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chemical-process machinery

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Journal Articles
Alloy Digest (1979) 28 (9): SA-364.
Published: 01 September 1979
... and toughness. This steel is ideally suited for many critical applications in oil-field and power-generating equipment as well as for machinery in the metalworking, chemical-process and construction fields. This datasheet provides information on composition, physical properties, elasticity, and tensile...
Journal Articles
Alloy Digest (1983) 32 (4): SA-388.
Published: 01 April 1983
... isotropy, ductility and toughness. This steel is ideally suited for many critical applications in oil-field and power-generating equipment as well as for machinery in the metalworking, chemical-process and construction fields. This datasheet provides information on composition, physical properties...
Journal Articles
Alloy Digest (1973) 22 (1): CS-49.
Published: 01 January 1973
... 28x106 DOI: 10.31399/asm.ad.cs0049 Copyright © ASM International® 1996 Heat Treatment: Critical Temperatures: Ael = 13350F Ae3 = 13950F Acl = 13450F Ac3 = 14100F MS = 5900F Mgo= 405oF Normalize: Heat to 1550-1625oF, air COOL FuB Anneal: Heat 1525-16000F, furnace cool Process Anneal (after cold work...
Journal Articles
Alloy Digest (1977) 26 (11): CS-70.
Published: 01 November 1977
... = 14200F MS = 6OooF Mgo= 415oF The Acl, Ae3, Ac3, MS and Mgo temperatures were estimated. Normalize: Heat to 1550-1625OF, air cool. Full Anneal: Heat to 152516OOoF. furnace cool. process Anneal (after cold work): llOG1225oF. Harden: Heat to 1450-1525oF, quench in water or oil, temper to desired hardness...
Journal Articles
Alloy Digest (1988) 37 (1): CS-117.
Published: 01 January 1988
.../asm.ad.cs0117 Copyright © ASM International® 1996 Heat Treatment: Critical Temperatures: Ael = 1335°F Ae3 = 1395OF Acl = 1345 F Ac3 = 1410 F MS = 59WF M90 405°F Normalize: Heat to 1550- 1625 F, air cool. Full Anneal: Heat 1525-1600 F, furnace cool. Process Anneal (after cold work): 1 100-1225°F. Harden: Heat...
Journal Articles
Alloy Digest (1980) 29 (2): CS-80.
Published: 01 February 1980
... = 14150F Mgo = 3400F AISI 1551 can be joined readily by soldering and brazing. Its high carbon content introduces difficulties in welding. It can be welded satisfactorily by the Thermit process. Welding by the gas an arc methods is difficult and the resulting welds are only moderately satisfactory. Scale...
Journal Articles
Alloy Digest (1976) 25 (10): CS-63.
Published: 01 October 1976
... in salt bath at 600oF, hold 15-20 minutes, quench to Rockwell C 50 (approximately). Martemper: Heat to 1525oF, hold 5-15 minutes, quench in salt bath at 600oF, hold 1 minute, quench in oil or air, temper to desired hardness. Process Anneal (after cold work): 1 lOO-12500F. Machinability: The machinability...
Journal Articles
Alloy Digest (1988) 37 (1): CS-118.
Published: 01 January 1988
... to Rockwell C 50 (approximately). Martemper: Heat to 1525 F, hold 5-15 minutes, quench in salt bath at 600 F. hold 1 minute, quench in oil or air, temper to desired hardness. Process Anneal (after cold work): 1 IOO-1250 F. Machinability: The machinability rating of SAE 1065 steel, compared with free...
Journal Articles
Alloy Digest (1979) 28 (9): CI-48.
Published: 01 September 1979
... 3.8 Silicon 2.7 Manganese 0.9 Sulfur 0.06 Phosphorus 0.20 Iron Remainder *Chemical analysis and process are adjusted according to weight and section size of casting to control the structure and thereby obtain the desired mechanical properties. Physical Constants: (Approximate) Density, lb/cu in. 0.264...
Journal Articles
Alloy Digest (1981) 30 (8): CI-51.
Published: 01 August 1981
.../OF (lOO-1oooOF) 62 x 10-6 Thermal conductivity, Btu/ft2/in./hr/oF (504OOoF) 350 Coefficient of friction (against steel) 0.196 Modulus of elasticity, psi 20 x 106 Modulus of rupture, psi 8.9 x 103 *Chemical analysis and process are adjusted according to weight and section size of casting to control...
Journal Articles
Alloy Digest (1983) 32 (2): CS-92.
Published: 01 February 1983
... 300 F lo desired hardness and strength. Process Anneal (after cold work): 1 IOO-1250° F. DOI: 10.31399/asm.ad.cs0092 Copyright © ASM International® 1996 Table 5 - MASS EFFECT DATA (Single heat results. 0.6C. grain size 90% 5-7. 10% l-3) (Oil quenched from 1550°F and tempered) Diameter inches Tensile...
Journal Articles
Alloy Digest (1981) 30 (2): Cu-412.
Published: 01 February 1981
... Copper Alloy No. C51100 is a copper-tin-phosphorus alloy with relatively high tensile and yield strengths, good ductility and good resistance to corrosion. It can be fabricated by a number of conventional processes. Its many applications include bridge bearing plates, numerous hardware uses...
Journal Articles
Alloy Digest (1984) 33 (2): CS-100.
Published: 01 February 1984
...: 10.31399/asm.ad.cs0100 Copyright © ASM International® 1996 (approximately). Martemper: Heat to 1525 F. hold 5- I5 minutes. quench in salt bath at 600°F. hold I minute. quench in oil or air, temper to desired hardness. Process Anneal (after cold work): I lO&l25o F. Machinability: The machinability rating...
Journal Articles
Alloy Digest (1980) 29 (6): CI-50.
Published: 01 June 1980
... 10-6 Thermal conductivity, Btu/ft2/in./hr/oF (504500F) 345 Coefficient of friction (against steel) 0.189 Modulus of elasticity, psi 18 x 106 Modulus of rupture, psi 8.5 x 103 *Chemical analysis and process are adjusted according to weight and section size of casting to control the structure...
Journal Articles
Alloy Digest (2018) 67 (1): SA-808.
Published: 01 January 2018
... in water or 900 950 °C (1652 1742 °F) and quenched in oil. Tempering after hardening usually is not necessary. To increase the yield strength, tempering between 200 250 °C (392 482 °F) can be carried out if necessary. Processing Prior to any processing, it is advisable to make use of the information...
Journal Articles
Alloy Digest (2018) 67 (2): SA-811.
Published: 01 February 2018
... (1598 1688 °F) and quenched in water or 900 950 °C (1652 1742 °F) and quenched in oil. Tempering after hardening usually is not necessary. To increase the yield strength, tempering between 200 °C and 250 °C (392 482 °F) can be carried out if necessary. Processing Prior to any processing, it is advisable...
Journal Articles
Alloy Digest (2014) 63 (10): SA-711.
Published: 01 October 2014
... by means of welding or metal spraying. Workability: General Processing Information. Prior to any processing, it is advisable to make use of the information available from the steel producer in order to draw on that experience for the processing. It is left to the discretion of the processor/fabricator...
Journal Articles
Alloy Digest (1977) 26 (9): CI-44.
Published: 01 September 1977
... Bronze Products, Inc. Composition*: Physical Constants: (Approximate) Nominal Total Carbon 3.2 Silicon 2.4 Manganese &6 SUlfUI 0.06 Phosphorus 0.20 Iron Remainder *Chemical analysis and process are adjusted according to weight and section size of casting to control the structure and thereby obtain...
Journal Articles
Alloy Digest (2017) 66 (10): SA-801.
Published: 01 October 2017
... can be produced using the producer s Fineline processing. For improved machinability, higher levels of sulfur can be maintained through the producer s Clean-Cut processing. The slabs or ingots are rolled to plate on one of two rolling mills depending on finished plate size. Both mills have hydraulic...
Journal Articles
Alloy Digest (1982) 31 (8): CS-89.
Published: 01 August 1982
...-making operation. Full Anneal: Heat to 1450-155O F. furnace cool. Process Anneal (after cold work): 1 lOO-1250°F. Normalize: Heat to 1550-165O F. air cool. Harden: Heat to 1450-1550°F. quench in water or oil, temper to the desired hardness. Oil quenching minimizes distortion but will not give maximum...