Turbine components, such as the one shown, are among the key applications for open die forgings produced by All Metals & Forge Group. (Photo courtesy All Metals & Forge Group)

By collaborating with an experienced seamless rolled ring manufacturer that can tailor the forging process to the specific end use, OEMs can ensure their final product meets all the necessary requirements and industry standards for their specific application.

By Royce Lowe

When forging seamless rolled rings for diverse sectors such as industrial machinery, pulp and paper, turbines, and oil and gas exploration, it is crucial to tailor components for their specific applications, or end use.

In the realm of metal parts, the term “end use” commonly denotes the ultimate form and state of the final machined part, along with a comprehension of the operating conditions it will face during service.

“By understanding the final application or purpose—the end use—for which these parts are designed and manufactured, forged parts suppliers can determine the appropriate materials, manufacturing processes, and quality standards necessary to ensure that the metal parts perform effectively and reliably in their intended applications,” said Jeff Klein, director of sales for All Metals & Forge Group.

A side view of a turbine component produced by All Metals & Forge Group. (Photo courtesy All Metals & Forge Group)

All Metals & Forge Group, an ISO 9001:2015 and AS9100D-certified manufacturer headquartered in Fairfield, New Jersey, produces open die forgings, seamless and contoured rolled rings, and complex forged parts to industry standard specifications in 8 to 10 weeks.

According to Klein, open die forgings and seamless rolled rings play a crucial role as components in gears, turbines, bearings, clutches, and couplings—as well as drives, flanges, valves, machines, and rollers—for a wide variety of end uses. These items must exhibit exceptional attributes, such as strength, durability, precision, and resistance to fatigue, deformation, and harsh environments in saltwater or downhole uses, to meet precise performance standards when deployed in the field.

In some cases, failing to consider the end use can even introduce serious risk, including catastrophic failure of a part while in operation.

For example, aircraft engines include seamless rolled rings. If such a part fails catastrophically during takeoff, flight, or landing, the engine can tear itself apart or explode, sending pieces of hot metal at high speed through the engine housing and into the plane wing—compromising structural integrity—or the passenger cabin, causing dangerous depressurization, passenger death, or an airliner crash.

In the oil and gas exploration industry, the failure of a forged part can occur more than a mile underground, causing a well shutdown and the withdrawal of the failed part that may be more than 10,000 feet below the surface. In machinery, a part failure can cripple production, and a replacement part may not be obtainable for several months.

Custom forged parts produced by All Metals & Forge Group. (Photo courtesy All Metals & Forge Group)

Consider End Use, from the Start

The consideration and planning to meet end use requirements should begin with the service requirements outlined during the engineering phase of design and conclude when the part is in its operating position, performing as intended.

“It is vital that the manufacturer specify the end use of each part and ensure it is communicated throughout the production chain, from the design engineer, through purchasing, the forging operation, heat treating, finish machining, and final assembly of the end use, including the mechanical property requirements and the heat or corrosive conditions in which the forged part will perform,” said Klein.

According to Klein, different industries, such as food processing, paper manufacturing, machinery building, oil and gas exploration, or energy, have unique specifications and standards that metal parts must meet. The specific function of the part will dictate its design, dimensions, material selection, forging, heat treating, and finishing processes. In all cases, the part must be manufactured to industry standard specifications, such as ASTM, AMS, AISI, or API, unless the OEM has developed its own requirements by modifying one of those standards.

In short, the finished product must comply with all quality, durability, chemistry, and mechanical properties within the selected standard.

Seamless rolled rings can be produced in a variety of alloys, sizes, and shapes specific to fit end use requirements. However, by collaborating closely with the forging supplier, engineers, buyers, and machinery builders can ensure the ideal selection of chemistry, mechanical properties, heat treatment, machining, and testing ultimately required for each part’s end use.

The process often begins with the selection of the alloy grade used for open die forging or seamless rolled ring production, which can apply to many specific end-uses. These range from low and medium carbon steels, through high-carbon steels, aluminum alloys, alloy steels, stainless steels, nickel alloys, tool steels, and titanium alloys. The precise alloy for the intended end use should always be specified and stated in the purchasing process according to final mechanical property requirements and service conditions.

Material properties can also be altered for specific end uses by hot working, as well as by using various chemistries, temperatures, heat treatment times, and cooling methods. This facilitates the production of seamless rolled rings or forged parts with optimized mechanical properties and structural integrity, before the part moves on to finish machining.

Turbine parts in production at All Metals & Forge Group. (Photo courtesy All Metals & Forge Group)

Each metal possesses unique alloy chemical compositions formed during the steel mill process, along with diverse production procedures for generating ingots or billets of different grades and purities tailored for industry specifications. Consequently, the quality of steel mill output is critical.

At All Metals & Forge Group, end use is emphasized from the very beginning in the request for quote (RFQ) process. The company works with its steel mills to purchase the correct starting stock to achieve the specified properties and operating reliability required of every part. In addition, rough machined parts are tested at least three times to prove chemistry, mechanical properties, and soundness before shipping.

According to Klein, there are groups of alloys within each metal material that lend themselves to specific end uses.

High-nickel alloys (I625, I718, I825), for example, are used at high temperatures in such applications as jet engine parts, nuclear power generation, and heat-treated fixtures where high oxidation resistance is required. Other alloys within this group find use in the pulp and paper or oil and gas industries, where corrosive conditions may be severe.

The Inconel 600 and 700 series were developed for specific end uses. Inconel 600 resists chloride-ion stress corrosion cracking. Inconel 690 resists sulfur-bearing gases. Inconel 718 is a precipitation-hardening alloy designed to give very high yield, ultimate tensile strengths, and resistance to creep rupture at temperatures up to 1300°F (705°C).

End use is equally important with stainless steels, where the various groups of martensitic (hardenable), ferritic, and austenitic cover a very wide range of properties and applications when resistance to corrosion and heat are critical.

Basic type 410 martensitic grade stainless, with about 13 percent chromium, is sufficient for mild corrosive conditions, whereas the ferritic type 430, with 17 percent chromium, shows resistance to more severe environments. The performance of the austenitic stainless steels, based on the 18 percent chromium/10 percent nickel in type 304, is selected for certain end uses when correctly heat treated and not subject to carbide precipitation. The various additions to the base 304, such as molybdenum, improve resistance to pitting corrosion. The resultant molybdenum-containing grades are types 316 and 317, normally supplied in the low-carbon versions, 316L and 317L.

The range of stainless steels continues through types 329 and 2205 duplex alloys—austenite and ferrite—that provide good resistance to pitting and stress corrosion cracking, to precipitation hardening grades such as 13-8Mo, 15-5PH, 15-7Mo, and 17-4PH. These latter grades reach high yield and ultimate tensile strengths from a single, low-temperature heat treatment following a solution anneal. This makes these types of stainless steels suitable for challenging applications, such as oil field valve parts, chemical process equipment, forged aircraft fittings, nuclear reactor parts, and jet engine components.

With so many options available, a thorough grasp of the end use is vital for establishing the correct material, dimensions, and properties needed during forging to guarantee peak performance in the eventual application. By collaborating with an experienced seamless rolled ring manufacturer that can tailor the forging process to the specific end use, OEMs can ensure their final product meets all the necessary requirements and industry standards for their specific application.

Royce Lowe is a freelance technical writer with more than 30 years of experience in metallurgy.