Fergana polytechnic insitute mechanical engineering faculty department of mechanical engineering and automation
Heat-resistant steels . Heat resistance criteria (criteria) of materials
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Heat-resistant steels . Heat resistance criteria (criteria) of materials.
The fact that the material withstands deformation (mechanical loads) for a long time above its melting temperature by 0.3 parts and does not break (does not erode) is called heat resistance. Modern machine parts operate at high temperatures under great forces: metallurgical furnaces, gas pipes, aircraft engines, internal combustion engines, etc When choosing a material, the length of time of working under force and the acting forces are decisive. Heating reduces interatomic bonding forces, elastic modulus decreases at high temperatures, temporary resistance also decreases, both yield strength and hardness decrease. The lower the melting temperature (t er ) of the base of the alloy, the lower its limited operating temperature (Fig. 6. 2 ) . , the state of the material during long-term loading is determined by diffusion processes in it. These conditions are characterized by yield processes and stress relaxation processes. 6. Fig. 2 Temperature dependence of yield strength: 1-Al; 2-Cu; 3-Ti; 4-To; 5-W. 70 gradual increase in plastic deformation under the influence of forces below the yield point is called yielding . A specific variation of the deformation with the length of time of application of the force is shown. The yield curve consists of three periods. In the 1st period, the deformation begins well and slowly fades away - the rate of deformation is not constant; In the 2nd period, the rate of deformation stabilizes; In the 3rd period, the deformation accelerates and the metal breaks. It is impossible to bring the detailed operation to the 3rd period, it will break, break, etc. The yield deformation develops as a result of displacement of dislocations in grains, displacement of grain boundaries and diffusion migration. Migration of dislocations (above the melting temperature -0.3T earth ) takes place in two ways: sliding, jumping. To ensure heat resistance, it is necessary to limit the mobility of dislocations and slow down diffusion. This is achieved by increasing the interatomic binding forces : obstacles are placed on the migration of dislocations between the grains, and the grain sizes are increased. The strength of interatomic forces is increased by alloying: by changing the crystal lattice, by changing from a metallic bond to a stronger covalent bond. The feasibility of alloying is alloying with hard-to-melt metal, heat-resistant steel with a centered crystalline lattice is alloyed with molybdenum (up to 1%), and heat-resistant steel with a centered crystalline lattice is alloyed with tungsten, molybdenum, cobalt (up to 15-20% in total). 71 Figure 6.3 Yield curve. 1st non-stagnant period; 2nd stagnant period; 3rd decay period. A small amount of alloying elements (0.1-0.01%) are introduced to increase the strength of the grain boundaries of heat-resistant steels. These accumulate at the grain boundaries and slow down the grain boundary movement. These are boron and cerium elements. Thermo-mechanical processing also increases the heat resistance of steel. increases. Yüklə 5,26 Mb. Dostları ilə paylaş:
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