Alloy Ti
합금 티

Alloy Ti(합금 티)란 무엇입니까?

Alloy Ti 합금 티 - The solution developed could also prove its efficiency in the machining of titanium-based alloy Ti6Al4V. ^[1] Dwell and non-dwell cyclic loading in alloy Ti-6Al-4V are investigated for two differing microstructures, and the cycles to failure predicted based solely on the crystal c-axis tensile strength, and the dwell debit quantified. ^[2] An experimental investigation of structure evolution kinetics in a new six-component TiAl-based alloy Ti-44. ^[3] The effect of the microstructure formed in different stages of softening under annealing after moderate cold deformation on martensitic transformations and functional properties of alloy Ti – 50. ^[4] High-temperature test mechanical properties of these alloys in compression and tension at 600°C are provided and compared with similar properties of alloy Ti–5Al–5Mo–5V–3Cr. ^[5] During 3D printing by Selective Laser Melting (SLM) of the alloy Ti-6Al-4V, the phase transformation of BCC to HCP is associated with selection of particular crystallographic variants. ^[6] This study investigates the effects of the addition of the intermetallic compounds ZrMn2 and Zr7Cu10 to the alloy TiCr1. ^[7] Methodology Research was performed in order to establish the influence of mechanical processing on the micro-roughness of the surface of the samples from the experimental bioalloy Ti10Zr. ^[8] In addition, a method of laser annealing of sheet materials from aluminum–magnesium alloy and low-alloy titanium alloys was developed. ^[9] Temperatures of critical points for a new Russian intermetallic TiAl-alloy Ti–44. ^[10] The results obtained enabled us to identify the alloy Ti0. ^[11] Firstly, computational thermodynamics has been used to provide a simple graphical means of predicting these additions; this method has been used to explore additions of Ni and Fe to the alloy Ti–6Al–4V (Ti64). ^[12] In this article, multifrequency eddy current testing is proposed to detect hydrogen concentration in alloy titanium. ^[13] Mass change measured for the heating rates 20 °C s−1 and 30 °C s−1 reveals that the alloy Ti–45Al–10Nb–0. ^[14] In order to solve the problem of the failure of the UMCo50 process burner, the orthogonal test was used to optimize the UMCo50 cobalt-based alloy TIG surfacing process, better joint performance was obtained for welding current of 120 A, surfacing speed of 12 cm min−1, interpass temperature of 50 °C and surfacing layer of 2 ∼ 3 layers; Tungsten inert gas(TIG) welding and plasma transferred arc weld(PTAW) surfacing were used to surfacing UMCo50 welding wire and T800 cobalt-based alloy powder on UMCo50 base metal. ^[15] The method of electron-microscopic analysis investigated the structure of the alloy Ti-50. ^[16] Tribological properties of titanium and alloy Ti6Al4V are changed by the irradiation with 160 MeV swift xenon ions. ^[17] % ceramics in the powder mixture with alloy Ti-6Al-4V the wear resistance of the coating increases by a factor of 4. ^[18] The methods of scanning electron microscopy and x-ray diffractometry are used to study the microstructure and mechanical properties of welded joints from alloy Ti60 after laser welding and subsequent heat treatment (PWHT). ^[19] The alloy Ti6Al7Nb with the in situ reinforcement of TiB has been processed by selective laser melting (SLM). ^[20] An experimental deformability assessment of a new six-component TiAl-based alloy Ti-44. ^[21]
개발된 솔루션은 티타늄 기반 합금 Ti6Al4V의 가공에서도 효율성을 입증할 수 있습니다. ^[1] Ti-6Al-4V 합금의 드웰 및 비 드웰 순환 하중은 두 가지 다른 미세 구조에 대해 조사되고 파손 주기는 오로지 결정 c축 인장 강도에 기초하여 예측되고 드웰 차변은 정량화됩니다. ^[2] 새로운 6성분 TiAl 기반 합금 Ti-44의 구조 진화 역학에 대한 실험적 조사. ^[3] Ti – 50 합금의 마르텐사이트 변태 및 기능적 특성에 대한 적당한 냉간 변형 후 어닐링 하에서 연화의 여러 단계에서 형성된 미세 구조의 영향. ^[4] 600°C에서 압축 및 인장에서 이러한 합금의 고온 시험 기계적 특성이 제공되고 Ti-5Al-5Mo-5V-3Cr 합금의 유사한 특성과 비교됩니다. ^[5] Ti-6Al-4V 합금의 선택적 레이저 용융(SLM)에 의한 3D 프린팅 중 BCC에서 HCP로의 상 변형은 특정 결정학적 변형의 선택과 연관됩니다. ^[6] 이 연구는 TiCr1 합금에 금속간 화합물 ZrMn2 및 Zr7Cu10의 첨가 효과를 조사합니다. ^[7] 방법론 실험적 생체합금 Ti10Zr에서 샘플 표면의 미세 거칠기에 대한 기계적 처리의 영향을 확립하기 위해 연구가 수행되었습니다. ^[8] 또한, 알루미늄-마그네슘 합금 및 저합금 티타늄 합금에서 판재의 레이저 어닐링 방법이 개발되었습니다. ^[9] 새로운 러시아 금속간 TiAl 합금 Ti-44의 임계점 온도. ^[10] 얻어진 결과를 통해 TiO 합금을 식별할 수 있었습니다. ^[11] 첫째, 컴퓨터 열역학은 이러한 추가를 예측하는 간단한 그래픽 수단을 제공하는 데 사용되었습니다. 이 방법은 Ti-6Al-4V(Ti64) 합금에 Ni 및 Fe의 추가를 조사하는 데 사용되었습니다. ^[12] 이 기사에서는 합금 티타늄의 수소 농도를 감지하기 위해 다중 주파수 와전류 테스트를 제안합니다. ^[13] 가열 속도 20°C s-1 및 30°C s-1에 대해 측정된 질량 변화는 합금 Ti-45Al-10Nb-0을 보여줍니다. ^[14] UMCo50 공정 버너의 고장 문제를 해결하기 위해 직교 테스트를 사용하여 UMCo50 코발트 기반 합금 TIG 표면 처리 공정을 최적화했으며 용접 전류 120A, 표면 속도 12cm/min에서 더 나은 접합 성능을 얻었습니다. -1, 50 °C의 인터패스 온도 및 2 ~ 3층의 표면층; 텅스텐 불활성 가스(TIG) 용접 및 플라즈마 전사 아크 용접(PTAW) 표면 처리를 사용하여 UMCo50 모재에 UMCo50 용접 와이어 및 T800 코발트 기반 합금 분말을 표면 처리했습니다. ^[15] 전자현미경 분석법으로 Ti-50 합금의 구조를 조사하였다. ^[16] 티타늄 및 합금 Ti6Al4V의 마찰 특성은 160MeV의 신속한 크세논 이온 조사에 의해 변경됩니다. ^[17] Ti-6Al-4V 합금과의 분말 혼합물의 세라믹 %는 코팅의 내마모성이 4배 증가합니다. ^[18] 주사 전자 현미경 및 x-선 회절 측정법은 레이저 용접 및 후속 열처리(PWHT) 후 합금 Ti60의 용접 조인트의 미세 구조 및 기계적 특성을 연구하는 데 사용됩니다. ^[19] TiB의 제자리 강화를 갖는 합금 Ti6Al7Nb는 SLM(선택적 레이저 용융)으로 처리되었습니다. ^[20] 새로운 6성분 TiAl 기반 합금 Ti-44의 실험적 변형성 평가. ^[21]

high temperature titanium 고온 티타늄

The dynamic recrystallization behavior of a high-temperature titanium alloy Ti600 has been investigated by hot compression tests at the strain rates of 0. ^[1] Through the hot press sintering experiment of the mixed powder under different heating and sintering processes, the plastic deformation behavior of the material is carried out on this basis Research, preliminarily discuss the constitutive relationship of the new high-temperature titanium alloy Ti-Al-Nb, establish the hot working map and recrystallization model. ^[2] The effects of pulse current on the tensile properties of high temperature titanium alloy Ti55 were investigated by pulse current assisted uniaxial tensile test under different electrical parameters. ^[3]
고온 티타늄 합금 Ti600의 동적 재결정화 거동은 0의 변형률 속도에서 고온 압축 테스트에 의해 조사되었습니다. ^[1] 다양한 가열 및 소결 과정에서 혼합 분말의 열간 프레스 소결 실험을 통해 재료의 소성 변형 거동을 기반으로 연구, 새로운 고온 티타늄 합금 Ti-Al-Nb의 구성 관계에 대해 사전 논의 , 뜨거운 작업 맵 및 재결정화 모델을 설정합니다. ^[2] nan ^[3]

metastable β titanium 준안정 β 티타늄

The effect of deformation temperature and strain rate (collectively described by the Zener-Hollomon parameter Z) on the deformation mechanism and texture formation of the metastable β-titanium alloy Ti5321 across the β-transus temperature during hot-compression was investigated by electron backscatter diffraction. ^[1] In this study, the crystallography and microstructure of the deformation bands formed in a metastable β titanium alloy Ti–7Mo–3Nb–3Cr–3Al during isothermal compression were investigated. ^[2] Dynamic mechanical behavior of a metastable β titanium alloy Ti-10V-2Fe-3Al (Ti-1023) with α+β dual-phase structure is investigated by a split Hopkinson tension bar (SHTB) system at two high strain rates of 2000 s-1 and 4000 s-1. ^[3]
고온 압축 동안 β-트랜서스 온도에 걸친 준안정 β-티타늄 합금 Ti5321의 변형 메커니즘 및 조직 형성에 대한 변형 온도 및 변형률 속도(Zener-Hollomon 매개변수 Z로 집합적으로 설명됨)가 전자 후방 산란 회절에 의해 조사되었습니다. . ^[1] 이 연구에서는 등온 압축 동안 준안정 β 티타늄 합금 Ti-7Mo-3Nb-3Cr-3Al에서 형성된 변형 밴드의 결정학 및 미세 구조를 조사했습니다. ^[2] nan ^[3]

Titanium Alloy Ti 티타늄 합금 Ti

The paper concerns the study of the possibilities for electroless plating of a nickel-cobalt-phosphorus alloy on titanium and titanium alloy TiAl6V4 substrates when pre-galvanic activation is used. ^[1] The present work gives us an insight of selecting a particular alloy based on its Engineering applications, Aluminium Alloys AL7075, AL2024, Titanium Alloy Ti6AL4V, Nickel Alloy NI718 are predominantly used as structural components and chosen as alloys of our interest to study the impact of a fundamental property “Coefficient of Thermal Expansion” on the Thermo Mechanical stresses. ^[2] The dynamic recrystallization behavior of a high-temperature titanium alloy Ti600 has been investigated by hot compression tests at the strain rates of 0. ^[3] The defect was replaced with a cellular bioactive 3D implant made of titanium alloy Ti6Al4V, manufactured using the additive technology. ^[4] This new technique renders both technical and theoretical advancements from the following aspects: (1) A special in-house designed drainage nozzle was integrated with the laser cladding head to create local dry cavity which ensured the successful manufacturing of titanium alloy Ti-6Al-4V in underwater environment; (2) Unique microstructure formation/evolution mechanisms have been revealed for the ULMD process, which significantly differ from those of the in-air LMD process; (3) The hydrogen content has been well controlled during ULMD, which can effectively prevent the formation of hydrogen-induced cracks; (4) The mechanical properties of the ULMD Ti-6Al-4V parts were equal or even better than that fabricated by in-air LMD or SLM technique. ^[5] An in-situ high-resolution synchrotron X-ray diffraction (XRD) experiment is used to measure microstructural damage accumulation (DA) during loading of an extruded sample of the α − β titanium alloy Ti-6Al-4V. ^[6] Here we have chosen a titanium alloy Ti6Al4v of 1 mm thickness. ^[7] The samples were made of titanium alloy Ti6Al4V by using selective laser melting (SLM) additive manufacturing. ^[8] These three-dimensional surface roughness parameters can be theoretically predicted with the proposed kinematic model for the scaly surface fabricated by rotary ultrasonic rolling of titanium alloy Ti-6Al-4V. ^[9] The effect of deformation temperature and strain rate (collectively described by the Zener-Hollomon parameter Z) on the deformation mechanism and texture formation of the metastable β-titanium alloy Ti5321 across the β-transus temperature during hot-compression was investigated by electron backscatter diffraction. ^[10] Calculations are done for multi-track depositions of a tool steel H13 and a titanium alloy Ti-6Al-4V and the computed results are tested using experimental data for different processing conditions. ^[11] Titanium alloy Ti6Al4V, an alpha-beta alloy, possesses many advantageous properties, such as high special strength, good resilience and resistance to high temperature and corrosion, fracture resistant characteristics and so on, being widely used in aerospace, biomedical and chemical industry. ^[12] The microstructure of double-sided welded joints of 3D-printed items made of titanium alloy Ti‒6Al–4V by the electron-beam freeform fabrication (EBF 3 ) method has been investigated using the methods of X-ray diffraction analysis, optical metallography, and scanning and transmission electron microscopy. ^[13] In this work, a layered composite material based on TiAl/TiB2 has been first obtained by unrestricted SHS-compression on the titanium alloy Ti6Al4V from the initial powders of titanium, aluminum, and boron. ^[14] Thus, in this study, we aimed to evaluate and compare the in vitro biological response to standard discs of four alternative biomaterials: polyether ether ketone (PEEK), zirconia toughened alumina (ZTA), silicon nitride (SN) and surface-textured silicon nitride (ST-SN), and the reference titanium alloy Ti6Al4V (TI). ^[15] Titanium alloy Ti6Al4V has the advantages of high specific strength, good heat resistance, and strong corrosion resistance, which is widely used in the manufacturing of aerospace industrial parts. ^[16] This paper presents the study of defects formation in the friction welding process of titanium alloy Ti-6Al-4V. ^[17] The analyzed joint is composed by two sheets of 2014 – T6 aluminium alloy and a T300/5208 Graphite/Epoxy quasi-isotropic laminate, which were joined by twelve Lockbolt Swaged Collar rivets titanium alloy Ti–6Al–4V annealed. ^[18] Electrospark treatment of a titanium alloy Ti6Al4V in a mixture of granules allows the formation of intermetallic Ti-Al coatings. ^[19] The data on the main technological parameters of atomization of nickel alloy Inconel 718 and titanium alloy Ti-6A1-4V are presented in the paper. ^[20] The metastable beta titanium alloy Ti-3Al-5Mo-7V-3Cr (Ti-3573) was used as experimental material in this paper. ^[21] On the one hand, the titanium alloy Ti-6Al-4V, as a material with low machinability and low formability at room temperature, and the stainless steel 316 L. ^[22] In this study, titanium alloy Ti–6Al–4V is used as the research object to conduct machining experiments. ^[23] In this study, the crystallography and microstructure of the deformation bands formed in a metastable β titanium alloy Ti–7Mo–3Nb–3Cr–3Al during isothermal compression were investigated. ^[24] Through the hot press sintering experiment of the mixed powder under different heating and sintering processes, the plastic deformation behavior of the material is carried out on this basis Research, preliminarily discuss the constitutive relationship of the new high-temperature titanium alloy Ti-Al-Nb, establish the hot working map and recrystallization model. ^[25] 826, 778, 680, 583 and 486 MPa, have been studied on a near α titanium alloy Timetal 834. ^[26] In this study, superhydrophobic titania nanoflower surfaces were successfully fabricated on a titanium alloy Ti-6Al-4V substrate with hydrothermal synthesis and vapor-phase silanization. ^[27] In this paper, ABAQUS finite element simulation software was used to establish a more reliable three-dimensional milling titanium alloy Ti6Al4V finite element simulation model. ^[28] Manufacturing processes such as welding subject the α/β titanium alloy Ti-6Al-4V to a wide range of temperatures and temperature rates, generating microstructure variations in the phases and in the precipitate dimensions. ^[29] The dependence of tensile properties and deformation behavior on microstructures of a near alpha titanium alloy Ti–3Al–2Zr–2Mo (wt. ^[30] These implants can be manufactured conventionally from medical grade titanium alloy Ti64 (titanium-aluminum-vanadium) in the form of plates ranging in thickness from 0. ^[31] The aim of this work is to study the influence of the welding thermal cycle and reducing of weld metal alloying degree on the structure and mechanical properties of welded joints of high-strength titanium alloy Ti-6. ^[32] This study focused on the use of supercritical carbon dioxide (scCO2) as a coolant in the face milling of titanium alloy Ti-6Al-4V. ^[33] In this study, the traditional α – β titanium alloy Ti6Al4V sheets were joined by the resistance spot welding (RSW) process. ^[34] This paper presented the influence of machined surface texture on fretting cracks behaviors of Titanium alloy Ti–6Al–4V under radial loading in conformal contact. ^[35] In the present work, surface characteristics of powder mixed electro-discharge machining (PMEDM) process are investigated using alumina and carborundum abrasive powder added dielectric fluid for titanium alloy Ti6Al4V. ^[36] For that purpose, we have characterized by X-ray tomography the porous microstructure of 4 different additively manufactured materials (aluminium alloy AlSi10Mg, stainless steel 316L, titanium alloy Ti6Al4V and Inconel 718L) with initial void volume fractions ranging from ≈ 0. ^[37] As a typical aerospace difficult-to-machine material, tool failure in milling titanium alloy Ti6Al4V will reduce the stability of the milling process and affect the surface quality of the workpiece. ^[38] In this work, we present experimental data on the structure, chemical composition and wear resistance of a titanium alloy Ti6Al4V after pulsed laser treatment. ^[39] This paper focuses on the machining of a super-dimensioned titanium alloy Ti6Al4V aviation deep-hole part (aspect ratio exceeding 20) with the axial ultrasonic vibration-assisted boring (AUVB) method. ^[40] Specimens are made from cryogenic compatible alloys namely Aluminium alloy AA2219, Stainless steel AISI 321 and Titanium alloy Ti6Al4V with a surface roughness of 0. ^[41] Titanium alloy Ti6Al4V and aluminium amalgam 6061 were effectively joined by laser beam welding. ^[42] This demonstrated that a shape deviation of harmonic surface structures on titanium alloy Ti6Al4V could be reduced by up to 91% by means of an adapted compensation signal. ^[43] The titanium alloy Ti-407 (Ti407) is a new alloy being considered for single load to failure applications where energy absorption is a key requirement. ^[44] The evolution of cutting forces in four different billet conditions of the alpha + beta titanium alloy Ti–6Al–2Sn–4Zr–6Mo (Ti-6246) was measured. ^[45] Coatings were deposited on two substrate materials, namely, titanium Grade 2 and titanium alloy Ti13Nb13Zr, by immersion in a solution containing vinyltrimethoxysilane, anhydrous ethyl alcohol, acetic acid and distilled water. ^[46] The promising directions of using electron-beam processing were analyzed and are as following: 1 – smoothing the surface, getting rid of surface microcracks, while simultaneously changing the structural-phase state of the surface layer, to create high-performance technologies for the finishing processing of critical metal products of complex shape made of titanium alloy Ti-6Al-4V and titanium; steels of various classes; hard alloy WC – 10 wt. ^[47] The simulation of multiple microstructures demonstrates that this integrated approach can be used to test the influence of different microstructures on the mechanical properties of titanium alloy Ti-5553. ^[48] Metal-ceramic coatings were obtained by electrospark treatment of a titanium alloy Ti6Al4V in a mixture of titanium granules with tantalum carbide powder. ^[49] Titanium alloy Ti-6Al-4V particles were used as reinforcement for AZ31B magnesium metal matrix composites (Mg MMCs) which were synthesized via friction stir processing (FSP). ^[50]
이 논문은 사전 갈바닉 활성화가 사용될 때 티타늄 및 티타늄 합금 TiAl6V4 기판에 니켈-코발트-인 합금의 무전해 도금 가능성에 대한 연구에 관한 것입니다. ^[1] 현재 작업은 엔지니어링 응용 프로그램을 기반으로 특정 합금을 선택하는 데 대한 통찰력을 제공합니다. 알루미늄 합금 AL7075, AL2024, 티타늄 합금 Ti6AL4V, 니켈 합금 NI718은 주로 구조 구성 요소로 사용되며 합금의 영향을 연구하기 위해 관심 합금으로 선택됩니다. 열역학적 응력에 대한 기본 속성 "열팽창 계수". ^[2] 고온 티타늄 합금 Ti600의 동적 재결정화 거동은 0의 변형률 속도에서 고온 압축 테스트에 의해 조사되었습니다. ^[3] nan ^[4] nan ^[5] nan ^[6] nan ^[7] nan ^[8] nan ^[9] 고온 압축 동안 β-트랜서스 온도에 걸친 준안정 β-티타늄 합금 Ti5321의 변형 메커니즘 및 조직 형성에 대한 변형 온도 및 변형률 속도(Zener-Hollomon 매개변수 Z로 집합적으로 설명됨)가 전자 후방 산란 회절에 의해 조사되었습니다. . ^[10] nan ^[11] nan ^[12] nan ^[13] nan ^[14] nan ^[15] nan ^[16] nan ^[17] nan ^[18] nan ^[19] nan ^[20] nan ^[21] nan ^[22] nan ^[23] 이 연구에서는 등온 압축 동안 준안정 β 티타늄 합금 Ti-7Mo-3Nb-3Cr-3Al에서 형성된 변형 밴드의 결정학 및 미세 구조를 조사했습니다. ^[24] 다양한 가열 및 소결 과정에서 혼합 분말의 열간 프레스 소결 실험을 통해 재료의 소성 변형 거동을 기반으로 연구, 새로운 고온 티타늄 합금 Ti-Al-Nb의 구성 관계에 대해 사전 논의 , 뜨거운 작업 맵 및 재결정화 모델을 설정합니다. ^[25] nan ^[26] nan ^[27] nan ^[28] nan ^[29] nan ^[30] nan ^[31] nan ^[32] nan ^[33] nan ^[34] nan ^[35] nan ^[36] nan ^[37] nan ^[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]

Ti Alloy Ti Ti 합금 Ti

residual stress, hardness in-depth direction surface roughness) of a β-Ti alloy Ti- 15 V-3Cr-3Al-3Sn (Ti-15–3) in duplex aged condition. ^[1] The URP of Ti alloy Ti5Al4Mo6V2Nb1Fe strengthened its surface layer properties, but the material performance did not improve to a greater extent. ^[2] Considering the great potential of extremely-low temperature applications, cryogenic tensile properties and deformation behavior of a metastable β-Ti alloy Ti–15Mo–2Al were investigated. ^[3] Ti alloy Ti-6Al-4V rods are adopted to support the cold mass. ^[4] The model is tested for cyclic and dwell loadings at multiple spatial scales of a Ti alloy Ti7AL, viz. ^[5]
이중 시효 조건에서 β-Ti 합금 Ti-15V-3Cr-3Al-3Sn(Ti-15-3)의 잔류 응력, 경도 깊이 방향 표면 거칠기). ^[1] Ti 합금 Ti5Al4Mo6V2Nb1Fe의 URP는 표면층 특성을 강화했지만 재료 성능은 크게 향상되지 않았습니다. ^[2] nan ^[3] nan ^[4] nan ^[5]

Entropy Alloy Ti 엔트로피 합금 Ti

The mechanical properties of novel hexagonal close-packed medium entropy alloy TiZrHf have been studied using first-principles method based on special quasi-random structure. ^[1] At the first stage of HEBM, a powder of high-entropy alloy TiTaNbZrHf was prepared. ^[2] The desorption behaviors of hydrogen from high entropy alloy TiZrVMoNb hydride surface have been investigated using the density functional theory. ^[3]
새로운 육각형 조밀 중간 엔트로피 합금 TiZrHf의 기계적 특성은 특수 준 무작위 구조에 기반한 제1 원리 방법을 사용하여 연구되었습니다. ^[1] HEBM의 첫 번째 단계에서 고엔트로피 합금 TiTaNbZrHf의 분말이 준비되었습니다. ^[2] nan ^[3]

Β Alloy Ti Β 합금 Ti

The present study investigated microstructure evolution and mechanical properties of a near β alloy Ti–5Al–5Mo–5V–3Cr–1Zr fabricated by additive manufacturing using electron beam melting. ^[1] Although tools are highly optimised for drilling the α+β alloy Ti-6Al-4V (Ti-64), insufficient information is available to efficiently improve tools for use on higher strength alloys due to the cost intensive processes required to design and optimize new drills. ^[2]
본 연구는 전자빔 용융을 이용한 적층 제조로 제조된 β에 가까운 합금 Ti-5Al-5Mo-5V-3Cr-1Zr의 미세구조 진화 및 기계적 특성을 조사하였다. ^[1] 공구가 α+β 합금 Ti-6Al-4V(Ti-64) 드릴링에 고도로 최적화되어 있지만 새로운 드릴을 설계하고 최적화하는 데 필요한 비용 집약적인 프로세스로 인해 고강도 합금에 사용할 도구를 효율적으로 개선하기 위한 정보가 충분하지 않습니다. . ^[2]