Fergana polytechnic insitute mechanical engineering faculty department of mechanical engineering and automation
materials with high melting points
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materials with high melting points
. Hard-melting metals have a melting temperature above 1539 o C (melting pure iron) and these include: titanium, zirconium, hafnium, vanadium, niobium, tantalum, chromium, molybdenum, rhenium, osmium, radium. Metals of the platinum group are also hard-melting metals, but depending on the accepted rule, they are included in the group of rare metals. Hafnium, radium, osmium, rhenium are added to rare elements. Tungsten, molybdenum, tantalum, titanium, zirconium are the most widely used in practice . Melting temperatures: W=3400 o C; Re=3180 o C; Ta=2996 o C; Mo=2625 o C; Nb=2500 o C; N b=2222 o C; Cr=1910 o C; V= 1900 o C; Zr=2860 o C; Ti=1725 o C; The compatibility ("optimal") of the mechanical, electrical, and physical properties of hard-to-melt metals is the reason why they are widely used in engineering, especially in aircraft and rocketry . 78 The mechanical properties of refractory metals depend on their purity from "primes" (N 2 ; O 2 ; S), thermal and mechanical treatment.N 2 ; C; O 2 ; H 2 embrittles tungsten, tantalum, molybdenum, niobium. strength increases if the plastic is first deformed and then released. Hard - to -melt metals - the most desirable operational properties include their operating temperature, thermoelectric current density ("plotnost"), relative electrical resistance. That's why they are radio and widely used in electronic equipment. W-Mo; W-Cu; W-Ags are highly resistant to electro erosion , therefore, they are used in highly loaded contacts. The melting temperature of W is quite high - 3410 o C. It is used in the production of hard alloys and alloying of steels. Nb is used in atomic engineering, electrical engineering, radio electronics, tool making and refractory steel production. Ta - the resistance to the external environment is not inferior to rare metals. Therefore, it is used to obtain alloys resistant to corrosion and corrosion. Rhenium - high mechanical properties, high elastic deformation, corrosion resistance. An alloy of rhenium with molybdenum and nickel has high precision even at high temperatures. Zirconium is the most widely used of KEMs. The reason: sufficient distribution in nature, corrosion resistance, technology. If it is cleaned and "naklep" - its mechanical properties will increase. KEM is mainly processed by the method of powder metallurgy. Titanium melts at 1725 o C, boils at 3000 o C . Relative weight = 4.54 kg/cm 3 . It has two allotropic forms: above 882 o C -titanium, below -titanium. -titanium's crystal lattice is hexagonal, its atoms are densely arranged. -the crystal lattice of titanium is a volume-centered cube. Titanium was discovered in 1791. It is in 4th place in terms of reserves in the earth's crust (after Al, Fe, Mg). Titanium cuts, hammers and rolls well. Titanium can be rolled into tunics, ribbons and even dice ("foil") - titanium paper. 79 Titanium has a high corrosion resistance , even higher than stainless steel. Titanium does not corrode in the atmosphere , fresh water, sea water, organic acids, some inorganic acids, abrasives . When titanium is heated in air at 400-600 o C, its surface is covered with a thin oxide film (film), which protects the part under it from corrosion . And when it is heated, oxygen begins to dissolve. As a result, the plasticity of titanium decreases. Titanium corrodes only under the influence of chloride, sulfuric and hydrofluoric acids. Based on the above properties, titanium is used in ship coating and chemical engineering. Titanium is slightly heavier than aluminum ( density - "plotnost": for Al = 2.7 g/cm 3 ; for Ti = 4.51 g/cm 3 ; for Fe = 7.68 g/cm 3 ). But the precision is 3 times higher than aluminum precision. Therefore, titanium is widely used in aircraft . Titanium also has its disadvantages: the normal modulus of elasticity is twice that of steel. This makes it difficult to create unique and superior constructions. Not only at high temperature, but also at normal temperature, the ductility property is wet oyo n. As can be seen from the table below , with the increase in the amount of additives in titanium, its hardness, strength and plasticity decrease. VT1, VT2 technical titanium rods, tins, tapes, and pokovka are manufactured . Technical titanium is rarely used as a structural material, because its mechanical properties are not high. Titanium alloys are classified as follows: 1. Depending on the processing technology: lumpy , deformable. Depending on the mechanical properties: standard precision , heat resistance , high precision . 3. Depending on the relationship to thermal performance: polished and non- polished. 4. Depending on the structure: -; + , and -alloys. Titanium alloys of medium precision: VT5, OT4. Based on Al(3-5%), Mn(1.5%). 80 High precision titanium alloys: VT14, VT15, VT16. Based on Al (2.5-4%), Mo (3-7.5%)/ Fire-resistant titanium alloys: VT3-1, VT8, VT9. Based on Al (5.5-8%), Mo (1.5-3.5%). 7 . Table 1 . Chemical composition and mechanical properties of titanium grades At high temperature - 300-600 o C, the strength of titanium alloys is several times higher than that of Al, Mg alloys. Therefore, it is widely used in aircraft construction. For supersonic aircraft coatings , which heats up to 450-500 o C at M = 3-3.5. Also for strength elements: spar, rib, frame. Also used for non-magnetic aircraft fuel tanks. From year to year, attention to the use of non-ferrous metal alloys in various fields of production is increasing. These alloys have several advantages. The most important of all advantages is their high relative strength compared to other alloys. Aluminum alloys are divided into three groups according to their technological properties: a) deformable alloys that cannot be strengthened by thermal processing; b) deformable alloys strengthened by thermal processing; c) deformable alloys that can be strengthened by casting. Apart from these alloys, sintered aluminum alloy (SAS) and aluminum powder (SAP) alloys are widely used. Titan brand the amount of additives in titanium, in % Mechanical properties Fe Si C Cl 2 O 2 N 2 H 2 v, kg / mm 2 , % , % A n kG / cm 2 NV VT00 0.15 0.05 0.05 0.06 0.1 0.03 ---- 38 36 64 - - 115 VT0 0.15 0.05 0.05 0.06 0.1 0.03 0.01 46 28 50 10 145 VT1 0.01 0.1 0.06 0.08 0.2 0.05 0.03 53 24 42 5 165 VT2 0.3 0.1 0.06 0.1 0.2 0.06 0.02 60 20 35 5 185 81 Aluminum alloys are marked as follows: the letters at the beginning of the mark - "D" means duralumin, "A" - technical aluminum, "AK" - bondable, "V" - high strength, "A" - cast aluminum alloy . The number (number) after the letters indicates the order number of the alloy (in silumins - silicon content, %). In some cases, in the brand of the alloy, after the number, the symbol of the state of the alloy is used. For example, "M" - soft (softened), T - heat-treated (hardened), N - heat-hardened (liquid- deformed), P - semi-hardened. Yüklə 5,26 Mb. Dostları ilə paylaş:
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