1) weld pool development
熔池发展
2) molten pool
熔池
1.
Numerical analysis for molten pool of TIG helium-arc spot-butt welding of tantalum sheet;
钽薄板微间隙TIG氦弧点对接焊熔池的数值分析
2.
The effect of welding parameters on molten pool of TIG helium-arc small-gap butt welding of tantalum sheet;
工艺参数对钽薄板小间隙TIG对接焊熔池的影响
3.
Numerical analysis of ternary alloy molten pool heated by electron gun;
电子枪加热三元合金熔池的数值分析
3) melting pool
熔池
1.
During LRF, the melting pool free surface serves as a moving window of laser power and powder mass input and a dynamic boundary of the LRF continuous growth domain, so the interaction between laser, powder and melting pool free surface is the basic problem that should be coped with in LRF process.
建立了描述激光快速成形过程中气/粉两相流送粉、粉末与熔池交互作用及激光熔覆成形温度场的联合模型。
2.
A transient, moving laser beam, three dimensional laser remelting mathematical model considering convection, diffusion and phase change process in laser melting pools and substrate was developed, which is suitable for the prediction of fluid flows, temperature field, liquid fraction field and phase change in solid, liquid and mash zone.
通过熔池深度的计算与实验值的比较验证了模型的正确性。
3.
The analytic results show that the growth direction of dendrites in the melting pool is obviously affected by the orientation of the matrix grain.
建立了枝晶尖端主长速度与激光荣扫描速度和固液界面前进速度的关系,根据此分析时熔池组织进行了预测,并与实验结果进行了比较,发现激光熔池中枝晶组织的生长方向强烈地受基材晶粒取向和激光束扫描方向的影响,枝晶生长条件下。
4) weld pool
熔池
1.
Current status and development trend of tridimensional monitoring and measurement technology for weld pool surface;
熔池表面三维检测与测量技术现状及发展趋势
2.
Dynamic monitoring of weld pool image for pulsed GTAW in welding scene;
焊接现场脉冲GTAW熔池图像动态检测
3.
Double-side visual sensing and image processing of weld pool in P-GMAW;
P-GMAW熔池双面视觉传感与图像处理
5) welding pool
熔池
1.
Test of fluid flow forming in A-TIG welding pool;
A-TIG焊熔池流体流动形态的测试
2.
Taking the plasma arc welding process as subject, this paper summarized some progress achieved on the simulation of welding arc and welding pool during plasma arc welding process.
以等离子弧焊接过程为对象,分别从焊接电弧和焊接熔池的角度,概括了近年来等离子弧焊接电弧及熔池数值模拟领域取得的一些进展,分析了现有数学模型中存在的问题,提出了今后的发展方向。
3.
The fluctuations of the keyhole bring about the surge of the welding pool,and the element distributions are decided by both.
利用计算机层析成像设备———工业CT分析了电子束焊缝中熔质密度分布 ,并进而分析了电子束焊接过程中熔池流动和小孔波动行为。
6) pool
[英][pu:l] [美][pul]
熔池
1.
Visual measuring and image processing of copper weld pool information;
焊接熔池信息图像检测和处理
2.
An image detect system with near infrared CCD(charge coupled devices) for monitoring the copper weld pool on the surface of steel was established.
建立了一个近红外CCD熔池动态信息的图像检测系统 ,用于钢表面铜熔池视觉信息的检测。
3.
A on-line adaptive PID closed-loop control system of TIG weld width was developed by the analysis of welding pool pictures taken by CCD camera and the research on the on-line adaptive PID control priciple.
本文在对采用CCD摄像机正面拍摄熔池图像并用微机进行图象处理,以及对参数在线自整定PID控制原理的研究基础上,设计了一种TIG焊参数在线自整定PID熔宽闭环控制系统。
补充资料:熔池熔炼炉解析
熔池熔炼炉解析
anallysis of bath smelting furnace
rongehi rongljonlu jiexi熔池熔炼炉解析(analysis of bath smeltingfumace)为实现熔池熔炼过程和设备的优化而进行的数学解析。熔池熔炼炉为火法冶金反应器中的一类。通过解析已提出的控制和最优化模型有:(l)热力学平衡计算模型;(2)表征熔池熔炼传递现象的熔体搅拌功计算模型;(3)瓦纽科夫熔炼炉的回归模型及列线图;(4)白银炼铜炉工艺参数优化模型。这些模型尚在发展中,但可用于工程开发与生产控制。 热力学平衡计算模型闪速熔炼和熔池熔炼以及吹炼都是动态过程,其化学反应以高速进行。和闪速熔炼一样,热力学平衡计算模型(见闪速炉解析)已用于解析诺兰达法中主要元素(铜、铁、硫、氧和510:)的行为。 熔体搅拌功计算模型熔池熔炼法的传热和熔池中强化熔炼能力,在很大程度上取决于喷嘴喷射气体给予熔池的强力搅拌混合。喷入熔体的气体所作的搅拌功可用下式表示: P。=0 .74QTln(l+尸mZ/P。)式中尸m为单位时间消耗的搅拌功W;Q为喷入熔体的气体流量L/s(标准状态);T为熔体的绝对温度,K;Pm为熔体密度g/cm“;Z为气体上升高度Cm;尸,为大气压力kg/cm,。表中比较了熔池熔炼与萃取混合、浮选、球磨、P一S铜转炉及底吹炼钢的搅拌功能耗数据。应该指出的是,底吹炼钢法的能耗较高。 各种过程搅拌功能耗的比较…蒸三牛,叩绪 续表根据原料的已知成分,需要的铜梳含铜量和渣含—一一一一一一一一下一一一一一一510,量计算数值a、,把式(7)和式(8)代入式(6), 赚磨、棒磨、自动磨矿}25一125山91+御92+山93一。叨)----一万)不—一—一一丁一一一一一—一一一所以-一一‘二一一一一一一一一书一一一一一一一一一g飞+92+93一1、z。,J 诺兰达炉}60要确定配料需要第三个方程,选择炉料含1定量 、*、,。}。二的硫作为其条件,得到方程式:—s,g一十s:92+5 393一s(川 方程组(9)一(11)的解可确定配料为得到给 瓦纽科夫熔炼炉的回归模型及列线图为了保证一,,泣二二石一‘。~,*。舒,。_,。二八。、、。,。 ‘、阻叮’\份孙刀‘,目,“’次土人J人以‘/,‘犷卜~定品位的铜铣所需氧气量,可根据过程的氧平衡得出正确选择瓦纽科夫炉的工艺制度及其控制方法,方便二_。~一,*,l_ha-,*,扁‘二,,l。、,.、,。‘、‘,、J1一咄胜”干f。趾’汗八万日”一“。’阴仄~伏’么’川““’公’zJ’入氧消耗于硫化铁和离解硫的氧化,炉料必须的耗氧量i一于算,在回归方程基础上编制了列线图来简化计算。
说明:补充资料仅用于学习参考,请勿用于其它任何用途。
参考词条