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    • 1. 发明申请
    • METHOD OF UNIDIRECTIONAL SOLIDIFICATION OF CASTINGS AND ASSOCIATED APPARATUS
    • 铸造和相关设备的单向固化方法
    • WO2007009060A9
    • 2008-01-17
    • PCT/US2006027348
    • 2006-07-12
    • ALCOA INCCHU MEN GYU HOGIRON ALVAROKALLAHER KENNETH JSHAW JEFFREY J
    • CHU MEN GYU HOGIRON ALVAROKALLAHER KENNETH JSHAW JEFFREY J
    • B22D7/02B22D7/06
    • B22D7/02B22D7/06B22D7/064Y10S428/939Y10T428/12493Y10T428/12764
    • Molten metal is injected uniformly into a mold from a feed chamber in a horizontal or vertical direction at a controlled rate, directly on top of the metal already within the mold. A cooling medium is applied to the bottom surface of the substrate, with the type and flow rate of the cooling medium being varied to produce a controlled cooling rate throughout the casting process. The rate of introduction of molten metal and the flow rate of the cooling medium are both controlled to produce a relatively uniform solidification rate within the mold, thereby producing a uniform microstructure throughout the casting, and low stresses throughout the casting. A multiple layer ingot product is also provided comprising a base alloy layer and at least a first additional alloy layer, the two layers having different alloy compositions, where the first additional alloy layer is bonded directly to the base alloy layer by applying the first additional alloy in the molten state to the surface of the base alloy while the surface temperature of the base alloy is lower than the liquidus temperature and greater than eutectic temperature of the base alloy - 50 degrees Celsuis.
    • 熔融金属以受控的速率在水平或垂直方向上从进料室均匀地注入到模具中,直接在已经在模具内的金属的顶部上。 将冷却介质施加到基底的底表面,其中冷却介质的类型和流速被改变以在整个铸造过程中产生受控的冷却速率。 控制熔融金属的引入速率和冷却介质的流量都被控制以在模具内产生相对均匀的凝固速率,从而在铸件中产生均匀的微观结构,并且在整个铸件中产生低应力。 还提供了多层锭产品,其包括基底合金层和至少第一附加合金层,所述两层具有不同的合金组成,其中第一附加合金层通过施加第一附加合金直接结合到基底合金层 在基体合金的表面温度低于液相线温度并且大于基体合金的共晶温度(50℃Celsuis)时,处于熔融状态。
    • 2. 发明申请
    • METHOD OF UNIDIRECTIONAL SOLIDIFICATION OF CASTINGS AND ASSOCIATED APPARATUS
    • 单向凝固铸件及相关设备的方法
    • WO2007009060A3
    • 2007-10-25
    • PCT/US2006027348
    • 2006-07-12
    • ALCOA INCCHU MEN GYU HOGIRON ALVAROKALLAHER KENNETH JSHAW JEFFREY J
    • CHU MEN GYU HOGIRON ALVAROKALLAHER KENNETH JSHAW JEFFREY J
    • B22D7/02B22D7/06
    • B22D7/02B22D7/06B22D7/064Y10S428/939Y10T428/12493Y10T428/12764
    • Molten metal is injected uniformly into a mold from a feed chamber in a horizontal or vertical direction at a controlled rate, directly on top of the metal already within the mold. A cooling medium is applied to the bottom surface of the substrate, with the type and flow rate of the cooling medium being varied to produce a controlled cooling rate throughout the casting process. The rate of introduction of molten metal and the flow rate of the cooling medium are both controlled to produce a relatively uniform solidification rate within the mold, thereby producing a uniform microstructure throughout the casting, and low stresses throughout the casting. A multiple layer ingot product is also provided comprising a base alloy layer and at least a first additional alloy layer, the two layers having different alloy compositions, where the first additional alloy layer is bonded directly to the base alloy layer by applying the first additional alloy in the molten state to the surface of the base alloy while the surface temperature of the base alloy is lower than the liquidus temperature and greater than eutectic temperature of the base alloy - 50 degrees Celsuis.
    • 熔融金属从进料室以水平或垂直方向以受控速率均匀注入模具中,直接位于模具内已有金属的顶部。 将冷却介质施加到基底的底部表面,其中冷却介质的类型和流量变化以在整个浇铸过程中产生受控的冷却速率。 控制熔融金属的引入速率和冷却介质的流量以在模具内产生相对均匀的凝固速率,由此在整个铸造过程中产生均匀的微观结构,并且在整个铸造过程中具有低应力。 还提供了多层铸锭产品,其包括基础合金层和至少第一附加合金层,这两个层具有不同的合金成分,其中第一附加合金层通过将第一附加合金直接结合到基础合金层 在基体合金表面以熔融状态存在,而基体合金的表面温度低于液相温度并且大于基体合金的共晶温度-50摄氏度。
    • 3. 发明专利
    • Controlled fluid flow mold and molten metal casting method for improved surface
    • 控制流体流动模型和改进表面的金属铸造方法
    • JP2006035312A
    • 2006-02-09
    • JP2005187624
    • 2005-06-28
    • Alcoa Incアルコア インコーポレイテッド
    • CHU MEN GGIRON ALVAROCASADA WILLIAM AYU HO
    • B22D11/04B22D11/00B22D11/049
    • B22D11/0401B22D11/049
    • PROBLEM TO BE SOLVED: To provide a mold structure where the flow of a molten metal is controlled in such a manner that the quantity of oxides present on an ingot surface can be made minimum in DC casting for aluminum.
      SOLUTION: A DC casting mold 200 comprises a cooling tubular body 100 that has a thermally insulated insert 400 attached to its top surface. The thermally insulated insert has a bottom portion with a beveled sidewall 402, which forms an angle with a horizontal plane layer 130 of the molten metal and creates an eddy. The eddy causes a substantial number of oxides that are formed during the casting process to remain in the bottom sidewall portion of the thermally insulated insert of the mold, thereby substantially reducing the number of ingot surface imperfections that promote ingot cracking. In addition, the eddy promotes break-up of the oxides into smaller pieces as the oxides flow toward the cooled inner walls of the cooled tubular body, thereby having limited surface area for growth of an oxide layer.
      COPYRIGHT: (C)2006,JPO&NCIPI
    • 要解决的问题:提供一种模具结构,其中以这样一种方式控制熔融金属的流动,使得在铝的直流铸造中,在铸锭表面上存在的氧化物的量可以最小化。 解决方案:直流铸造模具200包括具有附接到其顶表面的绝热插入件400的冷却管状体100。 绝热插入件具有底部,其具有倾斜的侧壁402,其与熔融金属的水平面层130形成一角度并产生涡流。 涡流导致在铸造过程中形成的大量氧化物保留在模具的绝热插入件的底部侧壁部分中,从而大大减少了促进锭裂纹的锭表面缺陷的数量。 此外,当氧化物流向冷却的管状体的冷却的内壁时,涡流促进氧化物分解成更小的部分,从而具有有限的氧化物层生长的表面积。 版权所有(C)2006,JPO&NCIPI
    • 4. 发明专利
    • Method of unidirectional solidification of casting and associated apparatus
    • 铸造和相关设备的非均匀固化方法
    • JP2013027928A
    • 2013-02-07
    • JP2012209923
    • 2012-09-24
    • Alcoa Incアルコア インク.
    • CHU MEN GYU HOGIRON ALVAROKALLAHER KENNETH JSHAW JEFFREY J
    • B22D27/04B22D7/00
    • B22D7/02B22D7/06B22D7/064Y10S428/939Y10T428/12493Y10T428/12764
    • PROBLEM TO BE SOLVED: To provide an apparatus and method of unidirectional solidification casting that produces a uniformly controlled cooling rate.SOLUTION: Molten metal is injected uniformly into a mold 10 from a feed chamber 34 in a horizontal or vertical direction at a controlled rate on top of the metal already within the mold. A cooling medium is applied to the bottom surface of a base material, with the type and flow rate of the cooling medium being varied to produce a controlled cooling rate throughout the casting process. The rate of introduction of molten metal and the flow rate of the cooling medium are both controlled to produce a relatively uniform solidification rate within the mold, thereby producing a uniform microstructure throughout the casting, and low stresses throughout the casting.
    • 要解决的问题:提供产生均匀控制的冷却速率的单向凝固铸造的装置和方法。 解决方案:熔融金属在进料室34中以水平或垂直方向均匀地注入模具10中,控制速率在已经在模具内的金属的顶部上。 将冷却介质施加到基材的底表面,随着冷却介质的类型和流速的变化,以在整个铸造过程中产生受控的冷却速率。 控制熔融金属的引入速率和冷却介质的流量都被控制以在模具内产生相对均匀的凝固速率,从而在铸件中产生均匀的微观结构,并且在整个铸件中产生低应力。 版权所有(C)2013,JPO&INPIT
    • 9. 发明专利
    • BRPI0613728B1
    • 2014-07-08
    • BRPI0613728
    • 2006-07-12
    • ALCOA INC
    • CHU MEN GYU HOGIRON ALVAROKALLAHER KENNETH JSHAW JEFFREY J
    • B22D7/02B22D7/06
    • Molten metal is injected uniformly into a mold from a feed chamber in a horizontal or vertical direction at a controlled rate, directly on top of the metal already within the mold. A cooling medium is applied to the bottom surface of the substrate, with the type and flow rate of the cooling medium being varied to produce a controlled cooling rate throughout the casting process. The rate of introduction of molten metal and the flow rate of the cooling medium are both controlled to produce a relatively uniform solidification rate within the mold, thereby producing a uniform microstructure throughout the casting, and low stresses throughout the casting.; A multiple layer ingot product is also provided comprising a base alloy layer and at least a first additional alloy layer, the two layers having different alloy compositions, where the first additional alloy layer is bonded directly to the base alloy layer by applying the first additional alloy in the molten state to the surface of the base alloy while the surface temperature of the base alloy is lower than the liquidus temperature and greater than eutectic temperature of the base alloy - 50 degrees Celsuis.