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{{short description|Part of an internal combustion engine}}
{{short description|Part of an internal combustion engine}}
{{refimprove|date=December 2018}}
{{more citations needed|date=March 2022}}
[[File:Cylinder block for V6 Diesel.jpg|thumb|Block of a modern [[V6 engine|V6]] diesel engine. The large holes are the cylinders, the small round orifices are mounting holes and the small oval orifices are coolant or oil ducts.]]
[[File:Cylinder block for V6 Diesel.jpg|thumb|Block of a modern [[V6 engine|V6]] [[diesel engine]]. The large holes are the cylinders, the small round orifices are mounting holes, and the small oval orifices adjacent to the cylinders are coolant or oil ducts.]]


An '''engine block''' is the structure which contains the [[cylinder (engine)|cylinders]], and other parts, of an [[internal combustion engine]]. In an early [[automotive engine]], the engine block consisted of just the cylinder block, to which a separate [[crankcase]] was attached. Modern engine blocks typically have the crankcase integrated with the cylinder block as a single component. Engine blocks often also include elements such as [[coolant]] passages and [[oil]] galleries.
In an [[internal combustion engine]], the '''engine block''' is the structure that contains the [[cylinder (engine)|cylinders]] and other components. The engine block in an early automotive engine consisted of just the cylinder block, to which a separate [[crankcase]] was attached. Modern engine blocks typically have the crankcase integrated with the cylinder block as a single component. Engine blocks often also include elements such as [[Internal_combustion_engine_cooling#Liquid_cooling|coolant]] passages and [[Motor oil|oil]] galleries.

The term "cylinder block" is often used interchangeably with "engine block". However, technically, the block of a modern engine (i.e., multiple cylinders integrated with another component) would be classified as a [[monobloc engine|monobloc]].


The term "cylinder block" is often used interchangeably with engine block, although technically the block of a modern engine (i.e. multiple cylinders in a single component) would be classified as a [[monobloc engine|monobloc]]. Another common term for an engine block is simply "block".
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__TOC__
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== Engine block components ==
[[File:De Dion-Bouton engine (Rankin Kennedy, Modern Engines, Vol III).jpg|thumb|right|upright=0.8 |[[De Dion-Bouton]] engine, circa 1950. The cylinder heads are integrated into the engine block, however the crankcase is separate. The bottom half of the crankcase also includes the oil sump.<ref name="Rankin Kennedy, Modern Engines, Vol III, De Dion-Bouton" >{{cite book |series=The Book of Modern Engines and Power Generators |title=The De Dion-Bouton Engine and Cars |year=1912 |last=Kennedy |first=Rankin |publisher=Caxton |location=London |pages=78–89 |ref=Rankin Kennedy, Modern Engines, Vol III}}</ref> ]]


== Construction ==
The main structure of an [[engine]] (i.e. the [[long block]], excluding any moving parts) typically consists of the [[cylinder]]s, coolant passages, oil galleries, crankcase and [[cylinder head|cylinder head(s)]]. The first production engines of the [[1880s]] to [[1920s]] usually used separate components for each of these elements, which were bolted together during engine assembly. Modern engines, however, often combine many of these elements into a single component, in order to reduce production costs.
The main structure of an engine typically consists of the [[cylinder (engine)|cylinder]]s, coolant passages, oil galleries, crankcase, and [[cylinder head|cylinder head(s)]]. The first production engines of the 1880s to 1920s usually used separate components for each element, which were bolted together during engine assembly. Modern engines, however, often combine many elements into a single component to reduce production costs.


The evolution from separate components to an engine block integrating several elements (a [[monobloc engine]]) has been a gradual progression throughout the history of internal combustion engines. The integration of elements has relied on the development of [[foundry]] and [[machining]] techniques. For example, a practical low-cost V8 engine was not feasible until Ford developed the techniques used to build the [[Ford flathead V8 engine]]. These techniques were then applied to other engines and manufacturers.
The evolution from separate components to monobloc engine blocks has gradually progressed since the early 20th century. The integration of elements has relied on the development of [[foundry]] and [[machining]] techniques. For example, a practical, low-cost V8 engine was not feasible until Ford developed the methods used to build its [[Ford flathead V8 engine|flathead V8 engine]]. Other manufacturers then applied those techniques to their engines.
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=== Cylinder blocks ===
=== Cylinder block ===
{{multiple image
{{multiple image
| title = Cylinder blocks for a [[straight-six engine|straight-6]] engine
| title = Cylinder blocks for a [[straight-six engine|straight-6]] engine
| width = 200
| width = 200
| align = right
| align = right
| direction = vertical
| direction = vertical
| image1 = Wolseley 6-cylinder marine oil engine (Rankin Kennedy, Modern Engines, Vol V).jpg
| image1 = Wolseley 6-cylinder marine oil engine (Rankin Kennedy, Modern Engines, Vol V).jpg
| caption1 = Cylinders cast in three pairs (on a marine engine)
| caption1 = Marine engine with cylinders cast in three pairs
| image2 = Six cylinder engine with three cylinder blocks (Autocar Handbook, Ninth edition).jpg
| image2 = Six cylinder engine with three cylinder blocks (Autocar Handbook, Ninth edition).jpg
| caption2 = Cylinders cast in two blocks of three
| caption2 = Cylinders cast in two blocks of three
| image3 = CarterBMW1.JPG
| image3 = CarterBMW1.JPG
| caption3 = Cylinders cast in a single block of six, with integrated crankcase (turbocharger in background)
| caption3 = Cylinders cast in a single block of six, with an integrated crankcase (turbocharger in background)
| alt1 = Wolseley marine engine
| alt2 = Six-cylinder engine
| alt3 = BMW engine block
}}
}}


A cylinder block is the structure which contains the [[Cylinder_(engine)|cylinder]], plus any [[Cylinder_(engine)#Cylinder_sleeving|cylinder sleeves]] and coolant passages. In the earliest decades of internal combustion engine development, cylinders were usually cast individually, so cylinder blocks were usually produced individually for each cylinder. Following that, engines began to combine two or three cylinders into a single cylinder block, with an engine combining several of these cylinder blocks combined together.
A cylinder block is a structure that contains the [[cylinder (engine)|cylinder]], plus any [[cylinder (engine)#Cylinder sleeving|cylinder sleeves]] and coolant passages. In the earliest decades of internal combustion engine development, cylinders were usually cast individually, so cylinder blocks were usually produced separately for each cylinder. Following that, engines began to combine two or three cylinders into a single-cylinder block, with an engine combining several of these cylinder blocks.


In early engines with multiple cylinder bankssuch as a [[V6 engine|V6]], [[V8 engine|V8]] or [[Flat-six engine|flat-6]] engine — each bank was typically a separate cylinder block (or multiple blocks per bank). Since the 1930s, mass production methods have developed to allow both banks of cylinders to be integrated into the same cylinder block.
In early engines with multiple cylinder banks{{snd}}such as [[V6 engine|V6]], [[V8 engine|V8]], or [[Flat-six engine|flat-6]] engines{{snd}}each bank was typically made of one or multiple separate cylinder blocks. Since the 1930s, mass production methods have developed to allow both banks of cylinders to be integrated into the same cylinder block.


=== Cylinder liners ===
=== Cylinder liners ===
[[Wet liner]] cylinder blocks use cylinder walls that are entirely removable and fit into the block using special gaskets. They are called "wet liners" because their outer sides come in direct contact with the engine's coolant. In other words, the liner is the entire cylinder wall, rather than merely a sleeve.
{{Anchor|wet liners}}
'''Wet liner''' cylinder blocks use cylinder walls that are entirely removable, which fit into the block by means of special gaskets. They are referred to as "wet liners" because their outer sides come in direct contact with the engine's coolant. In other words, the liner is the entire wall, rather than being merely a sleeve.


Advantages of wet liners are a lower mass, reduced space requirement and that the coolant liquid is heated quicker from a cold start, which reduces start-up fuel consumption and provides heating for the car cabin sooner.
The advantages of wet liners are a lower mass, reduced space requirements, and coolant being heated faster from a cold start, reducing start-up fuel consumption and heating the car cabin sooner.


[[Dry liner]] cylinder blocks use either the block's material or a discrete liner inserted into the block to form the backbone of the cylinder wall. Additional sleeves are inserted within, which remain "dry" outside, surrounded by the block's material.
{{Anchor|dry liners}}
'''Dry liner''' cylinder blocks use either the block's material or a discrete liner inserted into the block to form the backbone of the cylinder wall. Additional sleeves are inserted within, which remain "dry" on their outside, surrounded by the block's material.


For either wet or dry liner designs, the liners (or sleeves) can be replaced, potentially allowing overhaul or rebuild without replacement of the block itself, although this is often not a practical repair option.
For either wet or dry liner designs, the liners (or sleeves) can be replaced, potentially allowing an engine overhaul or rebuild without replacing the block itself. However, there are more practical repair options.


=== Coolant passages ===
=== Coolant and oil passages ===
{{main|Internal combustion engine cooling}}
{{See also|Internal combustion engine cooling|Oil pump (internal combustion engine)}}

=== Oil passages ===
{{main|Oil pump (internal combustion engine)}}


=== Crankcase ===
=== Crankcase ===
{{main|crankcase}}
{{main|Crankcase}}
The crankcase is the structure that houses the [[crankshaft]]. As with cylinder blocks, this is primarily an integrated component in modern engines.
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=== Materials ===
Engine blocks are typically cast from either [[cast iron]] or an [[aluminium alloy]]. Aluminium blocks are much lighter and transfer heat more effectively to coolant, but iron blocks retain some advantages, such as durability and reduced [[thermal expansion]].

'''Weight reductions through material selection'''. Presently, most of the engine blocks in mass production are gray castings. Reducing weight has resulted in using aluminum-silicon alloys more frequently for the engine block in small-displacement engines. Engine blocks of comparable design, but using Al-Si alloys, are not lighter than cast iron engine blocks in the same ratio as that for the specific weights of the materials.

In engine blocks made of gray cast iron, weight can be reduced by optimizing the structure and thin-wall casting. With this casting technique, a wall thickness of as little as about 3 mm is generally possible. In comparison, the walls of cast iron engine blocks are usually from 4.0 to 5.5 mm thick.

Using vermicular graphite cast iron (GGV), a casting material with great strength, enables weight reductions by about 30% compared to conventional casting materials such as GG 25. Weight reduction, to this extent, requires engineering for the engine block, taking into account the particular needs of the material.<ref>{{cite web |title=Minimizing Engine Block Mass |url= https://studedu.org/s1396t1.html |access-date=2024-05-14 |website=studedu.org}}</ref>


== Monoblocs ==
== Monoblocs ==
[[File:De Dion-Bouton engine (Rankin Kennedy, Modern Engines, Vol III).jpg|thumb|right|upright=1.0 |[[De Dion-Bouton]] engine, circa 1905. The cylinder heads are integrated into the engine block, but the crankcase is separate.<ref name="Rankin Kennedy, Modern Engines, Vol III, De Dion-Bouton" >{{cite book |series=The Book of Modern Engines and Power Generators |title=The De Dion-Bouton Engine and Cars |year=1912 |last=Kennedy |first=Rankin |publisher=Caxton |location=London |pages=78–89 |ref=Rankin Kennedy, Modern Engines, Vol III}}</ref> ]]
[[File:Cylinder block and head of sidevalve engine (Autocar Handbook, Ninth edition).jpg|thumb|Typical 1930-1960 [[flathead engine]] with integrated crankcase (the cylinder head is tipped upwards for illustrative purposes)]]
An engine where all the cylinders share a common block is called a [[monobloc engine]]. Most modern engines (including [[automobile|cars]], [[truck]]s, [[bus]]es and [[tractor]]s) use a monoblock design of some type, therefore few modern engines have a separate block for each cylinder. This has led to the term "engine block" usually implying a monobloc design and the term monobloc itself is rarely used.


[[File:Cylinder block and head of sidevalve engine (Autocar Handbook, Ninth edition).jpg|thumb|Typical 1930-1960 [[flathead engine]] with integrated crankcase. The cylinder head is tipped upwards for illustrative purposes.]]
In the early years of the internal combustion engine, [[casting]] technology could produce either large castings, or castings with complex [[core (manufacturing)|internal cores]] to allow for water jackets, but not both simultaneously. Most early engines, particularly those with more than four cylinders, had their cylinders cast as pairs or triplets of cylinders, then bolted to a single crankcase.
An engine where all the cylinders share a common block is called a [[monobloc engine]]. Most modern engines use a monobloc design, and few have a separate block for each cylinder. This has led to the term "engine block," which usually implies a monobloc design, with "monobloc" rarely used.


In the early years of the internal combustion engine, [[casting]] technology couldn't produce large castings with complex [[core (manufacturing)|internal cores]] (for water jackets etc). Most early engines, particularly those with more than four cylinders, had their cylinders cast as pairs or triplets of cylinders, then bolted to a separate crankcase.
As casting techniques improved, an entire cylinder block of 4, 6, or 8 cylinders could be produced in one piece. This monobloc construction was simpler and more cost effective to produce. For engines with an [[straight engine|inline]] configuration, this meant that all the cylinders, plus the crankcase, could be produced in a single component. One of the early engines produced using this method is the 4-cylinder engine in the [[Ford Model T]], introduced in 1908. The method spread to [[straight-six engine]]s and was commonly used by the mid-1920s.


As casting techniques improved, an entire cylinder block of 4, 6, or 8 cylinders could be produced in one piece. This monobloc construction was more straightforward and more cost-effective to produce. All the cylinders and crankcase could be made in a single component for [[straight engine]] cylinder layouts. One of the early engines produced using this method is the 4-cylinder engine in the [[Ford Model T]], introduced in 1908. The technique spread to [[straight-six engine]]s and was commonly used by the mid-1920s.
Up until the 1930s, most [[V engine]]s retained a separate block casting for each cylinder bank, with both bolted onto a common crankcase (itself a separate casting). For economy, some engines were designed to use identical castings for each bank, left and right.<ref name="Ludvigsen, V12 Engine, Buzzard">{{cite book |title=The V12 Engine |last=Ludvigsen |first=Karl |authorlink=Karl Ludvigsen |publisher=Haynes Publishing |year=2005 |isbn=1-84425-004-0}}</ref>{{refpage|page=120}} A rare exception is the [[Lancia]] 22½° narrow-angle V12 of 1919, which used a single block casting combining both banks.<ref name="Ludvigsen, V12 Engine, Buzzard"/>{{refpage|pages=50-53}} The [[Ford flathead V-8]] introduced in 1932represented a significant development in the production of affordable V engines. It was the first V8 engine with a single engine block casting, putting a V8 into an affordable car for the first time.<ref name="Sorensen1956pp225-231">{{cite book |last1=Sorensen |first1=Charles E. |last2=Williamson |first2=Samuel T. |title=My Forty Years with Ford |date=1956 |publisher=Norton |location=New York, USA |isbn=9780814332795 |pages=225-231}}</ref>


Up until the 1930s, most [[V engine]]s retained a separate block casting for each cylinder bank, with both bolted onto a common crankcase (itself a separate casting). For economy, some engines were designed to use identical castings for each bank, left and right.<ref name="Ludvigsen">{{cite book |title=The V12 Engine |last=Ludvigsen |first=Karl |author-link=Karl Ludvigsen |publisher=Haynes Publishing |year=2005 |isbn=1-84425-004-0}}</ref>{{refpage|page=120}} A rare exception was the [[Lancia]] 22½° narrow-angle [[V12 engine|V12]] of 1919, which used a single block casting combining both banks.<ref name="Ludvigsen"/>{{refpage|pages=50-53}} The [[Ford flathead V8 engine|Ford flathead V8]]{{snd}}introduced in 1932{{snd}}represented a significant development in the production of affordable V engines. It was the first V8 engine with a single-engine block casting, putting a V8 into an affordable car for the first time.<ref name="Sorensen1956pp225-231">{{cite book |last1=Sorensen |first1=Charles E. |last2=Williamson |first2=Samuel T. |title=My Forty Years with Ford |date=1956 |publisher=Norton |location=New York |isbn=9780814332795 |pages=225–231}}</ref>
The communal water jacket of monobloc designs permitted closer spacing between cylinders. The monobloc design also improved the mechanical stiffness of the engine against bending and the increasingly important torsional twist, as cylinder numbers, engine lengths, and power ratings increased.


The communal water jacket of monobloc designs permitted closer spacing between cylinders. The monobloc design approach also improved engines' [[Stiffness|torsional rigidity]] as cylinder numbers, engine lengths, and power ratings increased.
=== Integrated crankcase ===
Most engine blocks today, except some unusual V or radial engines and large marine engines, are a monobloc for all the cylinders, plus an integrated crankcase. In such cases, the skirts of the cylinder banks form a crankcase area of sorts, which is still often called a crankcase despite no longer being a discrete part.


=== Integrated cylinder block and crankcase ===
Use of steel [[Cylinder (engine)|cylinder]] liners and [[bearing (mechanical)|bearing]] shells minimizes the effect of the relative softness of aluminium. Some engine designs use [[plasma transferred wire arc thermal spraying]] instead cylinder sleeves, to reduce weight. They can also be produced in [[compacted graphite iron]] (CGI) such as some diesel engines.<ref>{{cite news |url=http://foundrymag.com/materials/navistar-now-producing-engine-blocks-heads-cgi |title=Navistar Now Producing Engine Blocks, Heads in CGI |work=Foundry Management & Technology |first=Robert |last=Brooks |date=January 25, 2012 |accessdate=May 2, 2017}}</ref>
Most engine blocks today, except some unusual V or radial engines and large marine engines, use a monobloc design with one block for all cylinders plus an integrated crankcase. In such cases, the skirts of the cylinder banks form a crankcase area of sorts, which is still often called a crankcase despite no longer being a discrete part.
{{clear right}}

Using steel cylinder liners and [[Main bearing|bearing]] shells minimizes the effect of the relative softness of aluminium. Some engine designs use [[plasma transferred wire arc thermal spraying]], instead of cylinder sleeves, to further reduce weight. These types of engines can also be made of [[compacted graphite iron]], such as in some diesel engines.<ref>{{cite news |url= http://foundrymag.com/materials/navistar-now-producing-engine-blocks-heads-cgi |title=Navistar Now Producing Engine Blocks, Heads in CGI |work=Foundry Management & Technology |first=Robert |last=Brooks |date=January 25, 2012 |access-date=May 2, 2017}}</ref>


=== Integrated cylinder head ===
=== Integrated cylinder block and head ===
{{multiple image
{{multiple image
| title = Integrated cylinder head engines
| title = Integrated cylinder head engines
| width = 200
| width = 220
| align = right
| align = right
| direction = vertical
| direction = vertical
| image1 = Daimler DB 605 cutaway.jpg
| image1 = Daimler DB 605 cutaway.jpg
| caption1 = [[DB 605]] inverted V12 aircraft engine
| caption1 = [[DB 605]] V12 aircraft engine
| image2 = Honda GX 160 engine.jpg
| image2 = Honda GX 160 engine.jpg
| caption2 = Honda GX 160 engine in a ride-on lawnmower
| caption2 = Honda GX 160 engine in a ride-on lawnmower
}}
}}


Some modern consumer-grade [[small engine]]s use a monobloc design where the cylinder head, block, and half the crankcase share the same casting. One reason for this, apart from cost, is to produce an overall lower engine height. The disadvantage can be that repairs become more time-consuming and perhaps impractical.
Some modern consumer-grade [[small engine]]s use a monobloc design where the cylinder head, block, and half of the crankcase share the same casting. Apart from cost, one reason for this is to produce an overall lower engine height.{{Citation needed|date=November 2022}} The primary disadvantage can be that repairs become more time-consuming and impractical.


An example of engines with integrated cylinder heads are the Honda [[list of Honda engines#Power equipment|GC]]-series and GXV-series engines, which are sometimes called "Uniblock" by Honda.<ref>{{cite web
An example of engines with integrated cylinder heads are the Honda [[list of Honda engines#Power equipment|GC]]-series and GXV-series engines, which are sometimes called "Uniblock" by Honda.<ref>{{cite web |title=Honda General Purpose Engines: GC Series - Single Cylinder |url= http://www.perr.com/honda.html |url-status=dead |archive-url= https://web.archive.org/web/20101127185645/http://perr.com/honda.html |archive-date=2010-11-27}} Includes sectioned drawings</ref>
|title = Honda General Purpose Engines: GC Series - Single Cylinder
|url = http://www.perr.com/honda.html
|url-status = dead
|archiveurl = https://web.archive.org/web/20101127185645/http://perr.com/honda.html
|archivedate = 2010-11-27
}} Includes sectioned drawings</ref>


=== Integrated transmission ===
=== Integrated crankcase and transmission ===
Several cars with [[transverse engine]]s have used an engine block consisting of an integrated [[transmission (mechanics)|transmission]] and crankcase. Cars that have used this arrangement include the 1966-1973 [[Lamborghini Miura]]<ref name="netcarshow.com">{{cite web |title=Lamborghini Miura SV (1971) |url=https://www.netcarshow.com/lamborghini/1971-miura_sv/ |website=www.netcarshow.com |accessdate=12 December 2018 |language=en}}</ref> and several cars using the BMC [[BMC A-series engine|A-series]] and [[BMC E-series engine|E-series]] engines.<ref name="aronline.co.uk">{{cite web |title=H and K-Series prototypes: BL's first attempt at replacing the A-Series |url=https://www.aronline.co.uk/facts-and-figures/engines/engines-h-and-k-series-prototypes/ |website=www.aronline.co.uk |accessdate=12 December 2018 |date=22 July 2017}}</ref><ref name="ateupwithmotor.com">{{cite web |title=Tiny and Triumphant: The Morris / Austin Mini |url=https://ateupwithmotor.com/model-histories/original-mini-history/ |website=www.ateupwithmotor.com |accessdate=12 December 2018 |date=1 May 2010}}</ref> This design often results in the engine and transmission sharing the same oil.
Several cars with [[transverse engine]]s have used an engine block consisting of an integrated [[transmission (mechanics)|transmission]] and crankcase. Cars that have used this arrangement include the 1966-1973 [[Lamborghini Miura]]<ref name="netcarshow.com">{{cite web |title=Lamborghini Miura SV (1971) |url= https://www.netcarshow.com/lamborghini/1971-miura_sv/ |website=www.netcarshow.com |access-date=12 December 2018 |language=en}}</ref> and cars using the BMC [[BMC A-series engine|A-series]] and [[BMC E-series engine|E-series]] engines.<ref name="aronline.co.uk">{{cite web |title=H and K-Series prototypes: BL's first attempt at replacing the A-Series |url= https://www.aronline.co.uk/facts-and-figures/engines/engines-h-and-k-series-prototypes/ |website=www.aronline.co.uk |access-date=12 December 2018 |date=22 July 2017}}</ref><ref name="ateupwithmotor.com">{{cite web |title=Tiny and Triumphant: The Morris / Austin Mini |url= https://ateupwithmotor.com/model-histories/original-mini-history/ |website=www.ateupwithmotor.com |access-date=12 December 2018 |date=1 May 2010}}</ref> This design often results in the engine and transmission sharing the same oil.


Motorcycles such as the [[Honda CB750]] use a similar layout, with the cylinder block and crankcase integrated with part of the transmission.
Many farm [[tractor]] designs have cylinder block, crankcase, transmission and rear axle integrated into a single unit. An early example is the [[Fordson tractor]].
{{clear right}}


Many farm [[tractor]] designs integrate the cylinder block, crankcase, transmission, and rear axle into a single unit. An early example is the [[Fordson]] tractor.
== Block material ==
Engine blocks are normally cast from either a [[cast iron]] or an [[aluminium alloy]]. The aluminium block is much lighter in weight, and has better heat transfer to the coolant, but iron blocks retain some advantages and continue to be used by some manufacturers.


==See also==
==See also==
*[[Core plug]]
*[[Core plug]]
*[[Cylinder head]]
*[[Head gasket]]
*[[Head gasket]]
*[[Long block]]
*[[List of auto parts]]
*[[Automobile engine replacement#Short block|Automobile engine replacement § Short block]]
*[[Short block]]
*[[Automobile engine replacement#Long block|Automobile engine replacement § Long block]]
{{clear right}}


==References==
==References==
{{Reflist|30em}}
{{Reflist|30em}}


{{Automotive engine |collapsed}}
{{Automotive engine |expanded}}


{{DEFAULTSORT:Engine Block}}
{{DEFAULTSORT:Engine Block}}

Revision as of 17:12, 14 May 2024

Block of a modern V6 diesel engine. The large holes are the cylinders, the small round orifices are mounting holes, and the small oval orifices adjacent to the cylinders are coolant or oil ducts.

In an internal combustion engine, the engine block is the structure that contains the cylinders and other components. The engine block in an early automotive engine consisted of just the cylinder block, to which a separate crankcase was attached. Modern engine blocks typically have the crankcase integrated with the cylinder block as a single component. Engine blocks often also include elements such as coolant passages and oil galleries.

The term "cylinder block" is often used interchangeably with "engine block". However, technically, the block of a modern engine (i.e., multiple cylinders integrated with another component) would be classified as a monobloc.

Construction

The main structure of an engine typically consists of the cylinders, coolant passages, oil galleries, crankcase, and cylinder head(s). The first production engines of the 1880s to 1920s usually used separate components for each element, which were bolted together during engine assembly. Modern engines, however, often combine many elements into a single component to reduce production costs.

The evolution from separate components to monobloc engine blocks has gradually progressed since the early 20th century. The integration of elements has relied on the development of foundry and machining techniques. For example, a practical, low-cost V8 engine was not feasible until Ford developed the methods used to build its flathead V8 engine. Other manufacturers then applied those techniques to their engines.

Cylinder block

Cylinder blocks for a straight-6 engine
Wolseley marine engine
Marine engine with cylinders cast in three pairs
Six-cylinder engine
Cylinders cast in two blocks of three
BMW engine block
Cylinders cast in a single block of six, with an integrated crankcase (turbocharger in background)

A cylinder block is a structure that contains the cylinder, plus any cylinder sleeves and coolant passages. In the earliest decades of internal combustion engine development, cylinders were usually cast individually, so cylinder blocks were usually produced separately for each cylinder. Following that, engines began to combine two or three cylinders into a single-cylinder block, with an engine combining several of these cylinder blocks.

In early engines with multiple cylinder banks – such as V6, V8, or flat-6 engines – each bank was typically made of one or multiple separate cylinder blocks. Since the 1930s, mass production methods have developed to allow both banks of cylinders to be integrated into the same cylinder block.

Cylinder liners

Wet liner cylinder blocks use cylinder walls that are entirely removable and fit into the block using special gaskets. They are called "wet liners" because their outer sides come in direct contact with the engine's coolant. In other words, the liner is the entire cylinder wall, rather than merely a sleeve.

The advantages of wet liners are a lower mass, reduced space requirements, and coolant being heated faster from a cold start, reducing start-up fuel consumption and heating the car cabin sooner.

Dry liner cylinder blocks use either the block's material or a discrete liner inserted into the block to form the backbone of the cylinder wall. Additional sleeves are inserted within, which remain "dry" outside, surrounded by the block's material.

For either wet or dry liner designs, the liners (or sleeves) can be replaced, potentially allowing an engine overhaul or rebuild without replacing the block itself. However, there are more practical repair options.

Coolant and oil passages

Crankcase

The crankcase is the structure that houses the crankshaft. As with cylinder blocks, this is primarily an integrated component in modern engines.

Materials

Engine blocks are typically cast from either cast iron or an aluminium alloy. Aluminium blocks are much lighter and transfer heat more effectively to coolant, but iron blocks retain some advantages, such as durability and reduced thermal expansion.

Weight reductions through material selection. Presently, most of the engine blocks in mass production are gray castings. Reducing weight has resulted in using aluminum-silicon alloys more frequently for the engine block in small-displacement engines. Engine blocks of comparable design, but using Al-Si alloys, are not lighter than cast iron engine blocks in the same ratio as that for the specific weights of the materials.

In engine blocks made of gray cast iron, weight can be reduced by optimizing the structure and thin-wall casting. With this casting technique, a wall thickness of as little as about 3 mm is generally possible. In comparison, the walls of cast iron engine blocks are usually from 4.0 to 5.5 mm thick.

Using vermicular graphite cast iron (GGV), a casting material with great strength, enables weight reductions by about 30% compared to conventional casting materials such as GG 25. Weight reduction, to this extent, requires engineering for the engine block, taking into account the particular needs of the material.[1]

Monoblocs

De Dion-Bouton engine, circa 1905. The cylinder heads are integrated into the engine block, but the crankcase is separate.[2]
Typical 1930-1960 flathead engine with integrated crankcase. The cylinder head is tipped upwards for illustrative purposes.

An engine where all the cylinders share a common block is called a monobloc engine. Most modern engines use a monobloc design, and few have a separate block for each cylinder. This has led to the term "engine block," which usually implies a monobloc design, with "monobloc" rarely used.

In the early years of the internal combustion engine, casting technology couldn't produce large castings with complex internal cores (for water jackets etc). Most early engines, particularly those with more than four cylinders, had their cylinders cast as pairs or triplets of cylinders, then bolted to a separate crankcase.

As casting techniques improved, an entire cylinder block of 4, 6, or 8 cylinders could be produced in one piece. This monobloc construction was more straightforward and more cost-effective to produce. All the cylinders and crankcase could be made in a single component for straight engine cylinder layouts. One of the early engines produced using this method is the 4-cylinder engine in the Ford Model T, introduced in 1908. The technique spread to straight-six engines and was commonly used by the mid-1920s.

Up until the 1930s, most V engines retained a separate block casting for each cylinder bank, with both bolted onto a common crankcase (itself a separate casting). For economy, some engines were designed to use identical castings for each bank, left and right.[3]: 120  A rare exception was the Lancia 22½° narrow-angle V12 of 1919, which used a single block casting combining both banks.[3]: 50–53  The Ford flathead V8 – introduced in 1932 – represented a significant development in the production of affordable V engines. It was the first V8 engine with a single-engine block casting, putting a V8 into an affordable car for the first time.[4]

The communal water jacket of monobloc designs permitted closer spacing between cylinders. The monobloc design approach also improved engines' torsional rigidity as cylinder numbers, engine lengths, and power ratings increased.

Integrated cylinder block and crankcase

Most engine blocks today, except some unusual V or radial engines and large marine engines, use a monobloc design with one block for all cylinders plus an integrated crankcase. In such cases, the skirts of the cylinder banks form a crankcase area of sorts, which is still often called a crankcase despite no longer being a discrete part.

Using steel cylinder liners and bearing shells minimizes the effect of the relative softness of aluminium. Some engine designs use plasma transferred wire arc thermal spraying, instead of cylinder sleeves, to further reduce weight. These types of engines can also be made of compacted graphite iron, such as in some diesel engines.[5]

Integrated cylinder block and head

Integrated cylinder head engines
DB 605 V12 aircraft engine
Honda GX 160 engine in a ride-on lawnmower

Some modern consumer-grade small engines use a monobloc design where the cylinder head, block, and half of the crankcase share the same casting. Apart from cost, one reason for this is to produce an overall lower engine height.[citation needed] The primary disadvantage can be that repairs become more time-consuming and impractical.

An example of engines with integrated cylinder heads are the Honda GC-series and GXV-series engines, which are sometimes called "Uniblock" by Honda.[6]

Integrated crankcase and transmission

Several cars with transverse engines have used an engine block consisting of an integrated transmission and crankcase. Cars that have used this arrangement include the 1966-1973 Lamborghini Miura[7] and cars using the BMC A-series and E-series engines.[8][9] This design often results in the engine and transmission sharing the same oil.

Motorcycles such as the Honda CB750 use a similar layout, with the cylinder block and crankcase integrated with part of the transmission.

Many farm tractor designs integrate the cylinder block, crankcase, transmission, and rear axle into a single unit. An early example is the Fordson tractor.

See also

References

  1. ^ "Minimizing Engine Block Mass". studedu.org. Retrieved 2024-05-14.
  2. ^ Kennedy, Rankin (1912). The De Dion-Bouton Engine and Cars. The Book of Modern Engines and Power Generators. London: Caxton. pp. 78–89.
  3. ^ a b Ludvigsen, Karl (2005). The V12 Engine. Haynes Publishing. ISBN 1-84425-004-0.
  4. ^ Sorensen, Charles E.; Williamson, Samuel T. (1956). My Forty Years with Ford. New York: Norton. pp. 225–231. ISBN 9780814332795.
  5. ^ Brooks, Robert (January 25, 2012). "Navistar Now Producing Engine Blocks, Heads in CGI". Foundry Management & Technology. Retrieved May 2, 2017.
  6. ^ "Honda General Purpose Engines: GC Series - Single Cylinder". Archived from the original on 2010-11-27. Includes sectioned drawings
  7. ^ "Lamborghini Miura SV (1971)". www.netcarshow.com. Retrieved 12 December 2018.
  8. ^ "H and K-Series prototypes: BL's first attempt at replacing the A-Series". www.aronline.co.uk. 22 July 2017. Retrieved 12 December 2018.
  9. ^ "Tiny and Triumphant: The Morris / Austin Mini". www.ateupwithmotor.com. 1 May 2010. Retrieved 12 December 2018.