and the energy consumption is only 50 percent of that of the traditional flow;

b) the production efficiency is high, the processing time of the semi-finished product is greatly shortened, and 5 working procedures (1, sawing the head and the tail of the ingot; 2. homogenizing annealing (which is a long-time process and takes up to 50 hours); 3. milling a surface; 4. heating before hot rolling; 5. hot rolling), from aluminum alloy liquid to hot rolled coil, from 20 days required by the traditional flow, to 20 minutes;

c) the yield is greatly improved: greatly reducing the consumption of head cutting, tail removing and face milling, and improving the yield by more than 20 percent;

d) the production line has a high degree of flexibility: the continuous casting machine of the production line can replace the alloy at any time without stopping the machine, thereby realizing seamless transition among automobiles, industry, household appliances and products in the packaging market.

5. Compared with the product produced by the traditional aluminum alloy production process, the invention has the advantages of obvious structure performance:

a) the density is high, and macrosegregation is almost not generated: the produced aluminum alloy thin strip has the characteristics of fine isometric crystal microstructure with rapid solidification characteristic, has high density, and avoids the cracking problem in the subsequent rolling process; almost no macrosegregation and almost no anisotropy exist, and the mechanical property is greatly improved after heat treatment;

b) the surface quality is good: because the spray deposition combined double-roller thin strip casting and rolling process is adopted, compared with the traditional double-roller casting and rolling (the drawing speed is only 1-3m/min), the drawing speed can be greatly improved to 20-80m/min, the problem of uneven cooling of the upper surface and the lower surface of the traditional horizontal double-roller casting and rolling can be avoided, the surface quality is greatly improved, and the harsh requirements of the automobile industry can be met;

c) excellent performance, obvious light weight advantage: the produced aluminum alloy thin strip has the advantages that the formability is higher than that of the existing 6XXX aluminum alloy by more than 40%, and the strength is higher than 30%; compared with the steel plate for the automobile, the light weight of more than 50 percent can be easily realized. The performance of the aluminum alloy thin strip is close to that of a steel plate, particularly, the aluminum alloy thin strip has high formability, is not easy to crack during forming, can be formed smoothly by a die which is commonly used for the steel plate during punch forming, can be deformed into a complex shape more easily, and does not need to additionally design the die.

6. The traditional double-roller cast-rolling aluminum alloy production usually adopts steel rollers, and the cooling and heat transfer efficiency is low, so that the drawing speed is only 1-3m/min, and the production efficiency is low.

The crystallization roller used for twin-roller thin strip continuous casting adopts a copper roller, the surface of the crystallization roller is processed into shapes such as textures, grooves or embossing, and the like, so that the interface heat conduction efficiency can be greatly improved, and the thin strip continuous casting speed can be improved; meanwhile, the width of 2200mm can be realized to the maximum, the width is really wide, and the width range required by the automobile engine covering part can be completely covered. After the surface appearance of the crystallization roller is processed, chromium electroplating treatment is carried out, so that the surface hardness and the wear resistance of the crystallization roller can be greatly improved, and the service life of the crystallization roller is prolonged.

Drawings

Fig. 1 is a schematic view of a process of vertical twin roll strip casting according to a first embodiment of the present invention.

Fig. 2 is a schematic view of the process of the second embodiment of the present invention (horizontal twin roll strip casting).

Detailed Description

The present invention is further illustrated by the following examples and the accompanying drawings, which are not intended to limit the present invention, and those skilled in the art can make modifications or improvements based on the basic idea of the invention, but within the scope of the present invention, without departing from the basic idea of the invention.

Referring to fig. 1, in the first embodiment of the present invention, a vertical casting machine is used to prepare a high-performance 6XXX aluminum alloy thin strip.

The smelted aluminum alloy liquid which is designed according to the chemical composition of the invention is led into a standing furnace 3 from a smelting furnace 1 through a launder 2 for standing. The aluminum alloy liquid is transferred from the standing furnace 3 to the front box 4 through the launder 2, degassed 5, filtered 6, and then poured into the tundish 7.

Molten aluminum alloy flows from the bottom of the tundish 7 through the submerged nozzle 8 into a slit type linear nozzle 9 and inert gas 11 (e.g., N)₂) The aluminum alloy flowing into the slit type linear nozzle 9 is atomized into fine droplets D and deposited into a roll gap defined by two relatively rotating and rapidly cooled twin roll thin strip casting and crystallizing rolls 10a, 10b and side closing plates 12a, 12 b. The droplets are solidified on the circumferential surfaces of the crystallization rolls 10a, 10b rotating, and then an aluminum alloy cast strip 15 having a thickness of 2-6mm and a width of 1000-. The diameter of the crystallization rollers 10a and 10b is between 400 and 800mm, and water is introduced for cooling. The casting speed of the casting machine ranges from 20 to 80m/min depending on the thickness of the aluminum alloy cast strip 15.

The aluminum alloy casting strip 15 comes out of the twin-roll strip caster and directly enters the closed chamber 14, and the closed chamber 14 is filled with inert gas to protect the aluminum alloy casting strip 15 to be solidifiedThe aluminum alloy cast strip 15 is protected against oxidation at present, and the atmosphere for protecting against oxidation can be N₂Ar, or other non-oxidizing gas, such as CO obtained by sublimation of dry ice₂Gas, etc., the oxygen concentration in the closed chamber 14 is controlled to be<5 percent, and the closed chamber 14 protects the aluminum alloy cast strip 15 from oxidation to the inlet of the No. 1 pinch roll 17. An aluminum alloy cast strip 15 passes through a conveying roller way 20 on a swing guide plate 13, is cooled by a water quenching cooling device 16, enters a No. 1 pinch roller 17, is subjected to head cutting by a flying shear 18, enters a four-roller No. 1 hot rolling mill 19 for hot rolling, the flying shear 18 guides the cut strip head into a waste hopper 26 through a guide plate 25, and the flying shear 18 also has the function of on-line cutting between coils, so that the continuous production can be ensured. In order to ensure that the aluminum alloy cast strip 15 does not deviate and ensure the smooth production, the 1# pinch roll 17 has the functions of deviation rectification and centering.

After the aluminum alloy cast strip 15 is hot-rolled by a No. 1 hot rolling mill 19, an aluminum alloy thin strip running on a conveying roller way 20 enters an air cooling/water cooling device 21 for cooling, then the aluminum alloy thin strip enters a four-roll No. 2 hot rolling mill 22 for hot rolling again to form a hot-rolled aluminum alloy thin strip of 0.3-4mm, and the rolled aluminum alloy thin strip enters a No. 2 pinch roll 23 and then directly enters a coiling machine 24 for coiling.

The coiling machine 24 adopts a double coiling mode and can also adopt a carrousel coiling mode to ensure the continuous production of the aluminum alloy thin strip. The coiling machine 24 has an automatic centering function to ensure good coil shape when the aluminum alloy thin strip is coiled and ensure smooth production.

Referring to fig. 2, in the second embodiment of the present invention, a horizontal casting machine is used to prepare a high performance 6XXX aluminum alloy thin strip.

The smelted aluminum alloy liquid which is designed according to the chemical composition of the invention is led into a standing furnace 3 from a smelting furnace 1 through a launder 2 for standing. The aluminum alloy liquid is transferred from the standing furnace 3 to the front box 4 through the launder 2, degassed 5, filtered 6, and then poured into the tundish 7.

Molten aluminum alloy flows from the bottom of the tundish 7 through the submerged nozzle 8 into a slit type linear nozzle 9 and inert gas 11 (e.g., N)₂) Under the action of the nozzle, the aluminum alloy flowing into the slit type linear nozzle 9 is atomized into smallThe droplets D are deposited in a gap defined by two counter-rotating, rapidly cooling twin roll strip casting crystallizers 10a, 10b and side sealing plates 12a, 12 b. The droplets are solidified on the circumferential surfaces of the crystallization rolls 10a, 10b rotating, and then an aluminum alloy cast strip 15 having a thickness of 2-6mm and a width of 1000-. The diameter of the crystallization rollers 10a and 10b is between 400 and 800mm, and water is introduced for cooling. The casting speed of the casting machine ranges from 20 to 80m/min depending on the thickness of the aluminum alloy cast strip 15.

The aluminum alloy cast strip 15 comes out of the twin-roll strip caster and directly enters the closed chamber 14, the closed chamber 14 is filled with inert gas to protect the aluminum alloy cast strip 15, and the anti-oxidation protection of the aluminum alloy cast strip 15 is realized, wherein the atmosphere of the anti-oxidation protection can be N₂Ar, or other non-oxidizing gas, such as CO obtained by sublimation of dry ice₂Gas, etc., the oxygen concentration in the closed chamber 14 is controlled to be<5 percent, and the closed chamber 14 protects the aluminum alloy cast strip 15 from oxidation to the inlet of the No. 1 pinch roll 17. The aluminum alloy cast strip 15 directly comes out of the upper roller channel 20 of the crystallizing rollers 10a and 10b, is cooled by the water quenching cooling device 16, enters the 1# pinch roller 17, is cut by the flying shear 18, and then enters the four-roller 1# hot rolling mill 19 for hot rolling, the flying shear 18 guides the cut strip head into the waste hopper 26 through the guide plate 25, and the flying shear 18 also has the function of on-line cutting between coils, so that the continuous production can be ensured. In order to ensure that the aluminum alloy cast strip 15 does not deviate and ensure the smooth production, the 1# pinch roll 17 has the functions of deviation rectification and centering.

After the aluminum alloy cast strip 15 is hot-rolled by a No. 1 hot rolling mill 19, an aluminum alloy thin strip running on a conveying roller way 20 enters an air cooling/water cooling device 21 for cooling, then the aluminum alloy thin strip enters a four-roll No. 2 hot rolling mill 22 for hot rolling again to form a hot-rolled aluminum alloy thin strip of 0.3-4mm, and the rolled aluminum alloy thin strip enters a No. 2 pinch roll 23 and then directly enters a coiling machine 24 for coiling.

The coiling machine 24 adopts a double coiling mode and can also adopt a carrousel coiling mode to ensure the continuous production of the aluminum alloy thin strip. The coiling machine 24 has an automatic centering function to ensure good coil shape when the aluminum alloy thin strip is coiled and ensure smooth production.

After coiling, the aluminum alloy strip may be subjected to a series of post-treatment processes, such as solution heat treatment, quenching, natural/artificial aging, paint baking, and the like. Optional other steps include off-line cold rolling, tension straightening, trimming, flattening, surface inspection, plate shape inspection, etc., and then a series of post-treatment processes can be performed after the final specification is reached.

The chemical compositions of the aluminum alloy thin strip of the embodiment of the invention are shown in table 1, and the balance of the compositions is Al and other inevitable impurities. The technological parameters of the preparation method of the embodiment of the invention are shown in Table 2, the parameters of the post-treatment process are shown in Table 3, and the properties of the finally obtained aluminum alloy thin strip are shown in Table 4.

In conclusion, the aluminum alloy thin strip manufactured according to the design range and the preparation method of the aluminum alloy composition provided by the invention can realize the yield strength of 160-240MPa, the tensile strength of 240-320MPa, the elongation of 28-37% and the forming limit test (test under the specification of the thickness of 1.0 mm) FLD under the natural aging condition (T4 or T42 state)₀In the range of 28-38%.

The aluminum alloy thin strip can realize yield strength of 180-₀In the range of 25-35%.

After the aluminum alloy thin strip is subjected to paint baking, the yield strength of 260-. Compared with the existing 6XXX aluminum alloy, the formability is higher than 40%, and the strength is higher than 30%; compared with the steel plate for the automobile, the light weight of more than 50 percent can be easily realized.

The performance of the aluminum alloy thin strip is close to that of a steel plate, particularly, the aluminum alloy thin strip has high formability, is not easy to crack during forming, can be formed smoothly by a die which is universal with the steel plate during punch forming, can be deformed into a complex shape more easily, and does not need to additionally design the die.

The aluminum alloy thin strip produced by the invention can be widely applied to the field of automobile application, such as parts of automobile engine covering parts, mud guards, automobile doors, automobile roofs, trunk lids and the like, and provides a wide space for the automobile industry in terms of light weight, energy consumption reduction and fuel economy improvement.

Table 1 units: mass percent

Serial number	Si	Mg	Fe	Mn	Cu	Ti	B
								Example 1	0.85	1.35	0.68	0.06	0.04	0.03	0.002
Example 2	0.68	0.90	0.23	0.27	0.02	0.01	0.001
								Example 3	0.50	1.28	0.35	0.40	0.18	0.02	0.004
Example 4	0.75	2.00	0.10	0.36	0.20	0.05	0.008
								Example 5	1.25	0.65	0.29	0.22	0.05	0.08	0.007
Example 6	1.42	0.57	0.82	0.05	0.08	0.07	0.008
								Example 7	1.19	0.85	0.25	0.50	0.06	0.07	0.005
Example 8	1.50	1.00	0.78	0.09	0.15	0.06	0.006
								Example 9	1.39	0.84	1.00	0.33	0.08	0.05	0.003
Example 10	0.64	0.40	0.22	0.41	0.13	0.04	0.004
								Example 11	0.70	0.65	0.41	0.12	0.09	0.06	0.005
Example 12	0.98	0.10	0.55	0.27	0.07	0.07	0.003
								Example 13	1.44	0.37	0.91	0.34	0.09	0.03	0.006
Example 14	1.35	1.40	0.17	0.43	0.14	0.05	0.005

Claims (16)

1. A high-performance 6XXX aluminum alloy thin strip is cast and rolled by spraying, and comprises the following components in percentage by mass: si: 0.5-1.5%, Mg: 0.1-2.0%, Fe: 0.1 to 1.0%, Mn: 0.05 to 0.5%, Cu: 0.02 to 0.2%, Ti: 0.01-0.08%, B: 0.001-0.008% and the balance of Al and other inevitable impurities, wherein the content of single impurity is less than or equal to 0.05%, and the content of total impurities is less than or equal to 0.15%.

2. The strip of claim 1, wherein the strip of high performance 6XXX aluminum alloy is capable of achieving a yield strength of 160-₀In the range of 28-38%;

the aluminum alloy thin strip can realize the yield strength of 180-260MPa, the tensile strength of 260-350MPa and the elongation of 26-35 percent under the artificial aging condition, namely T6 stateShape Limit test (test at 1.0mm thickness gauge) FLD₀In the range of 25-35%;

after the aluminum alloy thin strip is subjected to paint baking, the yield strength of 260-300MPa, the tensile strength of 340-380MPa and the elongation of 23-30% can be realized.

3. The method of making a thin strip of high performance 6XXX aluminum alloy as claimed in claim 1 or 2, comprising the steps of:

1) smelting

Smelting according to the composition requirements of claim 1;

2) standing, degassing, and filtering

Introducing the smelted aluminum alloy liquid into a standing furnace for standing, conveying the aluminum alloy liquid to a front box through a runner, and then degassing and filtering; the temperature of the aluminum alloy liquid introduced into the standing furnace is 780-850 ℃;

3) spray deposition, continuous casting

Atomizing aluminum alloy liquid into fine molten drops by adopting inert gas, depositing the molten drops on the surface of a double roller, and continuously casting a thin strip by adopting the double roller to obtain an aluminum alloy cast strip with the thickness of 2-6mm and the width of 1000-2200 mm; the pressure of inert gas is 0.8-2.0MPa, the temperature of the aluminum alloy cast strip is 550-600 ℃, the diameter of a crystallization roller is 400-800mm, water is introduced into the crystallization roller for cooling, and the casting speed of the casting machine is 20-80 m/min;

4) cooling down

The aluminum alloy casting strip is cooled to 410-510 ℃ through water quenching after coming out of the casting machine;

5) first hot rolling

Sending the cooled aluminum alloy cast strip to a rolling mill after pinch roll and crop treatment, and carrying out first hot rolling, wherein the temperature of the first hot rolling is 380-480 ℃, and the reduction rate of the first hot rolling is less than or equal to 50%;

6) cooling and second hot rolling

Air cooling or water cooling is carried out on the aluminum alloy thin strip subjected to the first hot rolling, then the second hot rolling is carried out, the temperature of the second hot rolling is 280-420 ℃, and the reduction rate of the second hot rolling is less than or equal to 60%; the thickness of the aluminum alloy thin strip after the second hot rolling is 0.3-4mm, preferably 0.5-3 mm;

7) coiling

Conveying the aluminum alloy thin strip subjected to the second hot rolling to a coiling machine through a pinch roll for coiling, wherein the coiling temperature is 200-370 ℃;

8) post-treatment

And (3) after the aluminum alloy thin strip is coiled, sequentially carrying out solution heat treatment and quenching.

4. The method of making thin strip of high performance 6XXX aluminum alloy as claimed in claim 3 wherein in step 3), the inert gas is one or both of nitrogen and argon.

5. The method of making thin strip of high performance 6XXX aluminum alloy as claimed in claim 3 wherein in step 3) the droplets are in a solid, semi-solid or liquid state.

6. The method of making a thin strip of high performance 6XXX aluminum alloy as specified in claim 3 wherein the quenching of step 8) is followed by aging and paint baking steps in that order.

7. The method for preparing the jet casting-rolling high-performance 6XXX aluminum alloy thin strip according to claim 6, wherein the aging is artificial aging or natural aging + artificial aging, wherein the artificial aging temperature is 90-200 ℃, the time is 25-120min, and the natural aging time is 25-35 days.

8. The method for preparing the thin strip of high performance 6XXX aluminum alloy according to claim 6, wherein the baking finish temperature is 150-220 ℃ and the time is 20-50 min.

9. The method for preparing the thin strip of high performance 6XXX aluminum alloy according to claim 6 or 8, wherein the additional artificial aging is performed after the paint baking, the temperature of the additional artificial aging is 90-200 ℃, and the time is 25-120 min.

10. The method for producing the strip of high performance 6XXX aluminum alloy as claimed in claim 3, wherein the solution heat treatment temperature in step 8) is 500-560 ℃ for 8-50 min.

11. The method of making a strip of high performance 6XXX aluminum alloy as claimed in claim 3, wherein in step 8), the strip of quenched aluminum alloy is at a temperature of from about room temperature to about 120 ℃.

12. The method of making a jet cast high performance 6XXX aluminum alloy ribbon as claimed in claim 3, wherein prior to the post-treatment step of step 8) the aluminum alloy ribbon is further subjected to one or more of off-line cold rolling, tension straightening, trimming, flattening, surface inspection, and strip shape inspection.

13. The method of making thin strip of high performance 6XXX aluminum alloy as specified in claim 3 wherein in step 3) the spray deposition atomizing nozzle is a slot type linear nozzle.

14. The method of making thin strip of high performance 6XXX aluminum alloy as claimed in claim 3 wherein in step 3) the continuous casting is performed using a vertical caster or a horizontal caster.

15. The method of making a thin strip of high performance 6XXX aluminum alloy as specified in claim 3 wherein the crystallizing roller is a copper roller and the surface of the crystallizing roller is textured, grooved, or embossed during step 3).

16. The method for preparing the high-performance 6XXX aluminum alloy thin strip by spray casting as claimed in claim 3 or 15, wherein the surface of the crystallization roller is electro-chromized, and the thickness of the electro-chromized layer is 0.05-0.10 mm.

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