DOCSLIB.ORG

INDUCTION HARDENING of GEARS OFFERS VARIOUS APPROACHES Fast, Clean, Highly Nduction Hardening Offers a Must When Considering the Method

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
INDUCTION HARDENING of GEARS OFFERS VARIOUS APPROACHES Fast, Clean, Highly Nduction Hardening Offers a Must When Considering the Method INDUCTION HARDENING OF GEARS OFFERS VARIOUS APPROACHES Fast, clean, highly nduction hardening offers a must when considering the method. practical alternative technique to Hardening under a quench press repeatable, and thermochemical methods such (die quenching) is used when very inexpensive when as carburizing or carbonitriding strict tolerances are required in the I to improve the mechanical prop- part design and need to be obtained properly sized for the job, erties of gears. Advancements in gear after the hardening operation. The induction heating offers a materials and the development of best approach is to use a press with new induction heating simulation specific dies. Depending on part de- desirable production and prediction tools have led to im- sign and accuracy requirements, the solution for gear proved induction systems that ex- press can use single or multiple dies tend the induction hardening process (Fig. 2). hardening regardless of capability to include very demanding The balance of the article will re- part size and geometry. gear configurations. This article de- view other gear hardening technolo- scribes the various induction proc- gies, focusing on whole gear hard- esses for hardening gears. ening processes. Induction hardening can meet pro- Fabien Marquis Hardening methods duction needs in processing a range Dr. Hans Stiele Interest in using induction hard- of gears designs, from small EFD Induction GmbH ening of gears continues to increase sprockets to very large gears used in Freiburg, Germany as process capabilities advance with transmissions. Two main concepts the development of larger power are to harden only the gear tooth or sources for manufacturing facilities. part of it (only where the tooth makes At the same time, users want faster contact, for example) and to harden and more flexible and repeatable the entire gear circumference in- hardening solutions. Hardening with cluding the tip and root of each tooth or without specific tooling were the (Fig. 3). Other considerations such as two main methods for hardening. gear size, module, production rate, Hardening methods using quench power availability influence the tooling include an operation using a choice of the process. specific tool and an operation under a quench press (die quenching). Tooth-by-Tooth Hardening Hardening using a specific tool is This technique is commonly used used with components where dimen- to harden flanks and/roots; for ex- sional tolerances are very ample, large sprockets such as those tight. A simple OD or ID found in off-road equipment, or ring calibration tool (Fig. 1) gears found in transmissions. In the keeps dimensions within process, the coil comes onto the tooth an acceptable range. to harden root and flanks, or flanks The process is simple to and tip. Possible approaches are integrate into induction single shot and scanning operations. machines and provides a Some processing, such as the so- quick solution when called NATCO approach, performs simple distortion needs the hardening operation under water, to be corrected. How- which minimizes the distortion re- ever, die hardening is sulting from the transformation. Fig. 1 — Example of tooling used in gear hardening. not an easy technique, and experi- A current method used for large ence and know-how are definitely a gears (e.g., slewing rings) uses more 22 HEAT TREATING PROGRESS • JULY 2007 Fig. 2 — Examples of quench-die configurations. Fig. 3 — Tooth by tooth hardening. measuring devices, which make it possible to guarantee a perfect loca- tion of the coil vs. the part even when part is not well centered. This also provides the necessary process re- peatability. The air gap between coil and tooth must be constant during the heating process, but more important is the re- peatability of positioning from one tooth to another. To achieve regular control using measuring probe, a CNC axis gives the best result. Other solutions used to ensure a constant gap between coil and tooth flanks and/or root include mechanical when using a contact probe in neigh- boring teeth and ground-fault detec- tion in connection with the control system (CNC or PLC) giving a set Fig. 4 — Classification of the different gear spin-hardening methods. point when approaching the root of ferent heating techniques for induc- the tooth. tive gear spin hardening. Gear Spin Hardening Through Hardening on Gear Teeth In spin hardening, the entire gear For gears that are predominantly is brought up to the austenitizing subject to wear (e.g., sprockets), the temperature via an encircling coil tooth is through hardened using a and subsequently quenched, which relatively low specific power [2]. If the allows either through hardening of frequency is too low, there is the risk the gear down to the tooth root (sim- that beyond the Curie temperature ilar to case hardening) or hardening (point where the material changes the outer surface at a uniform or ir- from magnetic to nonmagnetic) the regular distance from the face. Figure induced eddy current largely flows 4 shows different methods for con- only in the root circle, and the tem- Fig. 5 — Hardened pattern on submerged- tour hardening corresponding to dif- perature of the tooth lags behind. hardened gear. HEAT TREATING PROGRESS • JULY 2007 23 Quenching for through hardening can be either submersion or spraying depending on the material [3]. De- pending on factors from the module to the frequency, it is recommended to delay the quenching sequence to achieve a uniform temperature be- tween the tooth and the root circle. Tempering after through hardening is essential for crack prevention. An example of a submerged hardened gear is shown in Fig. 5. Fig. 6 — Time-temperature profile of Gear Hardening on Tooth Perimeter Fig. 10 — Example of gear hardened using single-frequency contour hardening with in- (Contour or No Contour) two separate frequencies. duction preheating. When hardening at an irregular working frequency is higher rather distance from the tooth face, or (ide- than lower for the given module. ally) at a uniform distance from the If the frequency is higher than in tooth face, one can choose between the ideal case, it is possible to heat the the single frequency concept (SFC), root circle by means of thermo-con- in which an single frequency power duction during the preheating phase supply is used, and the dual fre- to subsequently achieve hardening quency method (including multiple results at an irregular distance from frequency concept, or MFC) using the face with a final heating impulse Fig. 7 — Hardened pattern on single-fre- two frequency levels (either simul- using a high specific power (Fig. 7). quency hardened gear taneously or not). On the other hand, if the generator frequency is too low for a given Single Frequency Concept module, through hardening of the In the process, the inductor is fed tooth or an inadequate austenitizing from a single power supply using a temperature of the tooth tip is un- frequency selected according to the avoidable for physical reasons. In ad- module. Heating (austenitizing) is dition, if the initial microstructure is done either via single shot in one step not suitable for gear hardening, fur- or with preheating using reduced ther improvement in the hardening power to reach a temperature be- result may be achieved via induction tween 550 to 750°C (1020 to 1380°F) initial hardening and tempering op- and subsequent final heating using erations before the actual hardening a higher specific power to the hard- itself. For this, heating of the entire ening temperature. Preheating can gear area to an austenitizing temper- Fig. 8 — Time-temperature profile of also consist of several pulsed cycles. ature corresponding to the material single-frequency contour hardening, prehard- The purpose of preheating is to reach is carried out. Cooling by self- ened and tempered by induction. an adapted high austenitizing tem- quenching (mass quenching) is fol- perature in the root circle during final lowed by a short inductive tem- heating, without overheating the pering of the entire gear. The actual tooth tip. The schematic principle can hardening zone at an irregular dis- be seen in Fig. 6. To achieve hard- tance from the face is then generated ening profiles at an irregular distance by a short final heating. The from the tooth face using a single fre- schematic time-temperature graph quency, short heating times com- for single frequency contour hard- bined with a high specific power is ening, prehardened, and tempered usually required. Both parameters by induction, is shown in Fig. 8. (time and power) depend on the hardened gear module. Dual-Frequency Methods It is not always certain that the user Dual-frequency hardening using has the optimum power supply with separate frequencies allows achiev- Fig. 9 — Time-temperature profile of dual- respect to available frequency, or ing hardening profiles similar to frequency contour hardening with induction whether it can be correspondingly those achieved using case hardening. preheating. adjusted. In this case, better results Two different frequencies, one after can be achieved for contour hard- the other, are applied to the gear. The ening using a generator in which the tooth part is preheated (depending 24 HEAT TREATING PROGRESS • JULY 2007 Fig. 11 — Time-temperature profile of Fig. 12 —General principle of the multiple frequency concept, or MFC. dual-frequency contour hardening, pre- quenched and tempered by induction. on the material) using a low fre- quency and limited power to a tem- perature between 550 and 750°C. The frequency should be such that the preheating preferably takes place in the root circle region. After a short delay, austenitizing using a higher frequency and higher power density is then provided. Heating times are measured in tenths of seconds or seconds (depending on the module Fig. 13 —Example of MFC application on and gear thickness/length) in this a gear.
Load more

Recommended publications
  • Ferritic Nitrocarburizing Gears to Increase Wear Resisitance And
    Ferritic Nitrocarburizing Gears tOI Increase Wear Resistance and Reduce Distortion Loren ,JI, Epler uaHtygear manufacturing depends on controlled toler- asa gaseous territic nitrocarl:mrizillg process and patented by ances and geometry. As a re ult, ferritic nillocarburizing Lucas Industries in 1961. Lucas demonstrated that they could ha become the heat treat process of choice for many produce surface layers identical to those produced in salt bath gear manufacturers. The primary reason for this are: processes using an endothermic, ammonia-based atmosphere. The process is performed at low temperatures, i.e. less than The process was classified as a "thermochemical susfece critical treatment" that involved !he diffusion of both nitrogenand car- 2. The quench methods increase fatigue strength by up to, L25% bon into the surface of a metal at a temperature below the au tell- without distorting. Ferritlc nitrocarboriziag is used in place ite transforrnation temperature. The process would yield .3 single of carburizing and hardening, carbonitriding, nltriding or in phase epsilon layer with an atomic weight of Fep3' The ingle conjunction wi.th conventional and induction hardening. phase layer makes !:heproduct much more wear resistant than gas 3. h establishes gradient base haronesses, i.e, eliminates egg- or ionnitriding, according to Dawc and Trantner 0). shell effect on TiN, TiAlN,. ere. etc. [II 1982, lronbeund HeatTreat developed Ni.tmwear® using In addition, the process can also be applied to hobs, broaches, similar atmo pheres in a fluidized bed medium. Subsequently. drills and other cutting tools. Jack Ross, owner and founder of lronbound,. patented and HisUJry, Fenitic nitrocarburizing was first established in licensed the process to Dynamic Metal Treating.
    [Show full text]
  • Induction Hardening on Drive Axle Shaft and It's
    www.ierjournal.org International Engineering Research Journal (IERJ) Special Issue Page 1197-1201, June 2016, ISSN 2395-1621 Induction Hardening on Drive axle shaft and it’s FEA #1Aniket A. Deshmukh, #2Prof. D.H. Burande 1 PG student, Automotive Engineering, Mechanical Engineering Department, Savitribai Phule Pune University, Pune, Maharashtra, India. 2Associate professor, Mechanical Engineering Department, Savitribai Phule Pune University, Pune, Maharashtra, India. Abstract: This work deals with increasing strength of steel drive axle shafts by placing an extra bush support. It includes the modeling of shaft in CATIA. Drive shaft made up of MS material will be analyzed first. Stress and deformation will be the output of analysis. The meshing and boundary condition application will be carried using Hypermesh; Structural analysis of shaft will be carried out using ANSYS. Re-designing the shaft placing a bush for additional support in the length of shaft, and applying induction hardening process at the place of bush support for increasing the strength and reducing the deflection of the shaft. The design optimization also improves the performance of drive shaft. Keywords: Finite Element Analysis, Drive axle shaft, Induction hardening, Bush support. 1. INTRODUCTION Power is transmitted from engine to differential through propeller shaft, Axle shaft is connected between Hardening process is used for parts that wears while differential and wheel. It takes torque from engine. In this operating. During hardening core of the part does not get paper, drive axle shaft of Bolero automobile is thought of affected. Hardening increases wear resistance of a for the study. This axle shaft is semi-floating kind.
    [Show full text]
  • Hardening of Small Gears in Well Under a Second
    Hardening of small gears PUTTING THE SMARTER HEAT TO SMARTER USE A guide to the benefits of induction heating FD - 2011236 02/16 ENG How to reduce distortion and costs when hardening small gears Induction is the cost-cutting alternative to furnace Induction can heat precisely localized zones in gears. case hardening of small- and medium-sized Achieving the same degree of localized hardening gears. Key features of induction hardening are with carburizing can be a time- and labor-intensive fast heating cycles, accurate heating patterns and procedure. When carburizing specific zones such as cores that remain relatively cold and stable. Such the teeth areas, it is usually necessary to mask the characteristics minimize distortion and make it more rest of the gear with ‘stop off’ coatings. These masks repetitive, reducing post-heat processing such as must be applied to each and every workpiece, and grinding. This is especially true when comparing removed following the hardening process. No such induction to case carburizing. masking is necessary with induction hardening. Induction hardening also reduces pre-processing, as Induction hardening is ideal for integrating into the geometry changes are less than those caused by production lines. Such integrated hardening is carburizing. Such minimal changes mean distortion more productive than thermochemical processes. does not need to be accounted for when making Moreover, integrated hardening minimizes costs, as the gear. With gears destined for gas carburizing, the gears do not have to be removed for separate however, ‘offsets’ that represent distortion are often heat treatment. In fact, induction heating makes introduced at the design stage.
    [Show full text]
  • Induction Hardening of Gears and Critical Components
    Induction Hardening of Gears and Critical Components Dr.Valery Rudnev hypoid gears and noncircular gears are rarely heat treated by Management Summary induction. Induction hardening is a heat treating technique that Importance of Gear Material and Its Condition can be used to selectively harden portions of a gear, such Gear operating conditions, the required hardness and cost as the fl anks, roots and tips of teeth, providing improved are important factors to consider when selecting materials for hardness, wear resistance, and contact fatigue strength induction hardened gears. Plain carbon steels and low-alloy without affecting the metallurgy of the core and other steels containing 0.40 to 0.55% carbon content are commonly parts of the component that don’t require change. This article provides an overview of the process and special specifi ed (Refs. 1, 5). Examples include AISI 1045, 1552, considerations for heat treating gears. Part I covers 4140, 4150, 4340, and 5150. Depending on the application, gear materials, desired microsctructure, coil design tooth hardness after tempering is typically in the 48 to 60 HRC and tooth-by-tooth induction hardening. Part II, which range. Core hardness primarily depends upon steel chemical will appear in the next issue, covers spin hardening composition and steel condition prior to induction hardening. and various heating concepts used with it. For quenching and tempering, prior structure core hardness is usually in the 28–35 HRC range. When discussing induction hardening, it is imperative to Introduction mention the importance of having “favorable” steel conditions Over the years, gear manufacturers have gained knowledge prior to gear hardening.
    [Show full text]
  • Part No: 26109031 Rev/Chg Level: 002A Specification Name: SPEC, REQ for HT PARTS
    MATERIAL SPECIFICATION Part No: 26109031 Rev/Chg Level : 002A Specification Name: SPEC, REQ FOR HT PARTS Production Release SAFETY AND/OR GOVERNMENT REGULATED PART ☐YES ☒NO DESIGNATED CHARACTERISTICS DC SYMBOL QCL TYPE QCI TYPE REF: NEXTEER GLOBAL PROCEDURE G1331 0 LAST NO USED QS-100V SAFETY/COMPLIANCE CL1/CL2 QS-DR 0 TOTAL ON DRAWING CI-100V FIT/FUNCTION CL4/CL5 CI-DR DC NO TYPE DESCRIPTION RATIONALE ZONE SH Substances of Concern and Recycled Content per Nexteer Automotive 23000000 This document is protected by copyright and nothing in this document shall grant a license or any other rights to this document or the information conveyed therein. The reproduction, distribution, and utilization of this document or its related CAD math data, as well as communication of any content to others without express written authorization is prohibited. X-3461 June 2014 Nexteer Automotive Reference Procedure G1337 Nexteer Automotive Production Release 2 of 21 Part No: 26109031 Rev/Chg Level: 002A Specification Name: SPEC, REQ FOR HT PARTS 1. SCOPE: 1.1. The purpose of this specification is to provide the expectations and requirements for heat treated components for Nexteer Automotive. This specification is applicable to all heat treat processes being conducted on the intended component(s) at any point in the value stream. Heat treat processes governed by this standard include all of those referenced in AIAG CQI-9. Heat treaters are expected to conform to the Quality System Requirement provided in the Nexteer Automotive Global Supply Management Supplier Requirements. It assumes that quality planning, a quality manual, and continuous improvement programs are established.
    [Show full text]
  • Induction Heat Treatment
    a ...... ...... ....... ..... ...... .... ... ..... ...... .... ... ..... ...... ....... ..... ...... ....,...... ..... ...... .... ... ..... ...... ....... ..... ...... ....... ..... ...... .... ... ....I ...... ....... ..... ...... ....... ..... ...... ....... ..... ...... ....... ..... ...... .... ... ..... ...... .... ... ...... .... ... ...... .... ... ...... ....... ...... .... ... ...... ,....... ... ...... .... ... .....I .... .... ..... ... ... .....(... ....... ... ..... ... ........ ... ... ..... ...... i iG -i Publishedby the EPRl Center for MaterialsFabrication Vol. 2, No. 2, 1985Reprinted March, 1990 Using Induction Heat speed and selective heating capabil- Vol. 2, No. 1. Advantages specific to Treatment to Obtain ity, to produce quality parts cost induction heat treating are: Special Properties effectively. It will answer such ques- Speed - In heat treatment, the Cost Effectively tions as: What are the advantages higher heating rates play a central of induction heat treatment? What role in designing rapid, high- Heat treatment is often one of the heat treatments can I conduct with temperature heat treating most important stages of metal induction? What are some typical processes. Induction heat treating of processing because it determines parts and materials that are induc- steel may take as little as the final properties that enable tion heat treated? What properties 10 percent or less of the time cqmponents to perform under such can I obtain with induction heat required for furnace treatment. demanding service conditions
    [Show full text]
  • The Effects of Austempering and Induction Hardening on the Wear Properties of Camshaft Made of Ductile Cast Iron
    Vol. 131 (2017) ACTA PHYSICA POLONICA A No. 3 Special Issue of the 6th International Congress & Exhibition (APMAS2016), Maslak, Istanbul, Turkey, June 1–3, 2016 The Effects of Austempering and Induction Hardening on the Wear Properties of Camshaft Made of Ductile Cast Iron B. Karacaa;∗ and M. Ş˙ımş˙ırb aESTAŞ Eksantrik San. ve Tic. A.Ş., 58060 Sivas, Turkey bCumhuriyet University, Engineering Faculty, Department of Metallurgy and Materials Eng., 58100 Sivas, Turkey The aim of this study is to investigate the effects of heat austempering and induction hardening on the wear properties of GGG60 ductile cast iron for camshaft production. For this purpose, camshafts have been produced by sand mould casting method. Fe-Si-Mg alloy has been used for inoculation process to achieve iron nodulization. The casting has been done between 1410–1420 ◦C. The casted camshafts have been austenitized at two different temperatures (800 and 900 ◦C) and time intervals (60 and 90 min) under controlled furnace atmosphere. The austenitized camshafts have been quenched into the molten salt bath at 360 ◦C, held there for 90 min and then cooled in air. This way, austempering heat treatment has been applied. After that, surface hardening process was conducted using induction hardening machine with medium frequency. Microstructure of camshafts has been examined by optical methods and mechanical tests have been performed. Results show that austempering heat treatment increases the wear resistance of camshaft, compared to as-cast condition. Wear resistance of the camshaft increases with increasing austenitizing temperature, time and with induction hardening. The lowest weight loss of 0.62 mg has been obtained for the induction hardened camshaft austenitized at 900 ◦C for 90 min.
    [Show full text]
  • Hardness and Case Depth Analysis Through Optimization Techniques in Surface Hardening Processes K
    38 The Open Materials Science Journal, 2010, 4, 38-63 Open Access Hardness and Case Depth Analysis Through Optimization Techniques in Surface Hardening Processes K. Palaniradja*, N. Alagumurthi and V. Soundararajan Department of Mechanical Engineering, Pondicherry Engineering College, Pondicherry – 605 014, India Abstract: Surface engineering and surface engineered materials find wide applications in engineering industries in recent years. Inconsistency in hardness and case depth has resulted in the further optimization of the process variables involved in surface hardening. In the present study, the following operating parameters viz. preheating, carbon potential, holding position, furnace temperature, carburising time, quenching medium, quenching temperature, quenching time, tempering temperature and tempering time were taken for optimization using the Taguchi and Factorial design of experiment concepts. From the experiments and optimization analysis conducted on EN29 and EN34 materials it was observed that furnace temperature and quenching time had equal influence in obtaining a better surface integrity of the case hardened components using gas carburizing. Preheating before gas carburizing further enhanced the surface hardness and the depth of hardness. In the case of induction hardening process, power potential played a vital role in optimizing the surface hardness and the depth of hardness. Keywords: Pinion, hardness, case depth, taguchi techniques, optimization, process variables. 1. INTRODUCTION In this study, Taguchi’s Design of Experiment concept has been used for the optimization of the process variables of Changing demands of dynamic market place have Gas Carburizing process and Factorial design of Experiment improved and increased the commitment to quality for the optimization of process variables of Induction consciousness. All over the world, companies are developing Hardening process.
    [Show full text]
  • Specifics of Induction Hardening of Powder Metallurgy (P/M) Components
    INDUCTION THOUGHTS INDUCTIONINDUCTION THOUGHTSTHOUGHTS Dr. Valery Rudnev, known as “Professor Induction”, discusses in the heat processing diffe- rent aspects of induction heating, novel theoretical and practical knowledge related to dif- ferent heat treating technologies accumulated in the North America and around the globe. Specifics of induction hardening of powder metallurgy (P/M) components uring the last decade, the use of advanced powder metallurgy type of heat treatment. However, differences in electromagnetic D(P/M) materials in several industries has been expanded at properties are specific for processing those materials applying an impressive pace further penetrating markets of demanding electromagnetic induction. Table 1 summarizes the effect of applications; however, the biggest market for ferrous P/M com- density reduction and porosity increase on IH. ponents remains to be the transportation industry, particularly The relative magnetic permeability μr of P/M materials is consid- the automotive and agricultural sectors. An ability to manufacture erably lower than the μr of the corresponding wrought steels, while net-shape complex geometries offering competitive performance their electrical resistivities ρ are greater to some extent. Both factors at an economical cost is an attractive feature of P/M parts (e. g. gears, lead to noticeably larger current penetration depth (δ) during the timing sprockets, cams, splined hubs, shafts, shock absorbers etc.) heating cycle, affecting not only heat generation and temperature [1]. Density and porosity in the sintered compact are major factors profiles but also the magnitude and distribution of transient and affecting strength and hardenability of ferrous P/M materials; both residual stresses as well as coil electrical parameters.
    [Show full text]
  • A Common Misassumption in Induction Hardening
    htprof.qxp 9/3/2004 11:22 AM Page 1 PPRROOFFEESSSSOORR IINNDDUUCCTTIIOONN by Valery I. Rudnev • Inductoheat Group Professor Induction welcomes comments, questions, and A common misassumption in suggestions for future columns. Since 1993, Dr. Valery Rudnev has been on the staff of induction hardening Inductoheat Group, where he Ω µ currently serves as group henever someone is talking about the metal ( ·m), r is the relative mag- director – science and Winduction heating, reference is netic permeability, and F is the fre- technology. In the past, he was an associate often made to the phenomenon of skin quency (Hz), or (in inches) as: professor at several universities, where he 1 effect. Skin effect is considered a fun- taught graduate and postgraduate courses. δ × ρ µ ½ damental property of induction = 3160 ( / rF) , (Eq. 3) His expertise is in materials science, heat treating, heating, representing a nonuniform applied electromagnetics, computer modeling, and distribution of an alternating current where electrical resistivity ρ is in units process development. He has 28 years of within the conductor cross section. This of Ω·in. experience in induction heating. effect will also be found in any electri- Thus, the value of penetration Credits include 15 patents and 118 scientific cally conductive body (workpiece) lo- depth varies with the square root of and engineering publications. cated inside an induction coil or in close electrical resistivity and inversely with proximity to the coil. According to this the square root of frequency and rel- Contact Dr. Rudnev at Inductoheat Group 32251 North Avis Drive phenomenon, eddy currents induced ative magnetic permeability.
    [Show full text]
  • Heat Treatment and Properties of Iron and Steel
    National Bureau of Standards Library, N.W. Bldg NBS MONOGRAPH 18 Heat Treatment and Properties of Iron and Steel U.S. DEPARTMENT OF COMMERCE NATIONAL BUREAU OF STANDARDS THE NATIONAL BUREAU OF STANDARDS Functions and Activities The functions of the National Bureau of Standards are set forth in the Act of Congress, March 3, 1901, as amended by Congress in Public Law 619, 1950. These include the development and maintenance of the national standards of measurement and the provision of means and methods for making measurements consistent with these standards; the determination of physical constants and properties of materials; the development of methods and instruments for testing materials, devices, and structures; advisory services to government agencies on scientific and technical problems; inven- tion and development of devices to serve special needs of the Government; and the development of standard practices, codes, and specifications. The work includes basic and applied research, develop- ment, engineering, instrumentation, testing, evaluation, calibration services, and various consultation and information services. Research projects are also performed for other government agencies when the work relates to and supplements the basic program of the Bureau or when the Bureau's unique competence is required. The scope of activities is suggested by the listing of divisions and sections on the inside of the back cover. Publications The results of the Bureau's work take the form of either actual equipment and devices or pub- lished papers.
    [Show full text]
  • Why Tempering Is Required After Hardening
    Why Tempering Is Required After Hardening According and nocturnal Uriah outedges indemonstrably and weary his sniffler telepathically and oppositely. When Shorty Islamising his limitlessness force-feed not incomprehensibly enough, is Rustin ductless? Is Phillipe tyrannicidal when Shelley reinterrogated attentively? Normaly i look to reduce hardness just book steels showed that lighter loads and tempering is Users across the globe expect their privacy to be taken seriously and modern commerce must reflect this wish. Zinc Ascorbate and Zinc Gluconate? Many steels and why cryogenic treatments of fasteners. After heating for tempering the workpieces are indexed to perform slow cooling table. Why is tempering done after hardening? Find results that contain. Since fewer carbon is why choose which makes no value of a solid depending on tool surface hardening is why tempering required after that are properly support associated with belts work? After shorter duration of martensite, why is published for any action at that have any other bluewater that required tempering after hardening is why. But is tempering is why required after hardening? Since it requires too many elements. In tempering is why treat by selecting this would hardly allow limitations on many furnace thermocouple can be smaller grain growth will heat treating? A When silicon ranges or limits are required the following ranges and limits are commonly. Sufficient database security prevents data during lost or compromised which five have serious ramifications for the company both define terms of finances and reputation Database security helps Company's block attacks including ransomware and breached firewalls which case turn keeps sensitive information safe.
    [Show full text]