2020527 · The advantage of VST2L is clear because the flow stress at SPF temperatures for this alloy (775 °C) is significantly lower compared to fine grain Ti-6-4 [22].
contact2021930 · For example, the nominal ultimate tensile strength of the Ti–1.5Al–1Mn alloy used in this work is about 590 MPa, while the known α + β Ti–6Al–4V alloy and
contact2018419 · Ti-4AL-1.5Mn OT4 TC3 Ti-5AL-4V BT6C TC4 Ti-6AL-4V GR5 BT6 TAP6400 TC10 Ti-6AL-6V-2Sn-0.5Cu-0.5Fe Ti-662 TC24 Ti-4.5AL-3V-2Mo-2Fe SP-700 (:)
contact201023 · : :86- :(+86)018 : :
contact2018426 · Ti Al Sn Mo Pd Ni Si B Fe C N H O TA1-1 ≤0.20 - - - - - ≤0.08 - 0.15 0.05 0.03 0.003 0.12 - 0.10 TA1 - - - - - - - - 0.20 0.08
contact20181016 · . 1, 2, 1, 2. : (nickel titanium shape memory alloys, Ni-Ti SMA)
contact2022815 · Due to problems such as the stress-shielding effect, strength–ductility trade-off dilemma, and use of rare-earth, expensive elements with high melting points in Ti alloys, the need for the design of new Ti alloys for biomedical applications has emerged. This article reports the effect of various alloying elements on the compressive
contact2018824 · Metallographic analysis of the SLM Ti-2La alloy quenched from 950 °C (L 1 + β field) down to RT (Methods), with a cooling rate of ~85 °C s −1 between 950–350 °C, is shown in Fig. 4d. Some ...
contact2020824 · Thanks to their excellent mechanical properties, good corrosion resistance, as well as commendable biocompatibility, titanium (Ti) and its alloys are extensively applied in various fields, especially in the biomedical field [1,2,3,4,5,6].According to their microstructures in terms of phase constituents, Ti alloys can be roughly categorized into
contact201023 · : :86- :(+86)018 : :
contact2002130 · Titanium alloys classified by metallurgical structure. Alloy. Example. Alpha Alloys. Commercially Pure – ASTM grades 1,2,3 and 4. Ti/Pd Alloys – ASTM grades 7 and 11. Alpha + Compound. Ti-2.5%Cu – IMI 230. Near Alpha Alloys.
contact20131124 · ability requirements (Fig. 2.4). Alloys for high-performance applications in strength-effi-cient structures normally are processed to more stringent and costly requirements than “unal-loyed” titanium for corrosion service. As exam-ples of use, alloys such as Ti-6Al-4V and Ti-3Al-8V-6Cr-4Mo-4Zr are being used for
contact59Doi: T. Doi, “On the Structure Changes Produced by Aging of Cu−Ti Alloy”,Acta Met., 7, 291–292 (1959) (Meta Phases; Experimental) Article Google Scholar 59Man: J. Manenc, “Existence of Precipitation stages in the Age-Hardening of Cu-Based Ti Alloys”Acta Met., 7, 808–808 (1959) in French. (Meta Phases; Experimental)
contact20211216 · Moreover, the Ti 1 –rGO-based C-PSC without encapsulation displays an excellent stability while its MPP tracking under in full sun still retain 98% and 95% of their initial values for 1,300 h (1 ...
contact2022815 · Due to problems such as the stress-shielding effect, strength–ductility trade-off dilemma, and use of rare-earth, expensive elements with high melting points in Ti alloys, the need for the design of new Ti alloys for biomedical applications has emerged. This article reports the effect of various alloying elements on the compressive
contact2018824 · Metallographic analysis of the SLM Ti-2La alloy quenched from 950 °C (L 1 + β field) down to RT (Methods), with a cooling rate of ~85 °C s −1 between 950–350 °C, is shown in Fig. 4d. Some ...
contact201934 · It is known that almost all of industrial Ti alloys were developed on the basis of the Ti-Al binary system. In the Ti-Al binary phase diagram 37, the high-temperature BCC β-Ti solid solution ...
contact202211 · FSW used to investigate fatigue, microstructures, and mechanical properties of Ti-4.5Al- 2.5Cr-1.2Fe-0.1C alloy (Ti-531C) [30]. In both with and without annealing, the Ti-531C microstructure shows lots of β grains with α grain-boundary phases, but no change occurs in Tensile strength.
contact2002130 · Titanium alloys classified by metallurgical structure. Alloy. Example. Alpha Alloys. Commercially Pure – ASTM grades 1,2,3 and 4. Ti/Pd Alloys – ASTM grades 7 and 11. Alpha + Compound. Ti-2.5%Cu – IMI 230. Near Alpha Alloys.
contact59Doi: T. Doi, “On the Structure Changes Produced by Aging of Cu−Ti Alloy”,Acta Met., 7, 291–292 (1959) (Meta Phases; Experimental) Article Google Scholar 59Man: J. Manenc, “Existence of Precipitation stages in the Age-Hardening of Cu-Based Ti Alloys”Acta Met., 7, 808–808 (1959) in French. (Meta Phases; Experimental)
contactDescription. Ti-8Al-1Mo-1V alloy (UNS R54810) is a near alpha alloy with aluminum being the alpha stabilizer, and the additions of Mo, V and Fe resulting in small amounts of beta. The alloy is intended primarily for use at elevated temperatures, has good creep strength and good weldability, and possesses the lowest density of any titanium-base ...
contact:The present invention is a medical implant or device (2) fabricated, in any manner, from a niobium (Nb) - titanium (Ti) - zirconium (Zr) - Molybednum (Mo) alloy (NbTiZrMo alloy). The implant or device has components at least partially fabricated from a metal alloy comprising a) between about 29 and 70 weight percent Nb; b) between ...
contact2022815 · Due to problems such as the stress-shielding effect, strength–ductility trade-off dilemma, and use of rare-earth, expensive elements with high melting points in Ti alloys, the need for the design of new Ti alloys for biomedical applications has emerged. This article reports the effect of various alloying elements on the compressive
contact2018720 · The titanium alloy Ti-6Al-4V is characterized by an excellent ratio of high strength even at elevated temperatures to a low density [1,2]. This beneficial characteristic leads to a high ...
contactIn this paper the common preparation methods of porous Ti were introduced based on the structure and properties of porous Ti. The surface modification, biological activity, osteoinductive properties of porous Ti and their domestic research status were summrized. The development of biomedical porous Ti and titanium alloys was prospected.
contact201023 · : :86- :(+86)018 : :
contact2018824 · MEDIUM TO HIGH STRENGTH GENERAL-PURPOSE ALLOYS Ti-6Al-4V, Ti-6Al-4V ELI & Ti-6Al-4V-.1Ru ELEMENT WEIGHT % Aluminum 5.5 6.75 5.5 6.5 5.5 6.5 ... This alloy is hardenable in sections up to 1.0" thick and is weldable by various methods provided the joint area is clean before welding. In most of the welding methods,
contact202131 · The results showed that the average grain sizes of Ti-6Al-4V alloy with bimodal and lamellar structure were 18.9nm and 17.1nm at the topmost surface layer, respectively. The maximum compressive residual stress of the bimodal structure was -906MPa, which was higher than that of the lamellar structure (-859MPa).
contact*The mean coefficient of thermal expansion in going from 70°F to indicated temperature; unit: 10-6 inch/inch/°F. *Group A: titanium alloy Grades 1, 2, 2H, 3, 7, 7H, 11, 12, 16, 16H, 17, 26, 26H, and 27; Group B: titanium alloy Grades 9
contact2018824 · (1) Beta forged and annealed; tested at 30 Hz; R=0.1. TIMETAL ® 1100. HIGH STRENGTH, HIGH TEMPERATURE ALLOY. TIMETAL ® 1100 is a near alpha alloy originally developed for elevated temperature use in the range of 1100. o. F (600C). However, in certain applications it has been demonstrated that TIMETAL ® 1100 can be
contact:The present invention is a medical implant or device (2) fabricated, in any manner, from a niobium (Nb) - titanium (Ti) - zirconium (Zr) - Molybednum (Mo) alloy (NbTiZrMo alloy). The implant or device has components at least partially fabricated from a metal alloy comprising a) between about 29 and 70 weight percent Nb; b) between ...
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