The Info List - Crankshaft

A crankshaft—related to crank—is a mechanical part able to perform a conversion between reciprocating motion and rotational motion. In a reciprocating engine, it translates reciprocating motion of the piston into rotational motion; whereas in a reciprocating compressor, it converts the rotational motion into reciprocating motion. In order to do the conversion between two motions, the crankshaft has "crank throws" or "crankpins", additional bearing surfaces whose axis is offset from that of the crank, to which the "big ends" of the connecting rods from each cylinder attach. It is typically connected to a flywheel to reduce the pulsation characteristic of the four-stroke cycle, and sometimes a torsional or vibrational damper at the opposite end, to reduce the torsional vibrations often caused along the length of the crankshaft by the cylinders farthest from the output end acting on the torsional elasticity of the metal.

Schematic of operation of a crank mechanism


1 History

1.1 East Asia

1.1.1 Han China

1.2 Europe

1.2.1 Ancient Rome 1.2.2 Medieval and Renaissance Europe 1.2.3 Modern Europe

1.3 Middle East

1.3.1 Medieval Near East

2 Internal combustion engines

2.1 Bearings 2.2 Piston
stroke 2.3 Engine configuration 2.4 Engine balance 2.5 Flying arms 2.6 Rotary aircraft engines 2.7 Radial engines

3 Construction

3.1 Forging
and casting 3.2 Machining

3.2.1 Step 1: Industrial cleaning 3.2.2 Step 2: Magnetic particle inspection 3.2.3 Step 3: Check counterweights 3.2.4 Step 4: Check crankshaft bearings and straightness 3.2.5 Step 5: Check bolt holes 3.2.6 Step 6: Stamp counterweight webbing 3.2.7 Step 7: Re-straightening for rebuilt crankshafts 3.2.8 Step 8: Repeat magnetic particle inspection process 3.2.9 Step 9: Undercutting 3.2.10 Step 10: Thermal spraying 3.2.11 Step 11: Industrial crankshaft welding 3.2.12 Step 12: Relieve structural stress 3.2.13 Step 13: Recheck for straightness 3.2.14 Step 14: Rough crankshaft grinding 3.2.15 Step 15: Finished crankshaft grinding 3.2.16 Step 16: Shot peening 3.2.17 Step 17: Replace or re-tighten counterweights 3.2.18 Step 18: Determine proper balance 3.2.19 Step 19: Micro-polishing 3.2.20 Step 20: Test reman crankshaft Rockwell hardness 3.2.21 Step 21: Final quality control inspection 3.2.22 Step 22: Rustproof remanufactured crankshaft 3.2.23 Step 23: Packaging

3.3 Microfinishing 3.4 Fatigue strength 3.5 Hardening 3.6 Counterweights

4 Stress on crankshafts 5 See also 6 References 7 Sources 8 External links

History[edit] East Asia[edit] Han China[edit] Main article: Science and technology of the Han dynasty

Tibetan operating a quern (1938). The upright handle of such rotary handmills, set at a distance from the centre of rotation, works as a crank.[1][2]

The earliest hand-operated cranks appeared in China
during the Han Dynasty (202 BC-220 AD), as Han era glazed-earthenware tomb models portray, and was used thereafter in China
for silk-reeling and hemp-spinning, for the agricultural winnowing fan, in the water-powered flour-sifter, for hydraulic-powered metallurgic bellows, and in the well windlass.[3] In order to create a handle by means of a wheel to easily rotate their grain winnowers, the Chinese invented the crank handle and applied the centrifugal fan principle in the 2nd century BC.[4][5] The crank handle was used in well-windlasses, querns, mills, and many silk making machines.[4][5] The rotary winnowing fan greatly increased the efficiency of separating grain from husks and stalks. Harvesting grain by the use of rotary winnowing fan would not reach the Western world until the eighteenth century, where harvested grain was initially thrown up in the air by shovels or winnowing baskets.[6][7] However, the potential of the crank of converting circular motion into reciprocal one never seems to have been fully realized in China, and the crank was typically absent from such machines until the turn of the 20th century.[8] Europe[edit] Ancient Rome[edit] Main articles: Roman technology
Roman technology
and List of Roman watermills

Roman crank handle from Augusta Raurica, dated to the 2nd century.[9]

The eccentrically mounted handle of the rotary handmill which appeared in 5th century BC Celtiberian Spain
and ultimately spread across the Roman Empire
Roman Empire
constitutes a crank.[10][1][2] A Roman iron crank of yet unknown purpose dating to the 2nd century AD was excavated in Augusta Raurica, Switzerland. The 82.5 cm long piece has fitted to one end a 15 cm long bronze handle, the other handle being lost.[9][11] A ca. 40 cm long true iron crank was excavated, along with a pair of shattered mill-stones of 50−65 cm diameter and diverse iron items, in Aschheim, close to Munich. The crank-operated Roman mill is dated to the late 2nd century.[12] An often cited modern reconstruction of a bucket-chain pump driven by hand-cranked flywheels from the Nemi ships
Nemi ships
has been dismissed though as "archaeological fantasy".[13]

Hierapolis sawmill
Hierapolis sawmill
in Asia Minor
Asia Minor
(3rd century), a machine that combines a crank with a connecting rod.[14]

Evidence for the crank combined with a connecting rod appears in the Hierapolis sawmill
Hierapolis sawmill
in Asia Minor
Asia Minor
from the 3rd century and two stone sawmills at Gerasa, Roman Syria, and Ephesus, Asia Minor
Asia Minor
(both 6th century).[14] On the pediment of the Hierapolis mill, a waterwheel fed by a mill race is shown powering via a gear train two frame saws which cut rectangular blocks by the way of some kind of connecting rods and, through mechanical necessity, cranks. The accompanying inscription is in Greek.[15] The crank and connecting rod mechanisms of the other two archaeologically attested sawmills worked without a gear train.[16][17] In ancient literature, there is a reference to the workings of water-powered marble saws close to Trier, now Germany, by the late 4th century poet Ausonius;[14] about the same time, these mill types seem also to be indicated by the Christian saint
Christian saint
Gregory of Nyssa from Anatolia, demonstrating a diversified use of water-power in many parts of the Roman Empire[18] The three finds push back the date of the invention of the crank and connecting rod mechanism by a full millennium.[14] According to Tullia Ritti, Klaus Grewe, and Paul Kessener:

With the crank and connecting rod system, all elements for constructing a steam engine (invented in 1712) — Hero's aeolipile (generating steam power), the cylinder and piston (in metal force pumps), non-return valves (in water pumps), gearing (in water mills and clocks) — were known in Roman times.[19]

Medieval and Renaissance Europe[edit] Main articles: Medieval technology
Medieval technology
and Renaissance technology

Vigevano's war carriage

The crank became common in Europe by the early 15th century, seen in the works of those such as the military engineer Konrad Kyeser (1366–after 1405).[20] A rotary grindstone − the earliest representation thereof −[21] which is operated by a crank handle is shown in the Carolingian manuscript Utrecht Psalter; the pen drawing of around 830 goes back to a late antique original.[22] A musical tract ascribed to the abbot Odo of Cluny
Odo of Cluny
(ca. 878−942) describes a fretted stringed instrument which was sounded by a resined wheel turned with a crank; the device later appears in two 12th century illuminated manuscripts.[21] There are also two pictures of Fortuna cranking her wheel of destiny from this and the following century.[21] The first depictions of the compound crank in the carpenter's brace appear between 1420 and 1430 in various northern European artwork.[23] The rapid adoption of the compound crank can be traced in the works of the Anonymous of the Hussite Wars, an unknown German engineer writing on the state of the military technology of his day: first, the connecting-rod, applied to cranks, reappeared, second, double compound cranks also began to be equipped with connecting-rods and third, the flywheel was employed for these cranks to get them over the 'dead-spot'.[24] The use of crank handles in trepanation drills was depicted in the 1887 edition of the Dictionnaire des Antiquités Grecques et Romaines to the credit of the Spanish Muslim surgeon Abu al-Qasim al-Zahrawi; however, the existence of such a device cannot be confirmed by the original illuminations and thus has to be discounted.[25] The Benedictine
monk Theophilus Presbyter (c. 1070−1125) described crank handles "used in the turning of casting cores".[26] In Renaissance Italy, the earliest evidence of a compound crank and connecting-rod is found in the sketch books of Taccola, but the device is still mechanically misunderstood.[24] A sound grasp of the crank motion involved is demonstrated a little later by Pisanello, who painted a piston-pump driven by a water-wheel and operated by two simple cranks and two connecting-rods.[24] The Italian physician Guido da Vigevano (c. 1280−1349), planning for a new crusade, made illustrations for a paddle boat and war carriages that were propelled by manually turned compound cranks and gear wheels (center of image).[27] The Luttrell Psalter, dating to around 1340, describes a grindstone which was rotated by two cranks, one at each end of its axle; the geared hand-mill, operated either with one or two cranks, appeared later in the 15th century;[28] Medieval cranes were occasionally powered by cranks, although more often by windlasses.[29]

15th century paddle-wheel boat whose paddles are turned by single-throw crankshafts (Anonymous of the Hussite Wars)

The crank became common in Europe by the early 15th century, often seen in the works of those such as the German military engineer Konrad Kyeser.[28] Devices depicted in Kyeser's Bellifortis
include cranked windlasses (instead of spoke-wheels) for spanning siege crossbows, cranked chain of buckets for water-lifting and cranks fitted to a wheel of bells.[28] Kyeser also equipped the Archimedes' screws for water-raising with a crank handle, an innovation which subsequently replaced the ancient practice of working the pipe by treading.[30] The earliest evidence for the fitting of a well-hoist with cranks is found in a miniature of c. 1425 in the German Hausbuch of the Mendel Foundation.[31]

German crossbowman cocking his weapon with a cranked rack-and-pinion device (ca. 1493)

The first depictions of the compound crank in the carpenter's brace appear between 1420 and 1430 in various northern European artwork.[23] The rapid adoption of the compound crank can be traced in the works of the Anonymous of the Hussite Wars, an unknown German engineer writing on the state of the military technology of his day: first, the connecting-rod, applied to cranks, reappeared, second, double compound cranks also began to be equipped with connecting-rods and third, the flywheel was employed for these cranks to get them over the 'dead-spot'. One of the drawings of the Anonymous of the Hussite Wars
Hussite Wars
shows a boat with a pair of paddle-wheels at each end turned by men operating compound cranks (see above). The concept was much improved by the Italian engineer and writer Roberto Valturio
Roberto Valturio
in 1463, who devised a boat with five sets, where the parallel cranks are all joined to a single power source by one connecting-rod, an idea also taken up by his compatriot Italian painter Francesco di Giorgio.[32]

Water-raising pump powered by crank and connecting rod mechanism (Georg Andreas Böckler, 1661)

The 15th century also saw the introduction of cranked rack-and-pinion devices, called cranequins, which were fitted to the crossbow's stock as a means of exerting even more force while spanning the missile weapon (see right).[33] In the textile industry, cranked reels for winding skeins of yarn were introduced.[28] Around 1480, the early medieval rotary grindstone was improved with a treadle and crank mechanism. Cranks mounted on push-carts first appear in a German engraving of 1589.[34] Crankshafts were also described by Konrad Kyeser
Konrad Kyeser
(d. 1405), Leonardo da Vinci
Leonardo da Vinci
(1452–1519)[35] and a Dutch farmer and windmill owner by the name Cornelis Corneliszoon van Uitgeest in 1592. His wind-powered sawmill used a crankshaft to convert a windmill's circular motion into a back-and-forward motion powering the saw. Corneliszoon was granted a patent for his crankshaft in 1597. Modern Europe[edit] From the 16th century onwards, evidence of cranks and connecting rods integrated into machine design becomes abundant in the technological treatises of the period: Agostino Ramelli's The Diverse and Artifactitious Machines of 1588 alone depicts eighteen examples, a number that rises in the Theatrum Machinarum Novum by Georg Andreas Böckler to 45 different machines, one third of the total.[36] Cranks were formerly common on some machines in the early 20th century; for example almost all phonographs before the 1930s were powered by clockwork motors wound with cranks. Reciprocating piston engines use cranks to convert the linear piston motion into rotational motion. Internal combustion engines of early 20th century automobiles were usually started with hand cranks (known as starting handles in the UK), before electric starters came into general use. The 1918 Reo owner's manual describes how to hand crank the automobile:

First: Make sure the gear shifting lever is in neutral position. Second: The clutch pedal is unlatched and the clutch engaged. The brake pedal is pushed forward as far as possible setting brakes on the rear wheel. Third: See that spark control lever, which is the short lever located on top of the steering wheel on the right side, is back as far as possible toward the driver and the long lever, on top of the steering column controlling the carburetor, is pushed forward about one inch from its retarded position. Fourth: Turn ignition switch to point marked "B" or "M" Fifth: Set the carburetor control on the steering column to the point marked "START." Be sure there is gasoline in the carburetor. Test for this by pressing down on the small pin projecting from the front of the bowl until the carburetor floods. If it fails to flood it shows that the fuel is not being delivered to the carburetor properly and the motor cannot be expected to start. See instructions on page 56 for filling the vacuum tank. Sixth: When it is certain the carburetor has a supply of fuel, grasp the handle of starting crank, push in endwise to engage ratchet with crank shaft pin and turn over the motor by giving a quick upward pull. Never push down, because if for any reason the motor should kick back, it would endanger the operator.

Middle East[edit] Medieval Near East[edit] The crank appears in the mid-9th century in several of the hydraulic devices described by the Banū Mūsā
Banū Mūsā
brothers in their Book of Ingenious Devices.[37] These devices, however, made only partial rotations and could not transmit much power,[38] although only a small modification would have been required to convert it to a crankshaft.[39] Al-Jazari
(1136–1206) described a crank and connecting rod system in a rotating machine in two of his water-raising machines.[35] His twin-cylinder pump incorporated a crankshaft,[40] including both the crank and shaft mechanisms.[41] In the Artuqid State (Turkey), Al-Jazari
(1136–1206) described a crank and connecting rod system in a rotating machine, in two of his water-raising machines.[35] The twin-cylinder pump he invented incorporated a crankshaft,[40] including both the crank and shaft mechanisms.[41] Internal combustion engines[edit] See also: Internal combustion engine
Internal combustion engine
§ Structure

Crankshaft, pistons and connecting rods for a typical internal combustion engine

MAN marine crankshaft for 6cyl marine diesel applications. Note locomotive on left for size reference

Large engines are usually multicylinder to reduce pulsations from individual firing strokes, with more than one piston attached to a complex crankshaft. Many small engines, such as those found in mopeds or garden machinery, are single cylinder and use only a single piston, simplifying crankshaft design. A crankshaft is subjected to enormous stresses, potentially equivalent of several tonnes of force. The crankshaft is connected to the fly-wheel (used to smooth out shock and convert energy to torque), the engine block, using bearings on the main journals, and to the pistons via their respective con-rods. An engine loses up to 75% of its generated energy in the form of friction, noise and vibration in the crankcase and piston area.[citation needed] The remaining losses occur in the valvetrain (timing chains, belts, pulleys, camshafts, lobes, valves, seals etc.) heat and blow by. Bearings[edit] The crankshaft has a linear axis about which it rotates, typically with several bearing journals riding on replaceable bearings (the main bearings) held in the engine block. As the crankshaft undergoes a great deal of sideways load from each cylinder in a multicylinder engine, it must be supported by several such bearings, not just one at each end. This was a factor in the rise of V8 engines, with their shorter crankshafts, in preference to straight-8 engines. The long crankshafts of the latter suffered from an unacceptable amount of flex when engine designers began using higher compression ratios and higher rotational speeds. High performance engines often have more main bearings than their lower performance cousins for this reason. Piston
stroke[edit] The distance the axis of the crank throws from the axis of the crankshaft determines the piston stroke measurement, and thus engine displacement. A common way to increase the low-speed torque of an engine is to increase the stroke, sometimes known as "shaft-stroking." This also increases the reciprocating vibration, however, limiting the high speed capability of the engine. In compensation, it improves the low speed operation of the engine, as the longer intake stroke through smaller valve(s) results in greater turbulence and mixing of the intake charge. Most modern high speed production engines are classified as "over square" or short-stroke, wherein the stroke is less than the diameter of the cylinder bore. As such, finding the proper balance between shaft-stroking speed and length leads to better results. Engine configuration[edit] The configuration, meaning the number of pistons and their placement in relation to each other leads to straight, V or flat engines. The same basic engine block can sometimes be used with different crankshafts, however, to alter the firing order. For instance, the 90° V6 engine
V6 engine
configuration, in older days[when?] sometimes derived by using six cylinders of a V8 engine
V8 engine
with a 3 throw crankshaft, produces an engine with an inherent pulsation in the power flow due to the "gap" between the firing pulses alternates between short and long pauses because the 90 degree engine block does not correspond to the 120 degree spacing of the crankshaft. The same engine, however, can be made to provide evenly spaced power pulses by using a crankshaft with an individual crank throw for each cylinder, spaced so that the pistons are actually phased 120° apart, as in the GM 3800 engine. While most production V8 engines use four crank throws spaced 90° apart, high-performance V8 engines often use a "flat" crankshaft with throws spaced 180° apart, essentially resulting in two straight four engines running on a common crankcase. The difference can be heard as the flat-plane crankshafts result in the engine having a smoother, higher-pitched sound than cross-plane (for example, IRL Indy Car
Series compared to NASCAR Sprint Cup Series, or a Ferrari 355
Ferrari 355
compared to a Chevrolet Corvette). This type of crankshaft was also used on early types of V8 engines. See the main article on crossplane crankshafts. Engine balance[edit] For some engines it is necessary to provide counterweights for the reciprocating mass of each piston and connecting rod to improve engine balance. These are typically cast as part of the crankshaft but, occasionally, are bolt-on pieces. While counter weights add a considerable amount of weight to the crankshaft, it provides a smoother running engine and allows higher RPM levels to be reached. Flying arms[edit]

with flying arms (the boomerang-shaped link between the visible crank pins)

In some engine configurations, the crankshaft contains direct links between adjacent crank pins, without the usual intermediate main bearing. These links are called flying arms.[42] This arrangement is sometimes used in V6 and V8 engines, as it enables the engine to be designed with different V angles than what would otherwise be required to create an even firing interval, while still using fewer main bearings than would normally be required with a single piston per crankthrow. This arrangement reduces weight and engine length at the expense of less crankshaft rigidity.

Rotary aircraft engines[edit] Some early aircraft engines were a rotary engine design, where the crankshaft was fixed to the airframe and instead the cylinders rotated with the propeller. Radial engines[edit] The radial engine is a reciprocating type internal combustion engine configuration in which the cylinders point outward from a central crankshaft like the spokes of a wheel. It resembles a stylized star when viewed from the front, and is called a "star engine" (German Sternmotor, French Moteur en étoile) in some languages. The radial configuration was very commonly used in aircraft engines before turbine engines became predominant. Construction[edit]

Continental engine
Continental engine
marine crankshafts, 1942

Crankshafts can be monolithic (made in a single piece) or assembled from several pieces. Monolithic crankshafts are most common, but some smaller and larger engines use assembled crankshafts. Forging
and casting[edit]

Forged crankshaft

Crankshafts can be forged from a steel bar usually through roll forging or cast in ductile steel. Today more and more manufacturers tend to favor the use of forged crankshafts due to their lighter weight, more compact dimensions and better inherent damping. With forged crankshafts, vanadium microalloyed steels are mostly used as these steels can be air cooled after reaching high strengths without additional heat treatment, with exception to the surface hardening of the bearing surfaces. The low alloy content also makes the material cheaper than high alloy steels. Carbon steels are also used, but these require additional heat treatment to reach the desired properties. Cast iron crankshafts are today mostly found in cheaper production engines (such as those found in the Ford Focus diesel engines) where the loads are lower. Some engines also use cast iron crankshafts for low output versions while the more expensive high output version use forged steel. Machining[edit] Crankshafts can also be machined out of a billet, often a bar of high quality vacuum remelted steel. Though the fiber flow (local inhomogeneities of the material's chemical composition generated during casting) doesn’t follow the shape of the crankshaft (which is undesirable), this is usually not a problem since higher quality steels, which normally are difficult to forge, can be used. These crankshafts tend to be very expensive due to the large amount of material that must be removed with lathes and milling machines, the high material cost, and the additional heat treatment required. However, since no expensive tooling is needed, this production method allows small production runs without high costs. In an effort to reduce costs, used crankshafts may also be machined. A good core may often be easily reconditioned by a crankshaft grinding [43] process. Severely damaged crankshafts may also be repaired with a welding operation, prior to grinding, that utilizes a submerged arc welding machine. To accommodate the smaller journal diameters a ground crankshaft has, and possibly an over-sized thrust dimension, undersize engine bearings are used to allow for precise clearances during operation. Machining
or remanufacturing crankshafts are precision machined to exact tolerances with no odd size crankshaft bearings or journals. Thrust surfaces are micro-polished to provide precise surface finishes for smooth engine operation and reduced thrust bearing wear. Every journal is inspected and measured with critical accuracy. After machining, oil holes are chamfered to improve lubrication and every journal polished to a smooth finish for long bearing life. Remanufactured crankshafts are thoroughly cleaned with special emphasis to flushing and brushing out oil passages to remove any contaminants. Typically there are 23 steps to re-manufacturing a crankshaft which are as follows:[44] Step 1: Industrial cleaning[edit] The first step in the industrial crankshaft remanufacturing process is cleaning the entire crankshaft. Machine shops soak the rebuilt crankshafts in a hot tank and use a power washing station on the overall shaft as needed. Next machinists then wire brush all oil holes to remove caked on residue and other substances. Step 2: Magnetic particle inspection[edit] The second step in the crankshaft remanufacturing process is using a magnetic particle inspection method to check for cracks. The crankshaft is maganitized and sprayed with an iron oxide powder which, under blacklight conditions, makes any cracks or imperfections visible. All remanufactured crankshafts are checked for imperfections before proceeding forward in the manufacturing process. Step 3: Check counterweights[edit] The machine shop then removes and cleans the counterweights. The production facility then checks the counterweights to make sure they are tight. If the counterweights are loose a technician then replaces all of the counterweight bolts. Counterweights are inspected for cracks before being replaced or retightened. In step sixteen the machinist re-installs the counterweights back into the rebuilt crankshafts. Step 4: Check crankshaft bearings and straightness[edit] The machinist then inspects the entire incoming remanufactured crankshaft for damage and determines the size of the journals and mains. Next the machinist checks the hardness of the mains and journals. It is crucial to also inspect the crankshaft bearings and check the straightness of the overall crankshaft. Re-straightening the industrial crankshaft if not up to OEM standards occurs in step seven. Veteran machine shops typically do not re-straighten the rebuilt crankshafts until a quality control technician checks the bolt holes and seals the surface for divots. Step 5: Check bolt holes[edit] The technician checks the keyway, nose, bolt holes and seals the surface for non-conformities. Usually machine shops will tap bolt holes up to but not more than ½” on all remanufactured crankshafts. Step 6: Stamp counterweight webbing[edit] The rebuild team next stamps the counterweights & webbing in proper firing order (alpha if numeric & vice versa). Technicians then stamp the employee ID#, Work Order # and date on #1 rod webbing. Stamping this information on the rod webbing helps keep the quality control process order in case of future issues during the manufacturing process. Step 7: Re-straightening for rebuilt crankshafts[edit] The seventh step is industrial crankshaft re-straightening. If the remanufactured crankshaft is deemed un-straight than technicians use an industrial straightening machine on the crankshaft. The straightening machine determines how many dials are out of line. To re-straighten the shaft technicians heat up the crankshaft to 500-600 degrees. Any more than 700 degrees takes the hardness out of the shaft. The straightener process corrects the bent crankshaft to the proper OEM specifications for rebuilt crankshafts. Step 8: Repeat magnetic particle inspection process[edit] The eight step in the process is repeating the magnetic particle inspection process if straightening was performed. Anytime metal is being stressed it is imperative to re-inspect for cracks and structural imperfections on the reman crankshaft. Step 9: Undercutting[edit] The ninth step in the industrial crankshaft re-manufacturing process is undercutting. Technicians undercut the rod or journals to eliminate wear before buildup. Step 10: Thermal spraying[edit] The tenth step is the prevention of further buildup via metalizing often called thermal spraying. Thermal spraying
Thermal spraying
has been around for well over 100 years but is still widely known as the best preventative corrosion fighting technique in the world. Thermal spraying
Thermal spraying
is also known for changing the surface of the metallic component and is common with rebuilt crankshafts. Thermal spraying
Thermal spraying
involves protrusion of molten particles onto the heated metallic surface where is bonds and forms a smooth coating interwoven into the structure. There are many different types of thermal spray alloys that can be employed for re-manufactured crankshafts. Typically, boron alloys are used as they very dense, hard and are oxide free. They also prevent against abrasive materials that cause divots, scratches and cracks in addition to preventing surface erosion and corrosion. Thermal spray is an important step some machine shops employ, but not always performed in the industry. Step 11: Industrial crankshaft welding[edit] The welding process for re-manufactured crankshafts is called submerged arc welding. It is a powdered flux plus a weld which combines to produce a more precise weld. The most common flux powder used is called #1 Flux 2245 HD. This powder eliminates the need for technicians to wear weld masking and reduces the amount of dust by-product. Step 12: Relieve structural stress[edit] The twelfth step is to relieve stress upon the entire rebuilt crankshaft structure by heating it up again to 500-600 degrees. Step 13: Recheck for straightness[edit] Next step is to check for overall straightness of the re-manufactured crankshaft once again. If the re-manufactured crankshaft is out of alignment then the technician repeats step 7 and re-straighten the structure. Each of the re-manufactured crankshafts is checked multiple times throughout the re-manufacturing process to ensure quality control. If the straightness is not compromised the rebuilt crankshafts can proceed to step fourteen which is crankshaft grinding. Step 14: Rough crankshaft grinding[edit] This is one of the most important steps in the re-manufacturing process of industrial crankshafts. This step involves rough grinding the excess material from the rod or journals and is known as crankshaft grinding. On the rod there are various mains that need to be reground to proper OEM specifications. These rods are spun grind to the next under-size using the pultrusion crankshaft grinding machine. Rod mains are ground inside and outside. Machine shops have the ability to “crankshaft grind” to any size to bring back the crankshaft to standard OEM specifications. Step 15: Finished crankshaft grinding[edit] Next the technician performs a finished crankshaft grinding procedure. The finished crankshaft grinding is a more precise grind which reaches the correct OEM specifications. Before the technician starts the crankshaft grinding they should see what crankshaft bearings are available and start from there. For example, the OEM specification for a Caterpillar 3306 Rod is 2.9987” – 3.0003”. Top industrial crankshaft grinding technicians always stop at the high end of the tolerance level. Lastly the technician further refines the crankshaft grinding process in during the micro-polishing process at step eighteen. Step 16: Shot peening[edit] The next step is to process the industrial crankshaft in using shot peen machinery. Shot peening
Shot peening
adds an additional layer of hardness to the re-manufactured crankshaft. Step 17: Replace or re-tighten counterweights[edit] Step 17 involves replacing the counterweights in proper firing order. Either the new counterweights are installed or the old counterweight bolts are re-tightened and tested. Step 18: Determine proper balance[edit] The machine shop then determines if the proper rotational balance of the re-manufactured crankshafts is achieved. In the engine the crankshaft, pistons and rods all in a constant rotation. The counterweights are designed to offset the weight of the rod and the pistons in the engine. When in motion the kinetic energy and the sum of all forces should be equal to zero on all moving parts. If the re-manufactured crankshaft counterweights are imbalanced it adds additional stress on other components of the engine. The technician should then make sure the internal balance and the external balance of the crankshaft counterweights are properly aligned. Step 19: Micro-polishing[edit] Then the technician micro-polishes each of the rebuilt crankshafts by hand. To further refine the crankshaft grinding process the machinist makes the most precise fit by micro-polishing the component with a 600 grit emery cloth. Through micro-polishing and industrial crankshaft grinding, the machine shop achieves the recommended Rockwell hardness and Ra finish (Roughness Parameter). Step 20: Test reman crankshaft Rockwell hardness[edit] Next the technician checks the industry standard hardness. Industry standards crankshaft hardness is 40 on the Rockwell hardness scale. A 45-50 rating is what most reputable machine shops try to employ for all remanufactured crankshafts. When possible it is wise to go beyond industry standards to prevent any future weaknesses within the unit. Typically, hardness can be reduced if the engine is out of oil or the journal is spun incorrectly. Step 21: Final quality control inspection[edit] Quality control inspects all of the finished reman crankshafts for internal and external mistakes. A typical quality control department uses separate testing and analytical measurement tools from the technicians to ensure accuracy. If the rebuilt crankshaft passes the quality control inspection it goes onto the rust proofing stage. Step 22: Rustproof remanufactured crankshaft[edit] The vast majority of machine shops apply rust proofing to all remanufactured crankshafts using Cosmoline, which is standard rust-proofing for engine parts. Step 23: Packaging[edit] Lastly the machine shop packs the finished rebuilt crankshaft correctly making sure to using proper boxing and damage proof coverings. It is important to cover the rod journals (varies per crankshaft) with paper & tape in place. Microfinishing[edit] Microfinishing is a method of finishing the surface of the crankshaft in such a manner that microscopic roughness, pitting or cracking is reduced to a smooth, integral surface. Crankshafts fail by fatigue cracking and cracks start at the most highly stressed point in the material, which is the surface. Once a crack has developed, it increases the local stress in the area at its 'V' point, which slowly increases the size of the crack. The objective of microfinishing is to reduce to the smallest number and size any deviation in the surface and thus minimise the opportunity for cracks to develop. Fatigue strength[edit] The fatigue strength of crankshafts is usually increased by using a radius at the ends of each main and crankpin bearing. The radius itself reduces the stress in these critical areas, but since the radius in most cases is rolled, this also leaves some compressive residual stress in the surface, which prevents cracks from forming. Hardening[edit] Most production crankshafts use induction hardened bearing surfaces, since that method gives good results with low costs. It also allows the crankshaft to be reground without re-hardening. But high performance crankshafts, billet crankshafts in particular, tend to use nitridization instead. Nitridization
is slower and thereby more costly, and in addition it puts certain demands on the alloying metals in the steel to be able to create stable nitrides. The advantage of nitridization is that it can be done at low temperatures, it produces a very hard surface, and the process leaves some compressive residual stress in the surface, which is good for fatigue properties. The low temperature during treatment is advantageous in that it doesn’t have any negative effects on the steel, such as annealing. With crankshafts that operate on roller bearings, the use of carburization tends to be favored due to the high Hertzian contact stresses in such an application. Like nitriding, carburization also leaves some compressive residual stresses in the surface. Counterweights[edit] Some expensive, high performance crankshafts also use heavy-metal counterweights to make the crankshaft more compact. The heavy-metal used is most often a tungsten alloy but depleted uranium has also been used. A cheaper option is to use lead, but compared with tungsten its density is much lower. Stress on crankshafts[edit] The shaft is subjected to various forces but generally needs to be analysed in two positions. Firstly, failure may occur at the position of maximum bending; this may be at the centre of the crank or at either end. In such a condition the failure is due to bending and the pressure in the cylinder is maximal. Second, the crank may fail due to twisting, so the conrod needs to be checked for shear at the position of maximal twisting. The pressure at this position is the maximal pressure, but only a fraction of maximal pressure.[clarification needed] See also[edit]

Wikimedia Commons has media related to Crankshaft.

Bicycle crankset Brace (tool) Cam Camshaft Crankcase, the housing that surrounds the crankshaft Crankshaft
torsional vibration Crank (mechanism) Hudson Motor Car
Company, balanced crankshaft in 1916 allowed higher RPM & more power Piston
motion equations Tunnel crankshaft Sun and planet gear Scotch yoke swashplate wobble plate


^ a b Ritti, Grewe & Kessener 2007, p. 159 ^ a b Lucas 2005, p. 5, fn. 9 ^ Needham, Joseph. (1986). Science and Civilization in China: Volume 4, Part 2, Mechanical Engineering. Taipei: Caves Books, Ltd. Pages 118–119. ^ a b Quick, Graeme R. (2008). Remarkable Australian Farm Machines: Ingenuity on the Land. Grantham House Publishing. p. 68. ISBN 978-1869341053.  ^ a b Dorsey, Gray L. (1993). Jurisculture. Transaction Publishers. p. 82. ISBN 978-1560000907.  ^ Bautista Paz, Emilio; Ceccarelli, Marco; Otero, Javier Echávarri; Sanz, José Luis Muñoz (2010). A Brief Illustrated History of Machines and Mechanisms. Springer (published May 12, 2010). p. 19. ISBN 978-9048125111.  ^ Du Bois, George (2014). Understanding China: Dangerous Resentments. Trafford on Demand. ISBN 978-1490745077.  ^ White, Jr. 1962, p. 104:

Yet a student of the Chinese technology of the early twentieth century remarks that even a generation ago the Chinese had not 'reached that stage where continuous rotary motion is substituted for reciprocating motion in technical contrivances such as the drill, lathe, saw, etc. To take this step familiarity with the crank is necessary. The crank in its simple rudimentary form we find in the [modern] Chinese windlass, which use of the device, however, has apparently not given the impulse to change reciprocating into circular motion in other contrivances'. In China
the crank was known, but remained dormant for at least nineteen centuries, its explosive potential for applied mechanics being unrecognized and unexploited.

^ a b Schiöler 2009, pp. 113f. ^ Date: Frankel 2003, pp. 17–19 ^ Laur-Belart 1988, pp. 51–52, 56, fig. 42 ^ Volpert 1997, pp. 195, 199 ^ White, Jr. 1962, pp. 105f.; Oleson 1984, pp. 230f. ^ a b c d Ritti, Grewe & Kessener 2007, p. 161:

Because of the findings at Ephesus
and Gerasa
the invention of the crank and connecting rod system has had to be redated from the 13th to the 6th c; now the Hierapolis relief takes it back another three centuries, which confirms that water-powered stone saw mills were indeed in use when Ausonius
wrote his Mosella.

^ Ritti, Grewe & Kessener 2007, pp. 139–141 ^ Ritti, Grewe & Kessener 2007, pp. 149–153 ^ Mangartz 2006, pp. 579f. ^ Wilson 2002, p. 16 ^ Ritti, Grewe & Kessener 2007, p. 156, fn. 74 ^ Needham 1986, p. 113. ^ a b c White, Jr. 1962, p. 110 ^ Hägermann & Schneider 1997, pp. 425f. ^ a b White, Jr. 1962, p. 112 ^ a b c White, Jr. 1962, p. 113 ^ White, Jr. 1962, p. 170 ^ Needham 1986, pp. 112–113. ^ Hall 1979, p. 80 ^ a b c d White, Jr. 1962, p. 111 ^ Hall 1979, p. 48 ^ White, Jr. 1962, pp. 105, 111, 168 ^ White, Jr. 1962, p. 167; Hall 1979, p. 52 ^ White, Jr. 1962, p. 114 ^ Hall 1979, pp. 74f. ^ White, Jr. 1962, p. 167 ^ a b c Ahmad Y Hassan. The Crank-Connecting Rod System in a Continuously Rotating Machine. ^ White, Jr. 1962, p. 172 ^ A. F. L. Beeston, M. J. L. Young, J. D. Latham, Robert Bertram Serjeant (1990), The Cambridge History of Arabic Literature, Cambridge University Press, p. 266, ISBN 0-521-32763-6  ^ al-Hassan & Hill 1992, pp. 45, 61 ^ Banu Musa, Donald Routledge Hill
Donald Routledge Hill
(1979), The book of ingenious devices (Kitāb al-ḥiyal), Springer, pp. 23–4, ISBN 90-277-0833-9  ^ a b Sally Ganchy, Sarah Gancher (2009), Islam and Science, Medicine, and Technology, The Rosen Publishing Group, p. 41, ISBN 1-4358-5066-1  ^ a b Donald Hill
Donald Hill
(2012), The Book of Knowledge of Ingenious Mechanical Devices, page 273, Springer Science + Business Media ^ Nunney 2007, pp. 16, 41. ^ " Crankshaft
Grinding". Crankshaft
Repair.  ^ "Remanufactured Crankshafts - Capital Reman Exchange". Capital Reman Exchange. Retrieved 2015-12-28. 


Hall, Bert S. (1979), The Technological Illustrations of the So-Called "Anonymous of the Hussite Wars". Codex Latinus Monacensis 197, Part 1, Wiesbaden: Dr. Ludwig Reichert Verlag, ISBN 3-920153-93-6  al-Hassan, Ahmad Y.; Hill, Donald R. (1992), Islamic Technology. An Illustrated History, Cambridge University Press, ISBN 0-521-42239-6  Laur-Belart, Rudolf (1988), Führer durch Augusta Raurica
Augusta Raurica
(5th ed.), Augst  Mangartz, Fritz (2010), Die byzantinische Steinsäge von Ephesos. Baubefund, Rekonstruktion, Architekturteile, Monographs of the RGZM, 86, Mainz: Römisch-Germanisches Zentralmuseum, ISBN 978-3-88467-149-8  White, Jr., Lynn (1962), Medieval Technology and Social Change, Oxford: At the Clarendon Press  Ritti, Tullia; Grewe, Klaus; Kessener, Paul (2007), "A Relief of a Water-powered Stone Saw Mill on a Sarcophagus at Hierapolis and its Implications", Journal of Roman Archaeology, 20: 138–163  Schiöler, Thorkild (2009), "Die Kurbelwelle von Augst und die römische Steinsägemühle", Helvetia Archaeologica, 40 (159/160), pp. 113–124  Wilson, Andrew (2002), "Machines, Power and the Ancient Economy", The Journal of Roman Studies, 92, pp. 1–32  Nunney, Malcolm J. (2007), Light and Heavy Vehicle Technology (4th ed.), Elsevier Butterworth-Heinemann, ISBN 978-0-7506-8037-0 

External links[edit]

Interactive crank animation https://www.desmos.com/calculator/8l2kvyivqo D & T Mechanisms - Interactive Tools for Teachers (applets) http://www.content.networcs.net/tft/mechanisms.htm Grewe, Klaus (2009), "Die Reliefdarstellung einer antiken Steinsägemaschine aus Hierapolis in Phrygien und ihre Bedeutung für die Technikgeschichte. Internationale Konferenz 13.−16. Juni 2007 in Istanbul", in Bachmann, Martin, Bautechnik im antiken und vorantiken Kleinasien (PDF), Byzas (in German), 9, Istanbul: Ege Yayınları/Zero Prod. Ltd., pp. 429–454, ISBN 978-975-807-223-1, archived from the original (PDF) on 2011-05-11 

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Reciprocating engines and configurations


Bourke Orbital (Sarich) Piston Pistonless (Wankel) Radial Axial Rotary Split cycle Stelzer Tschudi

Stroke cycles

Two-stroke Four-stroke Five-stroke Six-stroke Two-and four-stroke

Configurations & number of cylinders

Single cylinder


Two cylinders

Split-single I2 V2 F2

Inline / straight

I2 I3 I4 I5 I6 I7 I8 I9 I10 I12 I14


F2 F4 F6 F8 F10 F12 F16

V / Vee

V2 V3 V4 V5 V6 V8 V10 V12 V14 V16 V18 V20 V24


W8 W12 W16 W18

Other inline

H U Square four VR Opposed X X24 Junkers Jumo 222



Cylinder head
Cylinder head
porting Corliss Intake Exhaust Multi Overhead Piston Poppet Side Sleeve Slide Rotary valve Variable valve timing Camless Desmodromic Hydraulic tappet

Fuel supplies

Carburetor Gasoline direct injection Common rail


Cam Camshaft Overhead camshaft Connecting rod Crank Crankshaft Scotch yoke Swashplate Rhombic drive


Peaucellier–Lipkin Watt's (parallel)


Hemi Recuperator Turbo-compounding

v t e

Automotive engine

Part of the Automobile

Basic terminology

Bore Compression ratio Crank Cylinder Dead centre Diesel engine Dry sump Engine balance Engine configuration Engine displacement Engine knocking Firing order Hydrolock Petrol engine Power band Redline Spark-ignition engine Stroke Stroke ratio Wet sump

Main components

Connecting rod Crankcase Crankpin Crankshaft Crossplane Cylinder bank Cylinder block Cylinder head
Cylinder head
(crossflow, reverse-flow) Flywheel Head gasket Hypereutectic piston Main bearing Piston Piston
ring Starter ring gear Sump


Cam Cam
follower Camshaft Desmodromic valve Hydraulic tappet Multi-valve Overhead camshaft Overhead valve Pneumatic valve springs Poppet valve Pushrod Rocker arm Sleeve valve Tappet Timing belt Timing mark Valve
float Variable valve timing


Air filter Blowoff valve Boost controller Butterfly valve Centrifugal-type supercharger Cold air intake Dump valve Electronic throttle control Forced induction Inlet manifold Intake Intercooler Manifold vacuum Naturally aspirated engine Ram-air intake Scroll-type supercharger Short ram air intake Supercharger Throttle Throttle
body Turbocharger Twin-turbo Variable-geometry turbocharger Variable-length intake manifold Warm air intake

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Electrics and engine management

Air–fuel ratio meter Alternator Automatic Performance Control Car
battery (lead–acid battery) Crankshaft
position sensor Dynamo Drive by wire Electronic control unit Engine control unit Engine coolant temperature sensor Glow plug Idle air control actuator MAP sensor Mass flow sensor Oxygen sensor Starter motor Throttle
position sensor

Exhaust system

emissions control Catalytic converter Diesel particulate filter Exhaust manifold Glasspack Muffler

Engine cooling

Air cooling Antifreeze
(ethylene glycol) Core plug Electric fan Fan belt Radiator Thermostat Water cooling Viscous fan (fan clutch)

Other components

Balance shaft Block heater Combustion chamber Cylinder head
Cylinder head
porting Gasket Motor oil Oil filter Oil pump Oil sludge PCV valve Seal Synthetic oil Underdrive pulleys

Portal Category

v t e

Aircraft piston engine components, systems and terminology


Mechanical components

Camshaft Connecting rod Crankpin Crankshaft Cylinder Cylinder head Gudgeon pin Hydraulic tappet Main bearing Obturator ring Oil pump Piston Piston
ring Poppet valve Pushrod Rocker arm Sleeve valve Tappet

Electrical components

Alternator Capacitor discharge ignition Dual ignition Electronic fuel injection Generator Ignition system Magneto Spark plug Starter


Air-cooled Aircraft engine
Aircraft engine
starting Bore Compression ratio Dead centre Engine displacement Four-stroke engine Horsepower Ignition timing Manifold pressure Mean effective pressure Naturally aspirated Monosoupape Overhead camshaft Overhead valve engine Rotary engine Shock cooling Stroke Time between overhaul Two-stroke engine Valve
timing Volumetric efficiency



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Autofeather Blade pitch Constant-speed Contra-rotating Counter-rotating Scimitar Single-blade Variable-pitch

Engine instruments

Annunciator panel EFIS EICAS Flight data recorder Glass cockpit Hobbs meter Tachometer

Engine controls

heat Throttle

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Avgas Carburetor Fuel injection Gascolator Inlet manifold Intercooler Pressure carburetor Supercharger Turbocharger Updraft carburetor

Other systems

Auxiliary power unit Coffman starter Hydraulic system Ice protection system Recoil start

v t e

Steam engines

Operating cycle

Atmospheric Watt Cornish Compound Uniflow




D slide

Piston Drop Corliss Poppet Sleeve Bash


Gab Stephenson link Joy Walschaerts Allan Baker Corliss Lentz Caprotti Gresley conjugated Southern


Beam Cataract Centrifugal governor Connecting rod Crank Crankshaft Hypocycloidal gear Link chain Parallel motion Plate chain Rotative beam Sun and planet gear Watt's linkage


Simple boilers

Haystack Wagon Egg-ended Box Flued Cornish Lancashire

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Feedwater heater Feedwater pump Injector


Locomotive Oscillating Single- and double-acting


Condensing steam locomotive Jet Kirchweger Watt's separate "Pickle-pot" Surface


Crosshead Cutoff Expansion valve Hydrolock Piston Reciprocating engine Return connecting rod engine Six-column beam engine Steeple engine Safety valve Steeple compound engine Stroke Working fluid



Savery Engine (1698)

Newcomen engine

Newcomen Memorial Engine
Newcomen Memorial Engine
(1725) Fairbottom Bobs
Fairbottom Bobs
(1760) Elsecar Engine
Elsecar Engine

Watt engine


Kinneil Engine
Kinneil Engine
(1768) Old Bess (1777) Chacewater Mine engine (1778) Smethwick Engine
Smethwick Engine
(1779) Resolution (1781)

Rotative beam

Soho Manufactory engine (1782) Bradley Works engine (1783) Whitbread Engine
Whitbread Engine
(1785) National Museum of Scotland engine (1786) Lap Engine
Lap Engine


Richard Trevithick

Puffing Devil (1801) London Steam Carriage (1803) "Coalbrookdale Locomotive" (1803) "Pen-y-Darren" locomotive (1804)


Woolf's compound engine (1803)


Murray's Hypocycloidal Engine
Murray's Hypocycloidal Engine
(1805) Salamanca (1812)


Porter-Allen (1862) Ljungström (1908)

See also

Glossary of steam locomotive components History of steam road vehicles

Cugnot's fardier à vapeur (1769) Murdoch's model steam carriage (1784)

Lean's Engine Reporter List of steam technology patents Modern steam Stationary steam engine Timeline of steam power Water-retu