Metal Arc(금속 아크)란 무엇입니까?
Metal Arc 금속 아크 - Regarding (i), we report on combining self-organization and 3D printing for light-scattering devices, stimuli-responsive liquid-crystal elastomer photoresists, and 3D polymer-metal architectures. [1] The invention "A four–plane cup-shaped trel-lis on metal arcs for vine growing with a square-nest planting scheme in the mecha-nized culture of vineyards is described. [2] Although non-equilibrium modeling should contribute to a deeper understanding of the gas–metal arc-welding (GMAW) process, no non-equilibrium model has been reported for GMAW processes, while several models have been reported for gas–tungsten arc-welding processes. [3] Metal architectures produced by this process have micron-scale resolution, are fully freeform and multiscale in geometry, and are made of dense metal, while the process speed largely exceeds what is achieved in current alternative metal microfabrication approaches. [4] This paper presents a novel approach to fabricate a highly sensitive capacitive pressure sensor by introducing a zinc oxide nanowire (ZnO NW) interlayers between the polydimethylsiloxane (PDMS)/electrodes interface in the conventional metal-insulator-metal architecture. [5] The metal multiplexed gratings are realized with two constitutive gratings and separated from a metallic ground plate by a thick dielectric spacer in order to construct the metal–insulator–metal architecture. [6] This requires their precise integration into functional heterojunctions, most commonly in the form of metal-molecule-metal architectures. [7](i)와 관련하여, 우리는 광산란 장치, 자극 반응성 액정 엘라스토머 포토레지스트 및 3D 폴리머-금속 아키텍처를 위한 자기 조직화 및 3D 인쇄 결합에 대해 보고합니다. [1] 발명품 "기계화 포도원 문화에서 사각형 둥지 식재 계획으로 포도 나무를 재배하기 위한 금속 호의 4면 컵 모양 격자 무늬가 설명되어 있습니다. [2] 비평형 모델링이 GMAW(가스-금속 아크 용접) 공정에 대한 더 깊은 이해에 기여해야 하지만 GMAW 공정에 대한 비평형 모델은 보고되지 않았으며 가스-텅스텐 아크 용접 공정에 대한 여러 모델이 보고되었습니다. . [3] 이 프로세스에 의해 생성된 금속 아키텍처는 미크론 규모의 분해능을 가지며 형상이 완전히 자유형이고 다중 규모이며 조밀한 금속으로 만들어지는 반면 프로세스 속도는 현재의 대체 금속 미세 가공 접근 방식에서 달성되는 것보다 훨씬 더 빠릅니다. [4] 이 논문은 기존의 금속-절연체-금속 아키텍처에서 PDMS(폴리디메틸실록산)/전극 인터페이스 사이에 산화아연 나노와이어(ZnO NW) 중간층을 도입하여 고감도 용량성 압력 센서를 제작하는 새로운 접근 방식을 제시합니다. [5] 금속 다중화 격자는 두 개의 구성 격자로 구현되며 금속-절연체-금속 아키텍처를 구성하기 위해 두꺼운 유전체 스페이서에 의해 금속 접지판과 분리됩니다. [6] 이를 위해서는 금속-분자-금속 아키텍처의 형태로 가장 일반적으로 사용되는 기능적 이종접합으로의 정밀한 통합이 필요합니다. [7]
low carbon steel 저탄소강
Different layers of a low-carbon Fe-Cr-C-Mo-Mn electrode were deposited on a plain low-carbon steel using shielded metal arc welding (SMAW). [1] Low carbon steel was welded using a shielded metal arc welding process (SMAW) and a single V-grooved butt joint was produced. [2] The work was conducted to study the effect of changing welding polarities using the shielded metal arc welding (SMAW) process on microstructure, microhardness, grain size, weld bead geometry and distortion of low carbon steel AISI 1020. [3] This experiment aims to study the relationship between nickel addition to the microstructure evolution and toughness of shielded metal arc welded SS400 low carbon steel plates. [4] The aim of this study is to optimize the process parameters for Pulsed gas metal arc welding (P-GMAW) of dissimilar metal joints involving stainless steel 304 and low carbon steel. [5] Usually, the welding processes like shielded metal arc welding, gas metal arc welding (GMAW), and electroslag welding are used for welding thick low carbon steel plates. [6] This work investigates the fatigue performance of 10 mm AISI C1018 low carbon steel plates welded with ER70S-6 using a gas metal arc welding-based spin-arc welding process. [7] In the experiment, high-speed welding was performed on typical low-carbon steel 3D zigzag-line welding seams using gas metal arc welding. [8] Low-carbon steel Q235B was successfully joined by plasma-pulsed gas metal arc welding (plasma-GMAW-P) with an external magnetic field. [9]저탄소 Fe-Cr-C-Mo-Mn 전극의 다른 층은 차폐 금속 아크 용접(SMAW)을 사용하여 일반 저탄소 강철에 증착되었습니다. [1] 저탄소강은 차폐 금속 아크 용접 공정(SMAW)을 사용하여 용접되었으며 단일 V-그루브 맞대기 이음이 생성되었습니다. [2] nan [3] 이 실험은 차폐 금속 아크 용접 SS400 저탄소 강판의 미세 구조 진화에 대한 니켈 첨가와 인성 사이의 관계를 연구하는 것을 목표로 합니다. [4] nan [5] nan [6] nan [7] nan [8] nan [9]
cold metal transfer 냉간 금속 이송
A proposed method using robotized gas metal arc welding-cold metal transfer to repair a “worst-case” scenario, linear crack like defect beneath the cladding, which extended into the reactor pressure vessel steel, was evaluated on laboratory scale in previous works (PVP2020-21233, PVP2020-21236). [1] The cold metal transfer (CMT) mode of gas metal arc welding (GMAW) was used. [2] Joining of dissimilar aluminium alloys with dissimilar thickness by using gas metal arc welding with cold metal transfer (GMAW-CMT) process, is the primary objective of this work. [3] Compared with the gas metal arc welding (GMAW), the cold metal transfer technology can significantly reduce the welding heat input owing to obtain the output current of almost zero in the droplet detaching, which has a greater advantage in additive manufacturing. [4] Components were deposited by short-circuiting and short-circuiting with pulse mode of droplet transfers using a commercial cold metal transfer gas metal arc welding (CMT-GMAW) power source. [5] Cold metal transfer-welding (CMT) process is an advanced variant of gas metal arc welding process characterized by reduced heat input in which the welding wire is retracted during the short circuit which allows sufficient time for the weld to cool before placing each drop. [6] Hence the main aim of this study is to compare the corrosion behaviour of H32 5052 Aluminium-galvanized mild steel joints welded by Gas metal arc welding-brazing (GMAW-brazing) and Cold metal transfer (CMT) techniques as a function of welding parameters viz. [7] An ABB robot was combined with the Cold Metal Transfer (CMT) Gas Metal Arc (GMA) process to deposit 20 layers of mild steel. [8]로봇화된 가스 금속 아크 용접-저온 금속 이송을 사용하여 "최악의" 시나리오, 원자로 압력 용기 강철로 확장된 피복재 아래의 선형 균열과 같은 결함을 수리하기 위해 제안된 방법은 이전 작업(PVP2020)에서 실험실 규모로 평가되었습니다. -21233, PVP2020-21236). [1] 가스 금속 아크 용접(GMAW)의 냉간 금속 전달(CMT) 모드가 사용되었습니다. [2] nan [3] nan [4] nan [5] nan [6] nan [7] nan [8]
gas tungsten arc 가스 텅스텐 아크
The main attention is paid to the parameters of the gas tungsten arc, plasma arc, and gas metal arc welding methods. [1] Sambungan las merupakan bagian sangat penting dalam sebuah kontruksi material yang didalamnya terdapat parameter-parameter penentu kualitas kekuatan dan ketangguhan material dalam menerima pembebanan tertentu, untuk mendapatkan kualitas maksimal penulis mencoba untuk mengangkat tema pengelasan kombinasi Shielded Metal Arc Welding (SMAW) dan Gas Tungsten Arc Welding (GTAW) dengan klasifikasi variasi arus metode pengelasan SMAW 95 A (arus rendah), 110 A (arus sedang), dan 125 A (arus tinggi), sedang pada metode pengelasan GTAW memakai arus 70 A, pada material pelat baja baja JIS SS400 dengan tebal 10 mm. [2] Conventional fusion welding processes like manual metal arc welding, gas metal arc welding, and gas tungsten arc welding are preferred to join the dissimilar metals. [3] Gas metal arc welding (GMAW), Gas Tungsten arc welding (GTAW) and shielded metal arc welding (SMAW) were chosen as widespread industrial welding techniques. [4] A high velocity air fuel thermal spraying process (HVAF), gas tungsten arc welding (GTAW or TIG), and shielded metal arc welding (SMAW) were used to prepare the deposit deposited/sprayed layers. [5] PurposeThe paper aims to analyze and compare the environmental performances of metal arc welding technologies: gas metal arc welding (GMAW), shielded metal arc welding (SMAW), gas tungsten arc welding (GTAW), submerged arc welding (SAW), and flux-cored arc welding (FCAW). [6] And the gas tungsten arc welding (GTAW) and gas metal arc welding (GMAW) models are used to conduct simulation experiments of welding process control to verify the feasibility of the controller preliminarily. [7] For welding of dissimilar metals, various methods are exploited including shielded metal arc welding (SMAW) and gas tungsten arc welding (GTAW). [8]가스 텅스텐 아크, 플라즈마 아크 및 가스 금속 아크 용접 방법의 매개 변수에 주요 관심을 기울입니다. [1] 용접 조인트는 특정 하중을 받을 때 재료의 강도와 인성의 품질을 결정하는 매개변수가 있는 재료 구성에서 매우 중요한 부분이며, 최대 품질을 얻기 위해 저자는 용접 조합의 주제를 올리려고 시도합니다. Shielded Metal Arc Welding(SMAW) 및 Gas Tungsten Arc Welding(GTAW) SMAW 용접 방식의 전류 변화를 95A(저전류), 110A(중전류), 125A(고전류)로 분류하여, GTAW 용접 방법은 10mm 두께의 JIS SS400 강판 재료에 70A의 전류를 사용합니다. [2] nan [3] nan [4] nan [5] nan [6] nan [7] nan [8]
wire arc additive 와이어 아크 첨가제
Purpose The use of a gas metal arc welding-based weld-deposition, referred to as wire-direct energy deposition or wire-arc additive manufacturing, is one of the notable additive manufacturing methods for producing metallic components at high deposition rates. [1] The gas metal arc welding (GMAW) based wire arc additive manufacturing (WAAM) process has been employed to deposit 5-layered NiTi alloy on the Titanium substrate using Ni50. [2] This paper presents the integration of wire-arc additive manufacturing (WAAM) using Gas Metal Arc Welding (GMAW) into a machine tool to create a retrofit hybrid computer numeric control (CNC) machine tool. [3] In this study, a wire arc additive manufacturing system based on cold metal transfer gas metal arc welding technology was used to fabricate a solid block component with ER70S6 MS alloy welding wire. [4] In wire arc additive manufacturing of Ti-alloy parts (Ti-WAAM) gas metal arc welding (GMAW) can be applied for complex parts printing. [5] Fabrication of thin-walled titanium structures by a gas metal arc based wire arc additive manufacturing process is considered challenging due to arc instability. [6] ABSTRACT Gas metal arc welding based on wire arc additive manufacturing was adopted to fabricate a non-equiatomic Al2. [7]목적 와이어 직접 에너지 증착 또는 와이어 아크 적층 제조라고 하는 가스 금속 아크 용접 기반 용접 증착의 사용은 높은 증착 속도로 금속 부품을 생산하기 위한 주목할만한 적층 제조 방법 중 하나입니다. [1] 가스 금속 아크 용접(GMAW) 기반 와이어 아크 적층 제조(WAAM) 공정은 Ni50을 사용하여 티타늄 기판에 5층 NiTi 합금을 증착하는 데 사용되었습니다. [2] nan [3] nan [4] nan [5] nan [6] nan [7]
submerged arc welding 서브머지드 아크 용접
The temperature decrease of the metal surface was also limited by the slag covering the metal surface, leading to a higher surface temperature in submerged arc welding than in gas metal arc welding. [1] In this study, Submerged Arc Welding (SAW) and Gas Metal Arc Welding (GMAW) processes were used in multi-pass welding of 33 mm thickness super duplex stainless steel plates. [2] The welding coupons were prepared with submerged-arc welding, gas-tungsten arc welding, and shielded-metal arc welding, using ferritic steel, SA-508 Gr. [3] In this paper, a kind of new cryogenic high manganese steel was welded with nickel-based welding materials by shielded metal arc welding (SMAW) and submerged arc welding (SAW). [4] Conventionally, welding processes include Shielded Metal Arc Welding (SMAW), Gas Metal Arc Welding (GMAW), Submerged Arc Welding (SAW) & Gas Tungsten Arc Welding (GTAW). [5] This paper presents a methodology to compare three welding processes, namely SAW (submerged arc welding), SMAW (shield metal arc welding) and GMAW (gas metal arc welding) and to select the best one for a given application. [6]금속 표면의 온도 감소는 또한 금속 표면을 덮고 있는 슬래그에 의해 제한되어 가스 금속 아크 용접보다 서브머지드 아크 용접에서 더 높은 표면 온도로 이어졌습니다. [1] 본 연구에서는 33mm 두께의 슈퍼듀플렉스 스테인리스 강판의 다중 패스 용접에 SAW(Submerged Arc Welding) 및 GMAW(Gas Metal Arc Welding) 공정을 사용했습니다. [2] nan [3] nan [4] nan [5] nan [6]
flux cored arc 플럭스 코어드 아크
This study aimed to compare the hardfacing between welding methods, such as shielded metal arc welding, flux-cored arc welding, and submerged arc welding with and without added metal powders that will give optimum longevity. [1] , total chromium (Cr), iron (Fe), lead (Pb), manganese (Mn), and nickel (Ni)) were experimentally determined for the gas metal arc welding and flux cored arc welding processes, which are commonly used in shipyards. [2] Three weldments with various inclusion contents were manufactured using different shielding gas compositions and welding processes: gas metal arc welding (GMAW) with 100% argon (Ar), GMAW 85% Ar/15% carbon dioxide (CO2), and flux cored arc welding (FCAW) 75% Ar/25% CO2. [3] The article describes a replacement and benefits between manual gas metal arc welding (GMAW) with solid wire and semi-automatic flux-cored arc welding (FCAW) with metal flux-cored wire for a specific application of a welded steel compensator used for connecting piping systems to form larger units. [4] The adjusted geometric means of flux-cored arc welding, metal inert and active gas welding, shielded metal arc welding and torch cutting ranged from 0. [5]이 연구는 최적의 수명을 제공하는 금속 분말을 첨가하거나 첨가하지 않은 차폐 금속 아크 용접, 플럭스 코어드 아크 용접 및 서브머지드 아크 용접과 같은 용접 방법 간의 표면 경화를 비교하는 것을 목표로 했습니다. [1] , 조선소에서 일반적으로 사용되는 가스 금속 아크 용접 및 플럭스 코어드 아크 용접 공정을 위해 총 크롬(Cr), 철(Fe), 납(Pb), 망간(Mn) 및 니켈(Ni)을 실험적으로 결정했습니다. . [2] nan [3] nan [4] nan [5]
austenitic stainless steel 오스테나이트계 스테인리스강
In this investigation, 15-mm-thick UHA steel plates are welded by shielded metal arc welding (SMAW) process using three different consumables such as austenitic stainless steel (ASS), low-hydrogen ferritic steel (LHF), and duplex stainless steel (DSS). [1] This investigation reviews various welding techniques including gas metal arc welding, shielded metal arc welding, friction welding, laser welding, tungsten inert gas welding, activated tungsten inert gas welding, and hybrid laser welding used for joining different grades of super austenitic stainless steel. [2] In this investigation, dissimilar armor-grade steels (rolled homogenous armor (RHA) steels and ultra-high hard armor (UHA) steel) are welded using three electrodes, namely low hydrogen ferritic (LHF), austenitic stainless steel (ASS), and duplex stainless steel (DSS) by shielded metal arc welding (SMAW) process. [3] The composition of shielding gas exerts a crucial influence on high nitrogen austenitic stainless steel (HNASS) deposited by gas metal arc additive manufacturing. [4] The purpose of this study is to propose a method to decide near optimal settings for the welding process parameters in pulsed gas metal arc welding (P-GMAW) of AISI 904L super austenitic stainless steel by using grey relational analysis. [5]본 연구에서는 15mm 두께의 UHA 강판을 ASS(Austenitic Stainless Steel), LHF(Low Hydrogen Ferrite Steel), 이중 스테인리스강( DSS). [1] 이 조사에서는 가스 금속 아크 용접, 차폐 금속 아크 용접, 마찰 용접, 레이저 용접, 텅스텐 불활성 가스 용접, 활성 텅스텐 불활성 가스 용접 및 다양한 등급의 슈퍼 오스테나이트 스테인리스강 접합에 사용되는 하이브리드 레이저 용접을 포함한 다양한 용접 기술을 검토합니다. [2] nan [3] 차폐 가스의 조성은 가스 금속 아크 적층 가공으로 증착된 고질소 오스테나이트 스테인리스강(HNASS)에 결정적인 영향을 미칩니다. [4] nan [5]
arc additive manufacturing 아크 적층 제조
In this paper, 18Ni (350) maraging steel thin-wall parts were fabricated by gas metal arc-based wire and arc additive manufacturing (GMA-based WAAM). [1] Wire plus arc additive manufacturing (WAAM) technology is utilized to fabricate a 347 stainless steel (SS347) plate using the gas metal arc welding process. [2] Wire and arc additive manufacturing (WAAM) based on gas metal arc welding (GMAW) is a potential technology for fabricating large-scale metallic structures due to its high deposition rate, high energy efficiency, and low cost. [3] ,In this work, a gas metal arc welding (GMAW) based wire + arc additive manufacturing (WAAM) system has been developed to use two material successively and fabricate bimetallic additively manufactured structure (BAMS) of low carbon steel and AISI 316L stainless steel (SS). [4]이 논문에서 18Ni(350) 마레이징 강철 박막 부품은 가스 금속 아크 기반 와이어와 아크 적층 가공(GMA 기반 WAAM)으로 제작되었습니다. [1] 와이어 플러스 아크 적층 제조(WAAM) 기술은 가스 금속 아크 용접 공정을 사용하여 347 스테인리스강(SS347) 플레이트를 제작하는 데 사용됩니다. [2] nan [3] nan [4]
duplex stainless steel 이중 스테인레스 스틸
In this paper, shielded metal arc welding on the dissimilar joint between 2205 duplex stainless steel and composite bimetallic plates (304 L stainless steel/10CrNi3MoV steel) with a filler metal E2. [1] This research tends to investigate the influence of shielded metal arc welding (SMAW) parameters and flux compositions on the metallurgy of welded AISI 2205 duplex stainless steel (DSS). [2] Super duplex stainless steel (UNS S32750) butt joints were prepared using ER2594 and ER2595 electrodes by shielded metal arc welding (SMAW) process. [3]이 논문에서는 2205 듀플렉스 스테인리스강과 복합 바이메탈 플레이트(304 L 스테인리스강/10CrNi3MoV 강) 사이의 이종 접합부에서 용가재 E2를 사용한 차폐 금속 아크 용접을 수행했습니다. [1] 이 연구는 용접된 AISI 2205 이중 스테인리스강(DSS)의 야금에 대한 차폐 금속 아크 용접(SMAW) 매개변수 및 플럭스 조성의 영향을 조사하는 경향이 있습니다. [2] nan [3]
heat affected zone 열영향부
Since heat affected zone (HAZ) is the weak area of welded joints, this article proposes a method to predict the HAZ microstructure and hardness for the triple-wire gas metal arc welding (GMAW) process of Q960E high strength steel. [1] This study aimed to investigate the heat-affected zone (HAZ) behavior in an API 5L X70 steel welded by the gas metal arc welding process (GMAW). [2] 1 software and an experimental investigation using gas metal arc welding (GMAW) process with fully austenite filler wire were applied to developed thermal cycle and evaluate residual stress in the heat-affected zone of both materials. [3]HAZ(열영향부)는 용접 접합부의 취약한 부분이므로, 본 논문에서는 Q960E 고강도강의 GMAW(Triple-Wire Gas Metal Arc Welding) 공정에서 HAZ 미세조직 및 경도를 예측하는 방법을 제안한다. [1] 이 연구는 가스 금속 아크 용접 공정(GMAW)으로 용접된 API 5L X70 강철의 열영향부(HAZ) 거동을 조사하는 것을 목표로 했습니다. [2] nan [3]
external magnetic field 외부 자기장
A few typical examples such as external magnetic field-assisted gas metal arc welding, ultrasonic vibration-assisted gas tungsten/metal arc welding, and ultrasonic-assisted plasma arc welding are introduced to demonstrate their system, principle and effectiveness. [1] A compound external magnetic field (EMF) can be used to prevent weld bead defects by controlling the metal transfer and arc behaviors during high-speed gas metal arc welding. [2]외부 자기장 보조 가스 금속 아크 용접, 초음파 진동 보조 가스 텅스텐/금속 아크 용접 및 초음파 보조 플라즈마 아크 용접과 같은 몇 가지 일반적인 예를 소개하여 시스템, 원리 및 효과를 보여줍니다. [1] 복합 외부 자기장(EMF)은 고속 가스 금속 아크 용접 중 금속 전달 및 아크 거동을 제어하여 용접 비드 결함을 방지하는 데 사용할 수 있습니다. [2]