Alloy Az31
합금 Az31

Alloy Az31(합금 Az31)란 무엇입니까?

Alloy Az31 합금 Az31 - This proposed corrosion model simulates the corrosion rate and its effects on magnesium (Mg) alloy AZ31 based on continuum damage mechanics. ^[1] The synthesis of Magnesium based alloy AZ31 using Magnesia Packed Sintering (MPS), an innovative approach in powder metallurgy is focused here. ^[2] To investigate the fan vibrations, modal analysis is also carried out using magnesium-alloy AZ31 as the fan material. ^[3] Plasma electrolytic oxidation (PEO) and a subsequent direct electroless nickel (EN) plating were carried out on magnesium (Mg) alloy AZ31B. ^[4] A Zinc-loaded montmorillonite (Zn-MMT) coating was hydrothermally prepared using Zn2+ ion intercalated sodium montmorillonite (Na-MMT) upon magnesium (Mg) alloy AZ31 as bone repairing materials. ^[5] Large pulsed electron beam (LPEB) irradiation was employed as a surface treatment of magnesium (Mg) alloy AZ31B to enhance its corrosion and wear resistance. ^[6]
이 제안된 부식 모델은 연속체 손상 역학을 기반으로 부식 속도와 마그네슘(Mg) 합금 AZ31에 미치는 영향을 시뮬레이션합니다. ^[1] 여기에서는 분말 야금의 혁신적인 접근 방식인 MPS(Magnesia Packed Sintering)를 사용한 마그네슘 기반 합금 AZ31의 합성에 초점을 맞춥니다. ^[2] 팬 진동을 조사하기 위해 팬 재료로 마그네슘 합금 AZ31을 사용하여 모달 해석도 수행되었습니다. ^[3] 플라즈마 전해 산화(PEO) 및 후속적인 직접 무전해 니켈(EN) 도금이 마그네슘(Mg) 합금 AZ31B에서 수행되었습니다. ^[4] 아연 로딩된 몬모릴로나이트(Zn-MMT) 코팅은 골 수복 재료로 마그네슘(Mg) 합금 AZ31에 Zn2+ 이온 삽입된 나트륨 몬모릴로나이트(Na-MMT)를 사용하여 열수적으로 준비되었습니다. ^[5] 부식 및 내마모성을 향상시키기 위해 마그네슘(Mg) 합금 AZ31B의 표면 처리로 LPEB(Large Pulsed Electron Beam) 조사를 사용했습니다. ^[6]

layered double hydroxide

Super-hydrophobic films were synthesized on the Mg alloy AZ31 by modifying in-situ grown Mg-Al layered double hydroxide (LDH) films with stearic acid (SA), sodium laurate (SL), myristic acid (MA) and 1H, 1H, 2H, 2H–perfluorodecyltrimethoxysilane (PFDTMS). ^[1] Mg-Al layered double hydroxides (LDHs) were deposited on the anodized magnesium alloy AZ31 via an easy in-situ method, and the surfaces of MgAl-LDHs were modified with myristic acid (MA) and 1H, 1H, 2H, 2H-Perfluorodecyltrimethoxysilane (PFDTMS). ^[2] A magnesium-aluminum layered-double-hydroxides (Mg Al LDHs) coating was fabricated on the surface of Mg alloy AZ31, followed by electrophoretic deposition of an Al2O3 nanoparticles layer. ^[3] A doublely-doped layered double hydroxide (LDH) film was produced on an anodized magnesium alloy AZ31. ^[4] Highly oriented Mg-Al layered double hydroxide (LDHs) films were deposited on magnesium alloy AZ31 with different deformation processes by an easy in-situ growth method. ^[5]
초소수성 필름은 스테아르산(SA), 라우르산나트륨(SL), 미리스트산(MA) 및 1H, 1H, 2H, 2H-퍼플루오로데실트리메톡시실란(PFDTMS). ^[1] 양극산화된 마그네슘 합금 AZ31에 Mg-Al 층상 이중 수산화물(LDHs)을 쉬운 in-situ 방법으로 증착하고 MgAl-LDHs의 표면을 미리스트산(MA)과 1H, 1H, 2H, 2H-Perfluorodecyltrimethoxysilane으로 개질했습니다. (PFDTMS). ^[2] nan ^[3] nan ^[4] nan ^[5]

Magnesium Alloy Az31 마그네슘 합금 Az31

A crosslinked ciprofloxacin (CIP) and polymethyltrimethoxysilane (PMTMS) with an inner micro-arc oxidation (MAO) coating was designed to improve the corrosion resistance and antibacterial property of magnesium alloy AZ31. ^[1] In the forming process of magnesium alloy AZ31B, the pulse current can significantly lift the elongation and reduce the flow stress. ^[2] This work investigates the influence of different barrier layers, based on plasma electrolytic oxidation (PEO) and PEO/sol-gel, on the galvanic corrosion between carbon fiber reinforced polymer (CFRP) and the magnesium alloy AZ31. ^[3] In this work, a commercial cast magnesium alloy AZ31 was compressed at room and cryogenic temperatures (RT and CT) to study how the twins and dislocations affect the flow stress, plastic strain and strain hardening. ^[4] Purpose: The current study examined magnesium alloy AZ31B specimens manufactured with Additive Manufacturing method (selective laser melting – SLM) to investigate the applicability of this technology for the production of medical devices. ^[5] A combination of advanced in-situ and ex-situ methods providing complementary information was employed in order to reveal the active deformation mechanisms during deformation of a heavily textured commercial magnesium alloy AZ31. ^[6] The subsequent tensile response of the magnesium alloy AZ31B sheet along the transverse direction and the rolling direction after pre-deformation is simulated. ^[7] The forming behaviors of magnesium alloy AZ31 is analyzed by free bulging tests at room temperature. ^[8] To investigate how dislocations and twins affect { 10 1 ‾ 2 } twinning, a rolled magnesium alloy AZ31 was pre-deformed along different directions and reloaded in in-plane compression at room temperature. ^[9] The dependence of normal anisotropy coefficient R on angle α in the sheet plane (angle α = 0° corresponds to the rolling direction) is determined in terms of a thermoactivation model of plastic deformation using the texture coefficients determined for magnesium alloy AZ31 sheets. ^[10] The effect of shot peening on mechanical properties and ballistic resistance of plates from magnesium alloy AZ31B 25 × 300 × 300 mm in size to the piercing action of a projectile (diameter 7. ^[11] In this study, (3-aminopropyl)-triethoxysilane–modified graphene oxide (GO) composite thin films were synthesized on magnesium alloy AZ31 substrate. ^[12] Magnesium alloy AZ31B is an important lightweight, high specific strength material for new generations of energy-effective vehicles. ^[13] The mechanical properties of magnesium alloy AZ31 were investigated experimentally with visco-plastic self-consistent modeling. ^[14] A concept for a flat band profile is elaborated and the impact on exemplary lightweight alloys, aluminum alloy AA6060 and magnesium alloy AZ31 is discussed. ^[15] In this study, magnesium alloy AZ31B is used as reinforcement material and graphene nanoparticle is used as reinforcement material. ^[16] This paper presents results obtained by ISIM Timisoara for FSW welding of magnesium alloy AZ31B. ^[17] In this study, the hybrid sol-gel silica-based coatings were investigated as sealants on anodized magnesium alloy AZ31 substrates. ^[18] The elastic visco-plastic self-consistent model with the twinning and detwinning scheme, in conjunction with a torsion specific finite element approach, is employed to model the deformation behavior of magnesium alloy AZ31 solid rod with different initial textures, including ideal basal, rolled, extruded, and random. ^[19] A magnesium alloy AZ31 sheet was processed by ultrasonic shot peening treatment to fabricate a surface nanocrystalline, and a ball-on-disk dry sliding wear test was performed to evaluate the tribological behavior after treatment. ^[20] In this study, the optimization of the symmetrical temperature distribution and process loading path for the warm T-shape forming of magnesium alloy AZ31B tube was carried out by finite element (FE) analysis using a fuzzy model. ^[21] The numerical simulations are compared with several reference results from the literature to validate the mechanical behavior of the particular HCP magnesium alloy AZ31. ^[22] The mechanical response of magnesium alloy AZ31B is addressed thanks to four-point bending tests. ^[23] In this study, the relationship between machining temperature and the accuracy of hole shapes in magnesium alloy AZ31 is investigated with four types of drills: high-speed steel, cemented carbide (K-Base), diamond-like carbon (DLC; K-Base), and TiN-coated cemented carbide (K-Base). ^[24] In this work, a series of high-rate tension experiments were performed on thin foil specimens of hot rolled magnesium alloy AZ31B using a miniaturized tensile Kolsky bar along an array of angles in the normal-rolling plane at strain rates of nominally 10 4 s − 1. ^[25] The starting texture from a rolled magnesium alloy AZ31B sheet was obtained using electron backscatter diffraction (EBSD) for initial input into the NVPSC. ^[26] In this work, we employed a unique solid-state joining process, friction self-piercing riveting (F-SPR), to join carbon fiber composites to the low-ductility magnesium alloy AZ31B. ^[27] In this research, the feedstocks with three magnesium alloy AZ31 powder loading of (63, 65, 67) vol%, was prepared comprising the binder component of paraffin wax, high density polyethylene, waste plastic, and stearic acid (PW/HDPE/WP/SA) with weight fraction 55/21/14/10, respectively. ^[28] This study aims to obtain fatigue life values with satisfactory results on the samples of magnesium alloy AZ31. ^[29] This study presents the advantages of fluoride-coated magnesium alloy AZ31 wires in unidirectionally reinforced Mg/PLA biodegradable composites. ^[30] A magnesium alloy AZ31 as plate of dimensions (60 x 60 x 3) mm has been constrained groove pressed (CGP) four deformation passes (16 pressings) at 250 oC by simulation and expremental. ^[31] In this work, the dip coating of dopamine on the surface of the magnesium alloy AZ31 is investigated to determine the effects of oxygen on the functionalization of the material. ^[32] The expansion test of BT S<< parallel strut) stent made from magnesium alloy AZ31 is conducted by using finite element analysis (FEA) with Abaqus software in order to find the value of mechanical performance aspects such as von mises, radial recoil, longitudinal recoil, foreshortening, and inflated diameter. ^[33] In this study, magnesium alloy AZ31 was successfully welded with aluminum alloy 6061 by diffusion bonding method. ^[34] Formation of these films enhanced the subsequent TLP bonding with the magnesium alloy AZ31. ^[35] The macroscopic deformation behavior of Magnesium alloy AZ31, a representative HCP material, is simulated in three different loading directions. ^[36] Billets of magnesium alloy AZ31 were extruded and the required extrusion force was measured vs. ^[37] Mg-Al layered double hydroxides (LDHs) were deposited on the anodized magnesium alloy AZ31 via an easy in-situ method, and the surfaces of MgAl-LDHs were modified with myristic acid (MA) and 1H, 1H, 2H, 2H-Perfluorodecyltrimethoxysilane (PFDTMS). ^[38] A doublely-doped layered double hydroxide (LDH) film was produced on an anodized magnesium alloy AZ31. ^[39] In this study the conversion of plastic work to heat of a hot-rolled magnesium alloy AZ31B is investigated using a mechanism-based approach. ^[40] Specific features of the strain hardening and unstable (jump-like) deformation of the microgranular magnesium alloy AZ31 deformed by tension at a temperature of 4. ^[41] Hot-extruded magnesium alloy AZ31 bar was cut into hexagonal prisms and then compressed at room temperature with the loading direction parallel to the extrusion direction (ED) or perpendicular to ED. ^[42] 0%) on the microstructure and mechanical properties of magnesium alloy AZ31 is studied after hot rolling with deformation of 15 and 30%. ^[43] In this paper, a deep drawing process of a cross-profile is realized to analyze the springback behavior of a magnesium alloy AZ31 at various forming temperatures. ^[44] The evolution of the structure and properties are analyzed for an aluminum alloy (AA) 5083 and a magnesium alloy AZ31 as model materials representing, respectively, the structural refinement under severe plastic deformation (SPD) via strain-induced formation of new grain boundaries and via dynamic recrystallization. ^[45] This research aims to characterize damage at the sheared edge caused by the blanking operation of magnesium alloy AZ31B sheets. ^[46] The aim of this paper is to analyse the surface roughness values of machined surface when drilling of magnesium alloy AZ31 using design of experiment of Taguchi Method. ^[47] Magnesium alloy AZ31 was reinforced with FA particles (10 vol. ^[48] Actual experiments of carbon steel 1045, high strength steel 42CrMo, and magnesium alloy AZ31 were carried out in a TSR testing mill. ^[49] In the present work, an effort has been made to optimize the external magnetic field (EMF) for mechanical properties of magnesium alloy AZ31B weld. ^[50]
내부 마이크로 아크 산화(MAO) 코팅이 있는 가교된 시프로플록사신(CIP) 및 폴리메틸트리메톡시실란(PMTMS)은 마그네슘 합금 AZ31의 내식성 및 항균성을 향상시키기 위해 설계되었습니다. ^[1] 마그네슘 합금 AZ31B의 성형 공정에서 펄스 전류는 신장률을 크게 높이고 유동 응력을 줄일 수 있습니다. ^[2] 이 연구는 탄소 섬유 강화 폴리머(CFRP)와 마그네슘 합금 AZ31 사이의 갈바닉 부식에 대한 플라즈마 전해 산화(PEO) 및 PEO/졸-겔을 기반으로 하는 다양한 장벽 층의 영향을 조사합니다. ^[3] 이 작업에서 상업용 주조 마그네슘 합금 AZ31을 실온 및 극저온 온도(RT 및 CT)에서 압축하여 쌍정 및 전위가 유동 응력, 소성 변형 및 변형 경화에 미치는 영향을 연구했습니다. ^[4] 목적: 본 연구에서는 이 기술을 의료기기 생산에 적용할 수 있는지 알아보기 위해 적층가공법(선택적 레이저 용융-SLM)으로 제조된 마그네슘 합금 AZ31B 시편을 조사하였다. ^[5] 심하게 질감이 있는 상업용 마그네슘 합금 AZ31의 변형 동안 활성 변형 메커니즘을 나타내기 위해 보완 정보를 제공하는 고급 현장 및 현장 외 방법의 조합이 사용되었습니다. ^[6] 사전 변형 후 가로 방향 및 압연 방향을 따라 마그네슘 합금 AZ31B 시트의 후속 인장 응답이 시뮬레이션됩니다. ^[7] 마그네슘 합금 AZ31의 성형 거동은 실온에서 자유 팽창 시험으로 분석됩니다. ^[8] 전위와 쌍정이 { 10 1 ‾ 2 } 쌍정에 미치는 영향을 조사하기 위해 압연 마그네슘 합금 AZ31을 다른 방향으로 미리 변형하고 실온에서 평면 내 압축으로 재하중했습니다. ^[9] 시트 평면의 각도 α에 대한 수직 이방성 계수 R의 의존성(각도 α = 0°은 압연 방향에 해당)은 마그네슘 합금 AZ31 시트에 대해 결정된 조직 계수를 사용하여 소성 변형의 열 활성화 모델 측면에서 결정됩니다. ^[10] 25 × 300 × 300mm 크기의 마그네슘 합금 AZ31B에서 발사체(직경 7.5mm)의 관통 작용까지 판의 기계적 특성 및 탄도 저항에 대한 쇼트 피닝의 영향. ^[11] 본 연구에서는 마그네슘 합금 AZ31 기판에 (3-아미노프로필)-트리에톡시실란-변성 그래핀 옥사이드(GO) 복합 박막을 합성하였다. ^[12] 마그네슘 합금 AZ31B는 차세대 에너지 효율적인 차량을 위한 중요한 경량, 고강도 재료입니다. ^[13] 마그네슘 합금 AZ31의 기계적 특성은 점소성 자체 일관성 모델링으로 실험적으로 조사되었습니다. ^[14] 플랫 밴드 프로파일에 대한 개념이 자세히 설명되고 예시적인 경량 합금인 알루미늄 합금 AA6060 및 마그네슘 합금 AZ31에 대한 영향이 논의됩니다. ^[15] 본 연구에서는 마그네슘 합금 AZ31B를 보강재로, 그래핀 나노입자를 보강재로 사용하였다. ^[16] 이 논문은 마그네슘 합금 AZ31B의 FSW 용접에 대해 ISIM Timisoara가 얻은 결과를 제시합니다. ^[17] 이 연구에서 하이브리드 졸-겔 실리카 기반 코팅은 양극 산화 마그네슘 합금 AZ31 기판의 실런트로 조사되었습니다. ^[18] 비틀림 특정 유한 요소 접근 방식과 함께 트위닝 및 디트위닝 방식을 사용하는 탄성 점소성 자체 일관성 모델은 이상적인 기저, 압연, 압출 및 무작위. ^[19] 마그네슘 합금 AZ31 판재를 초음파 쇼트 피닝 처리하여 표면 나노결정질을 제작하였으며, 처리 후 마찰 거동을 평가하기 위해 ball-on-disk drysliding wear test를 수행하였다. ^[20] 본 연구에서는 마그네슘 합금 AZ31B 튜브의 따뜻한 T형 성형을 위한 대칭적인 온도 분포 및 공정 하중 경로의 최적화를 퍼지 모델을 사용한 유한 요소(FE) 해석으로 수행했습니다. ^[21] 수치 시뮬레이션은 특정 HCP 마그네슘 합금 AZ31의 기계적 거동을 검증하기 위해 문헌의 여러 참조 결과와 비교됩니다. ^[22] 마그네슘 합금 AZ31B의 기계적 응답은 4점 굽힘 테스트 덕분에 해결되었습니다. ^[23] 이 연구에서는 마그네슘 합금 AZ31의 가공 온도와 구멍 형상의 정확도 사이의 관계를 고속강, 초경합금(K-Base), 다이아몬드형 탄소(DLC, K-Base)의 4가지 유형의 드릴로 조사했습니다. ), TiN 코팅 초경합금(K-Base). ^[24] 이 작업에서 일련의 고속 인장 실험은 명목상 10 4 s의 변형 속도에서 수직 압연 평면의 각도 배열을 따라 소형화된 인장 Kolsky 막대를 사용하여 열간 압연된 마그네슘 합금 AZ31B의 얇은 포일 시편에 대해 수행되었습니다. 1. ^[25] 압연된 마그네슘 합금 AZ31B 시트의 시작 질감은 NVPSC로의 초기 입력을 위해 전자 후방 산란 회절(EBSD)을 사용하여 얻어졌습니다. ^[26] nan ^[27] nan ^[28] nan ^[29] nan ^[30] nan ^[31] nan ^[32] nan ^[33] nan ^[34] nan ^[35] nan ^[36] nan ^[37] 양극산화된 마그네슘 합금 AZ31에 Mg-Al 층상 이중 수산화물(LDHs)을 쉬운 in-situ 방법으로 증착하고 MgAl-LDHs의 표면을 미리스트산(MA)과 1H, 1H, 2H, 2H-Perfluorodecyltrimethoxysilane으로 개질했습니다. (PFDTMS). ^[38] nan ^[39] nan ^[40] nan ^[41] nan ^[42] nan ^[43] nan ^[44] nan ^[45] nan ^[46] nan ^[47] nan ^[48] nan ^[49] nan ^[50]

Mg Alloy Az31 마그네슘 합금 Az31

Abstrct Polycaprolactone/hydroxyapatite (PCL/HA) composite coating was fabricated by a combination of hydrothermal and dipping methods to delay the degradation of Mg alloy AZ31 as bioresorbable materials. ^[1] The deformation behavior of rolled Mg alloy AZ31, previously compressed along the rolling direction (RD), was numerically investigated under reverse tension. ^[2] In this study, a fluorine-free superhydrophobic Mg(OH)2/DTMS composite coating was successfully fabricated on the surface of Mg alloy AZ31 by hydrothermal process and electrodeposition of dodecyltrimethoxysilane to enhance corrosion resistance. ^[3] In this work, a composite structure, mixing MXenes/magnesium aluminum-layered double hydroxides (MXenes/MgAl-LDHs) with Y(OH)3, was synthesized in-situ as a smart coating on Mg alloy AZ31 via (i) exfoliating those multilayer Ti3C2 to few-layer MXenes (FLMs), and (ii) adding Y(NO3)3 to FLMs solution for a one-step hydrothermal treatment. ^[4] Thereby, a combination of molecular dynamic (MD) simulations and experimental exploration is used to investigate the adsorption behavior and conformational change of bovine serum albumin (BSA), a representative protein of blood plasma, upon the surface of micro-arc oxidation (MAO) coated Mg alloy AZ31. ^[5] A superhydrophobic and corrosion-resistant coating with a hierarchical macro/nanostructure was constructed by one-step electrodeposition of dodecyltrimethoxysilane (e-DTMS) on Mg alloy AZ31. ^[6] In the present paper two sheet forming processes (the Super Plastic Forming and the Incremental Sheet Forming) have been investigated for manufacturing a resorbable cheekbone implant using the Mg alloy AZ31B. ^[7] In this study, two typical twinning models, predominant twin reorientation (PTR) and twinning-detwinning (TDT), were chosen to simulate the $$ \{ 10\bar{1}2\} $${101¯2}twinning-predominant deformations of a Mg alloy AZ31 rolled plate, in compression along the transverse direction (TD-c) and in tension along the normal direction (ND-t), and the results were compared with experimental data. ^[8] A graphene coating, prepared via spin coating on the Mg alloy AZ31, was characterized using Raman spectroscopy, scanning electron microscopy (SEM), and X-ray photoelectron spectroscopy (XPS). ^[9] Super-hydrophobic films were synthesized on the Mg alloy AZ31 by modifying in-situ grown Mg-Al layered double hydroxide (LDH) films with stearic acid (SA), sodium laurate (SL), myristic acid (MA) and 1H, 1H, 2H, 2H–perfluorodecyltrimethoxysilane (PFDTMS). ^[10] Dissimilar Friction stir and Diffusion bond welds of Al alloy 5083 and Mg alloy AZ31 were produced. ^[11] Therefore, this paper presents a breakthrough in tool design through the appropriate control of temperature distribution of the Mg alloy AZ31B tubular material to minimise the wrinkling defects in THF at evaluated temperatures. ^[12] Dissimilar Friction stir (FS) and Diffusion bond (DB) welds of Al alloy 5083 and Mg alloy AZ31 were produced at similar peak and bonding temperature of 435 °C. ^[13] A magnesium-aluminum layered-double-hydroxides (Mg Al LDHs) coating was fabricated on the surface of Mg alloy AZ31, followed by electrophoretic deposition of an Al2O3 nanoparticles layer. ^[14] Hence, in this study a dense Mg(OH)2 film was fabricated on MAO-coated Mg alloy AZ31 in an alkaline electrolyte containing ethylenediamine tetraacetic acid disodium (EDTA-2Na) to reinforce the protection. ^[15] When both anodized magnesium MgO with the higher current density alloys for (1 and 7 days) are compared to metallic Mg alloy AZ31, the adhesive stress between the anodized magnesium MgO with the higher current density and the ceramic paste or cement concrete with a hardening time of 1 day (24 h), exhibited a reduction of 45% and for 7 days the anodized magnesium MgO with the higher current density exhibited a reduction of 60%. ^[16] The work presented herein provides advancements in the understanding of corrosion resistant Mg alloys and is pertinent to the potential use of Mg-Sn alloys in transport applications, battery electrode materials and as a candidate sacrificial anode for the cathodic protection of Mg alloy AZ31B-H24. ^[17] The foremost reason was the quite wide gap of material properties between Mg alloy AZ31 layer (tensile loading in the outer region) and Al 4047 layer (compressive loading in the inner region). ^[18] Herein, corrosion and wear-resistant films are formed upon Mg alloy AZ31 through a micro-arc oxidation (MAO) process in silicate electrolyte in the presence of carbon spheres (CS). ^[19] Diffraction data were collected using synchrotron X-ray scattering (sXRD) and electron back-scattered diffraction (EBSD) during in situ tensile-compressive deformation of Mg alloy AZ31B dogbone samples. ^[20]
추상 폴리카프로락톤/하이드록시아파타이트(PCL/HA) 복합 코팅은 생체 흡수성 물질로서 Mg 합금 AZ31의 분해를 지연시키기 위해 열수 및 침지 방법의 조합으로 제작되었습니다. ^[1] 압연 방향(RD)을 따라 이전에 압축된 압연된 Mg 합금 AZ31의 변형 거동을 역장력 하에서 수치적으로 조사했습니다. ^[2] 본 연구에서는 내식성을 향상시키기 위해 도데실트리메톡시실란의 열수 공정과 전착을 통해 Mg 합금 AZ31의 표면에 불소가 없는 초소수성 Mg(OH)2/DTMS 복합 코팅을 성공적으로 제조하였다. ^[3] 이 연구에서 MXenes/마그네슘 알루미늄 층 이중 수산화물(MXenes/MgAl-LDHs)을 Y(OH)3와 혼합하는 복합 구조가 (i) 박리를 통해 Mg 합금 AZ31에 스마트 코팅으로 제자리에서 합성되었습니다. 다층 Ti3C2를 소수층 MXene(FLM)에, (ii) Y(NO3)3를 FLM 용액에 첨가하여 1단계 열수 처리. ^[4] 따라서, 분자 역학(MD) 시뮬레이션과 실험적 탐색의 조합을 사용하여 혈장의 대표적인 단백질인 소 혈청 알부민(BSA)의 마이크로 아크 산화(MAO) 표면에 대한 흡착 거동 및 구조적 변화를 조사합니다. 코팅된 Mg 합금 AZ31. ^[5] Mg 합금 AZ31에 도데실트리메톡시실란(e-DTMS)을 한 단계 전착시켜 계층적 매크로/나노 구조를 갖는 초소수성 및 내부식성 코팅을 구성했습니다. ^[6] 본 논문에서는 Mg 합금 AZ31B를 사용하여 흡수성 광대뼈 임플란트를 제조하기 위해 두 가지 시트 성형 공정(Super Plastic Forming 및 Incremental Sheet 성형)을 조사했습니다. ^[7] 이 연구에서는 $$ \{ 10\bar{1}2\} $${101¯2}tending- Mg 합금 AZ31 압연판의 횡방향 압축(TD-c) 및 법선 방향 인장(ND-t)의 주요 변형 및 그 결과를 실험 데이터와 비교했습니다. ^[8] Mg 합금 AZ31에 스핀 코팅을 통해 제조된 그래핀 코팅은 라만 분광법, 주사 전자 현미경(SEM) 및 X선 광전자 분광법(XPS)을 사용하여 특성화되었습니다. ^[9] 초소수성 필름은 스테아르산(SA), 라우르산나트륨(SL), 미리스트산(MA) 및 1H, 1H, 2H, 2H-퍼플루오로데실트리메톡시실란(PFDTMS). ^[10] nan ^[11] nan ^[12] nan ^[13] nan ^[14] nan ^[15] nan ^[16] nan ^[17] nan ^[18] nan ^[19] nan ^[20]

alloy az31 vium

In this work, a composite structure, mixing MXenes/magnesium aluminum-layered double hydroxides (MXenes/MgAl-LDHs) with Y(OH)3, was synthesized in-situ as a smart coating on Mg alloy AZ31 via (i) exfoliating those multilayer Ti3C2 to few-layer MXenes (FLMs), and (ii) adding Y(NO3)3 to FLMs solution for a one-step hydrothermal treatment. ^[1] Mg-Al layered double hydroxides (LDHs) were deposited on the anodized magnesium alloy AZ31 via an easy in-situ method, and the surfaces of MgAl-LDHs were modified with myristic acid (MA) and 1H, 1H, 2H, 2H-Perfluorodecyltrimethoxysilane (PFDTMS). ^[2]
이 연구에서 MXenes/마그네슘 알루미늄 층 이중 수산화물(MXenes/MgAl-LDHs)을 Y(OH)3와 혼합하는 복합 구조가 (i) 박리를 통해 Mg 합금 AZ31에 스마트 코팅으로 제자리에서 합성되었습니다. 다층 Ti3C2를 소수층 MXene(FLM)에, (ii) Y(NO3)3를 FLM 용액에 첨가하여 1단계 열수 처리. ^[1] 양극산화된 마그네슘 합금 AZ31에 Mg-Al 층상 이중 수산화물(LDHs)을 쉬운 in-situ 방법으로 증착하고 MgAl-LDHs의 표면을 미리스트산(MA)과 1H, 1H, 2H, 2H-Perfluorodecyltrimethoxysilane으로 개질했습니다. (PFDTMS). ^[2]

alloy az31 sheet 합금 Az31 시트

The dependence of normal anisotropy coefficient R on angle α in the sheet plane (angle α = 0° corresponds to the rolling direction) is determined in terms of a thermoactivation model of plastic deformation using the texture coefficients determined for magnesium alloy AZ31 sheets. ^[1] A magnesium alloy AZ31 sheet was processed by ultrasonic shot peening treatment to fabricate a surface nanocrystalline, and a ball-on-disk dry sliding wear test was performed to evaluate the tribological behavior after treatment. ^[2]
시트 평면의 각도 α에 대한 수직 이방성 계수 R의 의존성(각도 α = 0°은 압연 방향에 해당)은 마그네슘 합금 AZ31 시트에 대해 결정된 조직 계수를 사용하여 소성 변형의 열 활성화 모델 측면에서 결정됩니다. ^[1] 마그네슘 합금 AZ31 판재를 초음파 쇼트 피닝 처리하여 표면 나노결정질을 제작하였으며, 처리 후 마찰 거동을 평가하기 위해 ball-on-disk drysliding wear test를 수행하였다. ^[2]

alloy az31 substrate 합금 Az31 기질

In this study, (3-aminopropyl)-triethoxysilane–modified graphene oxide (GO) composite thin films were synthesized on magnesium alloy AZ31 substrate. ^[1] In this study, the hybrid sol-gel silica-based coatings were investigated as sealants on anodized magnesium alloy AZ31 substrates. ^[2]
본 연구에서는 마그네슘 합금 AZ31 기판에 (3-아미노프로필)-트리에톡시실란-변성 그래핀 옥사이드(GO) 복합 박막을 합성하였다. ^[1] 이 연구에서 하이브리드 졸-겔 실리카 기반 코팅은 양극 산화 마그네슘 합금 AZ31 기판의 실런트로 조사되었습니다. ^[2]