METHOD AND APPARATUS FOR SYNCHRONOUSLY MELTING AND PREPARING ALLOY

Abstract

An apparatus for synchronously melting and preparing alloy, the alloy to be added is made into wire in advance, and the wire feeding speed required for the preparation of the alloy with a specific composition is calculated according to the flow rate of raw molten aluminum in the launder. In the continuous ingot casting process, the wire is continuously and stably fed into the launder of the raw molten aluminum at the wire feeding speed, and the alloy preparation is formed in real time, which is able to avoid specific gravity segregation caused by the long-term standing of melt, and realize the preparation of gradient materials while significantly improving the alloying efficiency. The present disclosure also relates to a method for synchronously melting and preparing alloy.

Claims

1. A method for synchronously melting and preparing alloy, wherein an alloy to be added is made into a wire in advance, and a wire feeding speed required for preparing an alloy with a specific composition is calculated according to a flow rate of raw molten aluminum in a launder, wherein in a continuous ingot casting process, the wire was continuously and stably fed into the launder of the raw molten aluminum at the wire feeding speed, thereby real-time forming an alloy preparation.

2. The method for synchronously melting and preparing alloy melting according to claim 1, wherein the wire is an alloy wire or a pure metal wire; and an alloy with a high melting point refers to an alloy with a melting point higher than that of pure aluminum.

3. The method for synchronously melting and preparing alloy according to claim 1, wherein an alloy with a high melting point refers to Al—Mn, Al—Fe and Al—Cr.

4. The method for synchronously melting and preparing alloy according to claim 1, wherein the wire feeding speed Vwire is determined according to a flow rate V1 of the raw molten aluminum in the launder, wherein Vwire=kV1, where k is a fixed constant.

5. The method for synchronously melting and preparing alloy according to claim 1, wherein the real-time forming refers to: in order to make the wire quickly be dissolved into the raw molten aluminum, a method of high-frequency instantaneous heating is applied to melt an alloy with a high melting point while the wire is being fed, so that a melted alloy is able to be guided and diverted into the raw molten aluminum, so as to enable rapid mixing to realize a required concentration of alloying elements.

6. An apparatus for realizing the method according to claim 1, comprising: a launder for molten aluminum and at least one guiding tube, which has a wire feeding device and is disposed in the launder for molten aluminum, wherein the wire feeding device is disposed at an inlet end of the at least one guiding tube and is connected with a movement control device, so as to adjust a feeding speed of the wire, and a temperature control device is disposed at an outlet end of the at least one guiding tube, so as to adjust a temperature of the wire when the wire enters the launder for molten aluminum; and the at least one guiding tube is a hollow curved tube, with the wire arranged inside, and a bending direction of the at least one guiding tube is the same as a flow direction of the molten aluminum in the launder for molten aluminum.

7. The apparatus according to claim 6, wherein a depth of the at least one guiding tube located inside the launder for molten aluminum is ½˜⅔ of a depth of the launder.

8. The apparatus according to claim 6, wherein the temperature control device comprises an electric temperature transmitter module, an electronic potentiometer module, an electric controller module and a silicon controlled rectifier voltage regulator module, wherein a temperature change is measured by a thermocouple, and converted into 0˜10 mA of a DC current signal, which is a standard signal of a model meter, through an electric temperature transmitter, and the DC current signal is transmitted to an electronic potentiometer and an electric controller, respectively, wherein the electric controller outputs 0˜10 mA of the DC current signal based on a calculation pursuant to a predetermined control rule, according to a magnitude and direction of a bias, and transmits the DC current signal to a silicon controlled rectifier voltage regulator, thereby adjusting an AC voltage to realize an automatic control.

9. The method for synchronously melting and preparing alloy according to claim 2, wherein an alloy with a high melting point refers to Al—Mn, Al—Fe and Al—Cr.

10. The apparatus according to claim 6, wherein the wire is an alloy wire or a pure metal wire; and an alloy with a high melting point refers to an alloy with a melting point higher than that of pure aluminum.

11. The apparatus according to claim 6, wherein an alloy with a high melting point refers to Al—Mn, Al—Fe and Al—Cr.

12. The apparatus according to claim 6, wherein the wire feeding speed Vwire is determined according to a flow rate V1 of the raw molten aluminum in the launder, wherein Vwire=kV1, where k is a fixed constant.

13. The apparatus according to claim 6, wherein the real-time forming refers to: in order to make the wire quickly be dissolved into the raw molten aluminum, a method of high-frequency instantaneous heating is applied to melt an alloy with a high melting point while the wire is being fed, so that a melted alloy is able to be guided and diverted into the raw molten aluminum, so as to enable rapid mixing to realize a required concentration of alloying elements.

Description

BRIEF DESCRIPTION OF DRAWINGS

[0015] FIG. 1 is a schematic diagram of the apparatus of the present disclosure;

[0016] where 1 wire feeding device, 2 wire, 3 ceramic guiding tube, 4 high frequency induction coil, 5 launder, 6 movement control device, 7 temperature control device, 8 molten drop, 9 raw molten aluminum.

DETAILED DESCRIPTION OF EMBODIMENTS

Embodiment 1

[0017] As indicated in FIG. 1, the present embodiment relates to the synchronously melting and preparing alloy, comprising: several sets of guiding tube 3 having wire feeding device 1, wherein the outlet end of each of the guiding tubes 3 is disposed in the launder 5 and outlet end of each of the guiding tubes 3 is provided with a high frequency induction coil 4 connected to the temperature control device 7. The wire feeding device 1 is connected to the movement control device 6, so as to control the speed of the wire 2 entering the launder 5, and the outlet end of the guiding tube 3, heated by the high frequency induction coil 4, melts the wire 2 into molten drops 8 and introduces the same into the raw molten aluminum 9.

[0018] The guiding tubes 3 are immersed in the raw molten aluminum 9.

[0019] During the alloying process, the raw molten aluminum flows stably in the launder at the speed of v.sub.L (<3 m/s); the alloy wire required to be added, which has a diameter of d.sub.1, d.sub.2, d.sub.3 (<30 mm), respectively, is fed into the ceramic guiding tubes through the wire feeding devices at the speed of v.sub.1, v.sub.2, v.sub.3 (<5 m/s), respectively. The wire feeding speed is correlated with the concentration level of this element in the ingot to be prepared, and is controlled by the movement control device. Driven by the wire feeding device, the alloy wire moves downward in the ceramic guiding tube. The high frequency induction coils are controlled by the temperature control device to heat the corresponding local areas up to the temperatures of T.sub.1, T.sub.2, T.sub.3 (>melting point of the alloy wire), respectively, such that the alloy wire is rapidly melted to form molten drops, and the formed molten drops continue to enter into the raw molten aluminum along the ceramic guiding tubes, thereby achieving the alloying and uniform distribution along with the movement of the raw molten aluminum.

[0020] The guiding tube 3 having the wire feeding device 1 may be determined according to the number of elements to be added, and multiple sets can work simultaneously to achieve the online alloying of multiple alloying elements at the same time. After the alloying is completed, the alloy melt can enter the casting apparatus for casting to form an ingot.

[0021] In this embodiment, the Al—Mg—Si alloy was prepared by the above-mentioned apparatus: the raw molten aluminum was controlled to flow stably in the launder at the speed of 0.22 m/s, and the pure magnesium wire with a diameter of 1.8 mm and the Al-20Si alloy wire with a diameter of 3.0 mm were fed into the ceramic guiding tubes by the wire feeding devices at speeds of 1.8 cm/s and 2.6 cm/s, respectively. Driven by the wire feeding devices, the alloy wire moved downward in the ceramic guiding tubes. The high frequency induction coils were controlled by the temperature control device to heat the corresponding local areas up to the temperatures of 700° C. and 720° C., respectively, such that the alloy wire was rapidly melted to form molten drops, and the formed molten drops continued to enter into the raw molten aluminum along the ceramic guiding tubes, thereby achieving the alloying and uniform distribution along with the movement of the raw molten aluminum. The alloy melt entered the casting apparatus for casting to form Al—Mg—Si alloy ingot.

Embodiment 2

[0022] In this embodiment, the Al—Zn—Mg—Cu alloy with composition gradient was prepared by the above-mentioned apparatus: the raw molten aluminum was controlled to flow stably in the launder at the speed of 0.28 m/s, and pure zinc wire with a diameter of 4.0mm, pure magnesium wire with a diameter of 1.8mm, and an Al-20 Cu alloy wire with a diameter of 1.5 mm were fed into the ceramic guiding tubes by the wire feeding devices at speeds of 2.2 cm/s, 2.5 cm/s and 1.8 mm/s, respectively. Driven by the wire feeding devices, the alloy wire moved downward in the ceramic guiding tubes. The high frequency induction coils were controlled by the temperature control device to heat the corresponding local areas up to the temperatures of 460° C., 700° C. and 740° C., respectively, such that the alloy wire was rapidly melted to form molten drops, and the formed molten drops continued to enter into the raw molten aluminum along the ceramic guiding tubes, thereby achieving the alloying and uniform distribution along with the movement of the raw molten aluminum. The alloy melt entered the casting apparatus for casting to form Al—Zn—Mg—Cu alloy ingot. During the preparation process, the wire feeding speed of the pure zinc wire was uniformly reduced (wherein the wire feeding speed is reduced by 0.1 cm/s every 5 minutes), and the wire feeding speed of the pure zinc wire was reduced to 1.0 cm/s after the casting was completed. Tests indicate that the zinc content of the prepared alloy was 6.5% at the head of the ingot and 3% at the tail of the ingot, with a uniform gradient change from the head to the tail of the ingot.

[0023] The specific embodiments above may be partially adjusted by those skilled in the art in different ways without departing from the principle and purpose of the present disclosure. The protection scope of the present disclosure should be subject to the claims and is not limited by the specific embodiments above. All implementation solutions within the scope thereof are bound by the present disclosure.