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{{Short description|Hybrid V12 engine}}
{{Short description|Hybrid V12 engine}}
{{Infobox automobile engine
The '''RA''' is a 6.5-litre, [[Naturally-aspirated engine|naturally-aspirated]] [[V12 engine]], commissioned by [[Adrian Newey]], and designed, developed and produced by [[Cosworth]] for the [[Aston Martin Valkyrie]] [[sports car]]. The road-going engine is rated at {{convert|1000|hp|kW PS|0|abbr=on}} at 10,500&nbsp;rpm, with a max torque figure of {{convert|740|Nm|0|abbr=on}} at 7,000&nbsp;rpm, making it the most powerful naturally-aspirated engine ever fitted and used in a production road car.<ref>{{Cite web|url=https://media.astonmartin.com/aston-martin-valkyrie-v12-turns-the-hypercar-engine-up-to-11100/|title = Aston Martin Valkyrie V12 turns the hypercar engine up to 11,100}}</ref> The engine also revs to a maximum of 11,100&nbsp;rpm, and has a [[power density]] making {{convert|{{#expr:746/6.5 round 1}}|kW|PS hp|1|abbr=on|lk=on}} per litre.<ref>{{Cite web|url=https://www.cosworth.com/news/propulsion-news/aston-martin-valkyrie-v12-the-next-generation-in-hypercar-engines/|title = Hypercar Engines: Aston Martin Valkyrie V12|date = 12 December 2018}}</ref>
| name = Cosworth RA
| manufacturer = {{flagicon|UK}} [[Cosworth]]
| production = 2021–present
| configuration = [[V12 engine|V12]], [[naturally aspirated|naturally-aspirated]], 65° cylinder angle
| displacement ={{convert|6499|cc|L|1|order=flip|abbr=on}}
| bore = {{convert|98|mm|2|abbr=on}}
| stroke = {{convert|71.8|mm|2|abbr=on}}
| block = [[Aluminum]] alloy
| head = [[Aluminum]] alloy
| valvetrain = 48-valve, [[DOHC]], four-valves per cylinder
| power = {{convert|1000|hp|kW|0|lk=on|abbr=on}} at 10,500 rpm
| torque = {{convert|546|lb.ft|N.m|0|lk=on|abbr=on}} at 7,000 rpm
| compression =
| fuelsystem = [[Manifold injection|Port injection]]
| oilsystem = [[Dry sump]]
| coolingsystem = [[Water-cooled engine|water-cooled]] – twin-[[aluminium]] front [[radiator]]s
| weight = {{convert|206|kg|lb|1|abbr=on}}
}}
{{Use dmy dates|date=April 2022}}
The '''RA''' is a 6.5-litre, [[Naturally-aspirated engine|naturally-aspirated]] [[V12 engine]], commissioned by [[Adrian Newey]], and designed, developed and produced by [[Cosworth]] for the [[Aston Martin Valkyrie]] [[sports car]]. The road-going engine is rated at {{convert|1000|hp|kW PS|0|abbr=on}} at 10,500&nbsp;rpm, with a max torque figure of {{convert|740|Nm|0|abbr=on}} at 7,000&nbsp;rpm, making it the most powerful naturally-aspirated engine ever fitted and used in a production road car.<ref>{{Cite web|url=https://media.astonmartin.com/aston-martin-valkyrie-v12-turns-the-hypercar-engine-up-to-11100/|title = Aston Martin Valkyrie V12 turns the hypercar engine up to 11,100}}</ref> The engine also revs to a maximum of 11,100&nbsp;rpm, and has a [[power density]] making {{convert|{{#expr:746/6.5 round 1}}|kW|PS hp|1|abbr=on|lk=on}} per litre.<ref>{{Cite web|url = https://www.cosworth.com/news/propulsion-news/aston-martin-valkyrie-v12-the-next-generation-in-hypercar-engines/|title = Hypercar Engines: Aston Martin Valkyrie V12|date = 12 December 2018|access-date = 5 October 2021|archive-date = 7 December 2021|archive-url = https://web.archive.org/web/20211207160933/https://www.cosworth.com/news/propulsion-news/aston-martin-valkyrie-v12-the-next-generation-in-hypercar-engines/|url-status = dead}}</ref>


==Background and development==
==Background and development==
[[Aston Martin]] and [[Red Bull Racing#Red Bull Advanced Technologies|Red Bull Advanced Technologies]] teamed up to blueprint an all-new hypercar, and needed to rely on a technological partner able to challenge the norm, and redefine parameters while performing against an incredible brief. According to Cosworth, it is intended to be "evoking the spine-tingling, ultra-high-revving F1 engines of the 1990s, but benefitting from two decades of progress in design, material and manufacturing expertise." Red Bull’s Chief Technical Officer, Adrian Newey, specially delivered his brief to Cosworth, with the aim being to build the ultimate internal combustion engine. Cosworth's aim was to create the most powerful naturally-aspirated road engine ever, while meeting strict and often conflicting requirements in terms of durability, weight, emissions regulations.
{{See|Nissan GT-R LM Nismo}}
[[Aston Martin]] and [[Red Bull Racing#Red Bull Advanced Technologies|Red Bull Advanced Technologies]] teamed up to blueprint an all-new hypercar, and needed to rely on a technological partner able to challenge the norm, and redefining parameters while performing against an incredible brief. According to Cosworth, it is intended to be "evoking the spine-tingling, ultra-high-revving F1 engines of the 1990s, but benefitting from two decades of progress in design, material and manufacturing expertise." Red Bull’s Chief Technical Officer, Adrian Newey, specially delivered his brief to Cosworth, with the aim being to build the ultimate internal combustion engine. Cosworth's aim was to create the most powerful naturally-aspirated road engine ever, while meeting strict and often conflicting requirements in terms of durability, weight, emissions regulations.


Cosworth initially developed a 1.6-litre [[Inline-three engine|three-cylinder]] prototype (one-fourth of the Valkyrie's V12 engine) to make the combustion system hardware. The engine ran on Cosworth dynos within the first four months of beginning the project, so once the first V12 was tested after 14 months, it was already well along the development route.
Cosworth initially developed a 1.6-litre [[Inline-three engine|three-cylinder]] prototype (one-fourth of the Valkyrie's V12 engine) to make the combustion system hardware, which on its own was good for {{convert|250|hp|kW PS|abbr=on|0}}. The engine ran on Cosworth dynamometers within the first four months of beginning the project, so once the first V12 was tested after 14 months, it was already well along the development route.
Every part of the engine was devised for minimum weight, with [[titanium]] [[connecting rod]]s and F1-style [[piston]]s being used. The engine was also subjected to reliability and durability tests, comparable to those used on Cosworth's mass production units, typically 200 hours of hard running that equated to around 100,000 km (62,000 mi.) of road use. The product is an engine weighing only {{convert|206|kg|lb|0|abbr=on}}. For comparison, Cosworth’s last 3.0-litre [[V10 engine|V10]] [[Formula One engine]] in 2005 weighed 97 kg. If that V10 F1 race engine was scaled up to 6.5 litres, it would have weighed {{convert|210|kg|lb|0|abbr=on}}.
Every part of the engine was devised for minimum weight, with [[titanium]] [[connecting rod]]s and F1-style [[piston]]s being used. The engine was also subjected to reliability and durability tests, comparable to those used on Cosworth's mass production units, typically 200 hours of hard running that equated to around 100,000&nbsp;km (62,000&nbsp;mi.) of road use. The product is an engine weighing only {{convert|206|kg|lb|0|abbr=on}}. For comparison, Cosworth’s last 3.0-litre [[V10 engine|V10]] [[Formula One engine]], the ''[[Cosworth TJ / CA engine|TJ2005]]'', weighed {{convert|97|kg|lb|0|abbr=on}} in 2005. If that V10 F1 race engine was scaled up to 6.5 litres, it would have weighed {{convert|210|kg|lb|0|abbr=on}}.


Over 1,300 individual parts were manufactured for the Valkyrie's engine, with a total of 5,000 components making up the total product. Cosworth constructs all major components for every engine at their headquarters, including cylinder heads, cylinder block, [[camshaft]]s, [[crankshaft]]s, and [[piston]]s. Each engine is manufactured by a team of skilled technicians before being contoured to one of our ten dynamometer cells to execute a break-in and pass-off test. The cylinder block uses Cosworth's plasma bore coating procedure, in which a piece of iron, marginally thicker than a human hair, is sprayed on the surface of the aluminium cylinder bore. This layer assists in reducing abrasion and improving the heat dissipation from the cylinder. The technology is in its early beginnings for road cars, but Cosworth has been using it for more than a decade on racing engines. Besides major castings, including the [[Engine block|block]], cylinder heads, [[Oil pan|oil sump]] and structural cam covers, most of the engine’s internal parts are constructed from solid material; including titanium conrods and F1-spec pistons. Not only does this authorise the utilisation of materials with ideal properties, but the intricate manufacturing procedure means better consistency and parts designed for minimal mass and maximal strength.
Over 1,300 individual parts were manufactured for the Valkyrie's engine, with a total of 5,000 components making up the total product. Cosworth constructs all major components for every engine at their headquarters, including cylinder heads, cylinder block, [[camshaft]]s, [[crankshaft]]s, and [[piston]]s. Each engine is manufactured by a team of skilled technicians before being contoured to one of our ten dynamometer cells to execute a break-in and pass-off test. The cylinder block uses Cosworth's plasma bore coating procedure, in which a piece of iron, marginally thicker than a human hair, is sprayed on the surface of the aluminium cylinder bore. This layer assists in reducing abrasion and improving the heat dissipation from the cylinder. The technology is in its early beginnings for road cars, but Cosworth has been using it for more than a decade on racing engines. Besides major castings, including the [[Engine block|block]], cylinder heads, [[Oil pan|oil sump]] and structural cam covers, most of the engine’s internal parts are constructed from solid material; including titanium conrods and F1-spec pistons. Not only does this authorise the utilisation of materials with ideal properties, but the intricate manufacturing procedure means better consistency and parts designed for minimal mass and maximal strength.


Cosworth's focus on continual optimisation is apparent with the billet-manufactured crankshaft. Beginning life as a solid steel bar; 170 mm (6.7 in.) diameter and 775 mm (30.5 in.) long, it is first roughed-out, finish-machined, heat-treated, gear-ground, plasma-nitrided, final-ground, and super-finished. From start to finish, 80% of the initial bar was machined away, leaving a crankshaft that’s half the weight of that utilised in the [[Aston Martin One-77]]’s engine.
Cosworth's focus on continual optimisation is apparent with the billet-manufactured crankshaft. Beginning life as a solid steel bar; 170&nbsp;mm (6.7 in.) diameter and 775&nbsp;mm (30.5 in.) long, it is first roughed-out, finish-machined, heat-treated, gear-ground, plasma-nitrided, final-ground, and super-finished. From start to finish, 80% of the initial bar was machined away, leaving a crankshaft that’s half the weight of that utilised in the [[Aston Martin One-77]]’s engine.


With a [[Kinetic energy recovery system|KERS]]-style boost system akin to those fitted to F1 cars, the Aston Martin Valkyrie’s [[Hybrid vehicle drivetrain|hybrid system]] has been developed by two main technical partners; Integral Powertrain Ltd, who supplied the bespoke [[electric motor]], and [[Rimac Automobili|Rimac]] for the lightweight hybrid [[Electric battery|battery system]].<ref>{{Cite web|url=https://media.astonmartin.com/aston-martin-valkyrie-the-ultimate-hybrid-powertrain-for-the-ultimate-hypercar/|title=ASTON MARTIN VALKYRIE - THE ULTIMATE HYBRID POWERTRAIN FOR THE ULTIMATE HYPERCAR|website=media.astonmartin.com}}</ref><ref>{{Cite web|url=https://integralp.com/communication/aston-martin-valkyrie-the-ultimate-hybrid-powertrain-for-the-ultimate-hypercar/|title=Aston Martin Valkyrie - The Ultimate Hybrid Powertrain for the Ultimate Hypercar|date=March 1, 2019}}</ref>
With a [[Kinetic energy recovery system|KERS]]-style boost system akin to those fitted to F1 cars, the Aston Martin Valkyrie’s [[Hybrid vehicle drivetrain|hybrid system]] has been developed by two main technical partners; Integral Powertrain Ltd, who supplied the bespoke [[electric motor]], and [[Rimac Automobili|Rimac]] for the lightweight hybrid [[Electric battery|battery system]].<ref>{{Cite web|url=https://media.astonmartin.com/aston-martin-valkyrie-the-ultimate-hybrid-powertrain-for-the-ultimate-hypercar/|title=ASTON MARTIN VALKYRIE - THE ULTIMATE HYBRID POWERTRAIN FOR THE ULTIMATE HYPERCAR|website=media.astonmartin.com}}</ref><ref>{{Cite web|url=https://integralp.com/communication/aston-martin-valkyrie-the-ultimate-hybrid-powertrain-for-the-ultimate-hypercar/|title=Aston Martin Valkyrie - The Ultimate Hybrid Powertrain for the Ultimate Hypercar|date=March 1, 2019}}</ref>


As a result, the full hybrid system contributes an additional 160 bhp of power and a further 280 N⋅m of available torque with the certified max power output of Aston Martin Valkyrie standing at {{convert|1,160|hp|kW PS|abbr=on|0}} @ 10,500 rpm. Equally, with the full hybrid system, peak [[torque]] will stand at {{convert|900|Nm|lbft|abbr=on|0}} @ 6,000 rpm.
As a result, the full hybrid system contributes an additional 160&nbsp;bhp of power and a further 280 N⋅m of available torque with the certified max power output of Aston Martin Valkyrie standing at {{convert|1,160|hp|kW PS|abbr=on|0}} @ 10,500 rpm. Equally, with the full hybrid system, peak [[torque]] will stand at {{convert|900|Nm|lbft|abbr=on|0}} @ 6,000 rpm.


==Variants==
==Variants==
Line 25: Line 44:
==References==
==References==
{{Reflist}}
{{Reflist}}
==External links==


[[Category:Aston Martin]]
[[Category:Aston Martin]]

Latest revision as of 00:34, 10 November 2024

Cosworth RA
Overview
ManufacturerUnited Kingdom Cosworth
Production2021–present
Layout
ConfigurationV12, naturally-aspirated, 65° cylinder angle
Displacement6.5 L (6,499 cc)
Cylinder bore98 mm (3.86 in)
Piston stroke71.8 mm (2.83 in)
Cylinder block materialAluminum alloy
Cylinder head materialAluminum alloy
Valvetrain48-valve, DOHC, four-valves per cylinder
Combustion
Fuel systemPort injection
Oil systemDry sump
Cooling systemwater-cooled – twin-aluminium front radiators
Output
Power output1,000 hp (746 kW) at 10,500 rpm
Torque output546 lb⋅ft (740 N⋅m) at 7,000 rpm
Dimensions
Dry weight206 kg (454.2 lb)

The RA is a 6.5-litre, naturally-aspirated V12 engine, commissioned by Adrian Newey, and designed, developed and produced by Cosworth for the Aston Martin Valkyrie sports car. The road-going engine is rated at 1,000 hp (746 kW; 1,014 PS) at 10,500 rpm, with a max torque figure of 740 N⋅m (546 lbf⋅ft) at 7,000 rpm, making it the most powerful naturally-aspirated engine ever fitted and used in a production road car.[1] The engine also revs to a maximum of 11,100 rpm, and has a power density making 114.8 kW (156.1 PS; 153.9 hp) per litre.[2]

Background and development

[edit]

Aston Martin and Red Bull Advanced Technologies teamed up to blueprint an all-new hypercar, and needed to rely on a technological partner able to challenge the norm, and redefine parameters while performing against an incredible brief. According to Cosworth, it is intended to be "evoking the spine-tingling, ultra-high-revving F1 engines of the 1990s, but benefitting from two decades of progress in design, material and manufacturing expertise." Red Bull’s Chief Technical Officer, Adrian Newey, specially delivered his brief to Cosworth, with the aim being to build the ultimate internal combustion engine. Cosworth's aim was to create the most powerful naturally-aspirated road engine ever, while meeting strict and often conflicting requirements in terms of durability, weight, emissions regulations.

Cosworth initially developed a 1.6-litre three-cylinder prototype (one-fourth of the Valkyrie's V12 engine) to make the combustion system hardware, which on its own was good for 250 hp (186 kW; 253 PS). The engine ran on Cosworth dynamometers within the first four months of beginning the project, so once the first V12 was tested after 14 months, it was already well along the development route. Every part of the engine was devised for minimum weight, with titanium connecting rods and F1-style pistons being used. The engine was also subjected to reliability and durability tests, comparable to those used on Cosworth's mass production units, typically 200 hours of hard running that equated to around 100,000 km (62,000 mi.) of road use. The product is an engine weighing only 206 kg (454 lb). For comparison, Cosworth’s last 3.0-litre V10 Formula One engine, the TJ2005, weighed 97 kg (214 lb) in 2005. If that V10 F1 race engine was scaled up to 6.5 litres, it would have weighed 210 kg (463 lb).

Over 1,300 individual parts were manufactured for the Valkyrie's engine, with a total of 5,000 components making up the total product. Cosworth constructs all major components for every engine at their headquarters, including cylinder heads, cylinder block, camshafts, crankshafts, and pistons. Each engine is manufactured by a team of skilled technicians before being contoured to one of our ten dynamometer cells to execute a break-in and pass-off test. The cylinder block uses Cosworth's plasma bore coating procedure, in which a piece of iron, marginally thicker than a human hair, is sprayed on the surface of the aluminium cylinder bore. This layer assists in reducing abrasion and improving the heat dissipation from the cylinder. The technology is in its early beginnings for road cars, but Cosworth has been using it for more than a decade on racing engines. Besides major castings, including the block, cylinder heads, oil sump and structural cam covers, most of the engine’s internal parts are constructed from solid material; including titanium conrods and F1-spec pistons. Not only does this authorise the utilisation of materials with ideal properties, but the intricate manufacturing procedure means better consistency and parts designed for minimal mass and maximal strength.

Cosworth's focus on continual optimisation is apparent with the billet-manufactured crankshaft. Beginning life as a solid steel bar; 170 mm (6.7 in.) diameter and 775 mm (30.5 in.) long, it is first roughed-out, finish-machined, heat-treated, gear-ground, plasma-nitrided, final-ground, and super-finished. From start to finish, 80% of the initial bar was machined away, leaving a crankshaft that’s half the weight of that utilised in the Aston Martin One-77’s engine.

With a KERS-style boost system akin to those fitted to F1 cars, the Aston Martin Valkyrie’s hybrid system has been developed by two main technical partners; Integral Powertrain Ltd, who supplied the bespoke electric motor, and Rimac for the lightweight hybrid battery system.[3][4]

As a result, the full hybrid system contributes an additional 160 bhp of power and a further 280 N⋅m of available torque with the certified max power output of Aston Martin Valkyrie standing at 1,160 hp (865 kW; 1,176 PS) @ 10,500 rpm. Equally, with the full hybrid system, peak torque will stand at 900 N⋅m (664 lb⋅ft) @ 6,000 rpm.

Variants

[edit]

A more powerful, track-only, racing version of the RA engine will also be produced, and is set to be used in a racing-focused variant of the Valkyrie, called the Valkyrie AMR Pro. The AMR Pro uses the same 6.5-litre naturally-aspirated V12 engine as used in the Valkyrie road car, but this time without the KERS system. The engine will also be modified, which means the AMR Pro will have up to 1,100 (est. 1,160-1,300) horsepower; more than its standard road-legal counterpart.

Applications

[edit]

References

[edit]
  1. ^ "Aston Martin Valkyrie V12 turns the hypercar engine up to 11,100".
  2. ^ "Hypercar Engines: Aston Martin Valkyrie V12". 12 December 2018. Archived from the original on 7 December 2021. Retrieved 5 October 2021.
  3. ^ "ASTON MARTIN VALKYRIE - THE ULTIMATE HYBRID POWERTRAIN FOR THE ULTIMATE HYPERCAR". media.astonmartin.com.
  4. ^ "Aston Martin Valkyrie - The Ultimate Hybrid Powertrain for the Ultimate Hypercar". 1 March 2019.