Toyota JZ engine: Difference between revisions
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=== 1JZ-GTE === |
=== 1JZ-GTE === |
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[[File:1JZ-GTE_in_a_1991_Toyota_Mark_II_2.5GT_Twin_Turbo.jpg|thumb|250px|1JZ-GTE in a 1991 Toyota Mark II 2.5GT Twin Turbo]] |
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[[File:1JZ-GTE VVT-i engine in 1989 Toyota Cressida.jpg|thumb|250px|Third Generation 1JZ-GTE VVTi transplanted into a 1989 MX83 Toyota Cressida]] |
[[File:1JZ-GTE VVT-i engine in 1989 Toyota Cressida.jpg|thumb|250px|Third Generation 1JZ-GTE VVTi transplanted into a 1989 MX83 Toyota Cressida]] |
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Revision as of 05:33, 15 December 2018
This article needs additional citations for verification. (June 2009) |
Toyota JZ engine | |
---|---|
Overview | |
Manufacturer | Toyota Motor Corporation |
Production | 1990–2007 |
Layout | |
Configuration | Straight-six |
Chronology | |
Predecessor | Toyota M engine |
The Toyota JZ engine family is a series of inline-6 automobile engines. A replacement for the M-series inline-6 engines, the JZ engines were 24-valve DOHC engines. The JZ engine was offered in 2.5- and 3.0-litre versions.
1JZ
The 2,492 cc (2.5 L; 152.1 cu in) 1JZ version was produced from 1990 to 2007 (last sold in the Mark II BLIT Wagon and Crown Athlete). Cylinder bore and stroke was 86 mm × 71.5 mm (3.39 in × 2.81 in).[1]
It was a 24-valve DOHC engine with two belt-driven camshafts.
1JZ-GE
Output for the early non-turbo (1990–1995) 1JZ-GE was 170 PS (125 kW; 168 bhp) at 6000 rpm and 235 N⋅m (173 lb⋅ft) at 4800 rpm.
Later released non-turbo (1995->) 1JZ-GE had output of 200 PS (147 kW; 197 bhp) at 6000 rpm and 251 N⋅m (185 lb⋅ft) at 4000 rpm.
The 2.5-litre 1JZ uses over square bore dimensions 86 mm × 71.5 mm (3.39 in × 2.81 in) and, in naturally aspirated guise, a 10:1 compression ratio.
With the aid of a DOHC, 24-valve head and a dual-stage intake manifold.
Like all JZ-series engines, the early 1JZ-GE is designed for longitudinal mounting and rear-wheel-drive.
All of these models also came with a 4-speed automatic transmission as standard; no manual gearbox option was offered.[1]
1JZ-GTE
The first generation 1JZ-GTE employs twin CT12A turbochargers arranged in parallel and blowing through a side-mount or front mount air-to-air intercooler. With an 8.5:1 static compression ratio, the factory quoted power and torque outputs are 280 PS (206 kW; 276 hp) at 6200 rpm and 363 N⋅m (268 lbf⋅ft) at 4800 rpm. The bore and stroke are the same as for the 1JZ-GE: bore × stroke is 86 mm × 71.5 mm (3.39 in × 2.81 in). Yamaha may have had a hand in the development or production of these engines (possibly the head design), hence the Yamaha badging on certain parts of the engine, such as the cam gear cover. In 1991, the 1JZ-GTE was slotted into the all-new Soarer GT.
The early generation 1JZ-GTEs combined the inherent smoothness of an inline 6-cylinder engine with the revving capacity of its short stroke and early power delivery of its small, ceramic wheeled turbochargers. The ceramic turbine wheels are prone to delamination in the setting of high impeller rpm and local temperature conditions, usually a result of higher boost. The first generation 1JZs were even more prone to turbo failure due to there being a faulty one-way valve on the head, specifically on the intake cam cover causing blow-by gases to go into the intake manifold. On the exhaust side, a decent amount of oil vapor flows into the turbos causing premature wear on the seals. The later second generation engines had this problem fixed and in Japan there was actually a recall in order to repair the first generation engines, though that does not apply to 1JZs imported to other countries. The fix is simple, and involves replacement of the PCV valve (2JZ); all parts are available through Toyota.
The third generation of the 1JZ-GTE was introduced around 1996, still as a 2.5-litre turbo, but with Toyota's BEAMS architecture.[2] This included a reworked head, newly developed continuously variable valve timing mechanism (VVT-i), modified water jackets for improved cylinder cooling and newly developed shims with a titanium nitride coating for reduced cam friction.[3] The turbo setup changed from parallel twin turbo (CT12A x2) to a single turbo (CT15B). The single turbo is in part made more efficient by the use of smaller exhaust ports in the head, this allows the escaping exhaust gasses to have more velocity as they exit the head, which in turn, spools the turbo faster and at lower RPM.The adoption of VVT-i and the improved cylinder cooling allowed the compression ratio to be increased from 8.5:1 to 9.0:1. Even though the official power figures remained at 280 PS (206 kW; 276 hp) at 6200 rpm, torque was increased by 20 N⋅m (15 lbf⋅ft) to 379 N⋅m (280 lbf⋅ft) at 2400 rpm. These improvements resulted in increased engine efficiency that reduced fuel consumption by 10%. The adoption of a much higher efficiency single turbocharger than the twins as well as different manifold and exhaust ports were responsible for most of the 50% torque increase at low engine speeds. This engine was used primarily in Toyota's X chassis cars (Chaser, Mark II, Cresta, Verossa), the Crown Athlete V (JZS170) and in the later JZZ30 Soarer, as the JZA70 Supra was long discontinued by this time.
Applications:
- Toyota Chaser/Cresta/Mark II 2.5GT Twin Turbo (JZX81)
- Toyota Chaser/Cresta/Mark II Tourer V (JZX90, JZX100)
- Toyota Verossa/Mark II iR-V (JZX110)
- Toyota Soarer (JZZ30)
- Toyota Supra MK III (JZA70)
- Toyota Verossa
- Toyota Crown (JZS170)
- Toyota Mark II Blit
1JZ-FSE
In around 2000, Toyota introduced what are probably the least recognised members of the JZ engine family – the FSE direct injection variants. These FSE 1JZ and 2JZ engines are aimed at achieving minimal emissions and fuel consumption together with no loss of performance.
The 2.5-litre 1JZ-FSE employs the same block as the conventional 1JZ-GE; however, the design of the cylinder head is unique. The ‘D4’ FSE employs a relatively narrow angle cylinder head with swirl control valves that serve to improve combustion efficiency. This is necessary to run at extremely lean air-fuel ratios around 20 to 40:1 at certain engine load and revs. Not surprisingly, fuel consumption is reduced by around 20 percent (when tested in the Japanese 10/15 urban mode).
Normal unleaded fuel is enough to cope with the FSE’s 11:1 compression ratio.
The direct injection version of the 1JZ generates 147 kW (200 PS; 197 hp) and 250 N⋅m (184 lb⋅ft) – virtually the same as the conventional VVT-i 1JZ-GE. The 1JZ-FSE is always used with an automatic transmission.
Applications:
2JZ
The 2,997 cc (3.0 L; 182.9 cu in) 2JZ has been produced since 1991 (first released in the 1991 Toyota Aristo). Cylinder bore and stroke was 86 mm × 86 mm (3.39 in × 3.39 in). VVT-i variable valve timing was added later in 1997 for the 1998 model year. This engine is not merely a stroked version of the 1JZ (although they share a common bore size, bore pitch, and general architecture), but has a taller block deck and longer connecting rods to accommodate the 14.5 mm (0.57 in) stroke increase.
2JZ-GE
The 2JZ-GE is a common version. Output is 215–230 PS (158–169 kW; 212–227 bhp) at 5800 to 6000 rpm and 209–220 lb⋅ft (283–298 N⋅m) of torque at 3800 to 4800 rpm.
It uses Sequential Electronic Fuel Injection, has an aluminum head and 4 valves per cylinder, along with a cast-iron cylinder block, with some versions using VVT-i. The VVT-i version also featured DIS in favor of the traditional distributor set-up previously seen on the 2JZ-GE. Despite common misconception it was not a true COP (Coil-On-Plug, also known as Plug-top coil) ignition system instead relying on one coil to fire two cylinders, one of which was by spark plug wire.
Applications:
- Toyota Altezza AS300/Lexus IS300
- Toyota Aristo/Lexus GS300
- Toyota Crown/Toyota Crown Majesta
- Toyota Mark II/Toyota Chaser/Toyota Cresta
- Toyota Origin
- Toyota Progres
- Toyota Soarer / Lexus SC300
- Toyota Supra
2JZ-GTE
The 2JZ-GTE is an inline-layout, six-cylinder, belt-driven dual overhead camshaft, air-intercooled, twin-turbocharged, cast-iron block, aluminium cylinder headed engine designed and manufactured by Toyota Motor Corporation that was produced from 1991 until 2002 in Japan. Development and evolution of the engine was, principally, a response to Nissan's relatively new and then-successful RB26DETT engine[citation needed] which had achieved palpable success in FIA Group A and Group N touring car championships.
For all road car applications, two gearboxes were available for the engine:
- Toyota A340E 4-speed automatic
- Toyota V160 and V161 6-speed manual (jointly developed with Getrag as the Type 233)
The 2JZ-GTE originally powered the Toyota Aristo V (JZS147) in 1991 before becoming Toyota's flagship performance engine in the Toyota Supra RZ (JZA80). Its mechanical basis was the existing 2JZ-GE, but differed in its use of sequential twin turbochargers and an air-to-air side-mounted intercooler. The engine block, crankshaft, and connecting rods of the Supra's 2JZ-GE and 2JZ-GTE are the same, with notable differences being that the 2JZ-GTE has recessed piston tops (giving a lower compression ratio), oil spray nozzles to aid in cooling the pistons and a different head (redesigned inlet/exhaust ports, cams and valves). Toyota's VVT-i variable valve timing technology was added to the engine beginning in September 1997, hence it phased out the original engine. Consequently, maximum torque and horsepower was raised for engines selling in all markets. These later 2JZ-GE VVT-i equipped models (Aristo, Altezza, Mark II) share a different part number for weaker connecting rods.
The addition of twin turbochargers, jointly developed by Toyota with Hitachi, in sequential configuration had raised its commercially cited output from 230 PS (169 kW; 227 hp) to the contemporary industry maximum of 280 PS (206 kW; 276 hp) at 5600 rpm. In its first appearance, torque was advertised as 44.3 kg⋅m (320 lb⋅ft; 434 N⋅m) at 4000 rpm to be later recited as 46 kg⋅m (333 lb⋅ft; 451 N⋅m) with the introduction VVT-i in production year 1997. The mutually agreed, industry-wide output ceiling was enforced by Japan's now-defunct Gentlemen's Agreement exclusively between Japanese automakers selling to the Japanese domestic market. Engine power in the North American and European markets, as documented by Toyota, was increased to 325 PS (239 kW; 321 hp) at 5600 rpm.[4]
The export version of the 2JZ-GTE achieved its higher power output with the use of newer stainless steel turbochargers (ceramic for Japanese models), revised camshafts, and larger injectors (550 cc/min for export, 440 cc/min for Japanese). The mechanical similarities between the Japanese-specification CT20 turbine and export-specification CT12B turbine allow interchangeability of the exhaust-side propeller shaft. Additionally, the export-exclusive CT12B turbine received more durable turbine housings and stainless steel turbine and impeller fins. Multiple variants of the Japanese CT20 turbine exist discretely, which are identified with the B, R, and A part number suffixes (e.g.: CT20A).
2JZ-GTE - 594 lbs w/ Getrag V160 Applications:
- Toyota Aristo 3.0V JZS147 (Japan-only)
- Toyota Aristo V300 JZS161 (Japan-only)
- Toyota Supra RZ/Turbo JZA80
2JZ-FSE
The 3-litre 2JZ-FSE uses the same direct injection principle as the smaller 1JZ-FSE but runs an even higher 11.3:1 compression ratio. This engine matches the conventional VVT-i 2JZ-GE with 162 kW (217 hp; 220 PS) and 294 N⋅m (217 lb⋅ft) of torque. The 2JZ-FSE is always used with an automatic transmission. Weight: 200 kg (440 lb)
Applications:
See also
References
- ^ a b "Toyota JZ Engine Guide". Autospeed.drive.com.au. Archived from the original on 2012-12-30. Retrieved 2012-01-27.
{{cite web}}
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suggested) (help) - ^ "1996 TOYOTA CHASER". YouTube. 2009-02-19. Retrieved 2012-01-27.
- ^ "The Development of a New Turbocharged Engine with an Intelligent Variable Valve Timing System and New High Efficiency Turbocharger". 3sgte.com. 1996-06-28. Retrieved 2012-01-27.
- ^ "Toyota 2JZ-GTE Engine". JDM Spec Engines. Retrieved 2013-02-01.