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Hot metal ingot being loaded into a hammer forge
A billet in an open-die forging press

Forging is a manufacturing process involving the shaping of metal using localized compressive forces. The blows are delivered with a hammer (often a power hammer) or a die. Forging is often classified according to the temperature at which it is performed: cold forging (a type of cold working), warm forging, or hot forging (a type of hot working). For the latter two, the metal is heated, usually in a forge. Forged parts can range in weight from less than a kilogram to hundreds of metric tons.[1][2] Forging has been done by smiths for millennia; the traditional products were kitchenware, hardware, hand tools, edged weapons, cymbals, and jewellery.

Since the Industrial Revolution, forged parts are widely used in mechanisms and machines wherever a component requires high strength; such forgings usually require further processing (such as machining) to achieve a finished part. Today, forging is a major worldwide industry.[3]

History

[edit]
Forging a nail. Valašské muzeum v přírodě, Czech Republic

Forging is one of the oldest known metalworking processes.[1] Traditionally, forging was performed by a smith using hammer and anvil, though introducing water power to the production and working of iron in the 12th century allowed the use of large trip hammers or power hammers that increased the amount and size of iron that could be produced and forged. The smithy or forge has evolved over centuries to become a facility with engineered processes, production equipment, tooling, raw materials and products to meet the demands of modern industry.

In modern times, industrial forging is done either with presses or with hammers powered by compressed air, electricity, hydraulics or steam. These hammers may have reciprocating weights in the thousands of pounds. Smaller power hammers, 500 lb (230 kg) or less reciprocating weight, and hydraulic presses are common in art smithies as well. Some steam hammers remain in use, but they became obsolete with the availability of the other, more convenient, power sources.

Processes

[edit]
A cross-section of a forged connecting rod that has been etched to show the grain flow

There are many different kinds of forging processes available; however, they can be grouped into three main classes:[1]

  • Drawn out: length increases, cross-section decreases
  • Upset: length decreases, cross-section increases
  • Squeezed in closed compression dies: produces multidirectional flow

Common forging processes include: roll forging, swaging, cogging, open-die forging, impression-die forging (closed die forging), press forging, cold forging, automatic hot forging and upsetting.[1][4]

Temperature

[edit]
Main article: Forging temperature
See also: Hot working and Cold working

All of the following forging processes can be performed at various temperatures; however, they are generally classified by whether the metal temperature is above or below the recrystallization temperature.[5] If the temperature is above the material's recrystallization temperature it is deemed hot forging; if the temperature is below the material's recrystallization temperature but above 30% of the recrystallization temperature (on an absolute scale) it is deemed warm forging; if below 30% of the recrystallization temperature (usually room temperature) then it is deemed cold forging. The main advantage of hot forging is that it can be done more quickly and precisely, and as the metal is deformed work hardening effects are negated by the recrystallization process. Cold forging typically results in work hardening of the piece.[6][7]

Drop forging

[edit]
Boat nail production in Hainan, China

Drop forging is a forging process where a hammer is raised and then "dropped" into the workpiece to deform it according to the shape of the die. There are two types of drop forging: open-die drop forging and impression-die (or closed-die) drop forging. As the names imply, the difference is in the shape of the die, with the former not fully enclosing the workpiece, while the latter does.

Open-die drop forging

[edit]
Open-die drop forging (with two dies) of an ingot to be further processed into a wheel
A large 80 ton cylinder of hot steel in an open-die forging press, ready for the upsetting phase of forging

Open-die forging is also known as smith forging.[8] In open-die forging, a hammer strikes and deforms the workpiece, which is placed on a stationary anvil. Open-die forging gets its name from the fact that the dies (the surfaces that are in contact with the workpiece) do not enclose the workpiece, allowing it to flow except where contacted by the dies. The operator therefore needs to orient and position the workpiece to get the desired shape. The dies are usually flat in shape, but some have a specially shaped surface for specialized operations. For example, a die may have a round, concave, or convex surface or be a tool to form holes or be a cut-off tool.[9] Open-die forgings can be worked into shapes which include discs, hubs, blocks, shafts (including step shafts or with flanges), sleeves, cylinders, flats, hexes, rounds, plate, and some custom shapes.[10] Open-die forging lends itself to short runs and is appropriate for art smithing and custom work. In some cases, open-die forging may be employed to rough-shape ingots to prepare them for subsequent operations. Open-die forging may also orient the grain to increase strength in the required direction.[9]

Advantages of open-die forging

[edit]
  • Reduced chance of voids
  • Better fatigue resistance
  • Improved microstructure
  • Continuous grain flow
  • Finer grain size
  • Greater strength[11]
  • Better response to thermal treatment[12]
  • Improvement of internal quality
  • Greater reliability of mechanical properties, ductility and impact resistance

"Cogging" is the successive deformation of a bar along its length using an open-die drop forge. It is commonly used to work a piece of raw material to the proper thickness. Once the proper thickness is achieved the proper width is achieved via "edging".[13] "Edging" is the process of concentrating material using a concave shaped open-die. The process is called "edging" because it is usually carried out on the ends of the workpiece. "Fullering" is a similar process that thins out sections of the forging using a convex shaped die. These processes prepare the workpieces for further forging processes.[14]

  • Edging
    Edging
  • Fullering
    Fullering

Impression-die forging

[edit]

Impression-die forging is also called "closed-die forging". In impression-die forging, the metal is placed in a die resembling a mold, which is attached to an anvil. Usually, the hammer die is shaped as well. The hammer is then dropped on the workpiece, causing the metal to flow and fill the die cavities. The hammer is generally in contact with the workpiece on the scale of milliseconds. Depending on the size and complexity of the part, the hammer may be dropped multiple times in quick succession. Excess metal is squeezed out of the die cavities, forming what is referred to as "flash". The flash cools more rapidly than the rest of the material; this cool metal is stronger than the metal in the die, so it helps prevent more flash from forming. This also forces the metal to completely fill the die cavity. After forging, the flash is removed.[8][15]

In commercial impression-die forging, the workpiece is usually moved through a series of cavities in a die to get from an ingot to the final form. The first impression is used to distribute the metal into the rough shape in accordance to the needs of later cavities; this impression is called an "edging", "fullering", or "bending" impression. The following cavities are called "blocking" cavities, in which the piece is working into a shape that more closely resembles the final product. These stages usually impart the workpiece with generous bends and large fillets. The final shape is forged in a "final" or "finisher" impression cavity. If there is only a short run of parts to be done, then it may be more economical for the die to lack a final impression cavity and instead machine the final features.[16]

Impression-die forging has been improved in recent years through increased automation which includes induction heating, mechanical feeding, positioning and manipulation, and the direct heat treatment of parts after forging.[17] One variation of impression-die forging is called "flashless forging", or "true closed-die forging". In this type of forging, the die cavities are completely closed, which keeps the workpiece from forming flash. The major advantage to this process is that less metal is lost to flash. Flash can account for 20 to 45% of the starting material. The disadvantages of this process include additional cost due to a more complex die design and the need for better lubrication and workpiece placement.[16]

There are other variations of part formation that integrate impression-die forging. One method incorporates casting a forging preform from liquid metal. The casting is removed after it has solidified, but while still hot. It is then finished in a single cavity die. The flash is trimmed, then the part is quench hardened. Another variation follows the same process as outlined above, except the preform is produced by the spraying deposition of metal droplets into shaped collectors (similar to the Osprey process).[17]

Closed-die forging has a high initial cost due to the creation of dies and required design work to make working die cavities. However, it has low recurring costs for each part, thus forgings become more economical with greater production volume. This is one of the major reasons closed-die forgings are often used in the automotive and tool industries. Another reason forgings are common in these industrial sectors is that forgings generally have about a 20 percent higher strength-to-weight ratio compared to cast or machined parts of the same material.[16]

Design of impression-die forgings and tooling
[edit]

Forging dies are usually made of high-alloy or tool steel. Dies must be impact- and wear-resistant, maintain strength at high temperatures, and have the ability to withstand cycles of rapid heating and cooling. In order to produce a better, more economical die the following standards are maintained:[17]

  • The dies part along a single, flat plane whenever possible. If not, the parting plane follows the contour of the part.
  • The parting surface is a plane through the center of the forging and not near an upper or lower edge.
  • Adequate draft is provided; usually at least 3° for aluminium and 5° to 7° for steel.
  • Generous fillets and radii are used.
  • Ribs are low and wide.
  • The various sections are balanced to avoid extreme difference in metal flow.
  • Full advantage is taken of fiber flow lines.
  • Dimensional tolerances are not closer than necessary.

Barrelling occurs when, due to friction between the work piece and the die or punch, the work piece bulges at its centre in such a way as to resemble a barrel. This leads to the central part of the work piece to come in contact with the sides of the die sooner than if there were no friction present, creating a much greater increase in the pressure required for the punch to finish the forging.

The dimensional tolerances of a steel part produced using the impression-die forging method are outlined in the table below. The dimensions across the parting plane are affected by the closure of the dies, and are therefore dependent on die wear and the thickness of the final flash. Dimensions that are completely contained within a single die segment or half can be maintained at a significantly greater level of accuracy.[15]

Dimensional tolerances for impression-die forgings[15]
Mass [kg (lb)] Minus tolerance [mm (in)] Plus tolerance [mm (in)]
0.45 (1) 0.15 (0.006) 0.46 (0.018)
0.91 (2) 0.20 (0.008) 0.61 (0.024)
2.27 (5) 0.25 (0.010) 0.76 (0.030)
4.54 (10) 0.28 (0.011) 0.84 (0.033)
9.07 (20) 0.33 (0.013) 0.99 (0.039)
22.68 (50) 0.48 (0.019) 1.45 (0.057)
45.36 (100) 0.74 (0.029) 2.21 (0.087)

A lubricant is used when forging to reduce friction and wear. It is also used as a thermal barrier to restrict heat transfer from the workpiece to the die. Finally, the lubricant acts as a parting compound to prevent the part from sticking in the dies.[15]

Press forging

[edit]

Press forging works by slowly applying a continuous pressure or force, which differs from the near-instantaneous impact of drop-hammer forging. The amount of time the dies are in contact with the workpiece is measured in seconds (as compared to the milliseconds of drop-hammer forges). The press forging operation can be done either cold or hot.[15]

The main advantage of press forging, as compared to drop-hammer forging, is its ability to deform the complete workpiece. Drop-hammer forging usually only deforms the surfaces of the work piece in contact with the hammer and anvil; the interior of the workpiece will stay relatively undeformed. Another advantage to the process includes the knowledge of the new part's strain rate. By controlling the compression rate of the press forging operation, the internal strain can be controlled.

There are a few disadvantages to this process, most stemming from the workpiece being in contact with the dies for such an extended period of time. The operation is a time-consuming process due to the amount and length of steps. The workpiece will cool faster because the dies are in contact with workpiece; the dies facilitate drastically more heat transfer than the surrounding atmosphere. As the workpiece cools it becomes stronger and less ductile, which may induce cracking if deformation continues. Therefore, heated dies are usually used to reduce heat loss, promote surface flow, and enable the production of finer details and closer tolerances. The workpiece may also need to be reheated.

When done in high productivity, press forging is more economical than hammer forging. The operation also creates closer tolerances. In hammer forging a lot of the work is absorbed by the machinery; when in press forging, the greater percentage of work is used in the work piece. Another advantage is that the operation can be used to create any size part because there is no limit to the size of the press forging machine. New press forging techniques have been able to create a higher degree of mechanical and orientation integrity. By the constraint of oxidation to the outer layers of the part, reduced levels of microcracking occur in the finished part.[15]

Press forging can be used to perform all types of forging, including open-die and impression-die forging. Impression-die press forging usually requires less draft than drop forging and has better dimensional accuracy. Also, press forgings can often be done in one closing of the dies, allowing for easy automation.[18]

Upset forging

[edit]
"Upsetting" redirects here. For other uses, see upset (disambiguation).

Upset forging increases the diameter of the workpiece by compressing its length.[18] Based on number of pieces produced, this is the most widely used forging process.[18] A few examples of common parts produced using the upset forging process are engine valves, couplings, bolts, screws, and other fasteners.

Upset forging is usually done in special high-speed machines called crank presses. The machines are usually set up to work in the horizontal plane, to facilitate the quick exchange of workpieces from one station to the next, but upsetting can also be done in a vertical crank press or a hydraulic press. The initial workpiece is usually wire or rod, but some machines can accept bars up to 25 cm (9.8 in) in diameter and a capacity of over 1000 tons. The standard upsetting machine employs split dies that contain multiple cavities. The dies open enough to allow the workpiece to move from one cavity to the next; the dies then close and the heading tool, or ram, then moves longitudinally against the bar, upsetting it into the cavity. If all of the cavities are utilized on every cycle, then a finished part will be produced with every cycle, which makes this process advantageous for mass production.[18]

These rules must be followed when designing parts to be upset forged:[19]

  • The length of unsupported metal that can be upset in one blow without injurious buckling should be limited to three times the diameter of the bar.
  • Lengths of stock greater than three times the diameter may be upset successfully, provided that the diameter of the upset is not more than 1.5 times the diameter of the stock.
  • In an upset requiring stock length greater than three times the diameter of the stock, and where the diameter of the cavity is not more than 1.5 times the diameter of the stock, the length of unsupported metal beyond the face of the die must not exceed the diameter of the bar.

Automatic hot forging

[edit]

The automatic hot forging process involves feeding mill-length steel bars (typically 7 m (23 ft) long) into one end of the machine at room temperature and hot forged products emerge from the other end. This all occurs rapidly; small parts can be made at a rate of 180 parts per minute (ppm) and larger can be made at a rate of 90 ppm. The parts can be solid or hollow, round or symmetrical, up to 6 kg (13 lb), and up to 18 cm (7.1 in) in diameter. The main advantages to this process are its high output rate and ability to accept low-cost materials. Little labor is required to operate the machinery.

There is no flash produced so material savings are between 20 and 30% over conventional forging. The final product is a consistent 1,050 °C (1,920 °F) so air cooling will result in a part that is still easily machinable (the advantage being the lack of annealing required after forging). Tolerances are usually ±0.3 mm (0.012 in), surfaces are clean, and draft angles are 0.5 to 1°. Tool life is nearly double that of conventional forging because contact times are on the order of 0.06-second. The downside is that this process is only feasible on smaller symmetric parts and cost; the initial investment can be over $10 million, so large quantities are required to justify this process.[20]

The process starts by heating the bar to 1,200 to 1,300 °C (2,190 to 2,370 °F) in less than 60 seconds using high-power induction coils. It is then descaled with rollers, sheared into blanks, and transferred through several successive forming stages, during which it is upset, preformed, final forged, and pierced (if necessary). This process can also be coupled with high-speed cold-forming operations. Generally, the cold forming operation will do the finishing stage so that the advantages of cold-working can be obtained, while maintaining the high speed of automatic hot forging.[21]

Examples of parts made by this process are: wheel hub unit bearings, transmission gears, tapered roller bearing races, stainless steel coupling flanges, and neck rings for liquid propane (LP) gas cylinders.[22] Manual transmission gears are an example of automatic hot forging used in conjunction with cold working.[23]

Roll forging

[edit]

Roll forging is a process where round or flat bar stock is reduced in thickness and increased in length. Roll forging is performed using two cylindrical or semi-cylindrical rolls, each containing one or more shaped grooves. A heated bar is inserted into the rolls and when it hits a spot the rolls rotate and the bar is progressively shaped as it is rolled through the machine. The piece is then transferred to the next set of grooves or turned around and reinserted into the same grooves. This continues until the desired shape and size is achieved. The advantage of this process is there is no flash and it imparts a favorable grain structure into the workpiece.[24]

Examples of products produced using this method include axles, tapered levers and leaf springs.

Net-shape and near-net-shape forging

[edit]
See also: Near-net-shape

Also known as precision forging, it was developed to minimize cost and waste post-forging such that the resultant product needs little or no final machining. Costs are reduced by using less material, producing less scrap, less energy used, and less or no additional machining. Precision forging also requires less draft, 1° to 0°. The downside of this process is cost, it is only implemented when significant cost reduction can be achieved.[25]

Cold forging

[edit]

Near net shape forging is most common when parts are forged without heating the slug, bar or billet. Aluminum is a common material that can be cold forged depending on final shape. Lubrication of the parts being formed is critical to increase the life of the mating dies.

Induction forging

[edit]
Main article: Induction forging

Unlike the above processes, induction forging is based on the type of heating style used. Many of the above processes can be used in conjunction with this heating method.

Multidirectional forging

[edit]

Multidirectional forging is forming of a work piece in a single step in several directions. The multidirectional forming takes place through constructive measures of the tool. The vertical movement of the press ram is redirected using wedges which distributes and redirects the force of the forging press in horizontal directions.[26]

Isothermal forging

[edit]

Isothermal forging is a process by which the materials and the die are heated to the same temperature (iso- meaning "equal"). Adiabatic heating is used to assist in the deformation of the material, meaning the strain rates are highly controlled. This technique is commonly used for forging aluminium, which has a lower forging temperature than steels. Forging temperatures for aluminum are around 430 °C (806 °F), while steels and super alloys can be 930 to 1,260 °C (1,710 to 2,300 °F).

Benefits:

  • Near net shapes which lead to lower machining requirements and therefore lower scrap rates
  • Reproducibility of the part
  • Due to the lower heat loss smaller machines can be used to make the forging

Disadvantages:

  • Higher die material costs to handle temperatures and pressures
  • Uniform heating systems are required
  • Protective atmospheres or vacuum to reduce oxidation of the dies and material
  • Low production rates

Materials and applications

[edit]
Solid forged billets of steel (glowing incandescently) being loaded in a large industrial chamber furnace, for re-heating

Forging of steel

[edit]

Depending on the forming temperature steel forging can be divided into:[27]

  • Hot forging of steel
    • Forging temperatures above the recrystallization temperature between 950–1250 °C
    • Good formability
    • Low forming forces
    • Constant tensile strength of the workpieces
  • Warm forging of steel
    • Forging temperatures between 750–950 °C
    • Less or no scaling at the workpiece surface
    • Narrower tolerances achievable than in hot forging
    • Limited formability and higher forming forces than for hot forging
    • Lower forming forces than in cold forming
  • Cold forging of steel
    • Forging temperatures at room conditions, self-heating up to 150 °C due to the forming energy
    • Narrowest tolerances achievable
    • No scaling at workpiece surface
    • Increase of strength and decrease of ductility due to strain hardening
    • Low formability and high forming forces are necessary

For industrial processes steel alloys are primarily forged in hot condition. Brass, bronze, copper, precious metals and their alloys are manufactured by cold forging processes; each metal requires a different forging temperature.

Forging of aluminium

[edit]
  • Aluminium forging is performed at a temperature range between 350–550 °C
  • Forging temperatures above 550 °C are too close to the solidus temperature of the alloys and lead in conjunction with varying effective strains to unfavorable workpiece surfaces and potentially to a partial melting as well as fold formation.[28]
  • Forging temperatures below 350 °C reduce formability by increasing the yield stress, which can lead to unfilled dies, cracking at the workpiece surface and increased die forces

Due to the narrow temperature range and high thermal conductivity, aluminium forging can only be realized in a particular process window. To provide good forming conditions a homogeneous temperature distribution in the entire workpiece is necessary. Therefore, the control of the tool temperature has a major influence to the process. For example, by optimizing the preform geometries the local effective strains can be influenced to reduce local overheating for a more homogeneous temperature distribution.[29]

Application of aluminium forged parts

[edit]

High-strength aluminium alloys have the tensile strength of medium strong steel alloys while providing significant weight advantages. Therefore, aluminium forged parts are mainly used in aerospace, automotive industry and many other fields of engineering especially in those fields, where highest safety standards against failure by abuse, by shock or vibratory stresses are needed. Such parts are for example pistons,[citation needed] chassis parts, steering components and brake parts. Commonly used alloys are AlSi1MgMn (EN AW-6082) and AlZnMgCu1,5 (EN AW-7075). About 80% of all aluminium forged parts are made of AlSi1MgMn. The high-strength alloy AlZnMgCu1,5 is mainly used for aerospace applications.[30]

Forging of magnesium

[edit]
  • Magnesium forging occurs at a temperature range between 290–450 °C[31]

Magnesium alloys are more difficult to forge due to their low plasticity, low sensitivity to strain rates and narrow forming temperature.[31] Using semi-open die hot forging with a three-slide forging press (TSFP) has become a newly developed forging method for Mg–Al alloy AZ31, commonly used in forming aircraft brackets.[32][33] This forging method has shown to improve tensile properties but lacks uniform grain size.[34][35] Even though the application of magnesium alloys increases by 15–20% each year in the aerospace and automotive industry, forging magnesium alloys with specialized dies is expensive and an unfeasible method to produce parts for a mass market. Instead, most magnesium alloy parts for industry are produced by casting methods.

Equipment

[edit]
Hydraulic drop-hammer
(a) Material flow of a conventionally forged disc; (b) Material flow of a counterblow (impactor) forged disc

The most common type of forging equipment is the hammer and anvil. Principles behind the hammer and anvil are still used today in drop-hammer equipment. The principle behind the machine is simple: raise the hammer and drop it or propel it into the workpiece, which rests on the anvil. The main variations between drop-hammers are in the way the hammer is powered; the most common being air and steam hammers. Drop-hammers usually operate in a vertical position. The main reason for this is excess energy (energy that is not used to deform the workpiece) that is not released as heat or sound needs to be transmitted to the foundation. Moreover, a large machine base is needed to absorb the impacts.[9]

To overcome some shortcomings of the drop-hammer, the counterblow machine or impactor is used. In a counterblow machine both the hammer and anvil move and the workpiece is held between them. Here excess energy becomes recoil. This allows the machine to work horizontally and have a smaller base. Other advantages include less noise, heat and vibration. It also produces a distinctly different flow pattern. Both of these machines can be used for open-die or closed-die forging.[36]

Forging presses

[edit]

A forging press, often just called a press, is used for press forging. There are two main types: mechanical and hydraulic presses. Mechanical presses function by using cams, cranks and/or toggles to produce a preset (a predetermined force at a certain location in the stroke) and reproducible stroke. Due to the nature of this type of system, different forces are available at different stroke positions. Mechanical presses are faster than their hydraulic counterparts (up to 50 strokes per minute). Their capacities range from 3 to 160 MN (300 to 18,000 short tons-force). Hydraulic presses, such as the four-die device, use fluid pressure and a piston to generate force. The advantages of a hydraulic press over a mechanical press are its flexibility and greater capacity. The disadvantages include a slower, larger, and costlier machine to operate.[15]

The roll forging, upsetting, and automatic hot forging processes all use specialized machinery.

List of large forging presses, by ingot size[2][37]
Force
(tonnes) 		Ingot size
(tonnes) 		Company Location
16,500 600 Shanghai Electric Group[38] Shanghai, China
16,000 600 China National Erzhong Group[38] Deyang, China
14,000 600 Japan Steel Works Japan
15,000 580 China First Heavy Industries Group[39] Heilongjiang, China
13,000 Doosan South Korea
List of large forging presses, by force
Force
(tonnes) 		Force
(tons) 		Ingot size
(tonnes) 		Company Location
100,000 (110,231) Giva Group[40] Rho, Lombardy, Italy
80,000 (88,200) >150 China Erzhong[38] Deyang, China
75,000 (82,690) VSMPO-AVISMA Russia
65,000 (71,660) Aubert & Duval[41][42] Issoire, France
53,500 (60,000) Weber Metals, Inc.[43] California, United States
(45,350) 50,000 20 Alcoa 50,000 ton forging press
Alcoa,[44][45] Wyman Gordon[46][47] 		US
40,000 (44,100) Aubert & Duval[41] Pamiers, France
30,000 (33,080) 8 Wyman Gordon[48] Livingston, Scotland
30,000 (33,070) Weber Metals, Inc.[49] California, United States
30,000 (33,070) Howmet Aerospace[50] Georgia, United States

See also

[edit]

References

[edit]
Revisions and contributorsEdit on WikipediaRead on Wikipedia

Forging

View on Grokipedia
from Grokipedia
Forging is a process in which metal is deformed and shaped by applying localized compressive forces, typically using hammers, presses, or dies, to produce high-strength components with refined structures. This ancient technique, rooted in blacksmithing traditions where heated metal is hammered on anvils, allows for the creation of complex three-dimensional solid shapes from ingots or billets. The process enhances the material's mechanical , such as strength and , through deformation that aligns the internal flow. Forging is broadly classified by into hot forging, performed above the metal's recrystallization to reduce and improve ; warm forging, at intermediate temperatures for better precision; and cold forging, at or near for enhanced and dimensional accuracy. It is further categorized by tooling into open-die forging, where the metal is shaped between flat or simple dies through successive compressions, suitable for large or custom parts like shafts and rollers; and closed-die (impression-die) forging, where the workpiece is confined within shaped dies to form precise geometries, often producing excess flash material that must be trimmed. The advantages of forging over alternative processes like or include superior structural integrity, reduced material waste, and the ability to produce parts with consistent directional strength, making it ideal for demanding applications in industries such as , automotive, and . Commonly forged metals include , aluminum, , and copper alloys, with hot forging being the most prevalent for its efficiency in handling tough materials. Modern forging employs advanced equipment like hydraulic presses and to optimize deformation and minimize defects, ensuring high-volume production of reliable components.

History

Ancient origins

The earliest evidence of forging dates back to around 4000 BCE in and , where artisans employed basic techniques involving simple stone or metal hammers struck against rudimentary anvils to shape into tools and weapons. These early methods relied on cold-working or annealing heated metal over open fires, marking the transition from the to the Copper Age and enabling the production of functional implements like axes and adzes. By the , around 2000 BCE, the invention and adoption of revolutionized forging by allowing for sustained higher temperatures in furnaces, which facilitated the and working of and its alloy . In , hieroglyphic depictions from this period illustrate foot-operated directing air into forges, enhancing the efficiency of metal heating and deformation processes essential for crafting more durable items. This technological advancement spread across the , supporting larger-scale production of alloys that combined with tin for superior strength. Prominent artifacts exemplify these early forging achievements, such as Egyptian copper chisels from (circa 2686–2181 BCE), which were hammered from cast ingots to form sharp edges for stoneworking and . Similarly, Hittite iron swords and daggers from the late (circa 1400 BCE), forged from smelted or , demonstrate advanced and hammering techniques that produced harder edges than contemporary weapons. Forging held profound cultural significance in ancient societies, symbolizing craftsmanship and divine inspiration; in , blacksmiths associated with the god enjoyed elevated status for producing arms and armor vital to warfare and heroism. In , blacksmiths operated within collegia—formal craft associations that provided mutual support, regulated practices, and fostered ties among metalworkers essential to imperial and needs. These guilds underscored forging's role in sustaining economic and social structures, evolving later into more mechanized industrial processes.

Industrial developments

The introduction of steam-powered hammers marked a pivotal shift in forging during the early , transitioning the craft from labor-intensive manual methods to mechanized production capable of handling large-scale operations. In 1842, Scottish engineer patented the , a device that harnessed steam pressure to deliver precise and powerful blows, enabling the forging of massive components such as shafts and parts that were previously unfeasible with traditional trip hammers. This innovation addressed the growing demands of Britain's expanding industrial base, where the need for robust metalwork outpaced human strength, and it laid the groundwork for standardized forging processes that improved and output. The Industrial Revolution further propelled forging into the heart of mechanized manufacturing, particularly for infrastructure and transportation sectors like railroads and heavy machinery. By the mid-19th century, steam hammers and related equipment standardized the production of rails, axles, and engine components, facilitating the rapid expansion of rail networks across and that connected factories to markets and spurred . A landmark demonstration occurred at the 1851 in London's , where Nasmyth's showcased its precision in forging intricate metal pieces, highlighting Britain's industrial prowess and influencing global adoption of such technologies for machinery production. This event underscored forging's role in the era's technological optimism, as exhibited components exemplified how forged enhanced the durability and scale of steam engines and rail systems essential to industrial progress. In the late , the development of drop forging using hammers advanced precision manufacturing, allowing for the repeatable shaping of complex parts under controlled impacts from raised dies. These drop hammers, powered initially by steam and later by mechanical linkages, emerged as a refinement of earlier drop hammers, enabling the of uniform components with minimal waste and high strength. This technique proved instrumental in emerging industries, such as the bicycle boom of the 1890s, where drop-forged cranks, frames, and pedals provided the lightweight yet resilient structures needed for safer, faster designs, and in early automobiles, where it produced critical elements like gears and suspension parts that withstood vibrational stresses. The economic ramifications of these advancements were profound, fostering the proliferation of specialized forging shops that capitalized on the demand for industrialized goods. By 1900, the number of such facilities had surged in —particularly in Britain and —and the , where forging output supported the steel-intensive growth of railroads and urban machinery, contributing to the dramatic growth of U.S. manufacturing capacity, which increased over fivefold from 1870 to 1900. This expansion not only created thousands of jobs in but also integrated forging into supply chains, driving down costs for end-users in transportation and while establishing regional hubs like and as global centers for forged products.

Modern advancements

Following , the initiated the in 1950 to develop massive hydraulic forging presses for producing large, high-strength components essential for applications. This effort culminated in the construction of several 50,000-ton capacity presses between 1952 and 1957, including the press, which enabled the forging of complex aluminum and titanium structures for and commercial aircraft, significantly advancing capabilities. In the 1980s, the introduction of finite element analysis (FEA) revolutionized forging design by allowing computational simulation of material distribution, and defect formation during the process, thereby minimizing physical trial-and-error iterations and optimizing die designs. Early FEA applications in forging, building on foundational work from the , gained widespread industrial adoption through improved computing power, enabling more accurate predictions of deformation in bulk forming operations like and upsetting. This shift reduced development costs and time, with industry reports noting a surge in computer-aided forging simulations by the late 1980s. Post-2000 advancements have integrated hybrid processes combining forging with additive manufacturing (AM) to produce high-performance components, such as near-net-shape parts, by using AM to create preforms that are then forged for enhanced density and mechanical properties. These hybrid routes reduce material waste and machining needs while improving efficiency for and automotive applications. Concurrently, the adoption of eco-friendly, water-dilutable lubricants, such as synthetic graphite-free formulations, has minimized environmental impact by lowering emissions and enabling easier disposal, with industry formulations offering high biodegradability without compromising lubrication efficacy. A notable milestone in the was the application of isothermal forging for turbine blades, which maintains uniform temperatures to produce lightweight, heat-resistant components for advanced jet engines, enhancing in . This technique supports the production of blades with refined microstructures capable of withstanding extreme operational stresses. In the 2020s, advancements include the integration of for real-time process monitoring and , alongside further emphasis on sustainable practices to achieve net-zero emissions in forging operations.

Basic Principles

Definition and deformation processes

Forging is a process that shapes metal workpieces through the application of compressive forces, typically using hammers, presses, or dies, without the material. This plastic deformation refines the internal structure, aligning grains along the principal stress directions to enhance mechanical properties such as strength and . Unlike other methods, forging produces parts with directional grain flow that follows the contour of the final shape, resulting in superior fatigue resistance and reliability compared to cast components, which exhibit more isotropic microstructures prone to defects like . The primary deformation mechanism in forging is plastic deformation, which occurs when stresses exceed the material's yield strength, enabling permanent shape change through the movement of s within the crystal lattice. As deformation proceeds, dislocations multiply and interact, leading to that increases the material's resistance to further deformation by impeding subsequent dislocation motion. In processes involving elevated temperatures, such as hot forging, dynamic recovery and recrystallization can occur, where new strain-free grains nucleate and grow, counteracting to maintain and allow continued deformation without fracture. These mechanisms collectively refine the microstructure, breaking down coarse cast structures into finer, more uniform grains. The force required for forging derives from the fundamental relationship between applied stress and material response during flow. To initiate and sustain deformation, the applied σ\sigma must equal or exceed the material's , defined as the stress needed to maintain constant under given conditions of , , and . For a frictionless, homogeneous deformation in a simple compression test approximating ideal open-die forging, the forging force FF is given by F=σAF = \sigma \cdot A where AA is the instantaneous cross-sectional area of the workpiece perpendicular to the force direction. This equation arises from force equilibrium: the total force balances the integral of stress over the deforming area, assuming uniform stress distribution. In practice, σ\sigma (the flow stress) is not constant but depends on the material's constitutive behavior, often modeled empirically as σ=f(ϵ,ϵ˙,T)\sigma = f(\epsilon, \dot{\epsilon}, T), where ϵ\epsilon is strain, ϵ˙\dot{\epsilon} is strain rate, and TT is temperature; however, for basic estimation, an average flow stress value is used. This relation highlights why larger cross-sections or higher-strength materials demand greater press capacities, establishing the scale of equipment needed. In contrast to , which solidifies metal into an isotropic structure with potential inclusions and weak interdendritic regions, forging's directional deformation aligns grain flow to resist applied loads more effectively, yielding parts with up to 20-30% higher tensile strength in critical directions. , being a subtractive process, removes material but does not inherently strengthen the workpiece or align grains, often requiring additional heat treatments to achieve comparable properties. Thus, forging provides a net-shape or near-net-shape forming advantage, minimizing waste while optimizing structural integrity.

Temperature classifications

Forging processes are classified based on the relative to the material's (T_m, in Kelvin), which significantly influences the material's , required forming forces, and final properties. These classifications—hot, warm, and cold forging—determine the deformation behavior, with higher temperatures generally promoting easier flow but potentially introducing issues like oxidation, while lower temperatures enhance precision and strength at the cost of higher energy input. Hot forging occurs above the recrystallization , typically in the range of 0.5 to 0.8 T_m (or about 70-80% of the absolute ), such as 900-1200°C for steels, where dynamic recovery and recrystallization enable extensive ductile flow with minimal residual stresses and . This regime allows for large deformations in a single operation, reducing the need for multiple passes and improving grain refinement, though it requires careful control to avoid defects like hot shortness near the (limited to ~40°C below T_m). Warm forging takes place at intermediate temperatures, roughly 0.3 to 0.6 T_m (e.g., 500-900°C for steels), bridging the benefits of hot and cold processes by offering improved over cold forging while maintaining better dimensional precision and than hot forging, with lower energy consumption due to reduced compared to cold conditions. This range minimizes scaling and oxidation issues associated with higher temperatures, making it suitable for precision components, though it still demands higher forces than hot forging. Cold forging is conducted below 0.3 T_m, typically at or near (up to ~0.25 T_m, or around 200-300°C for steels including deformation-induced heating), emphasizing high-strength outcomes through significant but requiring substantially greater forming forces due to limited and no recrystallization. It excels in producing parts with excellent surface quality and tight tolerances, such as fasteners, but is limited to ductile materials and simpler shapes to avoid cracking. The (σ) in forging exhibits strong dependence, often modeled by an Arrhenius-type relation: σ=σ0exp(QRT)\sigma = \sigma_0 \exp\left(\frac{Q}{RT}\right) where σ_0 is a reference stress, Q is the for deformation, R is the , and T is the absolute ; this exponential form captures how decreases sharply with rising , facilitating lower force requirements in hot regimes. Higher temperatures reduce σ by promoting thermally activated motion, while effects can modify this through additional terms, underscoring the need for in .

Mechanical properties achieved

Forging enhances the tensile strength and fatigue resistance of metals primarily through refinement of the grain structure and its directional alignment along the lines of principal stress, which optimizes load distribution and minimizes crack initiation sites. This refined microstructure results in materials that can endure higher stresses without deformation or failure, making forged components preferable for applications requiring durability under repeated loading. Unlike , forging eliminates and inclusions by subjecting the material to compressive forces that close internal voids and redistribute defects, thereby achieving higher impact and greater resistance to brittle . This densification process ensures a more homogeneous structure, enhancing the material's ability to absorb energy during sudden impacts without . Forged can exhibit higher yield strength compared to rolled equivalents, depending on the and forging parameters, underscoring the process's role in elevating load-bearing capabilities. Microstructurally, hot forging promotes dynamic recrystallization, which breaks down coarse grains into finer ones for balanced strength and , whereas cold forging relies on strain hardening to increase density and boost . The temperature classifications influence these grain evolutions, with elevated temperatures facilitating recrystallization for optimal property refinement.

Processes

Open-die forging

Open-die forging involves the plastic deformation of a workpiece between two flat or simply contoured dies that do not fully enclose the material, permitting unrestricted lateral flow of the metal during compression. The process typically employs repeated blows from a or continuous pressing action from a hydraulic or mechanical press, gradually reducing the cross-section of the starting while elongating it in the direction perpendicular to the applied force. This free-form deformation contrasts with more constrained methods, as the dies provide only vertical support, allowing the metal to expand sideways and achieve uniform refinement of the internal structure. The technique is widely applied to produce large structural components such as billets, shafts, disks, and rings, often serving as the initial shaping stage for subsequent processing. It is particularly suited for hot forging operations, where elevated temperatures facilitate deformation of high-strength alloys like and , enabling the creation of custom or low-volume parts up to several hundred tons in weight. Common end-use sectors include , , and heavy machinery, where the improved grain flow and directional imparted by open-die forging enhance component . A primary advantage of open-die forging lies in its low tooling costs, as simple flat dies require minimal design and fabrication compared to shaped alternatives, making it economical for small-batch or production. Additionally, the process offers flexibility for handling oversized ingots and achieving significant microstructural improvements without the need for complex setups. However, it suffers from reduced dimensional accuracy, as the free metal flow can lead to inconsistencies in shape and , often necessitating extensive post-forging . This lack of precision limits its use for high-tolerance parts, where tighter control over deformation is required. Force requirements for open-die forging vary with workpiece size and material, but presses typically range from 1000 to 5000 tons for large components, with hammers providing impulsive forces up to several thousand tons per blow. The operation often involves multiple passes, each achieving 20-30% reduction in height to cumulatively reach 50-80% overall deformation, ensuring progressive working of the material without cracking. Hydraulic presses are preferred for their controlled application of force, allowing precise adjustment to accommodate varying dimensions.

Impression-die forging

Impression-die forging, also known as closed-die forging, utilizes precisely machined dies containing impressions of the desired part shape to deform a heated metal under compressive forces, enabling the production of complex geometries with high dimensional accuracy and repeatability. This method confines the metal flow within the die cavities, distinguishing it from open-die processes by providing guided deformation for intricate features such as , bosses, and undercuts. The resulting parts exhibit improved strength and resistance due to refined grain structure aligned with the component's contours. The process commences with heating a to a that renders the sufficiently ductile, often 900–1200°C for steels, followed by placement into the lower die's impression. The upper die then descends, applying that causes the billet to expand and fill the cavity details, with surplus metal extruding into a peripheral flash land—a shallow groove between the dies—where it thins to generate for complete filling. Upon completion, the dies separate, the part is ejected, and the flash is removed via trimming in a dedicated press to produce the final shape. This sequence ensures consistent part formation across high-volume production. Flashless impression-die forging represents an advanced variant that achieves near-net shapes by matching the billet volume precisely to the die cavity, preventing excess material extrusion and eliminating flash formation. This technique enhances material efficiency, reducing waste from 10–20% in traditional flash-based processes to virtually none, thereby minimizing machining requirements and material costs. It demands tight control over billet dimensions and die alignment to avoid incomplete filling or defects. Tooling design emphasizes multi-stage dies to distribute deformation progressively, typically including preform or blocking impressions for initial rough shaping and finishing impressions for detailed refinement, which helps control metal flow and reduce forging loads. Vertical surfaces in the impressions incorporate draft angles of 3–7° to facilitate smooth ejection, compensating for material contraction and preventing die damage from sticking. These angles are steeper on internal features to account for higher . Each impression stage typically involves 30–60% area reduction, allowing substantial deformation while maintaining metallurgical integrity and enabling the creation of parts with tight tolerances.

Drop forging

Drop forging is a gravity-assisted metal forming process that relies on the impact of a falling to deform heated workpieces, offering a balance of precision and for medium-volume production runs of components such as automotive parts, tools, and hardware. Historically, it emerged as a pivotal 19th-century , enabling the of uniform, high-strength parts by replacing labor-intensive manual hammering with mechanized drops, which revolutionized industries like toolmaking and machinery. This method is well-suited for batches ranging from hundreds to thousands of units, where setup costs for dies are justified but high-speed continuous processes are unnecessary. The core mechanism involves raising a heavy ram or tup—typically weighing 500 to 5000 kg—and releasing it to fall under onto the workpiece positioned between dies, delivering impulsive forces that plastically deform the metal. Board drop hammers employ friction-driven wooden boards or belts to elevate the ram, which is then disengaged to free-fall, while steam hammers use steam in a to lift and accelerate the ram for greater control and height. Open-die variants of drop forging are used for initial rough shaping of larger billets, allowing material to flow freely beyond the die boundaries, whereas impression-die setups confine the metal to form intricate features in parts like wrenches and levers. Each forging cycle typically requires 4 to 8 blows to achieve the desired , with drop times varying by hammer type: traditional board hammers operate at 5 to 20 seconds per drop due to manual board handling, while powered variants enable faster rates of 80 to 120 strokes per minute for smaller components. The energy imparted per blow is calculated as the gravitational potential energy of the falling mass, E=mghE = m g h where mm is the hammer mass, gg is the acceleration due to gravity (approximately 9.81 m/s²), and hh is the drop height, often ranging from 1 to 2 meters. Upon impact, this converts to kinetic form, achieving velocities of 12 to 16 ft/s (3.7 to 4.9 m/s) and contact durations of about 200 ms, resulting in high strain rates (up to 10³ s⁻¹) that promote refined structure but necessitate robust dies to withstand the dynamic stresses and vibrations. This impulsive loading distinguishes drop forging by enabling deep penetration and uniform deformation in a single station, though it demands precise timing to maintain workpiece temperature.

Press forging

Press forging is a manufacturing process that employs sustained mechanical or hydraulic force to deform metal workpieces uniformly between dies, enabling the production of precise components in high-volume applications. Unlike impact-based methods, it relies on slow, controlled ram movement to apply steady , ensuring consistent filling of die cavities without introducing shock loads that could cause defects. This approach is particularly effective for creating complex shapes with minimal flash, making it ideal for industries requiring reliability and repeatability. Presses used in this process fall into two primary types: mechanical and hydraulic. Mechanical presses, typically crank-driven, prioritize speed and are suited for operations requiring up to 50 strokes per minute, with force capacities ranging from 3 to 160 MN (approximately 300 to 18,000 tons). In contrast, hydraulic presses deliver exceptionally high forces, up to tons in the largest installations, allowing them to handle massive workpieces that demand greater deformation energy. The choice between these types depends on production needs, with mechanical presses favored for faster cycles and hydraulic ones for superior load control in heavy-duty forging. The forging stroke in press operations is characterized by slow, deep penetration at speeds of 0.5 to 1 m/s, which facilitates thorough metal flow into intricate die features while avoiding the vibrations associated with faster impacts. This controlled deformation supports the production of large structural components, such as those used in fuselages and mounts, where uniformity and strength are critical. Precision is a key advantage, with dimensional tolerances often achievable within 0.5 mm, enabling near-net-shape parts that reduce subsequent . Strain rates in press forging are notably lower, typically ranging from 0.1 to 1 s⁻¹, compared to the high rates (often exceeding 1000 s⁻¹) in impact forging methods. These reduced rates promote more uniform microstructure development, enhancing and resistance in the final product, though they may require longer cycle times. Press forging is commonly performed in hot or warm regimes to optimize material flow, aligning with broader classifications of thermal processing in forging.

Upset forging

Upset forging is a specialized metal forming that elongates and thickens the end of cylindrical through axial compression, primarily to create enlarged heads or sections for components like bolts, screws, and fasteners. The workpiece, typically a heated or unheated metal bar, is gripped securely and subjected to localized that causes to flow and increase in diameter while reducing at the upset end. This method is distinct from other forging techniques, such as roll forging, which involves rotational reduction along the rather than axial compression for local thickening. The process employs horizontal upsetting machines, known as or headers, where the bar is held between grooved gripper dies to prevent slippage during deformation. A ram or punch then applies force to the free end, pushing material into a die cavity to form the desired shape. Gripper dies, often split and mechanically actuated, clamp the bar with sufficient —typically matching or exceeding the upsetting force—to maintain control and avoid . Forces per upset generally range from 100 to 200 tons in standard machines, though larger setups can exceed 500 tons depending on material and size. Multiple progressive upsets are conducted in stages using a series of dies to achieve incremental increases, allowing for complex geometries on long parts without excessive strain in a single blow. Each stage gathers and displaces material from the bar's length to build up the end section, with the total deformation limited by factors like the unsupported length-to- ratio to prevent defects. This stepwise approach enables expansions that can approach four times the original in optimized multi-stage operations. The process is commonly applied to rods with of 6 to 50 mm, though capabilities extend to 100 mm for longer bars up to 6-10 meters. Both hot and variants exist, with hot upsetting preferred for larger to enhance , while forging suits smaller, precision parts for improved .

Roll forging

Roll forging is a hot forging process that shapes metal by passing a heated between two opposing cylindrical rolls equipped with circumferential grooves, which rotate in opposite directions to apply compressive forces and elongate the material. The heated bar, typically at forging temperatures, is incrementally fed into the grooved sections of the rolls, where it undergoes gradual deformation to form tapered or stepped profiles, such as those required for shafts or axles. This mechanism relies on the shearing action of the rotating grooves to reduce the bar's diameter while increasing its length in discrete passes. The rolls rotate at typical speeds of 10 to 50 (rpm), with the grooved portion spanning one-quarter to three-quarters of the roll to control the deformation zone and facilitate smooth feeding of the . There are two primary types: reduction roll forging, which uniformly thins the bar diameter for consistent cross-sections, and swaging roll forging, which imparts specific profiles like varying diameters for components such as automotive axles or tool blanks. Each pass achieves a cross-sectional area reduction of 20 to 40%, allowing for the production of elongated parts up to 10 meters in while preserving integrity and dimensional precision. Roll forging offers advantages including semi-continuous operation for high production throughput, minimal flash formation to optimize use, and enhanced mechanical properties from uniform deformation, making it particularly effective for precision long-form components in industries like automotive and .

Isothermal forging

Isothermal forging is a precision hot forging process in which the workpiece and dies are maintained at the same elevated temperature throughout deformation, typically within a controlled chamber to ensure uniform heating and minimize cooling effects. For , this temperature is often around 900–1050°C, with the environment utilizing or to prevent oxidation and of the material. The process involves slow deformation rates, allowing the material to flow evenly into complex die cavities without significant thermal gradients between the workpiece and tooling. A key benefit of isothermal forging is the exploitation of superplastic deformation, where materials like and nickel-based superalloys exhibit exceptional at low strain rates of $0.0010.1 , \mathrm{s}^{-1}$, enabling the production of parts with thin walls, intricate geometries, and near-net shapes that are challenging or impossible with conventional forging. This uniform temperature control reduces defects such as cracks or voids, improves grain flow, and enhances overall material properties like resistance. Additionally, the absence of gradients extends die life significantly—often by factors of 5–10 times compared to traditional hot forging—due to lower stresses on the tooling. In applications, isothermal forging is particularly valued in for high-performance components such as blades and compressor blades from , where precision and structural integrity are critical under extreme operating conditions. It is also used for disks in superalloys, supporting advanced designs that demand complex shapes and superior mechanical properties. While the setup costs for isothermal forging equipment and controlled environments are high, the process offers substantial material savings—up to 60% reduction in input weight for near-net-shape titanium components—compared to conventional methods, offsetting expenses through reduced and waste. For intricate parts, overall material cost reductions can reach 40–45%.

Materials

Steel forging

Steel forging is a critical process for shaping steel alloys, which are the most prevalent materials in forging due to their versatility, strength, and cost-effectiveness. Common grades include carbon steels such as AISI 1045, widely used for general-purpose applications like gears, shafts, and connecting rods owing to its balanced strength and machinability. For demanding high-strength requirements, alloy steels like AISI 4340 are preferred, offering exceptional toughness and fatigue resistance after heat treatment, making it suitable for aerospace and automotive components. These selections depend on the desired mechanical properties, with carbon steels providing moderate performance at lower cost and alloy steels enabling superior load-bearing capabilities. The forging temperature window for typically ranges from 850°C to 1250°C, allowing sufficient for deformation while minimizing risks such as cracking from excessive or grain coarsening. Initial heating often occurs around 1100-1250°C to ensure uniform austenitization, but finishing temperatures should not drop below 850-900°C to prevent brittle during the final stages. Following forging, normalization is a standard , involving reheating to approximately 870-920°C and to refine grain structure, relieve internal stresses, and promote uniform microstructure for enhanced and . The resulting microstructure in forged varies by carbon content and subsequent treatments. In low-carbon steels (less than 0.3% carbon), slow cooling yields a ferrite- structure, where soft ferrite matrices interspersed with lamellar provide good toughness and formability suitable for structural parts. High-carbon steels (over 0.6% carbon), when quenched after forging, form —a hard, needle-like phase that imparts high resistance but requires tempering to mitigate . A key challenge in forging is , where surface carbon loss during high-temperature heating reduces and life. This is prevented through controlled atmospheres in furnaces, maintaining a neutral or slightly environment (e.g., with endothermic gas compositions) to inhibit oxygen reaction with carbon at the surface. Proper atmosphere control ensures the forged component retains its specified carbon profile, preserving mechanical integrity.

Aluminum forging

Aluminum forging leverages the metal's inherent low and resistance to produce lightweight structural components, particularly in and automotive sectors where weight reduction enhances performance. The primary alloys employed are from the 2000-series, which are strengthened by additions to achieve high tensile strengths suitable for applications, such as alloy used in fuselage skins and wing structures due to its resistance and yield strength exceeding 300 MPa in tempered conditions. In contrast, the 6000-series alloys, alloyed primarily with magnesium and , offer excellent compatibility alongside forgeability, making them ideal for complex shapes in transportation components like parts, with 6061 being a representative example valued for its balanced strength and . These alloys' of approximately 2.7 g/cm³ results in forged parts that are roughly one-third the weight of comparable equivalents, enabling approximately 50% savings in designs requiring equivalent . Forging temperatures for aluminum alloys are maintained between 350°C and 500°C to optimize and avoid hot-shortness or cracking in age-hardenable variants, as higher temperatures can lead to over-aging and reduced potential. This range facilitates hot deformation that aligns grain flow for improved mechanical integrity without excessive oxidation. For instance, 2000-series alloys are typically forged near the upper end to counteract their lower formability compared to 6000-series, which perform well across the due to their finer microstructure response. Precise is critical, often using to minimize thermal gradients. To preserve and achieve near-net shapes, aluminum forging frequently incorporates warm forging at intermediate temperatures (around 200–350°C) or isothermal forging, where the billet and dies are equilibrated to minimize and barreling. These adaptations are especially beneficial for thin-walled or intricate geometries in high-strength alloys, reducing defects like laps or folds. Post-forging, solution —typically at 480–540°C followed by rapid —is essential for age-hardenable alloys to solubilize alloying elements, enabling subsequent artificial aging for peak strength levels, such as T6 temper in 6061 achieving ultimate tensile strengths over 300 MPa. This sequence ensures the final parts exhibit superior fatigue life and for demanding applications.

Copper forging

Copper alloys are valued in forging for their excellent electrical and thermal conductivity, corrosion resistance, and , making them suitable for applications in electrical components, valves, fittings, and marine hardware. Common alloys include forging (UNS C37700, copper-zinc), which offers high strength and , and naval (UNS C63000, copper-aluminum-nickel), noted for its toughness and wear resistance in shafts and rods. Forging temperatures for copper alloys typically range from 600°C to 900°C, depending on the alloy composition, to ensure adequate formability while preventing cracking or excessive oxidation. For example, brasses are often forged at 650–750°C to balance and strength retention. Post-forging heat treatments, such as stress relieving at 250–400°C, are common to restore conductivity and remove residual stresses without softening the material excessively. A challenge in copper forging is its tendency toward , which is managed through intermediate annealing during multi-step processes.

Magnesium and titanium forging

Magnesium alloys, such as AZ31, exhibit limited at ambient temperatures, necessitating forging processes conducted within a range of 300 to 450°C to achieve sufficient formability and microstructural refinement. This temperature window allows for effective deformation while minimizing defects like cracking, as demonstrated in multi-directional forging studies on AZ31 that enhance its mechanical properties for structural use. In automotive applications, these forged components leverage magnesium's low density—approximately one-quarter that of —to reduce and improve fuel efficiency, with examples including transmission cases and structural brackets. A primary challenge in magnesium forging is its inherent flammability, which poses significant safety risks during high-temperature processing and requires specialized ventilation, shielding, and to mitigate ignition from sparks or molten metal. Despite these hurdles, advancements in design have improved ignition resistance, enabling broader adoption in components without compromising performance. Titanium alpha-beta alloys, exemplified by , are forged at elevated temperatures of 900 to 1000°C to facilitate plastic deformation and control phase transformations for optimal strength and . This alloy's forging demands inert atmospheres, such as or environments, to prevent surface oxidation and the formation of brittle alpha case, which could impair fatigue resistance in critical applications. Forging requires deformation forces 1.5 to 2 times greater than those for comparable alloys, attributable to its high and sensitivity to , often necessitating robust hydraulic presses and precise temperature control to avoid inhomogeneities. Since the , hybrid approaches integrating with forging have emerged, using blended elemental powders to produce near-net-shape preforms that undergo secondary forging, resulting in refined microstructures and cost reductions for components. These methods, including powder-bed fusion followed by hot forging, address traditional limitations in consolidation while enhancing mechanical isotropy.

Equipment

Hammers and drop hammers

Hammers and drop hammers represent foundational equipment in impact forging, delivering high-energy blows to deform heated metal workpieces through repeated strikes. These machines are particularly suited for open-die forging processes, where the workpiece is shaped progressively without fully enclosing it in dies, ranging from traditional blacksmithing applications to large-scale industrial production. , driven by external energy sources such as or , accelerate the striking mass to achieve consistent impact forces, while drop hammers rely primarily on energy converted during . Power hammers are categorized into types such as pneumatic (air-driven) and steam-driven variants, with ram weights typically ranging from 500 to 3000 kg to suit various workpiece sizes. In pneumatic models, powers a to lift and propel the ram downward, enabling rapid cycling for efficient forging of billets up to 320 mm in . Steam-driven hammers, historically significant, use for similar , though modern installations favor pneumatic systems for reliability and lower operational costs. These hammers are self-contained units, often rated by falling weight and striking , such as up to 27 kJ in mid-sized models. Drop hammers operate on gravity-assisted principles, where the ram is raised to a height and released to fall freely, generating impact energies from falls of 1000 to 10,000 kg equivalents. Board hammers, a subtype, use rolls to lift wooden boards attached to the ram before release, providing controlled drops for precision shaping. These are commonly employed in drop forging operations, where multiple gravity-driven blows progressively form the metal against lower dies. Ram weights in drop hammers span 180 to 4500 kg, with capacities up to 10 tons in industrial setups for handling large forgings. Key components of both power and drop hammers include the ram, which houses the moving ; the anvil block, a massive stationary base weighing 50 to 200 tons to absorb and distribute impact forces—often 20 times the tup weight for stability; and the tup, the attachable striking tool that holds the upper die or flat face for direct contact with the workpiece. The frame provides , guiding the ram's vertical motion to ensure precise alignment during operation. These elements are typically constructed from high-strength cast to withstand repeated high-impact loads. In operation, hammers and drop hammers feature stroke lengths of 0.5 to 2 meters, allowing the ram to achieve impact velocities sufficient for deforming and other metals in open-die setups from artisanal scales to heavy industrial forging. The process begins with heating the , placing it on the , and delivering controlled blows via foot pedals or automated controls, with frequencies up to 60 strikes per minute in smaller units. This method excels in producing elongated shapes like shafts or billets, though it requires operator skill to manage flash and ensure uniform deformation. Maintenance of hammers and drop hammers emphasizes precise alignment of the ram and s to prevent lateral forces that could damage the tup or , ensuring longevity and operational safety. Regular inspections include checking for wear on guide columns, lubricating , and verifying the anvil block's foundation integrity against vibration-induced settling. Misalignment can lead to uneven strikes and accelerated component , necessitating periodic recalibration using laser alignment tools in modern facilities.

Hydraulic and mechanical presses

Hydraulic presses in forging utilize fluid pressure to generate ram force, transmitting pressure evenly through an incompressible to the ram, which applies controlled deformation to the workpiece. This mechanism, based on Pascal's principle, allows for consistent force application across the stroke, making them suitable for precision operations like and isothermal forging where uniform pressure is essential. Capacities range from 1,000 to over 50,000 tons, with examples including the 60,000-ton pull-down die press used for large components. Modern hydraulic presses incorporate programmable logic controllers (PLC) for precise ram speed management, typically 0.1 to 1 m/s during pressing, enabling adjustable approach and dwell times for optimal material flow. Energy efficiency is enhanced by hydraulic accumulators, which store and recover energy during cycles, achieving up to 39% improvement in overall system efficiency through pressure pulse absorption and reuse. These features support high-volume production of complex shapes in materials requiring extended contact times, such as . Mechanical presses, in contrast, employ crank or eccentric drive mechanisms to convert rotary motor motion into linear ram movement, providing rapid cycles suited for high-throughput warm and hot forging. The eccentric ensures a fixed length with peak near the bottom dead center, ideal for moderate-ductility metals in applications like automotive parts. Stroke rates vary from 18 to 50 per minute, depending on model and load, allowing for efficient production of low-profile forgings. Capacities for mechanical presses typically span 1,000 to 20,000 tons, with servo-assisted variants offering programmable motion for optimization and reduced . PLC integration enables fine-tuned speed control within 0.1 to 1 m/s, balancing cycle time and precision for geometries forged at 550–1,200°C. While less versatile for deep deformations than , their high output and minimal contact times extend die life, supporting applications in .

Supporting tooling and dies

Supporting tooling and dies in forging operations encompass the specialized components that shape the workpiece, including dies, lubricants, and ancillary safety elements. These tools are critical for ensuring precise forming, minimizing defects, and maintaining operational efficiency across various forging processes. Die materials are selected for their ability to withstand high temperatures, pressures, and repeated impacts. A common choice is H13 , a chromium-molybdenum known for its hot-work properties, which is typically hardened to 50-55 HRC to balance hardness and toughness. To enhance wear resistance, dies are often coated with (TiN), a layer that reduces and abrasion while improving thermal stability during high-temperature forging. Die design incorporates key features to facilitate material flow and prevent defects. The parting line, which separates the upper and lower die halves, is positioned at the part's maximum cross-section to optimize grain flow and structural integrity. Vents, often integrated as flash gutters along the parting line, allow excess material and any trapped gases from the or lubricants to escape, reducing internal pressures and voids in the forged part. Graphite-based lubricants are applied to die surfaces to minimize ; these water-dilutable emulsions or dry films can reduce the coefficient of by up to 50% in forging applications, aiding uniform deformation and extending tool life. The lifespan of forging dies varies by , , and operating conditions, typically ranging from 1,000 to 10,000 cycles before significant occurs. Hot forging dies may endure 5,000-7,000 cycles in standard carbon steels, while more demanding applications shorten this to around 1,000 cycles for complex shapes. When damage such as cracks or appears, dies can be repaired using (EDM), a non-contact that removes precisely to restore contours without inducing . Safety features integrated into supporting tooling protect operators and equipment from hazards like overloads. Interlocks, often in the form of limit switches on die alignment, prevent operation if components are misaligned or guards are open. Sensors for overload protection monitor force levels, automatically halting the process if pressures exceed safe thresholds to avoid die breakage or press damage.

Applications

Automotive and transportation

Forging is integral to the automotive and transportation industries, where it produces components that must withstand extreme mechanical stresses, , and cyclic loading under high-speed and heavy-duty conditions. In vehicles, forged parts enhance , performance, and efficiency by offering superior strength-to-weight ratios compared to or machined alternatives. This section focuses on key applications in road and , highlighting how forging supports and innovation in (EV) design. In automotive engines, crankshafts and connecting rods are predominantly manufactured using forged steel to achieve the necessary for high- operations. These components are designed to endure torque loads ranging from 500 to 1000 Nm, enabling reliable performance in both and diesel powertrains while resisting failure over millions of cycles. The forging process aligns the steel's grain structure, providing enhanced tensile strength and impact resistance essential for connecting rods that connect pistons to the under explosive forces. Globally, the production of such forged engine components exceeds tens of millions of units annually, driven by automobile output surpassing 85 million vehicles per year, with nearly all internal combustion engines incorporating forged crankshafts and rods. Rail transportation relies on forging for axles and wheels, which are critical for supporting massive loads and ensuring safe, high-mileage operation. Upset forging, a compressive process that enlarges the diameter of heated steel billets, is commonly used to form rail axles with uniform microstructure and high fatigue resistance, capable of handling axle loads up to 40 tonnes in heavy-haul applications equivalent to 100-ton freight cars. Similarly, forged wheels undergo multi-stage forming to achieve precise profiles that minimize wear and vibration on tracks, supporting loads in excess of 100 tons per car while maintaining structural integrity over extended service life. These forged elements contribute to the reliability of global rail networks, where annual production volumes align with the transportation sector's demand for durable, load-bearing parts. The transition to electric vehicles post-2020 has accelerated the adoption of aluminum forging for weight reduction, particularly in , suspension, and battery enclosure components. Aluminum-forged parts offer up to 40% weight savings over equivalents, improving EV range and efficiency by reducing overall vehicle mass by 100-200 kg per model. This shift has increased average aluminum content in light vehicles from 466 pounds in 2020 to projected higher levels by 2026, supporting regulatory pushes for lower emissions. A notable involves the use of forged gears in automotive transmissions, where the process yields components with refined grain flow that reduces meshing . In one optimization effort, incorporating forged gears alongside other refinements achieved a 4.9 dBA decrease in overall , improving cabin comfort by mitigating gear whine across frequency ranges. Such advancements demonstrate forging's role in enhancing (noise, vibration, and harshness) performance without compromising load capacity.

Aerospace and defense

Forging plays a critical role in the and defense sectors, where components must withstand extreme temperatures, pressures, and cyclic loads while meeting stringent safety and reliability requirements. High-strength materials like and alloys are commonly forged into precision parts to ensure structural integrity in engines, airframes, and hardware. Turbine disks, essential for jet engines, are often produced from such as using isothermal forging processes that maintain uniform temperatures around 900–980 °C, enabling complex geometries with minimal defects and enhanced high-temperature performance. This method, which involves deforming the material at a constant temperature to avoid thermal gradients, supports operation in environments exceeding 1000°C while preserving microstructural uniformity. Landing gear components, forged from high-strength alloys like 4340 or Custom 465, are designed to endure repeated impacts and achieve lives typically exceeding 50,000 cycles under operational loads, contributing to during . Aerospace forging operations adhere to AS9100 certification, an international standard that supplements ISO 9001 with additional requirements for design, production, and risk management specific to , ensuring traceability and compliance for critical parts. Non-destructive testing (NDT) methods, such as ultrasonic and inspections, are mandatory for forged components to detect subsurface flaws without compromising integrity, as required by standards for airframes, engines, and . In defense applications, forging produces casings from high-strength alloys including and steels, providing the necessary toughness and pressure resistance for motor housings up to 26 inches in . barrels are forged from specialized high-strength alloys like 4140 chrome-molybdenum or advanced variants such as 32CrMoV12-10 (ARMAD), offering superior wear resistance, hardness, and ballistic performance in firearms. Advancements in near-net shape forging have optimized production for programs like the F-35, where components such as bulkheads and are formed closer to final dimensions, reducing requirements by approximately 40% to 50% and lowering overall costs through minimized material waste and labor.

Industrial and consumer goods

In industrial applications, forging is extensively used for components requiring high strength and resistance to extreme pressures, such as valves and housings. Forged valves are preferred in high-pressure systems due to their superior mechanical properties and lack of , ensuring reliability in demanding environments. Similarly, forged housings for , particularly in mud pumping systems, are designed to withstand pressures up to 5000 psi, with each forging machined and heat-treated for optimal performance. For consumer goods, forging produces durable everyday items like hand tools and components. Hammers, such as those from Estwing, feature one-piece forged construction for enhanced strength and reduced vibration during use. cranks are often cold-forged from aluminum alloys, like 6061-T6, to achieve lightweight yet robust structures suitable for high-performance cycling. The industrial and consumer goods sector constitutes a significant portion of global forging output, with applications in machinery and tools driving steady demand. This segment experiences notable growth in components, such as wind turbine hubs, where the market is projected to expand at a 7.3% CAGR from 2025 to 2034 due to increasing adoption of sustainable technologies. For customization in , open-die forging is employed to produce prototypes and low-volume custom parts, offering flexibility for unique designs before transitioning to higher-volume closed-die processes.

Advantages and Limitations

Benefits over other manufacturing methods

Forging offers superior mechanical properties compared to , primarily due to the directional alignment of metal grains achieved during the deformation , which results in enhanced strength and durability. In particular, forged components exhibit 15-30% better life than cast equivalents, as the continuous grain flow minimizes internal defects like and inclusions that are common in castings. This advantage is evident in applications requiring high reliability, such as crankshafts, where forged demonstrates approximately 37% higher strength than ductile under similar loading conditions. In terms of cost efficiency, forging significantly reduces material waste compared to from , achieving 20-50% less scrap through near-net-shape forming that closely matches the final part geometry. from often results in up to 50% material loss for complex shapes, whereas closed-die forging attains material utilization rates exceeding 80-90%, minimizing excess removal and associated expenses. This efficiency translates to overall cost savings, especially in medium- to high-volume production, where the initial tooling investment is amortized over many parts. Forging also excels in production speed for high-volume runs, with hot forging cycles typically under 1 minute per part, enabling rapid throughput in automated lines. For instance, high-speed hot forming processes can produce up to 180 components per minute, far outpacing the sequential operations required in or for similar volumes. This capability supports just-in-time in industries like automotive, reducing inventory costs and lead times. Environmentally, forging consumes less than for large parts, as the latter's powder production phase— involving high-energy atomization—becomes inefficient at scale, requiring around 5 kWh/kg, while hot forging requires about 2.5 kWh/kg for iron-based materials. For sizable components where is impractical due to size limitations and uniform challenges, forging's direct deformation process lowers overall use and emissions, promoting in applications.

Challenges and quality considerations

Forging processes are susceptible to various defects, primarily laps and folds, which arise from the folding of metal surfaces during deformation due to improper die design, inadequate preform geometry, or excessive material flow into die corners. Laps manifest as surface discontinuities where thin metal layers fold over, often open to the exterior, while folds represent internal or subsurface overlaps that compromise structural integrity. These defects are predominantly process-related and can be mitigated through adjustments to the forging sequence, preform shape, or , ensuring uniform metal flow. Finite element analysis (FEA) plays a critical role in preventing such defects by simulating metal flow and stress distribution, allowing optimization of die geometry and process parameters prior to production to avoid laps and folds. This computational approach predicts potential points, reducing trial-and-error in physical forging and enhancing defect-free outcomes in complex shapes. Key challenges in forging include high initial tooling costs, with die sets for closed-die processes typically ranging from $1,500 to $25,000 or more depending on , due to the need for precision from high-strength tool steels like H13, which must withstand repeated and mechanical cycles. Additionally, thermal cracking in steels poses a significant risk, caused by overheating leading to or uneven gradients that induce residual stresses during cooling. Prevention involves controlled heating to avoid excessive temperatures, uniform billet heating, and post-forging heat treatments to relieve stresses, ensuring crack-free components. Quality control in forging relies on nondestructive and mechanical testing methods to verify part integrity. Ultrasonic testing employs high-frequency sound waves to detect internal voids, inclusions, or cracks by analyzing wave reflections from discontinuities within the material, providing a reliable means to identify subsurface defects without damaging the forging. Hardness testing using the Rockwell scale assesses surface and near-surface properties by measuring indentation depth under a specified load, with scales like HRC ensuring forged parts meet required strength and wear resistance criteria through portable or benchtop testers for larger components. Safety considerations in forging operations emphasize (PPE), including heat-resistant gloves, eye and face shields, and hearing protection, to guard against burns, flying debris, and exposure. Machine guarding is mandated by OSHA standards, requiring barriers or enclosures on hammers, presses, and dies to prevent access to and pinch points during operation. Recent OSHA guidelines under 29 CFR 1910.95 address levels, with an action level of 85 dBA triggering hearing conservation programs and a of 90 dBA over eight hours to protect workers from in high-noise forging environments.

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