1999 FIAT PUNTO Petrol
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2B*10 DOHC (16-valve) petrol engine in-car repair procedures
9.10 Extract the exhaust camshaft oil seal...
Inspection 12 Examine the camshaft bearing surfaces and cam lobes for signs of wear ridges and scoring. Renew ihe camshaft If any of these conditions are apparent. Examine the condition of the bearing surfaces, both on the camshaft journals and in the cylinder head extension. If the head extension beanng surfaces are worn excessively, the extension will need to be renewed. If suitable measuring equipment Is available, camshaft bearing journal wear can be checked by direct measurement. 13 Examine the cam follower bearing surfaces which contact the camshaft lobes for wear ridges and scoring. Renew any follower on which these conditions are apparent. If a follower bearing surface is badty scored, also examine the corresponding lobe on the camshaft for wear, as it is likely that both will be worn. Renew worn components as necessary.
9.11 ... then remove the exhaust camshaft from the cylinder head extension
Refitting 14 Liberally lubricate the camshaft journals and cylinder head extension bearings, then locate both camshafts in position Note that the exhaust camshaft is nearest to the front facing side of the engine. 15 With the camshafts In position, rotate them as necessary until the camshaft locking tools can be re-inserted (see illustration). 16 Lubricate the Hps of a new exhaust camshaft oil seal with clean engine oil, and drive It into position until it seats on its locating shoulder (see Illustration). Use a suitable tubular drifl, such as a socket, which bears only on the hard outer edge of the seaJ. Take care not to damage the seal lips during fitting. Noto that the seal lips should face inwards. 17 Refit the Inlet camshaft drive gear and retaining boll then tighten the bolt to the specified torque (see illustration).
9.16 Fit a new exhaust camshaft oil seal M7 Tighten the Inlet camshaft drive gear retaining bolt to the specified torque
9.15 Refit the camshaft locking tools
18 Refit the exhaust camshaft drive gear to the exhaust camshaft. As the gear is being fitted, It will be necessary to align the anti» backlash inner gear teeth using a screwdriver to enable the teeih of both Ihe gears to mes-i (see Illustration). 19 At this stage it is advisable lo check tie camshaft endfloat using a dial gauge mounted on the cylinder head extension, with its probe in contact with Ihe camshaft being checked Move the camshaft one way. zero the gauge, then move the camshaft as far as it will go ihe other way. Record the reading on the dial gauge and compare the figure with that given in the Specifications. Repeat on the other camshaft. If either of the readings exceeds the tolerance given, a new cylinder head extension will be required. 20 Locate a new gasket on the cylinder head extension end cover, then wrap round the protruding tangs on Ihe gasket to retain it in position (see Illustrations). 21 Locate the end cover on the cylinder heed extension and secure with the retaining nuts securely tightened. 22 Locate a new O-ring on the inlet camshaft cover plate, then apply RTV gasket sealant lo the cover plate contact face (see Illustrations), Fit tho cover plate and secure with the nut and bolt. 23 Refit the camshaft sprocket and secure with the retaining bolt tightened finger tight only at this stage. 24 Liberally lubricate the cam followers and piece them in position in their respective cylinder head extension bores (see illustration),
9.18 Refit the exhaust camshaft drive gear white aligning the anti-backlash Inner gear teeth 9.20a Locate a new gasket on the cylinder head extension end cover... 9.20b ... then wrap round the protruding tangs to retain the gaskel
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DOHC (16-valve) petrol engine in-car repair procedures 2B*11
camshaft cover plate... 25 Locate the cam follower retaining tools in position and refit the cylinder head extension
as
described In Section 8.
10
Cylinder head - &
removal and
refitting S
Removal Note; The cylinder head bolts are of special
sekned
design and a Fiat tool should be
obtained
to unscrew them. A Ton key will not
JSt however
in practise It was found that a dose-httlng Alien key could be used as an itemative. 1 Drain the cooling system as described in Chapter 1A. 2 Remove the cylinder head extension as oescAbed
m
Section 8. 3 Disconnect the radiator hose from the thermostat housing on the left-hand end of
Ihe
cylinder head. 4 Disconnect the heater hose from the outlet
at the
rear of the cylinder head. 5 Disconnect the coolant temperature sensor md temperature gauge sensor wiring plugs
torn
the left-hand end of the cylinder head. 9 Undo the engine oil dipstick tube bracket retaining bolt and the two bolts securing the wing harness support clips to the inlet marriold lower section. 7 Undo Ihe retaining nuts and separate the ixhaust system front pipe from the exhaust manifold flange.
8
Check that nothing remains attached to the cinder head likely to impede removal. It Is assumed that the head will be removed complete with exhaust manifold and inlet manifold lower section. 9 Unscrew the cylinder head bolts half a turn K
e
time in the reverse order to that shown in (lustration 10.20a. When the bolts are free. «mwe them from their locations.. Id Lift the cylinder head from the block. If it is stuck tight rock the head to break the joint by mans of the manifolds. On no account drive
levers
into the gasket Joint, nor attempt to tap tf« head sideways, as it is located on positioning dowels. 11 Remove and discard the cylinder head gasket.
JK'
l^. 9.22b ... then apply RTV gasket sealant to the cover plate contact face 12 Refer to Chapter 20 for cylinder head dismantling and inspection procedures. Preparation for refitting 13 The mating faces of the cylinder head and cylinder block must be perfectly dean before refitting the head. Use a hard plastic or wooden scraper to remove all traces of gasket and carbon; also clean the piston crowns, Take particular care when cleaning the piston crowns as the soft aluminium alloy is easily damaged. Make sure that the carbon is not allowed to enter the oil and water passages -this Is particularly important for the lubncahon system, as carbon could block the oil supply to the engine's components. Using adhesive tape and paper, seal the water, oil and bolt holes in the cylinder block. To prevent carbon entering the gap between the pistons and bores, smear a little grease In the gap. After cleaning each piston, use a small brush to remove all traces of grease and carbon from the gap. then wipe away the remainder with a clean rag. Clean all the pistons in the same way. 14 Check the mating surfaces of the cylinder block and the cylinder head for nicks, deep scratches and other damage. If slight, they may be removed carefully with a file, but If excessive, machining may be the only alternative to renewal. If warpage of the cylinder head gasket surface Is suspected, use a straight-edge to check it for distortion. Refer to Part 0 of this Chapter if necessary. 15 Check the condition of the cylinder head bolts, and particularly their threads, whenever they are removed. Wash the bolts In a suitable
sequence
9.24 Lubricate the cam followers and place them in position in their respective bores solvent, and wipe them dry. Check each bolt for any sign of visible wear or damage, renewing them if necessary.
Refitting 18 Before refitting the assembled cylinder head, make sure that the head and block mating surfaces are perfectly clean, and that the bolt holes in the cylinder block have been mopped out to clear any oil, 17 The now gasket should not be removed from its nylon cover until required for use. Fit Ihe gasket dry, and make sure that the mating surfaces on the head and block are perfectly clean. 18 Place the gasket on the cylinder block so that the word ALTO can be read from above. 19 Lower the cylinder head onto the block so that it locates on the positioning dowel. 20 The cylinder head bolt threads must be clean and lightly lubricated. Screw the bolts in finger-tight then working progressively and in the sequence shown, lighten all the cylinder head bolts to the Stage 1 torquo setting given In the Specifications, using a torque wrench and a suitable socket. With all the bolts tightened to their Stage 1 setting, working again in the specified sequence, first angle-tighten the bolts through the specified Stage 2 angle, then again through the Stage 3 angle, using a socket and extension bar. It Is recommended that an angle-measuring gauge Is used during this stage ot tightening, to ensure accuracy (see Illustrations). 21 Reconnect the exhaust system front pipe to the manifold using a new flange gasket.
10.20b Tighten the cylinder head bolts to the Stago 1 torque setting ...
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2B*12 DOHC (16-valve) petrol engine in-car repair procedures
... then through the Stage 2 end Stage 3 angle
22 Refit the engine oil dipstick tube bracket retaining bolt and the two bolts securing the wiring harness support clips to the inlet manifold lower section. 23 Connect the coolant temperature sensor and temperature gauge sensor wiring plugs. 24 Connect the radiator hose lo the thermostat housing and the heater hose to the cylinder head outlet. 25 Refit the cylinder head extension as described in Section 8. 26 On completion, refill tha cooling system as described In Chapter 1A.
11 Flywheel -removal, Inspection arid refitting
12 Engine mountings -inspection and renewal
Refer to Chapter 2A, Section 11.
13 Sump -removal and refitting
R6fer to Chapter 2A. Section 12.
14 Oil pump and pick-up tube -removal, Inspection and refitting
Refer to Chapter 2A, Section 10. Refer to Chapter 2A. Section 13.
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2C*2 Diesel engine in-car repair procedures
1 General information
Using this Chapter Chapter 2 is divided Into four Parts; A. 8, C and 0. Repair operations that cart be carried out with the engine in the vehicle are described In Part A, SOHC (B-valve) petrol engines. Part B, DOHC (16-valve) petrol engines and Part C. diesel engines, Part D covers the removal of the engine/transmission as a unit, and describes the engine dismantling and overhaul procedures. In Parts A. 8 and C. the assumption Is made that the engine is installed in Ihe vehicle, with all anciliaries connected If the engine has been removed for overhaul, the preliminary dismantling information which precedes each operation may be ignored.
Engine description Both normally aspirated (non-turbo) and turbocharged diesel engines are fitted to the Punto range. The engines together with their codes are given in the Specifications at the start of lhis Chapter. The engines are water-cooled, single-overhead camshaft. In-line lour cylinder units with cast-iron cylinder blocks and aluminium-alloy cylinder heads. The engine is mounted transversely at the front of the vehicle, with the transmission bolted to the left-hand side of the engine. The cylinder head carries the camshaft which is driven by a toothed timing belt. It also houses the inlet and exhaust valves which are closed by single coll valve springs and run in valve guides pressed into the cylinder head. The valves are operated by cam followers fitted over each valve, and the clearances are adjusted by shims positioned between the followers and the camshaft lobes. The camshaft is supported by four bearings • the end bearings are machined in the cylinder head and the remaining bearings have caps bolted to the cylinder head. The cylinder head contains integral oiiways which supply and lubricate the camshaft and followers and it also Incorporates renewable swirl chambers. The crankshaft Is supported by five main bearings, and endfloat Is controlled by a thrust bearing fitted on the rear main bearing. All diesel engines are fitted with a brake servo vacuum pump dnven from the left-hBnd end of the camshaft. Engine coolant is circulated by a pump, driven by the auxiliary drivebeit. For details of the cooling system refer to Chapter 3. Lubricant is circulated under pressure by a pump, driven from the front of the crankshaft. Oil is drawn from the sump through a strainer, and then forced through an externally-mounted, replaceable screw-on filter. From there, it is distributed to the cylinder head.
where il lubncates the camshaft journals and followers, and also to the crankcase, where it lubricates the main bearings, connecting rod big- and small-ends, gudgeon pins and cylinder bores. Oil jets are fitted to the base of each cylinder bore - these spray oil onto the underside of the pistons, lo Improve cooling. An oil cooler is also fitted to reduce the temp-erature of oil before it re-enters the engine.
Repair operations possible with the engine in the car The following work can be carried out with the engine in the can a) Compression pressure - testing b) Auxiliary drivebeit - removal and refitting (refer to Chapter rej c) Valve clearances • checking and adjustment (refer to Chapter 1B) d) Camshaft cover - removal and refitting e) Tim/ng belt and covers • removal and refitting 0 Timing belt tensioner and sprockets -removal and refitting g) Cylinder head - removal and refitting' h) Camshaft and cam followers - removal end refitting' I) Camshaft oil seal - renewal j) Crankshaft oil seals - renewal k) Flywheel • removal, inspection and refitting I) Engine mountings - inspection and renewal m)Sump • removal and refitting n) Oil pump and pick-up tube assembly -removal, inspection and refitting 'Cylinder head dismantling procedures are detalfed In Chapter 2D, with details of camshaft and cam follower removal. Note: It ts possible to remove the pistons and connecting rods (after removing the cylinder nead and sump) without removing the engine. However, this is not recommended. Work of this nature is more easily and thoroughly completed with the engine on tho bench as described in Chapter 2D.
2 Location of
TDC
on ^ No
1
cylinder ||
General information 1 The camshaft and fuel Injection pump are driven by the crankshaft, by means of sprockets and a timing belt. All three sprockets rotate in phase with each other and this provides the correct valve and injection pump timing as the engine rotates. When the timing bell is removed during servicing or repair, it is possible for the camshaft, injection pump and crankshaft to rotate independently of each other and the correct timing Is then lost.
2 It
Location of TDC on cylinder No
1
6 Remove the air inlet ducting as described ft Chapter 4C, Section 2. 7 Remove the heater glow plugs with reference to Chapter 5C. Due to the high compression ratio of diesel engines this Is necessary to allow the engine to be turned by hand. 8 Unscrew the mounting bolts and move the coolant expansion tank to one side for access to the timing covers. Release the hose from the clips on Ihe camshaft cover. 9 Release the toggle clips and remove the upper timing cover (see illustration),
2.9 Removing the upper timing cover
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2C*2 Diesel engine in-car repair procedures
4.4a Unbolt the engine oil dipstick tube...
3 Cylinder compression test
Note: A compression tester specifically designed for diesef engines must be used for this test. 1 When engine performance Is down, or if misfiring occurs, a compression test can provide diagnostic clues as to the engine's condition, If the lest is performed regularly, it can give warning of trouble before any other symptoms become apparent. 2 A compression tester specifically Intended for diesel engines must be used, because of the higher pressures involved. The Ie6ter is connected to an adapler which screws Into the glow plug or injector hole. It is unlikely to be worthwhile buying such a tester for occasional use. but it may be possible to borrow or hire one • if not. have the test performed by a garage. 3 Unless specific instructions to the contrary are supplied with the tester, observe the following points: 9) The battery must bo in a good state of charge, the air titter must be clean, end the engine should be at normal operating temperature. b) AH the in/actors or glow plugs should be removed before starting the lest. If removing the injectors, also remove the flame shield washers, otherwise they may be blown out. c) The stop solenoid must be disconnected.
4.4b ... and remove it from the rubber grommet in the oil pump housing
fo prevent the engine from running or fuel from being discharged. 4 There is no need to hold the accelerator pedal down during the test, because the diesel engine air inlet is not throttled. 5 The cause of poor compression Is less easy to establish on a diesel engine than on a petrol one. The effect of introducing oil into the cylinders (wet testing) Is not conclusive, because there is a risk that the oil will sit in the recess on the piston crown, instead of passing to the rings. However the following can be used as a rough guide to diagnosis. 6 All cylinders should produce very similar pressures; a difference of more than 5 bars between any two cylinders Indicates the existence of a fault. Note that the compression should build up quickly In a healthy engine; low compression on the first stroke, followed by gradually-increasing pressure on successive strokes, indicates worn piston rings. A low compression reading on the first stroke, which does not build up during successive strokes, indicates leaking valves or a blown head gasket (a cracked hoad could also be the cause). 7 A low reading from two adjacent cylinders Is almost certainly due to the head gasket having blown between them: the presence of coolant In the engine oil will confirm this,
Leakdown test 8 A leakdown test measures the rate at which compressed air fed into the cylinder Is lost. It is an alternative to a compression test, and in many ways it is better, since the escaping air provides easy identification of where pressure loss is occurring (piston rings, valves or head gasket). 9 The equipment needed for leakdown testing is unlikely to be available to the home mechanic. If poor compression Is suspected, have the test performed by a suitably-equipped garage.
4 Timing belt and covers -removal
and
refitting
Note: Fiat specify the use of a spec/a/ timing belt tension measuring tool to correctly set the timing belt tension. If access to this equipment cannot be obtained, an approximate setting can be achieved using the method described below. If the method described is used, the tension must be checked using the special tool at the earliest possible opportunity. Do not drive the vehicle over large distances, or use high engine speeds, until the belt fens/on rs known to be correct. Refer to a Fiat dealer for advice.
General Information 1 The function of the timing belt is to drive the camshaft and fuel injection pump. Should the belt slip or break in service, the valve timing will be disturbed and piston-to-valve contact
will occur, resulting In serious engine damage. 2 The timing bolt should be renewed at the specified intervals (see Chapter 1B), or earlier If It is contaminated with oil. or If It is at al noisy In operation (a scraping noise due to uneven wear),
Removal 3 Set the engine at TDC on No 1 cylinder
as
described in Section 2. 4 Unbolt and remove tho engine oil dipstick tube and remove It from the rubber gromme! in the oil pump housing (see illustrations), 5 Before removing the timing belt check rts tension by turning the belt through 90" with finger and thumb midway between u* injection pump and camshaft sprockets. This will give you an Idea of the tension to apply when refitting, assuming the tension is already correct. Also note the position of the tensions pulley as a reference mark. 6 Release tho nut on the timing bea tensioner, move the tensioner pulley away from the belt and retlghten the nut to hold the pulley in the retracted position. 7 If the timing belt is to be re-used, use white paint or chalk to mark the direction of rotation on the belt (if markings do not already exist), then slip the belt off the camshaft, crankshaft and injection pump sprockets, and the idler and tensioner pulleys. Caution: If the belt appears to be In good condition and can be re-used, it fs essential that It Is refitted the same
wsy
round, otherwise accelerated wear will result, leading fo premature failure. 8 Check the timing belt carefully for any signs of uneven wear, splitting, or oil contamination. Pay particular attention to the roots of the teeth. Renew it if there is the slightest doutt about its condition. If the engine is undergoing an overhaul, renew the belt as a matter of course, regardless of its apparent conditio*. The cost of a new belt Is nothing compa/ed with the cost of repairs, should the belt freak in service. If signs of oil contamination art found, trace the source of the oil leak and rectify It. Wash down the engine timing baft area and all related components, to remove
sd
traces of oil.
Refitting 9 Before refitting, thoroughly clean the tknmg belt sprockets. Check that the tensioner and idler pulleys rotate freely, without any sign ol roughness. If necessary, renew them as described in Section 5. 10 Ensure that the crankshaft, camshaft and injection pump sprockets are still at their TDC positions as described In Section 2. 11 Engage the timing belt with the crankshaft sprocket, then locate it around the idler pufiey and onto the Injection pump sprocket making sure that it is kept taught. Continue to locate! around the camshaft sprocket and finally around Ihe tensioner pulley (see Illustration) Ensure the belt teeth seat correctly on Ihe sprockets.
Page 88 of 225
2D»1
Chapter 2 Part D:
Engine removal and overhaul procedures
Contents
Crankshaft - refitting and main bearing running clearance check... 12 Engine overhaul • dismantling sequence 5 Crankshaft • removal and inspection 8 Engine overhaul • general Information .. Cylinder block/crankcase - cleaning and Inspection 9 Engine overhaul - reassembly sequence Cylinder head - dismantling, cleaning inspection and reassembly .. 6 General Information Engine and transmission - removal, separation, connection and refitting 4 Engine and transmission removal • methods and precautions 3 Engine * Initial start-up after overhaul and reassembly 13
Degrees of difficulty
Engine overhaul - general Information 2 11 1 Main and big-end bearings - Inspection and selection 10 Pistons and connecting rods - removal, inspection, refitting and big-end bearing running clearance check 7
Easy, suftable for FaHy easy, suitable ^ FaMy difficult, ^ Difficult, suitable for % Very difficult, ^ novice with littla | for beginner with suitable for competent ^ experienced DIY suitable for expert DIY « experience | some experience ^ HYmechanic mechanic or professional ^
Specifications
Engine codes See Chapter 2A. 2B or ZC.
Cylinder head Camshaft bearing diameters:* Petrol engines: No
1
bearing 24.045 to 24.070 mm No 2 bearing 23.S45 to 23.570 mm No 3 bearing 24.025 to 24.070 mm Diesel engine: No
1
bearing (In right-hand side mount) 29.990to30.015mm No 2 bearing 25.545 to 25.570 mm No 3 bearing 24.045 to 24.070 mm No 4 bearing (in left-hand side mount) 23.990 to 24.015 mm Valve seat angle 45° ±5' Cam follower (tappet) running clearance In head' 0.005 to 0.050 mm Difference between swirl chamber and cylinder head surface (diesel engine only) -0.765 to 0.055 mm '
Refer
to Chapter 2B for camshaft and cam follower specifications on 1242 cc
(16-velve)
petrol engines. Valves Valve stem diameter (Inlet and exhaust): Petrol engines: 1108 cc and 1242 cc (8-valve) engines 6.982 to 7.000 mm 1242
CC
(16-valve) engine 5.974 to 5.992 mm Diesel engine 7.974 to 7.992 mm Valve face angle 45° 30'±5' Valve stem-to-guide clearance: Petrol engines: 1108 cc and 1242 cc(B-valve) engines 0.022 to 0.05B mm 1242 cc (16-valve) engine 0.030 to 0.066 mm Diesel engine 0.030 to 0.066 mm Cam follower (tappet) sJiim sizes 3.20 to 4.70 mm In Increments of 0.05 mm Camshaft Camshaft bearing Journal diameters:' Petrol engines Diesel engine No
1
bearing 24.000 to 24.015 mm 29.945 to 29.960 mm No 2 bearing 23.500 to 23.515 mm 25.500 to 25.515 mm No 3 bearing 24.000 to 24.015 mm 24.000 to 24.015 mm No 4 bearing N/A 23.945 to 23.960 mm Camshaft bearing running clearance* 0.030 to 0.070 mm Camshaft endfloat* 0.070 to 0.250 mm 'Refer to Chapter 2B for camshaft specifications on 1242 cc
(16-valve)
enginss.
20
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2D*10 Engine removal and overhaul procedures
Cylinder block Bore diameter: Petrol engines: 1106 cc engine 70.000 to 70.030 mm 1242 cc engine 70.800 to 70.630 mm Diesel engine 82.600 to 82.650 mm Underslzes * Increments of 0.010 mm
Pistons and piston rings Piston diameter: Petrol engines: Grade A; 1108 cc engine 69.960 to 69.970 mm 1242 cc engine 70.760 to 70.770 mm Grade 8: 1108 cc engine 69.970 to 69.980 mm 1242 cc engine 70.770 to 70.780 mm Grade C; 1108 cc engine 69.980 to 69;990 mm 1242 cc engine 70.780 to 70.790 mm Diesel engine: Grade A 82.530 to 82.640 mm GradeB GradeC , 82.550 to 62.560 mm Grade E ; 82.570 to 82.580 mm Piston projection above top of bore: Diesel engine 0.637 to 1.162 mm Piston to bore clearance: Petrol engines 0.030 to 0.050 mm Diesel engine 0.060 to 0.080 mm Maximum difference in weight between pistons x 5g Gudgeon pin diameter 17.970 fo 17.974 mm Gudgeon pin-to-plston clearance: Petrol engines 0.008 to 0.016 mm Diesel engine 0.003 to 0.009 mm Piston ring-to-groove clearance: Petrol engines: Top compression ring: 1108 cc engine 0.040 to 0.075 mm 1242 cc (8-valve) engine 0,040 lo 0,080 mm 1242 cc (16-valve) engine 0 to 0.06 mm 2nd compression ring: 1108 cc and 1242 cc (8-valve) engines 0.020 to 0.055 mm 1242 cc
(1
B-valve) engine 0 to 0.055 mm Oil scraper ring: 1108 cc and 1242 cc (8-valve) engines 0.020 to 0.055 mm 1242 cc (16-valve) engine 0 to 0.055 mm Diesel engine: Top compression ring 0.080 to 0.130 mm 2nd compression ring 0.020 to 0.052 mm Oil scraper ring 0.030 to 0.065 mm Piston ring end gap: Petrol engines: Top compression ring: 1108 cc engine 0.25 to 0.45 mm 1242ccengine : 0.20to0.40mm 2nd compression ring 0.25 to 0.45 mm Oil scraper ring 0.20 to 0.45 mm Diesel engine: Top compression ring 0.020 to 0.350 mm 2nd compression ring 0.300 to 0.500 mm Oil scraper ring 0.250 lo 0.500 mm
Connecting rods Gudgeon pin-to-small end clearance: Petrol engines Interference fit Diesel engine 0.014 to 0.020 mm
Page 90 of 225
2D*10 Engine removal and overhaul procedures
Crankshaft Main bearing journal diameters: Petrol engines: 1108 cc engine: Grade
1
43.994 to 44.000 mm Grade 2 43.988 to 43.994 mm Grade 3 43.982 to 43.988 mm 1242 cc engine: Grade
1
47.994 to 48.000 mm Grade 2 47.988 to 47.994 mm Grade 3 47.982 to 47.988 mm Diesel engine: Grade 1 52.995 to 53.004 mm Grade 2 52.986 to 52.995 mm Crankpin Journal diameters: Petrol engines: 1108 cc engine: Grade A 38.001 to 38.008 mm Grade 8 37.995 to 38.001 mm Grade C 37.988 to 37.995 mm 1242 cc (8-valve) engine: Grade A 42.001 to 42.008 mm Grade 8 41.995 to 42.001 mm Grade C 41.988 to 41.995 mm 1242 cc <16-valve) engine: Grade A 41.990 to 42.008 mm Diesel engine: Grade A 50.796 to 50.805 mm Grade B 50.787 to 50.796 mm Main bearing running clearance: Petrol engines: 1108 cc and 1242 cc (8-valve) engines 0.025 to 0.049 mm 1242 cc (16-valve) engine 0.025 to 0.040 mm Dlese! engine 0.027 to 0.066 mm Big-end bearing running clearance: Petrol engines: 1108 cc and 1242 cc (8-valve) engines 0.024 to 0.062 mm 1242 cc (16-vaJve) engine 0.024 to 0.060 mm Diesel engine 0.026 to 0.063 mm Crankshaft endtloat: Petrol engines 0.055 to 0.265 mm Diesel engine 0.049 to 0.231 mm
Torque wrench settings Nm ibf
t
Petrol engines Big-end bolt 41 30 Camshaft bearing caps (1108 cc and 1242 cc (8-valve) engines: M8x 1.25 20 15 MB 10 7 Main bearing cap: Stage 1 40 30 Stage 2 Angle-tighten a further 90°
Diesel engines Big-end bolt: Stage 1 25 18 Stage 2 Angle-tighten a further 50° Camshaft bearing caps 19 14 Camshaft side mounts 19 14 Main bearing cap 113 83 Swirl chamber to head 118 87