Fiat 128 SOHC engine

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Fiat SOHC engine
Overview
Manufacturer Fiat / Lancia / Zastava / Tofaş
Production 1969–1999
Combustion chamber
Configuration SOHC 2-valve I4

Designed by Aurelio Lampredi, the Fiat SOHC engine first appeared in the front-wheel drive (FWD) Fiat 128 of 1969.[1] The in-line four-cylinder engine comprised an iron block with an aluminium cylinder-head containing a single over-head camshaft operating directly on both the inlet and exhaust valves in a reverse-flow cylinder-head configuration. The camshaft was driven by a belt rather than chain. The engine remained in production until the mid 1990s and grew in capacity over the years from 1100 cc (in the Fiat 128) to an eventual 1600 cc (in the Fiat Tipo/Tempra). The Fiat 130 2866 cc V6 engine, also appearing in 1969, although having cross flow cylinder-head, is directly related to the 128 SOHC engine, but with a 1.20 upscale in bore and stroke.

Design and production

File:Fiat 1581cc engine cutup.jpg
Cut apart 1,581 cc version of the 128 engine

The engine was designed as a transverse mounted FWD-only power-plant being the second engine/gearbox combination to exhibit the now standard transverse engine-next-to-gearbox layout with unequal length driveshafts (the first was the Autobianchi Primula, the Mini had its gearbox in the sump of the engine). The one exception to the engines FWD-only design is its revolutionary use as a mid-engine drive-train in the Fiat X1/9. Unusual for the time was the electrically driven fan, rather than it being powered directly by the engine.[1] The 128 engine has five crankshaft bearings.

A prominent feature of the Fiat SOHC engine its massively over-square proportions. This over-square design allows large (within the constrains of a reverse-flow configuration) valve sizes relative to engine capacity. A secondary benefit is the short crank throw reduces the accelerative forces on the con-rod allowing the engine to operate at significantly increased engine-speeds. The original engine's limit was only reached at 8000 rpm.[1]

The engine was developed for forced-induction use in the Fiat Uno Turbo. It was then further refined for the Uno Turbo Mark II, and later for the Punto GT.

As with its bigger brother the famous Fiat DOHC (aka Fiat/Lancia twincam) engine, the Fiat SOHC engine was shared with the Fiat subsidiary Lancia (appearing in 1,500 cc guise in the Lancia Delta/Prisma of the 1980s) as well as being used in the Fiat 128 derived Yugo.

The final incarnation of the 128 SOHC engine was modified to utilise 16 valves and dual cam shafts. The engine (using the designation "Torque") featured the bore-spacing, bore and stroke of the 1580 cc 159/160 series engine with a new 16 valve DOHC cylinder-head. To incorporate the extra oil-return-paths and symmetrical head (as opposed to the asymmetrical SOHC head) the cylinder-block was slightly revised making the DOHC head non-interchangeable with the previous incarnations of the 128 engine. Development of the Torque engine took place in the US rather than Italy, whilst Fiat was in partnership with GM. The "Torque" engine (178.B3 - 182.A4) powered the Brava/Bravo, Marea and Multipla Fiat[citation needed] automobiles as well as the second-generation Lancia Delta (never sold in the UK), finally ending production in 1999.

Engine specification

The Fiat SOHC engine was produced in a number of configurations differing in stroke and bore but maintaining a standard bore-spacing. The first generation of 128 derived engines used a stroke of 55.5 mm and a bore of 80 mm to produce a displacement of 1116 cc. The bore was increased to 86 mm (maintaining the 55.5 mm stroke) to give a displacement of 1290 cc for the X1/9. The original 1290 cc 128/X1/9 engine is the only one of the family to have used the 86 mm bore. The second generation used bores of either 80 mm or 86.4 mm with strokes of 55.5 mm or 63.9 mm giving four possible engine capacities. The final generation of SOHC engines standardised on a longer 67.4 mm stroke with either an 80.5 mm or 86.4 mm bore (giving 1372 cc and 1581 cc respectively).

Valid engine bore/stroke combinations
Stroke
(mm)
Bore (mm)  
80 80.5 86 86.4
55.5 1116 1130 1290 1302 Capacity
(cc)
63.9 1285 1301 1485 1499
67.4 1355 1372 1566 1581
Key
1st Generation  
1st & 2nd Generation  
2nd Generation  
3rd Generation  
Engine specification (by engine-number)
Engine Code Bore (mm) Stroke (mm) Capacity (cc)
stated
Capacity (cc)
calculated
Production
(from - to)
BHP Notes
128.A.000 80 55.5 1116 1116 1969–1982 55-65 128
128.A1.000 86 55.5 1290 1290 1978 - ? 75-85 128
128.AS.000 86 55.5 1290 1290 1972–1978 75 X1/9 1300
138.A.000 80 55.5 1116 1116 1978–1985 60 Ritmo 60
138.A1.000 86.4 55.5 1301 1302 1978–1982 75-65 Ritmo 65
138.A2.000 86.4 63.9 1498 1499 1978–1982 75-85 X1/9 1500, Ritmo 75
138.A3.000 86.4 55.5 1301 1302 1982 75 Ritmo S75
138.A4.000 86.4 63.9 1498 1499 1980–1982 75-85 X1/9 1500, Ritmo S85
138.A5.000 86.4 55.5 1301 1302 1982–1985 70 Also 138.AS.000
138.B.000 80 55.5 1116 1116 1983–1985 55 Uno 55
138.B1.000 80 55.5 1116 1116 1982–1985 55-58 Ritmo Mk II
138.B2.000 86.4 55.5 1301 1302 1983–1986 68-70 Uno 70
138.B3.000 86.4 63.9 1498 1499 1982–1985 70-85 Regata 85S
146.A4.048 80 55.5 1116 1116 1985–1989 58,5 Uno 60
146.A2.000 80 63.9 1301 1285 1985–1989 105 Uno Turbo Mk I (specification A)
146.A2.000 86.4 55.5 1301 1302 1985–1989 105 Uno Turbo Mk I (specification B)
146.A8.000 80.5 67.4 1372 1372 1989 112 Uno Turbo Mk II
146.C1.000 80.5 67.4 1372 1372 1989–1993 72 Uno 70SX
149.C1.000 86.4 63.9 1498 1499 1988 75 Uno 75 SX i.e. (cat)/Selecta
159.A2.000 80.5 67.4 1372 1372 1990–1993 76 Tipo/Tempra 1.4 (carb & i.e.)
159.A3.000 86.4 67.4 1581 1581 1990–1996 75-78 Tipo/Tempra 1.6 (carb & i.e.)
160.A1.000 80.5 67.4 1372 1372 1988–1993 72 Tipo/Tempra 1.4 i.e.
160.A1.046 80.5 67.4 1372 1372 1992–1993 69 Uno Selecta
160.A2.000 86.4 67.4 1580 1581 1988–1993 83 Tipo/Tempra 1.6 (carb & i.e.)
835.C1.000 86.4 67.4 1580 1581 1993–1995 75 Tipo/Tempra 1.6 i.e. (Typ 160)
176.A4.000 80.5 67.4 1372 1372 1993–1995 136 Mk I Punto GT (GT1), CR 7.8:1
176.A4.000 80.5 67.4 1372 1372 1995–1997 133 Mk I Punto GT (GT2), CR 7.8:1
176.B6.000 80.5 67.4 1372 1372 1997–1999 130 Mk I Punto GT (GT3), CR 9.0:1
176.A9.000 86.4 67.4 1581 1581 1994–1997 88 Mk I Punto Sporting & Cabrio
835.C1.000 86.4 67.4 1581 1581 1989–1994 75-78 Lancia Dedra Mk I (1.6 i.e.)
835.A1.046 86.4 67.4 1581 1581 1989–1994 75-78 Lancia Dedra Mk I (1.6 i.e.)
835.A1.000 86.4 67.4 1581 1581 1995–1997 90 Lancia Dedra Mk II (1.6 i.e.)
182.A4.000 86.4 67.4 1581 1581 1995–2002 103 DOHC 16v, Bravo/Brava/Marea/Multipla/Lancia Dedra 1.6 16v
182.B6.000 80.5 78.4 1596 1596 2002–2005 103 DOHC 16v, Marea/Multipla/Stilo
310 A3.011 86.4 78.4 1839 1839 2008–2010 132 DOHC 16v, Brazilian Linea 1.9 16v EcoFlex
Key
1st Generation  
2nd Generation  
3rd Generation  

Applications

List of vehicles utilising variations of the Fiat SOHC engine.

Fiat

Lancia

Zastava

  • Yugo 55
  • Yugo 60
  • Yugo 65
  • Zastava 101
  • Zastava 128
  • Zastava Florida
  • Yugo sana 1.3 1.4

Tofaş

Induction

Production

The Fiat SOHC used the full gamut of induction techniques through its long production run. The original 128 and 138 series engines originally used a single down-draught carburettor. The carburettor was normally of progressive twin-choke design (two asymmetric sized chokes operated progressively) such as the Weber DMTR and DATR of the X1/9. Multi Point fuel Injection (MPI) was introduced late in the 138 series to help meet lowered emission requirements in the US. The original MPI system comprised a large cylindrical plenum running parallel to the engine with individual runners to each inlet port and a single throttle controlling air-flow into the plenum. This plenum was pressurised in the Mk I Uno Turbo. The plenum was slightly redesigned to a more angular "box" shape for the 3rd Generation engines and was again pressurised for the Uno and Punto GT Turbo models. For the 3rd Generation engines the down-draft carburettor was replaced with a Single Point fuel Injection system (SPI) in the base-level models. The SPI system mounts on a manifold similar to that of the carburetted models and looks, as well as acts, much like a single-choke carburettor with a single throttle plate but no venturi and a centrally mounted single injector.

Tuning & modification

Carburettor

Traditionally both down-draft (DCNF & IDF) and side-draft (DCOE) twin-choke carburettors have been used to extract more power from the 128 derived engines. IDFs are rarely used due to an incorrect orientation of the float-bowls (causing possible surge/starve issues under cornering), the correctly orientated DCNF being the preferred down-draft carburettor in this application (also having a much lower profile than the IDF). For ultimate power the DCOE carburettor is used even though the float-bowl direction matches that of the IDF (i.e. incorrect). The aforementioned carburettors are usually used in pairs (effectively giving one independently tuneable carburettor per engine-cylinder), though applications where a single DCNF/DCOE are used to feed a shared manifold do exist. DCNF's tend to be either 36 mm or 40 mm, the larger 44-DCNF is deemed too large for the engine. Both 40-DCOE and 45-DCOE are commonly used where space allows.[2]

MPI

Tuning of the early MPI systems has previously been difficult as the electronic control systems are analogue making them difficult to "re-map". Low-cost DIY Fuel Injection (FI) controllers (such as MegaSquirt) have made it easier to alter the characteristics of the early MPI systems and release similar potential as the DCNF/DCOE carburettors. It is possible to "chip" the later digital MPI systems though aftermarket FI controllers again give greater flexibility.

Throttle bodies

Individual FI Throttle Bodies (TBs) are available for mounting to DCNF and DCOE manifolds as well as custom-built FI systems which, with aftermarket controllers, give the most flexibility and control over fuelling out of all the options.

Motorcycle carburettors

Motorcycle, or "bike" carburettors, being a modern and cost-effective alternative to DCOE/DCNFs, have been adapted to work with the 128-derived engines. They potentially offer better control over fuelling than DCNF/DCOE, but their use on the Fiat SOHC engine is still in its infancy.

Camshaft profile

The camshaft was a main methods of varying the 128 series engines characteristics for different applications/markets. The high-revving oversquare design of the 128 engine lends itself to high-overlap high-duration cam profiles better than more traditional square/under-square engine designs without losing drivability.[3] Though a beneficial characteristic for sports orientated engine the high-overlap high-duration cam design gives poor emissions output which was unacceptable under the tightened US emissions regulations. To remedy this (in addition to the introduction of MPI) camshafts for emission-restricted markets featured asthmatic low-lift, low-duration, low-overlap profiles totally unsuited to the nature of the 128 engine.

Production

Standard production camshaft specifications
Profile Duration
(degrees)
Overlap
(degrees)
Lift
(mm)
Clearance (mm)
Inlet/Exhaust
Application
12/52-52/12 244 24 - - 1.1 L 128 - European Specification
10/54-54/10 244 20 - - 1.1 L 128 - North-American Specification
24/68-68/24 272 48 9.85 - 128 Rally
24/68-68/24 272 48 9.85 - 1300 X1/9 - European Specification
10/54-54/10 244 20 - - 1300 X1/9 - North-American Specification
12/52-52/12 244 24 - - 1300 X1/9 - Australian Specification
24/68-68/24 272 48 9.9 - 1500 X1/9 - European Specification (carb)
10/54-54/10 244 20 - - 1500 X1/9 - North-American Specification (FI)
10/54-54/10 244 20 - - 1500 X1/9 - Australian Specification (carb)
9/39-31/1 228-212 10 8 - 1.3 L Uno
0/30-40/10 210-230 10 8 - 1.3 L Uno Turbo
14/36-44/6 230 20 8.8 - 1.4 L Uno Turbo

Tuning and modification

Fast-road/race camshaft specifications
Manufacturer Profile name Profile Duration
(degrees)
Overlap
(degrees)
Lift
(mm)
Clearance (mm)
Inlet/Exhaust
Application
Kent FT7 35/67-67/35 282 70 10.33 0.20 / 0.20 NA - fast road
Kent FT8 52/76-76/52 308 104 10.82 0.20 / 0.20 NA - race
Piper BP270 33/67-67/33 280 66 9.80 0.20 / 0.20 NA - fast road
Piper BP285 36/72-72/36 288 72 10.40 0.20 / 0.20 NA - fast road
Piper BP300 39/71-71/39 290 78 11.18 0.25 / 0.25 NA - race
Piper BP320 53/83-83/53 316 106 11.18 0.25 / 0.25 NA - race

Footnotes

  1. 1.0 1.1 1.2 Lua error in package.lua at line 80: module 'strict' not found.
  2. To fit DCOE carburettors in an X1/9 a small amount of bodywork must be removed/reshaped
  3. The standard European carburettord X1/9 used a camshaft more radical than many after-market "performance" camshafts offered for contemporary engines from other (non Italian) European manufacturers.