1) gas metal arc welding
熔化极气体保护焊
1.
Application of Digital Processing Method in the Submerged Arc Welding and Gas Metal Arc Welding;
数字处理方法在埋弧焊和熔化极气体保护焊中的应用
2.
Some welding parameters attribute values,such as current,voltage etc,were acquisited in GMAW(gas metal arc welding) process.
检测了熔化极气体保护焊(GMAW)中焊接电流和电弧电压大小等参数特征,利用数字信号分析与处理中的时域自相关特性原理,分析GMAW熔滴过渡过程的稳定性与参数关系,判断焊接电流和电压是否具有周期性。
3.
An investigation was made to the gas metal arc welding(GMAW) systems, and further for the control purpose a dynamic system and control model was proposed according to the characteristics of the GMAW systems.
在分析熔化极气体保护焊(GMAW)的基础上,建立电流及弧长的非线性数学模型。
2) GMAW
熔化极气体保护焊
1.
Gas metal arc welding(GMAW) is the main welding method in welding production.
熔化极气体保护焊(GMAW)是焊接生产中常用的焊接方法之一。
2.
The technology of numerical simulation for metal transfer in GMAW is one of the front and research hotspot in the weld filed , which has achieved great progress in recent years.
熔化极气体保护焊熔滴过渡数值模拟作为焊接学科的前沿领域和研究的热点之一,近年来已经取得了较大的进展。
3.
Gas metal arc welding (GMAW) has been widely used in automatic welding,where the quality problem often appears during the disturbance.
熔化极气体保护焊 (GMAW )广泛地应用于自动焊中 ,其焊接过程在干扰存在的情况下易产生焊接质量问题 ,因此 ,自动焊中焊接质量的在线监测已成为制造业中亟待解决的问题之一。
3) MIG
[英][miɡ] [美][mɪɡ]
熔化极气体保护焊
1.
The arc electrical signals were collected the data acquisition system in the plasma-MIG welding process, and the U-t、I-t、U-I diagrams analyzed with the Labview software were obtained.
比较了熔化极等离子弧焊与常规熔化极气体保护焊电弧电信号的不同,前者电流、电压波动很小,后者波动很大;研究了熔化极等离子弧焊接方法中MIG电流增大对电弧电信号的影响,并对熔化极等离子弧焊接的不稳定电弧电信号进行了分析,发现内弧对外弧的影响有一定规律性。
2.
Microstructure and properties of repaired welding area in large aluminum alloy ZL114A castings by MIG(Metal Inertia Gas) welding technology were studied.
研究了ZL114A合金大型铸件熔化极气体保护焊 (MIG)焊补区域的组织与性能。
3.
10mm-5A06 aluminum alloy was butt-welded in a single pass by the plasma-gas metal arc (plasma-MIG) welding procedure, the joints were subjected to X-ray inspection, the microstructure and mechanical performance of weld were also studied.
结果表明:与常规的铝合金熔化极气体保护焊相比在减少焊缝气孔、提高焊接接头质量、增大熔敷速率方面有显著的优越性。
4) metal inert-gas welding
熔化极隋性气体保护焊
5) GMAW-P process
熔化极脉冲气体保护焊
6) non-consumable gas shielded arc welding
非熔化极气体保护焊
1.
Application of non-consumable gas shielded arc welding controlled by magnetic field;
磁控电弧焊接工艺在非熔化极气体保护焊中的应用
补充资料:熔化极惰性气体保护焊
熔化极惰性气体保护焊
metal inert gas welding
ronghuaJ一duox一ngq}tl boohuhan熔件极惰性气体保护焊(m·‘a,‘n二‘g二半弓{户少甲.、_是利用金属焊丝作电极,以连续送遥的亨垄气竺材之间形成电弧加热金属,以惰碳床露矛杏弧和熔融的熔池的电弧,焊接方滋’裔百益焊 一,,.,「J‘,孟人、J O 实心焊丝 通保护气休/ 仃走方向、、/详终甘相导电嘴 ’一’~一~、~衫认龟J拍、、一飞体保护 母材一,翩 MIG焊示意图MIG焊金属熔滴过渡的形式主要采用喷射过渡,电弧燃烧稳定,无飞溅现象。与TIG焊相比,MIG焊电流可以大大提高,熔透深度增加。焊接过程为自动或半自动方式,适合于各种金属的中、厚板的焊接,主要用于易氧化的有色金属、稀有金属、不锈钢和高合金钢的焊接。 (田志凌)
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