| Toyota S engine | |
|---|---|
 3S-GE engine in a Toyota Altezza | |
| Overview | |
| Manufacturer | Toyota Motor Corporation |
| Production | 1980–2007 |
| Layout | |
| Configuration | Inline-four engine |
| Chronology | |
| Successor | Toyota AZ engine Toyota AR engine |
The Toyota S Series engines are a family of straight-four petrol (or CNG) engines with displacements between 1.8 and 2.2 litres, produced by Toyota Motor Corporation from January 1980 to August 2007. The S series has cast iron engine blocks and aluminium cylinder heads.
| Code | Years | Bore | Stroke | Compr. | Displ. | Power | Torque | Notes |
|---|---|---|---|---|---|---|---|---|
| 1S [1] | 1982–1988 | 80.5 mm | 90.0 mm | 9:1 | 1,832 cc | 90 PS (66 kW; 89 hp) at 5,200/5,400 rpm | 142 N⋅m (105 lbf⋅ft) at 3,400 rpm | Camry (SV10 export) |
| 1S-L [2] | Unknown | 80.5 mm | 90.0 mm | 9:1 | 1,832 cc | 68 kW (92 PS; 91 hp) at 5,200 rpm | 142 N⋅m (105 lbf⋅ft) at 3,400 rpm | Corona (ST150) (New Zealand, Latin America) |
| 1S-U 1S-LU | 1982–1986 | 80.5 mm | 90.0 mm | 9:1 | 1,832 cc | 100 PS (74 kW; 99 hp) at 5,400 rpm | 152 N⋅m (112 lbf⋅ft) at 3,400 rpm |
|
| 1S-iLU [3] | 1983–1986 | 80.5 mm | 90.0 mm | 9:1 | 1,832 cc | 105 PS (77 kW; 104 hp) at 5,400 rpm | 157–160 N⋅m (116–118 lbf⋅ft) at 2,800-3,000 rpm | |
| 1S-iL | 1986 | 80.5 mm | 90.0 mm | 9:1 | 1,832 cc | 90 PS (66 kW; 89 hp) at 5,200 rpm | 142 N⋅m (105 lbf⋅ft) at 3,400 rpm | EU |
| 1S-E | 1984–1987 | 80.5 mm | 90.0 mm | Unknown | 1,832 cc | Unknown | Unknown | Cressida/MKII/Chaser (SX60) |
| 1S-ELU [3] | 1983–1986 | 80.5 mm | 90.0 mm | 9:1 | 1,832 cc | 115 PS (85 kW; 113 hp) at 5,400 rpm | 164 N⋅m (121 lbf⋅ft) at 4,000 rpm | Corona FF (ST150) |
| 1S-EL | 1986 | 80.5 mm | 90.0 mm | 9:1 | 1,832 cc | 100 PS (74 kW; 99 hp) at 5,200 rpm | 154 N⋅m (114 lbf⋅ft) at 4,000 rpm | EU |
| 2S | 1984–??? | 84.0 mm | 90.0 mm | Unknown | 1,995 cc | Unknown | Unknown | |
| 2S-C | 1983–1986 | 84.0 mm | 90.0 mm | 8.7:1 | 1,995 cc | 73 kW (99 PS; 98 hp) at 5,200 rpm | 157 N⋅m (116 lbf⋅ft) at 3,200 rpm | Corona (ST141) (Australia) Celica (SA6x) (not US) |
| 2S-E | 1982–1987 | 84.0 mm | 90.0 mm | 8.7:1 | 1,995 cc | 92 hp (69 kW; 93 PS) at 4,200 rpm | 153 N⋅m (113 lbf⋅ft) at 2,400 rpm | |
| 2S-E | 1986 | 84.0 mm | 90.0 mm | 8.7:1 | 1,995 cc | 97 hp (72 kW; 98 PS) | Unknown | US (but not Canadian) Camrys; The extra power is related to new timing, which is now electronically controlled. |
| 2S-E | 1986 | 84.0 mm | 90.0 mm | 9:1 | 1,995 cc | 107 PS (79 kW; 106 hp) | Unknown | Carina II ST151 |
| 2S-ELU | 1986 | 84.0 mm | 90.0 mm | 8.7:1 | 1,995 cc | 120 PS (88 kW; 118 hp) at 5,400 rpm | 173 N⋅m (128 lbf⋅ft) at 4,000 rpm | Camry/Vista (SV10) |
| 2S-EL | 1984–1986 | 84.0 mm | 90.0 mm | 9:1 | 1,995 cc | 107 PS (79 kW; 106 hp) at 5,200 rpm | 166–173 N⋅m (122–128 lbf⋅ft) at 4,000 rpm | Camry (SV11), EU Toyota Corona (ST151), NZ |
| 2S-ELU | 1986 | 84.0 mm | 90.0 mm | 9:1 | 1,995 cc | 98 hp (73 kW; 99 PS) at 5,400 rpm | 160 N⋅m (120 lbf⋅ft) at 4,000 rpm | US |
| 2S-E | 1986 | 84.0 mm | 90.0 mm | 8.7:1 | 1,995 cc | 100 PS (74 kW; 99 hp) at 5,400 rpm | 161 N⋅m (119 lbf⋅ft) at 4,000 rpm | Camry SV11 |
| 3S-FC [4] | 1987–1991 | 86.0 mm | 86.0 mm | 9.8:1 | 1,998 cc | 115 PS (85 kW; 113 hp) at 5,600 rpm 82 kW (111 PS; 110 hp) at 5,600 rpm (Aus) | 166 N⋅m (122 lbf⋅ft) at 3,200 rpm | Catalyzed Camry (SV21) Holden Apollo (JK/JL) |
| 3S-FE | 1987–1990 | 86.0 mm | 86.0 mm | 9.8:1 | 1,998 cc | 90 kW (122 PS; 121 hp) at 5,600 rpm | 169 N⋅m (125 lbf⋅ft) at 4,400 rpm | Celica GT (US), Celica ZR (Japan, ST162) |
| 3S-FE | 1987–1994 | 86.0 mm | 86.0 mm | 9.8:1 | 1,998 cc | 115 PS (85 kW; 113 hp) at 5,600 rpm | 162 N⋅m (119 lbf⋅ft) at 4,400 rpm | Equipped with catalytic converter |
| 3S-FE | 1995–1998 | 86.0 mm | 86.0 mm | 9.8:1 | 1,998 cc | 130 PS (96 kW; 128 hp) at 6,000 rpm | 178 N⋅m (131 lbf⋅ft) at 4,400 rpm | Refined valve timing and ECU settings, introduced with Carina E (ST190) model |
| 3S-FE | 1998–2000 | 86.0 mm | 86.0 mm | 9.8:1 | 1,998 cc | 94 kW (128 PS; 126 hp) at 6,000 rpm | 178 N⋅m (131 lbf⋅ft) at 4,400 rpm | Slightly less power with better torque characteristics. Stricter pollution control. Introduced with the new Avensis (ST220) model |
| 3S-FSE | 2001–2003(?) | 86.0 mm | 86.0 mm | 9.8:1 | 1,998 cc | 107 kW (145 PS; 143 hp) at 6,000 rpm | 196 N⋅m (145 lbf⋅ft) at 4,400 rpm | D-4 (Direct injection); Corona Premio G D-4 Package (ST210), [5] Nadia D-4 (SXN10-AHSEH) [6] |
| 3S-GE | 1985–1989 | 86.0 mm | 86.0 mm | 9.2:1 | 1,998 cc | 103 kW (140 PS; 138 hp) at 6,200 rpm | 175 N⋅m (129 lbf⋅ft) at 4,800 rpm | Celica 2.0 GT-i 16, GT-R, GT-S (ST162) |
| 3S-GE | 1989–1993 | 86.0 mm | 86.0 mm | 10.0:1 | 1,998 cc | 115 kW (156 PS; 154 hp) at 6,600 rpm | 186 N⋅m (137 lbf⋅ft) at 4,800 rpm | Celica 2.0 GT-i 16, GT-R (ST182/ST183), MR2 (SW20) |
| 3S-GE | 1994–1998 | 86.0 mm | 86.0 mm | 10.3:1 | 1,998 cc | 132 kW (180 PS; 178 hp) at 7,000 rpm | 192 N⋅m (142 lbf⋅ft) at 4,800 rpm | Celica GT, SS-II (ST202), MR2 (SW20), Curren ZS (ST206) |
| 3S-GE | 1997–1998 | 86.0 mm | 86.0 mm | 11.0:1 | 1,998 cc | 147 kW (200 PS; 197 hp) at 7,000 rpm | 210 N⋅m (155 lbf⋅ft) at 6,000 rpm | Celica (ST202), MR2 (SW20) |
| 3S-GE | 1997–1998 | 86.0 mm | 86.0 mm | 10.5:1 | 1,998 cc | 140 kW (190 PS; 188 hp) at 7,000 rpm | 210 N⋅m (155 lbf⋅ft) at 6,000 rpm | RAV4 (SXA10), Caldina (ST210) |
| 3S-GE | 1997–2005 | 86.0 mm | 86.0 mm | 11.5:1 | 1,998 cc | 156 kW (212 PS; 209 hp) at 7,500 rpm | 220 N⋅m (162 lbf⋅ft) | Altezza, Caldina GT |
| 3S-GT (503E) | 1987–199? | 89.0 mm | 86.0 mm | 7.0:1 | 2,140 cc | 560 PS (412 kW; 552 hp) at 8,500 rpm | 639 N⋅m (471 lb⋅ft) at 5,500 rpm | 87C, 88C, Eagle HF89, Eagle Mk III |
| 503E | 1987–1989 | 89.0 mm | 86.0 mm | 7.0:1 | 2,140 cc | 680 PS (500 kW; 671 hp) at 8,500 rpm | 639 N⋅m (471 lb⋅ft) at 5,500 rpm | 87C, 88C (Le Mans setup with CT26R turbocharger) |
| 503E | 1995–1996 | 89.0 mm | 86.0 mm | 7.0:1 | 2,140 cc | 680 PS (500 kW; 671 hp) at 8,500 rpm | Unknown | Supra GT JZA80 (Le Mans setup, Garrett turbocharger with 55.9 mm restrictor) |
| 503E | 1997 | 86.0 mm | 86.0 mm | 7.0:1 | 1,998 cc | 480 PS (353 kW; 473 hp) at 6,800 rpm | 639 N⋅m (471 lb⋅ft) at 4,500 rpm | Supra GT JZA80 (JGTC setup with 45.3 mm restrictor) |
| 3S-GTE | 1986–1989 | 86.0 mm | 86.0 mm | 8.5:1 | 1,998 cc | 185 PS (136 kW; 182 hp) at 6,000 rpm | 250 N⋅m (184 lbf⋅ft) at 3,600 rpm | Celica GT-Four (ST165) |
| 3S-GTE | 1990–1993 | 86.0 mm | 86.0 mm | 8.8:1 | 1,998 cc | 224 PS (165 kW; 221 hp) at 6,000 rpm | 304 N⋅m (224 lbf⋅ft) at 3,200 rpm | Celica GT-Four (ST185), MR2 (SW20) |
| 3S-GTE | 1994–1999 | 86.0 mm | 86.0 mm | 8.5:1 | 1,998 cc | 245 PS (180 kW; 242 hp) at 6,000 rpm | 304 N⋅m (224 lbf⋅ft) at 4,000 rpm | Celica GT-Four (ST205), MR2 (SW20) |
| 3S-GTE | 1999–2007 | 86.0 mm | 86.0 mm | 9.0:1 | 1,998 cc | 260 PS (191 kW; 256 hp) at 6,200 rpm | 324 N⋅m (239 lbf⋅ft) at 4,400 rpm | Caldina GT-T (ST215w), Caldina GT-Four (ST246w) |
| 4S-Fi | 1987–1991 | 82.5 mm | 86.0 mm | 9.3:1 | 1,838 cc | 105 PS (77 kW; 104 hp) at 5,600 rpm | 149 N⋅m (110 lbf⋅ft) at 2,800 rpm | Single point fuel injection |
| 4S-FE [7] | 1989–1998 | 82.5 mm | 86.0 mm | 9.5:1 | 1,838 cc | 115 PS (85 kW; 113 hp) at 5,600 rpm | 157 N⋅m (116 lbf⋅ft) at 4,400 rpm | Corona (ST170) |
| 4S-FE | 1995–1998 | 82.5 mm | 86.0 mm | 9.5:1 | 1,838 cc | 125 PS (92 kW; 123 hp) at 6,000 rpm | 162 N⋅m (119 lbf⋅ft) at 4,600 rpm | MKII/Chaser (SX80) Vista Etoile (SV30) |
| 5S-FE | 1990–1992 | 87.0 mm | 91.0 mm | 9.5:1 | 2,164 cc | 132 PS (97 kW; 130 hp) at 5,400 rpm | 197 N⋅m (145 lb⋅ft) at 4,400 rpm | Celica ST184 (5th Gen) Australia, MR2 (SW21), Toyota Camry |
| 5S-FE | 1993–2001 | 87.0 mm | 91.0 mm | 9.5:1 | 2,164 cc | 137 PS (101 kW; 135 hp) at 5,400 rpm | 197 N⋅m (145 lb⋅ft) at 4,400 rpm | Celica ST204 (6th Gen) Australia, MR2 (SW21), Toyota Camry |
| 5S-FE | 1997–1999 | 87.0 mm | 91.0 mm | 9.5:1 | 2,164 cc | 135 PS (99 kW; 133 hp) at 5,200 rpm | 199 N⋅m (147 lb⋅ft) at 4,400 rpm | Camry (4th Gen) U.S. spec 1st semester styling |
| 5S-FE | 2000–2001 | 87.0 mm | 91.0 mm | 9.5:1 | 2,164 cc | 138 PS (101 kW; 136 hp) at 5,200 rpm | 203 N⋅m (150 lb⋅ft) at 4,400 rpm | Camry (4th Gen) U.S. spec 2nd semester styling |
The 1.8 L (1,832 cc)1S is the first version of the S-series engine. It is a member of Toyota's Lasre engine family (Lightweight Advanced Super Response Engine). Bore and stroke are 80.5 x 90.0 mm. The engine was first seen in 1981, and was fitted to a wide range of Toyotas, in both RWD and FWD applications.
Original 1S engine, designed for longitudinal, rear-wheel-drive applications. Designated 1S-U with Japanese emissions controls.
Adaption of the 1S engine, designed for transverse, front-wheel-drive applications. Designated 1S-LU with Japanese emissions controls.
Adaption of the 1S-L engine, with added central injection (Ci). Designated 1S-iLU with Japanese emissions controls.
Later versions renamed 1S-i. Sometimes labelled 1S-Ci in marketing material.
Adaption of the 1S-L engine, with added multiport fuel injection. Designated 1S-ELU with Japanese emissions controls.
Later versions renamed 1S-E.
The 2S is a 2.0 L (1,995 cc) four-cylinder engine with an iron block and an alloy head. Bore and stroke are 84.0 x 90.0 mm. [1] This was to be the last of the S engine family not to be equipped with double overhead camshafts.
The 2S (with no extra letters at the end) is carburetted.
The 2S-C is the same as the 2S except it has US emissions controls.
It was used in the Australian delivered SA63 Celica (replacing the 21R-C powered RA60), and ST141 Corona.
The 2S-E is the same as the 2S except it uses EFI. This particular engine was used in the Camry and in the Celica ST161. It was fitted with hydraulic lash adjusters.
The 2S-EL, 2S-ELU and 2S-ELC are the same as the 2S-E except they are transversely mounted (as fitted to the V10 Camry). The 2S-ELU has Japanese emission controls and the 2S-ELC has US emission controls.
The 3S is a 2.0 L (1,998 cc) inline-four engine with an iron block and an alloy head. Similar to the 2S engine, the bore was increased to 86.0 mm and the stroke was reduced to 86.0 mm, [8] allowing for the fitment of larger valves and enabling higher power outputs. [9] First introduced in May 1984, [10] the 3S remained in production until 2007.
Two-barrel carburettor version of the 3S-FE. This engine is found in lower-specification variants of the 1986–1992 Toyota Camry and its Holden Apollo twin (SL and SLX versions). Power is 82 kW (111 PS) at 5,600 rpm, with max torque of 166 N⋅m (122 lb⋅ft) at 3,200 rpm. [4]
The Toyota 3S-FE is a 16-valve 2.0 L twin camshaft, single cam gear engine built by Toyota from 1986 to 2000. European version produces 128 PS (94 kW; 126 hp) at 7,900 rpm and 179 Nm (132 ft-lb) at 4,400 rpm without a catalytic converter; with, maximum power is 121 PS (89 kW; 119 hp). [11] It is commonly used in the Camry 1987–1992 model, the Celica T160/T180/T200, Carina 1987–1992, Carina 1988–2001, Caldina 1992–2002, Carina ED 1985–1998 and Carina E 1993–1998 models, Corona T170/T190 as well as Avensis 1997–2000 models and RAV4, 1994–2000, Picnic/Ipsum 1996–2002 and Comfort 2001–2007. The 3S-FE was also used in some MR2 Mk2 cars due to its torque band being suitable for the automatic models. The 3S-FE is fitted with EFI. The 3S-FE engine is fitted with a cast iron crankshaft, whereas the 3S-GE/GELU engines have forged crankshafts. [10]
The 3S-FSE was a direct injection engine with Toyota D4 system. A cam driven high pressure fuel pump is at the #4 end of the head. This engine was only released in Japan, and installed in the Camry (Windom).
The Toyota 3S-GE (originally titled 3S-GELU in transversely-mounted applications with Japanese emission controls), is an in-line 4 cylinder engine in the S engine family, manufactured by Toyota and designed in conjunction with Yamaha. While the block is iron, the cylinder head is made of aluminium alloy. The pent-roof combustion chambers are complemented by a cross-flow intake and exhaust layout. [10] The spark plug is located in the center of the combustion chamber. The firing order is 1-3-4-2, with cylinder number 1 adjacent to the timing belt. The 3S-GE was designed to be light, the first iteration 3S-GELU weighing in at a low 143 kg (315 lb). [9]
The forged crankshaft, [10] located within the crankcase, rotates on five aluminium alloy bearings and is balanced by eight weights. Oil holes are located in the middle of the crankshaft to provide oil to the connecting rods, bearing, pistons and other moving components. The intake manifold has four independent ports and benefits from inertia build up to improve engine torque at low and medium speeds.
A single timing belt drives the intake and exhaust camshaft. The cam journals are supported on five points between the valve lifters of each cylinder and on the front of the cylinder head, and are lubricated by an oiler port located in the middle of the camshaft.
The pistons are made from an aluminium alloy, designed to withstand high temperatures. An indentation is incorporated into the piston head to prevent the pistons from hitting the valves, should the timing belt break (this is not true of the later BEAMS - an acronym which stands for Breakthrough Engine with Advanced Mechanism System - motors). This is commonly referred to as a "non-interference" engine. Piston pins holding the pistons in place are locked by snap rings. The "Outer Shim Type System" allows for the replacement of the shims without the need to remove the camshaft. To adjust the valve clearance, adjust the shims above the valve lifters.
The first compression ring and the oil ring are made of steel, the second compression ring is made of cast iron. Compression rings 1 and 2 prevent exhaust leakage from the combustion chamber while the oil ring works to clear oil off the cylinder walls, preventing excessive oil from entering the combustion chamber. An oil pan baffle is used to ensure that there is sufficient oil available to the oil pump.
There are five generations of the 3S-GE, which were used in the Toyota Celica, Toyota Corona, MR2, Caldina, RAV4, and Altezza. All 3S-GE engines had a displacement of 2.0 L (1,998 cc). Additionally, the turbocharged 3S-GTE engines are based on the 3S-GE platform.
The first-generation 3S-GE was produced from May 1984 [10] to 1989, arriving in both North American versions, as well as In Japan as a second variation. The North American engine was slightly less powerful, producing around 135 bhp (101 kW). This engine was the only 3S-GE to come to North America, in the Celica GT-S (ST162). Among other things, the Japanese market version sported a more aggressive ECU and lacked the EGR valve system, pushing the output to somewhere around 160 PS (118 kW) at 6,400 rpm and 19.0 kg⋅m (186 N⋅m) of torque. The engine was originally available in particular in the Toyota Camry/Vista Twin Cam 2000 (3S-GELU for V10s, 3S-GE for V20s) [10] and Toyota Corona *T150 (limited chassis version - ST162 with 3S-GELU).
The second generation was produced from 1990 to 1993, receiving a slight boost in output to 165 PS (121 kW) at 6,800 rpm in Japanese specifications, 156 PS (115 kW) at 6,600 rpm in European markets. Peak torque went to 191 N⋅m (141 lb⋅ft) at 4,800 rpm, 186 N⋅m (137 lb⋅ft) in Europe. [12] It also proved to be a slightly more reliable engine. The second generation also did away with the T-VIS system, which was replaced by the ACIS (Acoustic Control Induction System), proving to be much more efficient. T-VIS was, however, retained on the second-generation 3S-GTE, the turbocharged counterpart.
The third-generation 3S-GE was produced from 1994 to 1999. Power output for the Japanese market was increased to 180 PS (132 kW; 178 hp) as the compression ratio was increased to 10.3:1, while motors for other markets received a minor revision in 1996 for emissions (EGR) which reduced power output slightly to 170 PS (125 kW; 168 hp) at 7,000 rpm. Torque remains the same for both at 19.5 kg⋅m (191 N⋅m).
The fourth-generation 3S-GE, also known as the 'Red Top BEAMS' 3S-GE began production in 1997. BEAMS is an acronym which stands for Breakthrough Engine with Advanced Mechanism System. The first version was equipped with VVT-i and produced 200 PS (147 kW; 197 hp) at 7,000 rpm when coupled to a manual transmission. The automatic version produced 190 PS (140 kW; 187 bhp) at 7000 rpm; this is believed to be an ECU restriction implemented by Toyota due to gearbox limitations. It was available in a few models sold only in Japan: the MR2 G and G-Limited and the Celica ST202 SS-II and SS-III.
The second version generation 4 3S-GE, the 'Grey Top BEAMS' 3S-GE, was an available engine option in the RAV4 and second-generation Caldina Active Sports GT in Japan. Even though the valve cover on this engine is black, it is referred to as the "Grey Top", taking its name from the grey intake plenum colouring. This naming is as such to differentiate it from the fifth-generation Dual-VVTi "Black Top" in the Altezza. Power output is 180 PS (132 kW; 178 hp) at 6,600 rpm in the RAV4 and 190 PS (140 kW; 187 hp) in the Caldina GT. The mechanical differences between the Red Top and Grey Top are the exhaust manifold and the ECU. Wiring is identical.
The bottom end is shared with the gen 4 3S-GTE aside from higher compression pistons. Casting provisions exist in the heads for Exhaust VVT solenoid, and RWD water gallery is open, behind the alternator mount. Rear oil drain at the back of the head is in a different position.
Gen 4 also runs a manual throttle body.
This engine was used in some TTE WRC Corollas (modified for Turbo).
In 1998, the fifth and final version of the 3S-GE was released, found only in the Japanese-delivered Altezza RS200. The 'Black Top' as it came to be referred to as, was fitted with a dual VVT-i system that adjusted timing on both intake and exhaust camshafts and came in two different spec levels dependent on which transmission it was coupled to. Compression ratio was raised to 11.5:1 and rods and pistons were lightened for a higher redline.
Gen 5 uses electronic controlled throttle with cable (semi-drive by wire), so no idle speed controller is required. A returnless fuel rail is also used.
The MT version that came equipped with the J160 6-speed manual transmission featured larger diameter titanium intake valves measuring 35mm, larger exhaust valves measuring 29.5mm also made from titanium, a larger 33mm bucket, and stiffer valve springs. It made 210 PS (154 kW; 207 hp) at 7,600 rpm and 22.0 kg⋅m (216 N⋅m) at 6,400 rpm.
Compared to the MT version, the 5-speed AT version came equipped with the A650E 5Super ECT (with manual shift mode) automatic transmission, a less aggressive cam profile, smaller steel-alloy valves and smaller 31mm buckets. This engine made 200 PS (147 kW; 197 hp) at 7,000 rpm and 22.0 kg⋅m (216 N⋅m) at 4,800 rpm. The MT and AT versions produce equal peak torque, however, the AT version achieves this at 4,800 rpm, with the MT version achieving this at 6,400 rpm. Externally, the AT model can be identified by differences in the wiring loom and the lack of an acoustic blanket on the intake plenum.
| 3S-GE Specifications | ||||||
|---|---|---|---|---|---|---|
| Gen 1 | Gen 2 | Gen 3 | Gen 4 | Gen 5 AT | Gen 5 MT | |
| Capacity | 1,998 cc (2.0 L) | |||||
| Bore x Stroke | 86 mm (3.39 in) x 86 mm (3.39 in) | |||||
| Variable Performance Mechanism | T-VIS | ACIS | VVT-i | Dual VVT-i | ||
| Compression Ratio | 9.2:1 | 10:1 | 10.3:1 | 11:1 | 11.5:1 | |
| Valve Material | Steel-Alloy | Titanium | ||||
| Intake Valve Diameter | 33.5 mm (1.32 in) | 34.5 mm (1.36 in) | 34.5 mm (1.36 in) | 35 mm (1.38 in) | ||
| Exhaust Valve Diameter | 29.0 mm (1.14 in) | 29.5 mm (1.16 in) | 29.5 mm (1.16 in) | 29.5 mm (1.16 in) | ||
| Included Valve Angle | 25 ° | 22.5 ° | ||||
The 3S-GTE is an in-line 4-cylinder 1,998 cc (2.0 L; 121.9 cu in) engine from Toyota, based on the 3S-GE with the addition of under piston oil squirters and a reduced compression ratio to accommodate the addition of a turbocharger.
There are four generations of this engine, which started manufacture in 1986 and was built until 2007. The turbochargers used in the 3S-GTE engines are Toyota designs and use an internal wastegate design. Depending on where the engine was intended to be sold the exhaust turbine is either ceramic (Japan) or steel (US and Australia). It was fitted to the MR2 (North America and Japan only. There is no official MR2 for the European market with this engine.), Toyota Celica GT-Four, and the Caldina GT-T and GT-Four.
| Generation | Year | Model | Power | Torque |
|---|---|---|---|---|
| 1 | 1986–1989 | Celica ST165 |
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| 2 | 1990–1993 |
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| 3 | 1994–1999 |
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| |
| 4 | 1997–2001 | Caldina ST215 (GT-T) | 260 PS (191 kW; 256 hp) @ 6200 rpm | 324 N⋅m (239 lbf⋅ft) @ 4400 rpm |
| 4.5 | 2002–2007 | Caldina ST246 (GT-Four) | 260 PS (191 kW; 256 hp) @ 6200 rpm | 324 N⋅m (239 lbf⋅ft) @ 4400 rpm |
Its cylinders are numbered 1-2-3-4, cylinder number 1 is beside the timing belt. The Dual Over Head Cam (DOHC) 16-valve cylinder head designed by Yamaha is made of aluminum alloy. The pent-roof combustion chambers are complemented by a cross flow intake and exhaust layout. Spark plugs are located in the middle of the combustion chambers. A distributor based system is used to fire the cylinders in a 1-3-4-2 order.
The crankshaft, located within the crankcase, rotates on five aluminum alloy bearings and is balanced by eight weights. Oil holes are located in the middle of the crankshaft to provide oil to the connecting rods, bearing, pistons and various other components.
A single timing belt drives the intake and exhaust camshaft along with the oil and water pumps. The cam journal is supported on 5 points between the valve lifters of each cylinder and on the front of the cylinder head. The cam journals are lubricated by oiler port located in the middle of the camshaft. To adjust the valve clearance in the first two generations, a shim over bucket system is employed. In the following generations a shim under bucket system is used.
The pistons are made from an aluminum alloy designed to withstand high temperatures. An indentation is incorporated into the pistons to prevent the pistons from hitting the valves if the timing belt breaks. Piston pins holding the pistons in place are locked by snap rings.
The first compression ring and the oil ring is made of steel, the second compression ring is made of cast iron. Compression ring 1 and 2, prevents gas leakages from the combustion chamber while the oil ring works to clear oil off the cylinder walls, preventing any excessive oil from entering the combustion chamber.
The first-generation Toyota CT26 utilized a single entry turbine housing and a single wastegate port design. It was fitted to the first generation Toyota Celica GT-Four (ST165). The intake charge was cooled by a water-to-air intercooler and the intake manifold design is Toyota's T-VIS. It has 8 independent ports and benefits from the inertia build up to improve engine torque at low and medium speeds by closing 4 ports below a certain RPM and throttle position to increase air speed and maximize fuel atomization and opening all 8 at higher engine loads for better air volume. Air metering is through an air flow meter and there is no factory BPV/BOV in this generation. Fuel delivery is through 430 cc injectors while air is fed through a 55 mm (2.2 in) throttle body and 7.15 mm (0.281 in) intake and exhaust valve lift. Compression ratio is 8.5:1 and produces 182–190 hp (136–142 kW; 185–193 PS) and 190 lb⋅ft (258 N⋅m) with a factory 8-9 psi of boost. Fuel cut is at 12 psi. [13]
The second-generation Toyota CT26 used a twin entry turbine housing with dual wastegate ports. It was fitted to the second generation Toyota Celica GT-Four (ST185) as well as the Toyota MR2 Turbo (SW20). The intake charge is cooled by an air-to-air intercooler either top-mounted in the Celica or side-mounted in the MR2. The rally homologation Celica (known as GT-Four RC in Japan, Group A Rallye in Australia, or Carlos Sainz Limited Edition in Europe) used a top-mounted water-to-air intercooler and is distinguished by a hood vent rather than a hood scoop as found in the non-homologation ST185s. This generation retains the T-VIS intake manifold and the Air Flow Meter. A factory BPV is included in the SW20 MR2 Turbo but not on the Celicas. Compression ratio is 8.8:1 and produces 200–232 hp (149–173 kW; 203–235 PS) and 200–224 lb⋅ft (271–304 N⋅m). This generation retains the injector size and throttle body size from the previous generation. However, boost is increased to 10-11 psi in the ST185 and MR2 while it is increased to 16 psi in the ST185RC. [14] Intake and exhaust valve lift is significantly increased to 8.2 mm (0.32 in).
The third-generation engine uses the Toyota C20b turbo, which was of the same design as the second-generation but with a slightly improved turbine housing and larger compressor wheel. A factory BPV is installed on all applications. The intake charge is cooled by a water-to-air top-mounted intercooler similar in shape to the ST185RC WTA. One can tell the difference as the ST205 WTA is black while the ST185 WTA is silver with a black centre. This generation does away with T-VIS and uses a normal 4 runner intake with the same port shape and size as the NA engine (but with larger injector holes for side feed). The Air Flow Meter is also removed in favor of a MAP sensing system (prior generations used a MAP sensor only for the purpose of the factory boost gauge and determining overboost fuel cut). Various increases included injector size (540 cc), boost (13 psi), overboost fuel cut limit (18 psi), intake cam lift (8.7 mm [0.34 in]), throttle body size (60 mm [2.4 in]), and a 10 mm (0.39 in) increase in exhaust ports. Exhaust valve lift is retained at 8.2 mm (0.32 in). [13] In late 1997, the block casting was revised with added support around the head to prevent block cracking problems. [14] The C20b turbo found in this generation is backwards compatible with the second generation motors, however not the first generation. Further improvements include a factory oil catch can. Compression is reduced down to 8.5:1 however power is improved to 245–255 PS (180–188 kW; 242–252 hp) and 304 N⋅m (224 lbf⋅ft).
The fourth-generation engine uses a proprietary CT15B turbocharger. This generation was used in the Toyota Caldina GT-T AWD Wagon (ST215). The exhaust housing is actually cast into the cylinder exhaust manifold, rather than the normal practice of a separate turbine housing after the cylinder exhaust manifold. Due to this, the CT15 is backwards compatible with the third-generation 3S-GTE cylinder head only, not either the first or second generation. Intake charge was cooled by an air-to-air top-mounted intercooler fed through a new side-feed intake manifold. This generation utilizes a coil-on-plug ignition system and 550 cc injectors. Boost remains at 13-14 psi, however overboost fuel cut is increased to 21 psi. Compression is increased to 9:1 and produces 260 PS (191 kW; 256 hp) and 324 N⋅m (239 lbf⋅ft).
The fifth-generation engine uses the same turbo as the fourth generation model. This generation was used in the Toyota Caldina GT-Four (ST246). There are only minor differences to this engine compared to the previous version and due to only limited markets receiving the ST246, very little is known and very few are aware of the engine. Differences include longer injectors to be closer to the intake ports. The intake manifold returns to a center-feed type fed by an air-to-air top-mounted intercooler. This intercooler is slightly smaller than the previous generation and is oriented slightly different than any of the previous generations. It is tilted more towards the front of the car. The coil-on-plug ignition is different in this generation and it is not compatible with the ST215 ECU. The valve cover is different as for the first time in the 3S-GTE series as the oil filler hole is on top of the exhaust camshaft instead of the intake. Other differences include the first time that there is no oil cooler in this generation as well as OBD2 diagnostics. Despite the downsize in various components of this generation, power is retained at 260 PS (191 kW; 256 hp) and 324 N⋅m (239 lbf⋅ft). [15]
| Gen 1 | Gen 2 | Gen 3 | Gen 4 | Gen 4.5 | |
|---|---|---|---|---|---|
| Capacity | 1,998 cc (2.0 L; 121.9 cu in) | ||||
| Bore x Stroke | 86 mm × 86 mm (3.39 in × 3.39 in) | ||||
| Variable Performance Mechanism | T-VIS | Traditional | |||
| Ignition | Distributor | Coil-on-Plug | |||
| Compression Ratio | 8.5:1 | 8.8:1 | 8.5:1 | 9.0:1 | 9.0:1 |
| Valve Material | Steel-Alloy | Heat-Treated Steel with Nitride | |||
| Intake Valve Diameter | 33.5 mm (1.32 in) | ||||
| Exhaust Valve Diameter | 29.0 mm (1.14 in) | ||||
| Intake Valve Lift | 7.15 mm (0.281 in) | 8.2 mm (0.32 in) | 8.7 mm (0.34 in) | 8.75 mm (0.344 in) | 8.4 mm (0.33 in) |
| Exhaust Valve Lift | 7.15 mm (0.281 in) | 8.2 mm (0.32 in) | |||
| Injector Size | Top-Feed 430 cc | Side-Feed 430 cc | Side-Feed 540 cc | Top-Feed 540 cc | Extended length Top-Feed 540 cc |
| Turbo (All Single Turbo) | Single-Entry CT26 | Dual-Entry CT26 | Dual-Entry CT20b | Cast-in-manifold Single-Entry CT15B | |
| Intake Manifold | Center Feed | Side Feed | Center Feed | ||
| Intercooler | WTA TMIC | ATA TMIC/SMIC (ST185RC - WTA) | WTA TMIC/SMIC | ATA TMIC | |
| Factory Boost | 8–9 psi (0.55–0.62 bar) | 10–11 psi (0.69–0.76 bar) | 13 psi (0.90 bar) | ||
| Fuel Cut | 12 psi (0.83 bar); ST185RC - 16 psi (1.1 bar) | 18 psi (1.2 bar) | 21 psi (1.4 bar) | ||
The 503E was used to power a number of Toyota Sports cars, including the Toyota 88C Group C entry and the All American Racers-built Eagle HF89/HF90 and Eagle MkIII IMSA Grand Touring Prototypes. It was hand-built by Toyota Racing Development in Torrance, California and produced up to 600 kW (800 bhp). The 3S-GTE was later based on its design. They are similar engines, though not identical.[ citation needed ]
The Toyota TOM'S Supra GT500 race car used a version of the 3S-GTE known as the 3S-GT, another name for the 503E which was detuned to 360 kW (480 bhp), in accordance to the regulations of GT500 at the time. This was due to the Supra's conventional engine, the 2JZ, being deemed as too front-heavy for the race car. [16]
The 4S is a 1.8 L (1,838 cc), a narrower bore version of the 3S (82.5 x 86.0 mm). This was essentially a multi-valve, twin cam replacement for the 1.8-litre 1S series, with parallel differences as those between the 2S and 3S. There were both 4S-Fi (central point fuel injection) and 4S-FE (multi-point fuel injection) versions.
105 PS (77 kW; 104 hp) and 149 N⋅m (110 lb⋅ft), central-point fuel injection.
The 5S engine was essentially the same basic design as the 3S, but features a slightly increased bore and an increased stroke (87.1 x 90.9 mm). The total displacement was thus increased to 2.2 L (2,164 cc). It was used in the fifth- and sixth-generation Celica, the second-generation MR2, the third- and fourth-generation Camry, as well as the first-generation Camry Solara. Like the 3S, the 5S is of a non-interference design to prevent the pistons from striking the valves in case of a timing belt failure.
The 5S-FE was available in several variations each being distinguished by valve cover design. The first generation, introduced in the 1990–92 Celica GT/GT-S and MR2, had a power rating of 130 hp and 144 lb ft of torque. The second generation was introduced in 1993 with the fifth generation (ST184) Celica, and continued through the sixth generation (ST204) Celica. The second generation was also used in the MR2 (SW21) and Camry/Scepter (XV10) series and had a power output of 135 hp and 145 lb ft of torque. It had slightly less aggressive cams, no cold start injector, a knock sensor, and more aggressive tuning to give it slightly more power. In states that had adopted California emission standards the 5S-FE was rated at 130 hp and 145 lb ft of torque due mainly to emission equipment used to meet those emission regulations. The third generation was the last 5S-FE engine produced and was used in the 1997–01 Camry XV20 and 1999–01 Camry Solara; however, from 1996 onward, the engine received a crank angle sensor instead of a cam angle sensor for a smoother idle. From 1997 to 1999 the engine produced 133 hp at 5,200 rpm and 147 lb ft of torque at 4,400 rpm. From 2000 to 2001, the engine received modest improvements to increase power output to 136 hp at 5,200 rpm and 150 lb ft of torque at 4,400 rpm. The 5S-FE was replaced in all applications by the 2.4 L 2AZ-FE.
California specification 1994-1996 5S-FEs in the Celica and Camry used air-assisted, 250 cc injectors, and sequential fuel injection for reduced emissions over the grouped (2+2) firing scheme. The 1994-1995 MR2 did not receive this change, nor did Camrys/Celicas in federal emissions states.[ citation needed ]
Camry 5S-FEs have a counter-rotating balance shaft assembly to reduce noise, vibration, and harshness. These reduce the second order vibrations common to four-cylinder engines by spinning at twice the crankshaft speed. The 1994-1999 Celica and 1991-1995 MR2 5S-FEs lack these balance shafts, so any 5S-FE engine with balance shafts likely came from a Camry.[ citation needed ]
In 1997, for the fourth generation Camry, the 5S-FE was updated for the last time. This engine received a direct ignition system with external camshaft and crankshaft sensors. This system used a wasted-spark design, and the coils had integrated igniters. The engine did not use a typical coil-on-plug design, but rather two coil+igniter assemblies mounted near cylinder four, and provided spark via normal high-tension cords (spark plug wires). This change means that the 1997-01 Camry 5S-FE has a blocked off distributor mounting hole and could be used with older 5S-FEs without swapping cylinder heads.[ citation needed ]
The 1997-99 Camry 5S-FE continued with the air-assisted, 250 cc injectors. The Camry 5S-FE also had a factory 4-to-1 exhaust design - in Federal form, it had no pre-catalyst, although the California version did replace the collector design of the Federal version with a warm-up pre-catalyst for reduced cold start emissions.[ citation needed ]
For 2000 Toyota removed the air-assisted injectors and moved to superfine atomization (~50 micrometers), 12-hole, 235 cc injectors made by Denso. They are of a different design, and required a change in the cylinder head casting.[ citation needed ]
For 2001 Toyota started fitting factory MLS (multi-layer steel) head gaskets and other metal gaskets layered with Viton to engines, including the 5S-FE. MLS head gaskets require cylinder head and cylinder block resurfacing on older engines to ensure proper sealing; consequently, the MLS head gasket did not supersede the old composite head gasket.[ citation needed ]
The 1994 through 1999 Celica 5S-FE was not updated with these changes, and continued to use a distributor and the older electronic control system and injectors.
The 5S-FE has a 9.5:1 compression ratio.
| Year | Power | Torque |
|---|---|---|
| 1990–92 | 130 bhp (97 kW) at 5,400 rpm | 144 lb⋅ft (195 N⋅m) at 4,400 rpm |
| 1993–96 | 135 bhp (101 kW) at 5,400 rpm | 145 lb⋅ft (197 N⋅m) at 4,400 rpm |
| 1997–99 | 133 bhp (99 kW) at 5,400 rpm | 147 lb⋅ft (199 N⋅m) at 4,400 rpm |
| 2000–01 | 136 bhp (101 kW) at 5,400 rpm | 150 lb⋅ft (203 N⋅m) at 4,400 rpm |
Essentially a CNG version of the 5S-FE. This engine was fitted to the XV20 Camry in California to fleet customers in 1999. [19]
The Toyota Celica is an automobile produced by Toyota from 1970 until 2006. The Celica name derives from the Latin word coelica meaning heavenly or celestial. In Japan, the Celica was exclusive to the Toyota Corolla Store dealer chain. Produced across seven generations, the Celica was powered by various four-cylinder engines, and bodystyles included convertibles, liftbacks, coupés and notchback coupés.
The Toyota Supra is a sports car and grand tourer manufactured by the Toyota Motor Corporation beginning in 1978. The name "supra" is derived from the Latin prefix, meaning "above", "to surpass" or "go beyond".
The Toyota MR2 is a line of two-seater, mid-engined, rear-wheel-drive sports cars, manufactured in Japan and marketed globally by Toyota from 1984 until 2007 over three generations: W10 (1984–1989), W20 (1989–1999) and W30 (1999–2007). It is Japan's first rear mid-engined production car.
The Toyota A Series engines are a family of inline-four internal combustion engines with displacement from 1.3 L to 1.8 L produced by Toyota Motor Corporation. The series has cast iron engine blocks and aluminum cylinder heads. To make the engine as short as possible, the cylinders are siamesed.
The F engine family from Mazda is a mid-sized inline-four piston engine with iron block, alloy head and belt-driven SOHC and DOHC configurations. Introduced in 1983 as the 1.6-litre F6, this engine was found in the Mazda B-Series truck and Mazda G platform models such as Mazda 626/Capella as well as many other models internationally including Mazda Bongo and Ford Freda clone, Mazda B-series based Ford Courier, Mazda 929 HC and the GD platform-based Ford Probe
The RB engine is an oversquare 2.0–3.0 L straight-6 four-stroke gasoline engine from Nissan, originally produced from 1985 to 2004. The RB followed the 1983 VG-series V6 engines to offer a full, modern range in both straight or V layouts.
Toyota Motor Corporation's M family of engines were a longitudinally mounted straight-6 engine design. They were used from the 1960s through the 1990s. All M family engines were OHC designs. While the M family was born with a chain-driven single camshaft it evolved into a belt-driven DOHC system after 1980. All M family engines used a cast-iron block with an aluminum cylinder head, and were built at the Toyota Kamigo plant in Toyota City, Japan.
The Toyota JZ engine family is a series of inline-6 automobile engines produced by Toyota Motor Corporation. As a replacement for the M-series inline-6 engines, the JZ engines were 24-valve DOHC engines in 2.5- and 3.0-litre versions.
The Toyota ZZ engine family is a straight-4 piston engine series. The ZZ series uses a die-cast aluminium engine block with thin press-fit cast iron cylinder liners, and aluminium DOHC 4-valve cylinder heads. The camshafts are chain-driven. The two 1.8 L members of the family, the 1ZZ and 2ZZ, use different bore and stroke. The former was optimised for economy, with torque emphasised in lower revolutions per minute operating range, while the latter is a "square" design optimised for high-RPM torque, yielding higher peak power. The ZZ family replaced the extremely popular cast-iron block 4A engines.
The Toyota AZ engine family is a straight-4 piston engine series. The AZ series uses an aluminium engine block with cast iron cylinder liners and aluminium DOHC cylinder head. The engine series features many advanced technologies including slant-squish combustion chambers, offset cylinder and crank centers, and the VVT-i continuously variable intake valve timing system. The aluminium engine measures 626 mm (24.6 in) long, 608 mm (23.9 in) wide, and 681 mm (26.8 in) tall.
The Toyota MZ engine family is a piston V6 engine series. The MZ series has an aluminium engine block and aluminium alloy DOHC cylinder heads. The cylinders are lined with cast iron, and is of a closed deck design. The engine is a 60 degree V6 design. It uses multi-port fuel injection (MFI), four valves per cylinder, a one-piece cast camshaft and a cast aluminium intake manifold. The MZ family is a lightweight V6 engine of an all-aluminium design, using lighter weight parts than the heavier duty VZ block engines in an effort to lower production costs, decrease engine weight, and decrease reciprocating weight without sacrificing reliability. Toyota sought to enhance the drivability pattern of the engine at exactly 3000 rpm, since that was the typical engine speed for motors cruising on the highway. The result was less cylinder distortion coupled with the decreased weight of rotating assemblies, smoother operation at that engine speed, and increased engine efficiency.
The Toyota VZ engine family is a series of V6 gasoline piston engines ranging from 2.0 to 3.4 L in displacement and both SOHC and DOHC configurations. It was Toyota's first V6 engine, being made as a response to Nissan’s VG engine, one of Japan’s first mass-produced V6 engines.
The Toyota UZ engine family is a gasoline fueled 32-valve quad-camshaft V8 piston engine series used in Toyota's luxury offerings and sport utility vehicles. Three variants have been produced: the 1UZ-FE, 2UZ-FE, and 3UZ-FE. Production spanned 24 years, from 1989 to mid 2013, ending with the final production of the 3UZ-FE-powered Toyota Crown Majesta I-FOUR. Toyota's UZ engine family was replaced by the UR engine family.
The Toyota R family was a series of inline-four gasoline automobile engines. Designed for longitudinal placement in such vehicles as the Celica and Hilux and in production from 1953 through 1997, usage faded out as many of Toyota's mainstream models moved to front-wheel drive. Overhead cam (OHC) versions featured a chain-driven camshaft.
The Toyota T series is a family of inline-4 automobile engines manufactured by Toyota beginning in 1970 and ending in 1985. It started as a pushrod overhead valve (OHV) design and later performance oriented twin cam (DOHC) variants were added to the lineup. Toyota had built its solid reputation on the reliability of these engines.
The Toyota GR engine family is a gasoline, open-deck, piston V6 engine series. The GR series has a 60° die-cast aluminium block and aluminium DOHC cylinder heads. This engine series also features 4 valves per cylinder, forged steel connecting rods and crankshaft, one-piece cast camshafts, a timing chain, and a cast aluminium lower intake manifold. Some variants use multi-port fuel injection, some have D4 direct injection, and others have a combination of direct injection and multi-port fuel injection or D4-S.
The Toyota E engine family is a straight-four piston engine series, and uses timing belts rather than chains. The E engines were the first multi-valve engines from Toyota designed with economy, practicality and everyday use in mind. Like many other Toyota engines from the era, the E engine series features a cast iron block, along with an aluminium cylinder head. E engines are lighter than earlier Toyota engines, due to the hollow crankshaft, thinned casting of the cylinder block, and several other reductions in auxiliaries as well as in the engine itself. Carbureted versions include a newly designed, variable-venturi carburetor. All of these changes improved economy and emissions. The members of the E engine family, range from 1.0 L to 1.5 L. The E family supplanted the K engines in most applications. A large number of parts in the E engine series are interchangeable between each other.
The Subaru EJ engine is a series of four-stroke automotive engines manufactured by Subaru. They were introduced in 1989, intended to succeed the previous Subaru EA engine. The EJ series was the mainstay of Subaru's engine line, with all engines of this series being 16-valve horizontal flat-fours, with configurations available for single, or double-overhead camshaft arrangements. Naturally aspirated and turbocharged versions are available, ranging from 96 to 310 hp. These engines are commonly used in light aircraft, kit cars and engine swaps into air-cooled Volkswagens, and are also popular as a swap into copy wasserboxer engined Volkswagen T3/Vanagon. Primary engineering on the EJ series was done by Masayuki Kodama, Takemasa Yamada and Shuji Sawafuji of Fuji Heavy Industries, Subaru's parent company.
The Toyota Sprinter Trueno is a series of compact sports coupés and hot hatches which were produced by Toyota from 1972 to 2000. The name Trueno in Spanish means thunder. In Japan, the Sprinter Trueno was exclusive to Toyota Auto Store locations, later renamed Toyota Vista Store in 1980.
The AR engine family is an Inline-4 piston engine series by Toyota, first introduced in 2008 for the RAV4, and subsequently for the Highlander, Venza, Camry and Scion tC.
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