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Preparation of oriented alloy material by original position deep supercooling process

An alloy material and deep supercooling technology, applied in the field of materials, can solve the problems of high scrap rate, high production cost, difficult to control, etc., and achieve the effect of good effect, less volatile burning loss, and easy control

Inactive Publication Date: 2006-03-08
SHANGHAI JIAO TONG UNIV
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

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Problems solved by technology

Including power reduction method (PD), rapid solidification method (HRS), liquid cooling method (LMC), etc., but using these methods to prepare directional immiscible alloy materials, it is necessary to consider the interphase wetting, the height of the immiscible zone, and the liquid phase Many factors such as line slope, growth rate, and temperature gradient at the front of the solidification interface lead to complex actual production processes, difficult control, and high production costs.
After literature search, it was found that Chinese patent application number 03114937.5, publication number CN1431327A, patent name: method for preparing oriented Ni-Pb immiscible alloy by deep supercooling, this patent proposes a method for preparing oriented Ni-Pb alloy material by using deep supercooling technology In this paper, the method of triggering nucleation of Ni-Pb in the range of 70-110K undercooling is used to prepare oriented materials, but in the actual operation process, there are disadvantages that the trigger position and the size of the trigger point are difficult to control, which often leads to poor orientation effect. Ideal, high scrap rate
Also found in the search, Fu Hengzhi et al published "The solidification characteristics of near rapid and supercooling directional solidification” (solidification characteristics of near rapid deep supercooling directional solidification process), this paper proposes the technology of deep supercooling and directional triggering in two steps, and the effect is improved, but because of the two steps, As a result, the deep supercooling of the alloy obtained in the first step is difficult to maintain in the second step, and the directional trigger of the second step also has uneven melting temperature of the alloy, prone to clogging, and high scrap rate

Method used

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Examples

Experimental program
Comparison scheme
Effect test

Embodiment 1

[0014] Example 1: Preparation of Oriented Ni by Deep Supercooling 2 FeGa alloy

[0015] ① put Ni 2 Put the FeGa alloy material into the first quartz tube in the insulation shell, and add an appropriate amount of glass purifier on the upper and lower surfaces of the metal material; ② Vacuumize to 5×10 -3 After Pa, fill with 99.99% argon to 0.08MPa; ③Inductively heat the alloy to 1273K through a high-frequency induction coil, so that the purifying agent is melted and coated on the surface of the alloy; ④Raise the temperature to 1650K and keep it for 2 minutes; For 2 minutes, carry out "solidification-remelting-overheating" cycle processing. During the cycle processing, the temperature optical signal of the alloy is measured by the infrared probe. After being processed by the signal processing unit, the 3056 desktop recorder is used to continuously record the temperature change in real time and monitor the temperature of the alloy. supercooling. During the cooling process, whe...

Embodiment 2

[0016] Example 2: Preparation of Oriented Co by Deep Supercooling 2 NiGa alloy

[0017] ① will Co 2 Put the NiGa alloy material into the first quartz tube in the insulation shell, and add an appropriate amount of glass purifier on the upper and lower surfaces of the metal material; ② Vacuumize to 5×10 -3 After Pa, fill in 99.99% argon to 0.08MPa; ③ Inductively heat the alloy to 1323K through a high-frequency induction coil, so that the purifying agent is melted and coated on the surface of the alloy; ④ Raise the temperature to 1800K and keep it for 2 minutes; For 2 minutes, carry out "solidification-remelting-overheating" cycle processing. During the cycle processing, the temperature optical signal of the alloy is measured by the infrared probe. After being processed by the signal processing unit, the 3056 desktop recorder is used to continuously record the temperature change in real time and monitor the temperature of the alloy. supercooling. During the cooling process, wh...

Embodiment 3

[0018] Example 3: Preparation of Oriented Fe by Deep Supercooling 80 Ga 20 alloy

[0019] ① Fe 80 Ga 20 Put the alloy material into the first quartz tube in the insulation shell, and add an appropriate amount of glass purifier on the upper and lower surfaces of the metal material; ② Vacuumize to 5×10 -3 After Pa, fill in 99.99% argon to 0.08MPa; ③ Inductively heat the alloy to 1373K through a high-frequency induction coil, so that the purifying agent is melted and coated on the surface of the alloy; ④ Heat up to 1850K and keep it for 2 minutes; For 2 minutes, carry out "solidification-remelting-overheating" cycle processing. During the cycle processing, the temperature optical signal of the alloy is measured by the infrared probe. After being processed by the signal processing unit, the 3056 desktop recorder is used to continuously record the temperature change in real time and monitor the temperature of the alloy. supercooling. During the cooling process, when the superc...

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Abstract

A in-situ deep overcold process for preparing the oriented alloy material includes such steps as using HF induction heater and the combination of fused glass protection with cyclic overheat to make the Ni-Fe-Ga, Co-Ni-Ga, or Fe-Ga alloy in overcold state, heating the alloy to the soft point of quartz tube, and flowing the alloy from the first quartz tube to the second one whose bottom is in contact with molten Ga-In alloy.

Description

technical field [0001] The invention relates to a method for preparing an oriented alloy material, in particular to a method for preparing an oriented alloy material by in-situ deep supercooling, which belongs to the field of material technology. Background technique [0002] Magnetic materials are anisotropic, and the properties of materials with different orientations vary greatly. In order to meet practical engineering applications, materials scholars have successively proposed a series of orientation material preparation technologies. Including power reduction method (PD), rapid solidification method (HRS), liquid cooling method (LMC), etc., but using these methods to prepare directional immiscible alloy materials, it is necessary to consider the interphase wetting, the height of the immiscible zone, and the liquid phase Many factors such as line slope, growth rate, and temperature gradient at the front of the solidification interface lead to complex and difficult-to-con...

Claims

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Application Information

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Patent Type & Authority Patents(China)
IPC IPC(8): B22D27/04C22C1/00
Inventor 郑红星卢玉英夏明许刘剑李建国
Owner SHANGHAI JIAO TONG UNIV
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