| V8 engine | |
|---|---|
.jpg) A 331 series V8 from the 1950s | |
| Overview | |
| Manufacturer | Cadillac (General Motors) |
| Also called | Type 51, Monobloc, LaSalle, Northstar, Blackwing |
| Production | 1914–present |
| Layout | |
| Configuration | 90°V8 |
| Displacement |
|
| Cylinder bore |
|
| Piston stroke |
|
| Cylinder block material | Cast iron Aluminium |
| Cylinder head material | Cast iron Aluminium |
| Valvetrain |
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| Compression ratio | 8.5:1, 10.0:1, 10.5:1 |
| Combustion | |
| Supercharger | Withintercooler (in 4.4 L and 6.2 L LSA engines) |
| Turbocharger | Twin-turbo (in 4.2 L engine) |
| Fuel system | |
| Fuel type | Gasoline |
| Cooling system | Water-cooled |
| Output | |
| Power output | 70–550 hp (52–410 kW) |
| Torque output | 265–640 lb⋅ft (359–868 N⋅m) |
| Dimensions | |
| Dry weight | 595 lb (270 kg) |
The termCadillac V8 may refer to any of a number ofV8 engines produced by theCadillac division ofGeneral Motors since it pioneered the first such mass-produced engine in 1914.[1]
Most commonly, such a reference is to one of the manufacturer's most successful, best known, or longest-lived 90° V8 engine series. These include the pioneeringoverhead valve331 cu in (5.4 L) cu in introduced in 1949, made in three displacements up to 390 cu in (6.4 L); a390 cu in (6.4 L) introduced in 1963 that grew to429 cu in (7.0 L); and a472 cu in (7.7 L) introduced in 1968 and enlarged to 500 cu in (8.2 L). Also notable was theNorthstar, which debuted in 1992 as a 4.6 litre, and was also produced in 4.4 L and 4.2 L versions.
When theNorthstar engine series ended production in 2010, it became the lastGeneral Motors division to retain its own proprietary V8 design. This changed when Cadillac created the twin-turbo "Blackwing" engine in 2019.
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TheType 51 was the first Cadillac V8. Introduced in 1914, it was the standard engine for 1915 Cadillac models. It was a 90° design with an L-head (sidevalve) configuration and waswater-cooled. Bore and stroke was 3.125 in × 5.125 in (79.4 mm × 130.2 mm), for a total of 314 cu in (5.1 L) of displacement. Output was 70 hp (52 kW).
This engine was designed under the leadership of Cadillac's chief engineer (1914–1917), Scottish-born D (D'Orsay) McCall White (1880 -), later a vice president of Cadillac.[2] Hired byHenry Leland for his V-engine expertise from his employment as chief engineer atNapier, and previouslyDaimler at Coventry, he was later to move toNash withLaFayette. White was appointed to a committee of three to supervise the development of the V12Liberty aircraft motor, that later contributed to cross town rivalLincoln Motor Company introducing theLincoln L series much later in 1917.[3]
The engine was refined for 1923 with acrossplanecrankshaft that introduced the (now standard) 90° offset for each pair of cylinders which improved balance and smoothness. Power was up to 83.5 hp (62.3 kW).
The L-head was on theWard's 10 Best Engines of the 20th century list.
L-head applications:
Cadillac created a new V8, the341, for 1928. It was a 341 cu in (5.6 L) engine and produced 90 hp (67 kW). The same year saw the introduction of thesynchromesh transmission. This engine was used in the Series 341 and 341B cars of 1928 and 1929.
From 1930 through 1935, Cadillac produced a version with an increased displacement of 353 cu in (5.8 L). This used a 3.38 in × 4.94 in (85.9 mm × 125.5 mm) bore and stroke. This engine was used in the Cadillac Series 353 andSeries 355.
A 322 cu in (5.3 L) "monobloc engine" was used in the 1936Series 60. It was designed to be the company's next-generation powerplant at reduced cost from the 353 andCadillac V12. The monobloc's cylinders and crankcase were cast as a single unit,[4] and it used hydraulic valve lifters for durability. This design allowed the creation of the mid-priced Series 60 line.
Bore and stroke was 3.375 in × 4.5 in (85.7 mm × 114.3 mm). This engine was closely related to a monobloc design earlier introduced in the 1936–1948 346 cu in (5.7 L) engine, which was modified with a 3.5 in (88.9 mm) bore. This was used in theSeries 60/60S/61/62/63/65/67 and70/72/75. It was also used in a dual setup intanks (e.g.M5 Stuart and theM24 Chaffee), inWorld War II mated to aHydramatic transmission.
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In 1937, the newmonoblocflathead gained 24 cu in (390 cc) in Cadillac V-8 models to 346 cu in (5.7 L), while theLaSallestraight-8 of 1934–1936 that originated fromOldsmobile actually was replaced with the 1936 smaller 322 cu in (5.3 L) version at 125 hp (93 kW). In 1941, the LaSalle nameplate was phased out along with the 322 cu in (5.3 L), and Cadillacs, all 346 cu in (5.7 L) powered, were available with the newHydramaticautomatic transmission which debuted in Oldsmobile the previous year. These engines were produced through 1948.
For 1949, Cadillac andOldsmobile each produced their V8 designs (the Oldsmobile engine was the303). Both of the engines wereoverhead valve designs, pioneered by Buick. The Cadillac 331 engine featured a "dry" (coolant exited through an assembly attached directly to the cylinder heads), open runner (requiring the use of a tappet valve cover)intake manifold, rear-mounteddistributor, and shaft-mounted rockers. Crankshaft end play is carried by the rear bearing on the two GM engines. It has the lighter "skirtless" block where the oil pan flange does not descend appreciably below the crankshaft centerline and they both have a partial integral cast iron clutch housing that compares to the earlyChrysler Hemi V8 design. 1955 331 engines went to a lighter "flat back" that bolted to a clutch and flywheel housing at the front of the transmission.
Bore and stroke are3+13⁄16 in × 3+5⁄8 in (96.8 mm × 92.1 mm) for an overall displacement of 331.1 cu in (5.4 L). This engine features an oiling system which uses a central cast-in passage between the lifter galleries feeding oil to the cam and crank by grooves machined into the cam bores. A single drilled passage per bearing saddle feeds both cam and crank journals. Shared with the Oldsmobile Rocket V8 is how the lifters are supplied oil through small "bleeds" instead of placing the lifters directly into the right and left side oil supply galleries. Many early racers would replace the Cadillac hydraulic lifter and rocker assemblies with the solid lifters and adjustable rockers from the Studebaker V8 for operation at higher engine speeds.
Displacement was increased to 365 cu in (6.0 L) for 1956 by increasing the bore to 4 inches (101.6 mm) while maintaining the3+5⁄8 in (92.1 mm) stroke. For the three years that the 365 was made, the base versions had a single four-barrel carburetor. The 1956 version produced 285 horsepower. The 1957 version raised that base engine output to 300 horsepower, while the 1958 base version cranked out 310. Eldorados featured multi-carb engines in all 3 years. The Eldorado engines were also optional on all other Cadillacs. The 1958 Eldorado 3-2bbl version produced 335 hp (250 kW).
A longer,3+7⁄8 in (98.4 mm) stroke pushed displacement to 389.6 cu in (6.4 L) for 1959, yielding 325 hp (242 kW), while the Eldorado Tri-power reached 345 hp (257 kW).
For the 1963 model year, Cadillac redesigned its V8 engine, modernizing the tooling used in the production line while optimizing the engine's design. Although it shared the same layout and architecture with the 1949-vintage engine, the revised engine had shorterconnecting rods and was 1 in (25 mm) lower, 4 in (101.6 mm) narrower, and 1.25 in (32 mm) shorter. The accessories (water pump,power steering pump,distributor) mounted on adie-castaluminum housing at the front of the engine for improved accessibility. Analternator replaced the formergenerator. Thecrankshaft was cored out to make it both lighter and stronger. The revised engine was 52 lb (24 kg) lighter than its predecessor, for a total dry weight of 595 lb (270 kg).
The revised engine shared the same 4 in × 3.875 in (101.6 mm × 98.4 mm) bore and stroke of its predecessor, for an unchanged displacement of 390 cu in (6.4 L). Power was unchanged at 325 hp (242 kW), as was torque at 430 lb⋅ft (583 N⋅m).
For 1964, the engine had a 4.13 in × 4 in (105 mm × 102 mm) bore and stroke, raising displacement to 429 cu in (7.0 L). Power rose to 340 hp (254 kW) and torque to 480 lb⋅ft (651 N⋅m). It also included its firstemission control system, which was apositive crankcase ventilation unit. The 429 was used through the 1967 model year.
Cadillac introduced an all-new engine for 1968. Although the modernized 390 series engine was compact and light for its displacement and output, 429 cu in (7.0 L) represented the limit of the original architecture's expansion, and it had been surpassed byChrysler's440 andLincoln's462 and460. Cadillac went bigger, with provision for even more expansion.
At introduction, the new engine had a 4.3 in × 4.06 in (109.2 mm × 103.1 mm) bore and stroke for a displacement of 472 cu in (7.7 L). "Extensively redesigned" to ease maintenance, it used 10% fewer parts and 25% fewer gasketed joints as before.[5] It delivered 375 hp (280 kW) at 4400 rpm and a massive 525 lb⋅ft (712 N⋅m) torque at just 3000 rpm. The new engine was about 80 lb (36 kg) heavier than its predecessor. It was used through 1974. It was designed with potential for a 500-cubic-inch (8.2 L) displacement.
For 1970, Cadillac fitted a crankshaft with a 4.304 in (109.3 mm) stroke, increasing total displacement on the engine to 500.02 cu in (8.2 L). At its introduction it was rated at 400 hp (298 kW),SAE gross, and 550 lb⋅ft (746 N⋅m) of torque. For 1971, compression was reduced from 10.0:1 to 8.5:1, the lowered compression ratio dropped the 500's gross output from 400 bhp (298 kW) to 365 bhp (272 kW), or 235 hp (175 kW) in the newSAE net ratings. By 1976, its final year, it had fallen to 190 hp (142 kW). However, a newBendixelectronic fuel injection system was offered as an option, and it increased power output to 215 hp (160 kW). The 500 was exclusive to theEldorado until 1975 where the powerplant was standard in all Cadillacs except for the Seville, which was powered by a fuel-injectedOldsmobile 350.
| Year | EngineVIN code | Engine letter code | Displacement | Rated horsepower | Rated torque | Bore x stroke | Compression ratio | Oil pressure |
|---|---|---|---|---|---|---|---|---|
| 1968–1969 | None | None | 472 cu in (7.7 L) | 375 hp (280 kW) at 4400 rpm | 525 lb⋅ft (712 N⋅m) at 3000 rpm | 4.3 in × 4.06 in (109.2 mm × 103.1 mm) | 10.5:1 | 33 psi (2.3 bar) |
| 1970 (SAE gross) | 10.0:1 | 35–40 psi (2.4–2.8 bar) | ||||||
| 500 cu in (8.2 L) | 400 hp (298 kW) at 4400 rpm | 550 lb⋅ft (746 N⋅m) at 3000 rpm | 4.3 in × 4.304 in (109.2 mm × 109.3 mm) | |||||
| 1971 (SAE gross) | R | 61E,Q | 472 cu in (7.7 L) | 345 hp (257 kW) at 4400 rpm | 500 lb⋅ft (678 N⋅m) at 2800 rpm | 4.3 in × 4.06 in (109.2 mm × 103.1 mm) | 8.5:1 | |
| S | 500 cu in (8.2 L) | 365 hp (272 kW) at 4400 rpm | 535 lb⋅ft (725 N⋅m) at 2800 rpm | 4.3 in × 4.304 in (109.2 mm × 109.3 mm) | ||||
| 1972 (SAE net) | R | 62E,Q | 472 cu in (7.7 L) | 220 hp (164 kW) at 4400 rpm | 365 lb⋅ft (495 N⋅m) at 2400 rpm | 4.3 in × 4.06 in (109.2 mm × 103.1 mm) | 35 psi (2.4 bar) | |
| S | 500 cu in (8.2 L) | 235 hp (175 kW) at 4400 rpm | 385 lb⋅ft (522 N⋅m) at 2400 rpm | 4.3 in × 4.304 in (109.2 mm × 109.3 mm) | ||||
| 1973 | R | 63E,Q | 472 cu in (7.7 L) | 220 hp (164 kW) at 4400 rpm | 365 lb⋅ft (495 N⋅m) at 2400 rpm | 4.3 in × 4.06 in (109.2 mm × 103.1 mm) | ||
| S | 500 cu in (8.2 L) | 235 hp (175 kW) at 4400 rpm | 385 lb⋅ft (522 N⋅m) at 2400 rpm | 4.3 in × 4.304 in (109.2 mm × 109.3 mm) | ||||
| 1974 | R | 64E,Q | 472 cu in (7.7 L) | 205 hp (153 kW) at 4400 rpm | 380 lb⋅ft (515 N⋅m) at 2400 rpm | 4.3 in × 4.06 in (109.2 mm × 103.1 mm) | ||
| S | 500 cu in (8.2 L) | 210 hp (157 kW) at 3600 rpm | 380 lb⋅ft (515 N⋅m) at 2000 rpm | 4.3 in × 4.304 in (109.2 mm × 109.3 mm) | ||||
| 1975 | 65E,Q | |||||||
| 1976 | 66E,Q | 190 hp (142 kW) at 3600 rpm | 360 lb⋅ft (488 N⋅m) at 2000 rpm |
Starting in the mid to late 1970s, Cadillac expanded its product range, offering more mid-sized vehicles. For example, while theCadillac Seville initially used a variant of the 350 cu in (5.7 L) Oldsmobile V8, Cadillac also began work on its own proprietary engines.[6][7]
In 1977, Cadillac introduced a new 425 cu in (7.0 L) V8, based on the architecture of the 472, but with a smaller, 4.082 in (103.7 mm) bore and the same 4.06 in (103.1 mm) stroke. The new engine was also 100 lb (45 kg) lighter.
The 425 was offered inL33 form, with a four-barrel carburetor, producing 180 hp (134 kW) at 4000 rpm and 320 lb⋅ft (434 N⋅m) of torque at 2000 rpm, andL35 with electronicmulti-port fuel injection for 195 hp (145 kW) and 320 lb⋅ft (434 N⋅m) of torque, but peaked at 2400 rpm.
The 425 was used through 1979 on all Cadillacs except the Seville and 1979 Eldorados.
In 1980, the 425 was replaced with theL61, which was the same basic 472 family engine de-bored to 3.8 in (97 mm) but retaining the 472 and 425 engines' 4.06 in (103.1 mm) stroke for a total displacement of 368 cu in (6.0 L). The reduction in displacement was largely an effort to meetCAFE requirements forfuel economy.Throttle-body fuel injection was now standard on Eldorado and Seville when equipped with the 368.Rear-wheel-drive cars and the Commercial Chassis for hearse and ambulance builders used theRochesterQuadrajet 4-barrelcarburetor.
Cadillac referred to this new TBI (throttle-body fuel injection) system asDigital Fuel Injection (DFI); this particular induction system was later adopted by other GM divisions, except on Oldsmobile V8s, and was used well into the mid-1990s on GM trucks.
Power output dropped to 145 hp (108 kW) at 3600 rpm and torque to 270 lb⋅ft (366 N⋅m) at 2000 rpm in DEFI forms as used on thefront-wheel-drive Seville and Eldorado but 150 hp (112 kW) on the four-barrel Quadrajet-equipped RWD models. This engine was standard on all Cadillacs except the redesignedSeville, in which it was optional.
For 1981, Cadillac introduced a new engine that would become notorious for its unreliable electronics, theV8-6-4 (L62). The L61 had not provided a significant improvement in the company's CAFE numbers, so Cadillac andEaton Corporation devised acylinder deactivation system called Modulated Displacement that would shut off two or four cylinders in low-load conditions such as highway cruising, then reactivate them when more power was needed. When deactivated,solenoids mounted to those cylinders'rocker arm studs would disengage thefulcrums, allowing the rockers to "float" and leave the valves closed despite the continued action of thepushrods. These engines are easily identified by theirrocker covers, which each have elevated sections over two cylinders with electrical connectors on top. With the valves closed, the cylinders acted as air springs, which both eliminated the feel of "missing" and kept the cylinders warm for instant combustion upon reactivation. Simultaneously, the engine control module would reduce the amount of fuel metered through the TBI unit. On the dashboard, an "MPG Sentinel" digital display could show the number of cylinders in operation, average or currentfuel consumption (in miles per gallon), or estimated range based on the amount of fuel remaining in the tank and the average efficiency since the last reset.[8]
Another rare and advanced feature introduced with DFI was Cadillac's truly "on-board" diagnostics. For mechanics who had to deal with the 368s, the cars contained diagnostics that did not require the use of special external computerscan tools. The new electronic climate control display, along with the MPG Sentinel, provided on-board readout of any stored trouble codes, instantaneous readings from all the various engine sensors, forced cycling of the underhood solenoids and motors, and on the V8-6-4 engines, manual cylinder-pair control. The L62 produced 140 hp (104 kW) at 3800 rpm and 265 lb⋅ft (359 N⋅m) at 1400 rpm. Cadillac hailed the L62 as a technological masterpiece, and made it standard equipment across the whole Cadillac line.
While cylinder deactivation would make a comeback some 20 years later with modern computing power (and using oil pressure to deactivate the valves by collapsing the lifters), Cadillac's 1981 V8-6-4 proved to have insurmountable engineering problems. The main issue was that theengine control module simply lacked the robustness, programming and processing speed to efficiently manage the cylinder-deactivation under all load conditions. In the era before electronically operatedEGR valves, the engineers also made an error in using a back-pressure-type EGR valve. While this early effort to match the vacuum-controlled EGR volume more accurately to the engine's load made sense in a conventional engine, it had the effect of causing pinging (detonation) problems in the V8-6-4 engine, because four cylinders operating under higher load needed more EGR, while they were actually producing less exhaust flow and therefore less back-pressure to operate the valve.
In an effort to increase reliability, Cadillac issued thirteen updatedPROM chips for the ECMs, but many of these engines simply had their Modulated Displacement function disabled by dealers, leaving them with permanent eight-cylinder operation. This was accomplished by merely disconnecting a single wire from the transmission's "3rd-gear switch", or running it through a switch inside the car for manual override. The 368 was dropped from most Cadillac passenger cars after the 1981 model year, although the V8-6-4 remained the standard engine for Fleetwood Limousines and the carbureted 368 remained in the Commercial Chassis through 1984.
The 368 has the distinction of being the last traditional "big-block" cast-iron pushrod V8 engine available in a production car. It lasted through 1984 in the limousines. Rival big blocks, ranging in displacement from 396 to 460 cubic inches, disappeared between 1976 and 1978. RWD models were coupled with the heavy-duty THM400 transmission, the last factory-produced GM passenger car fitted with this transmission.
GM reintroduced an updated fuel management system in 2005, marketed asActive Fuel Management orDisplacement on Demand.
TheOHVCadillac High Technology engine was produced from 1982 to 1995 in displacements of 4.087 L (249.4 cu in), 4.467 L (272.6 cu in), and 4.893 L (298.6 cu in).
Cadillac'sDOHC,four-valve-per-cylinderNorthstar debuted in 1992, which at the time was its most technologically advanced engine.
AlthoughOldsmobile,Pontiac, andBuick have borrowed the Northstar architecture for their V8 (and even V6) engines, it was not until the 2004Pontiac Bonneville that a non-Cadillac used the Northstar name.
The Northstar has been produced in 4.6 L; 278.6 cu in (4,565 cc), 4.4 L; 266.7 cu in (4,371 cc), and 4.0 L; 243.8 cu in (3,995 cc) versions.
The 4.6 L; 278.6 cu in (4,565 cc) 275 hp (205 kW) version was available starting in 1993 on theSeville SLS andEldorado ESC. TheAllanté, the Seville STS, and the Eldorado ETC had the 300 hp (224 kW) version of the Northstar. In 1994, theDeVille Concours received the 270 hp (201 kW) version of this engine. By 1996, the Northstar engine became standard equipment in the front-wheel-drive Cadillac line. The 275 hp (205 kW) engine was in the Seville SLS 1993–2004, Eldorado ESC 1993–2002, Standard Deville 1996–2005, Devile d'elegance 1997–1999, and Deville DHS 2000–2005. The 300 hp (224 kW) version was used in the Seville STS 1993–2004, Eldorado ETC 1996–2002, Deville Concours 1997–1999, and Deville DTS 2000–2005. Its final appearance was in the final generation of the DTS series, produced from 2006 to 2011.
The 275 hp (205 kW) version of the Northstar was also standard equipment in the top GXP trim level of thePontiac Bonneville, produced only in 2004 and 2005. It was also the top engine option available in theBuick Lucerne CXS and a 292 hp (218 kW) NHP (Northstar High Output) version in the Buick Lucerne Super, produced from 2006 through 2011. The Lucerne shared its platform and the Detroit/Hamtramck assembly plant with the final generation of the Cadillac DTS.[9]
The 4.4 L; 266.7 cu in (4,371 cc) versions were all supercharged, exclusive to Cadillac's V-series. The STS-V engine, produces 469 hp (350 kW) and 439 lb⋅ft (595 N⋅m) under the SAE certified rating system.
The 2006 - 2008 XLR-V uses the same supercharged Northstar V8 as the STS-V, though output is down somewhat due to design changes made to accommodate the model's more limited underhood space. For the XLR-V, the SAE certified output is 443 hp (330 kW) and 414 lb⋅ft (561 N⋅m). Thesupercharger and fourintercoolers are built into the intake manifold.
The bores were reduced in size to increase block strength, increasing the safety margin under boost.
The 4.0 L; 243.8 cu in (3,995 cc) is theOldsmobile Aurora variant, never installed in a Cadillac. The Aurora's cylinder heads had lower flow characteristics to match the engine's reduced size. This engine produces 250 hp (186 kW).
The engine in the 1976–1979 Seville was "marketed" as a Cadillac engine and was exclusive to the Cadillac product line, but was in reality produced by the Oldsmobile division. Buyers were able to choose between 350 gasoline and 350 diesel versions. From 1982 to 1985, allrear-wheel-drive Cadillacs (except for the limousines) could be ordered with the 350 cu in (5.7 L)OldsmobileLF9Diesel V8. In fact, for most of its life, the 1980–1985 version of Cadillac's Seville came standard with Oldsmobile's V8 diesel, with the gasoline engine being a no-cost option.
From 1986 to 1990, the rear-wheel-driveCadillac Brougham used a carbureted307 cu in (5.0 L) Oldsmobile V8 (replacing the Cadillac HT-4100). In 1990, a 175 hp (130 kW), fuel-injected small-block 350 cu in (5.7 L)Chevrolet L05 V8 was available for Brougham models equipped with the towing package. In 1991, the Oldsmobile 307 was replaced with a 305 cu in (5.0 L) throttle body fuel-injected small-blockChevrolet L03 V8, which was also found in Chevrolet's Caprice,C/K light trucks, andG-series vans. In 1993, the 180 hp (134 kW) 350 cu in (5.7 L) L05 V8 became standard in the newly-renamedCadillac Fleetwood. In 1994, the L05 was replaced with an iron-headed small-blockChevrolet CorvetteLT1 V8 with 260 hp (194 kW), which the Fleetwood used until discontinued at the end of the 1996 model year.
With the introduction of theEscalade to the Cadillac lineup, the small-blockChevrolet L31 V8 (Vortec 5700) was used, as it was part of the C/K truck line on which the Escalade was based. In 2001, the newly-redesigned 2002 Escalade used the performance version of the 6.0 L Generation III series engine (RPO codeLQ9), although the regular length 2002–2005 Escalade 2WD used the5.3-liter LM7 version of the Generation III series engine. From 2007 to 2014, all Cadillac Escalades were equipped with the Generation IV 6.2L engine, which was also used in the GMC Yukon Denali, while hybrid models used a 6.0-liter version of the Generation IV series engine. Since 2015, gasoline-powered Escalades have used the Generation V 6.2L engine, with the Escalade-V using a supercharged version known as theLT4.
The 2004 and 2005Cadillac CTS-V used the previous-generation Corvette C5's 400 hp (298 kW) 5.7 LLS6 Gen III V8. The 2006 and 2007 CTS-V used the 400 hp (298 kW) 6.0 LLS2 Gen IV V8, similar to that used in the standardCorvette C6. The 2009–2015 CTS-V carried a supercharged 6.2 LLSA variant of the Gen IV V8, producing an SAE-certified 556 hp (415 kW), while the 2016–2019 model carried a supercharged 6.2 LLT4 with 640 hp (477 kW).
The 2022–presentCadillac CT5-V Blackwing carries a supercharged 6.2 LLT4 variant of the Gen V series engine, producing 668 hp (498 kW), the most powerful Cadillac sedan in history.
The 4.2-liter V8 engine (GM RPO codeLTA) is an eight-cylinder,dual overhead cam (DOHC) twin turbo engine produced by General Motors specifically for use in Cadillac luxury vehicles. The engine is the result of a new clean-sheet engine design as well as Cadillac's firsttwin-turbo V8 engine. It first launched with the 2019Cadillac CT6.[10]
From the 1950s through the 1970s, each GM division had its own V8 engine family. Some were shared among other divisions, but each respective design was engineered and developed by its own division:
GM later standardized on the later generations of the Chevrolet design: