Start Your Engines

I have good oil pressure, so how did my turbo fail due to no oil pressure? 

Sounds like a conundrum but it is indeed possible...

I'm late for work again, jump into my car, lunch in one hand keys in the other, with a slice of toast between my teeth I hit the ignition, bounce off the the rev limiter a couple of times, drop the clutch, hit boost before the front gate, gone!

I get away with this a few times due to a slight  film of oil which hasn't drained into the sump during the night until one day on the way to work I start to hear a metallic sound from my turbocharger; concerned, I ring a turbocharger specialist who just happens to be myself for an explanation of the possible noise.

One of the questions he asks me is whether during "cold start", I allowed the engine to warm up before revving it and I reply rarely because I'm always in a hurry to get to work.

Then the turbo dude explains; on average, the inside of a turbocharger doesn't see oil for about 5 to 15 seconds which I know from testing numerous vehicles. There are a few variables affecting this delay, hot or cold day, oil temperature / viscosity, the distance and route the oil needs to travel before reaching the turbocharger, excessive clearances elsewhere in the engine just to mention a few.

Overnight, the oil drains out of the turbocharger into the sump and leaves only a thin film of oil covering the inside components of the turbo as mentioned above but enough to allow for a safe low RPM start up. Revving the engine hard at start up forces the wheels & shaft to rapidly spin up to around 100,000 RPM, give or take, with no oil pressure inside the turbo for those few seconds.

This will cause the clearances between the shaft and bearing(s) to increase due to abrasive wear from metal to metal contact. The wear is more prevalent on the rear turbine side since the turbine wheel is much heavier than the front compressor wheel and also more on the inside diameter of the bearing than the outer diameter since the inside diameter is the last place to see oil pressure and of course that's the location where the shaft spins.

There is a prenuptial agreement between oil pressure and clearances for their relationship to last;  oil pressure is fairly constant up to about .002 thousands of an inch, increase the clearance and you lose oil pressure exponentially until it arrives at a point when the turbine wheel starts to gyrate until it rubs against other parts of the turbocharger causing a metallic sound as per the enquiry above. Unfortunately by this time all the other components inside the turbocharger including the compressor wheel, bearing housing and back-plate etc. have all sustained damage.

During disassembly of the turbocharger the rear bearing is sometimes jammed solid in the bearing housing and difficult to remove; this is caused due to the turbine wheel being damaged and consequently way out of balance; the turbine wheel and shaft pound the bearing on the inside diameter causing it to expand on the outside diameter whilst the inside diameter increases in diameter dramatically. Final diagnosis; The turbo flat lined ________________  DOA - RIP.

Oil starvation is easy enough to diagnose from inspection of the worn components. The reason however can be problematic to diagnose since an oil pressure and flow test will show no signs of oil starvation given that the turbo failed due to momentary oil starvation by the manner in which the vehicle was started and driven whilst cold. I mention cold, in addition to momentary oil starvation which is more related to time, because oil has a minimum and maximum temperature within which it operates correctly. In fact some massive and/or multiple oil coolers can cause the oil too run too cold and not operate as it should.

Experience has taught us this but a mechanic who is unfamiliar with turbocharged vehicles maybe chasing his tail for some time looking for an oil pressure problem before he realises the driver is in fact the cause of the problem.

Anyway after an expensive lesson learned, I now let my car warm up at idle and drive it easy until the engine is running at its proper operating temperature and haven't had a problem since other than being sacked at work for being late so often.

Vehicle Fault Diagostics Chart

My turbo is leaking oil, is it the turbo?

Loss of power, excess smoke, high fuel consumption, overheating, high exhaust temperatures and oil leakages from the turbocharger are all symptoms that could indicate turbocharger malfunction...

However, these faults are often wrongly attributed to the turbocharger because defects in other components can produce the same symptoms. The turbocharger performance can only be impaired by mechanical damage or blockage caused by carbonisation. Please refer to our Fault Diagnosis Chart For Turbocharged Vehicles, (opens in a new window), which provides a comprehensive list of the most common symptoms related to turbocharger failure before replacing a turbocharger.

If after taking the appropriate action a problem(s) still persists please contact us.

Rank - Name - Serial Number

How do I identify my turbo?

Identification tags on a turbocharger are normally located either on the front of the compressor cover, rear of the compressor cover on the backing plate or on the centre housing near the oil feed or oil drain...

Tags can vary quite a lot pending the turbocharger manufacturer, country in which it was manufactured,  year in which it was manufactured as manufacturers tend to change their style of tag over time or from OEM requirements. Some turbo manufacturers such as IHI prefer to engrave the turbocharger identification details rather than use a tag.

I prefer IHI's method of identification as a tag can be removed, naturally just fall off or fall off during the cleaning process when reconditioning a turbocharger.

Regardless of all the above every turbocharger shares common identification traits:

Model Number or Type: This generally indicates the general size and/or type of turbocharger within a manufacturers range of turbochargers.

Part Number: The specific part number of this turbocharger within the manufacturers specific range of turbochargers as mentioned above. This is best form of identification of your turbocharger for turbocharger specialists to identify your turbocharger.

Serial Number: The specific number for a specific turbocharger for the manufacturers reference to tell them from their records when the turbocharger was manufactured and/or when sold and to whom.

Customer Number or OEM Number: This is the part number assigned to the turbocharger for a specific vehicle for a vehicle manufacturer. The tag may also show the logo of the vehicle manufacturer along with the turbocharger manufacturer. Performance turbochargers for generic use will not have an OEM number.

So how do you identify your turbocharger if the tag is missing?

Vehicle model, engine model and build date all assist in identifying turbochargers however I'm always reluctant to ship out a new turbocharger without the proper tag numbers since sometimes an owner or previous owner may have  retrofitted a different type of turbocharger to his vehicle. An emailed or faxed image also assists in identification. In most cases we can tell you what type of turbocharger it is by just looking at it on our bench from years of experience however when it is an uncommon turbocharger missing a tag we may have to remove the compressor cover and turbine housing to measure the wheels to aid in its identification.

Examples:

Turbocharger Failure Analysis

So what was wrong with my Turbocharger?

Carbonisation:

The most common cause of turbo failure is carbonisation and it is easily diagnosed once a turbocharger is stripped. Most turbocharged vehicle owners would have no doubt heard or read about the importance of regular oil changes and allowing your vehicle to idle for a couple of minutes prior to turning it off.

Contaminated Oil:

Contaminated oil, caused by engine wear or lack of maintenance is also easily diagnosed as it scores or leaves scratch marks on the bearings, bore and shaft in that order due to the hardness of the materials and pending how long the vehicle has been driven with contaminated oil. Carbon and engine wear or damage are the most common causes. The thrust bearing may also suffer severe wear as the small oil gallery feeding the thrust bearing or the even smaller oil galleries in the thrust bearing itself may also become blocked by contaminates.

Air Intake System Contamination:

Dust will leave small nibbling marks on the edge of the compressor wheel blades and is due to either poor maintenance of the air cleaner system, the wrong size air cleaner or a split in a hose or loose intake pipe from the air cleaner assembly to the front of the turbocharger. It is more common in off road vehicles however some owners remove the air cleaner in order to try and gain more power and suffer the same fate. The same dust also enters the combustion chamber and scores the cylinder bores resulting in blow-by or complete engine failure.

Pressure Imbalance:

Thrust wear on the inlet side of the turbocharger generally indicates a problem on the turbine side of the turbocharger, the reverse of what sounds logical Spock. If a muffler has collapsed, exhaust pipe damaged, too small an exhaust system or incorrect sized turbocharger, will result in back pressure in the turbine housing. Naturally one would think this pressure would "push" the turbine wheel forward and consequently wear the turbine side of the thrust bearing which is not the case. Try to imagine pressure as water and the exhaust wheel blades are the propeller on a boat in reverse. Due to its design when it spins in this pressure, (water), it will pull itself backwards towards the rear of the turbocharger hence wear the front or inlet side of the thrust bearing.

Wear on the turbine side of the thrust bearing, is generally due to a problem on the inlet side of the turbocharger but from different causes. If there is a restriction on the pressure side (outlet) of the compressor housing, like the turbine wheel described above, it will try to pull itself forward as if in water, however if the restriction is on the non-pressure side of the compressor cover such as a totally blocked air filter, the turbocharger will create a vacuum or over-speed and the pressure on the exhaust side of the turbocharger will drag the wheels backwards, again wearing the inlet side of the thrust bearing as described in the first paragraph.

As a rule of thumb, inlet manifold pressure, (boost) should equal exhaust manifold pressure or thereabouts. On many occasions I have measured vehicles with 15 lbs of boost running over 50 lbs of exhaust manifold pressure and doomed to fail.

Impact Damage:

Impact damage on the inlet side of the turbocharger will be caused by something foreign entering the turbocharger, no matter how small such as dust mentioned above to something larger which will instantly cause a major turbocharger failure. Impact damage to the turbine blades can be even more concerning as it is normally due to a piece of engine, such as piston or exhaust valve colliding with the exhaust wheel tips causing them to bend, chip or break off altogether.

Excessive Heat:

Bluing of the turbine shaft indicates excessive heat however there can be a number of causes including, lack of oil due to carbonisation, lack of oil pressure or flow, poor oil quality, excessive exhaust temperatures due to lean air/fuel mixtures, incorrect engine or ignition timing, wrong sized turbocharger, or damaged exhaust system are amongst the most common.

Nuked Turbo:

Total turbocharger failure where virtually every component has been obliviated may prove difficult if not impossible to diagnose from trying to determine which component failed first and why. This may be the case if a turbo fails under extreme load or worse, is driven whilst damaged creating a chain reaction damaging all components. A turbine wheel at high RPM has more mass than the much heavier flywheel; I have seen large holes in cast iron turbine housings from turbine wheels exploding under load usually from excessive turbine temperatures due to running too lean in race applications.

A Turbocharger Fault Diagnostics Chart located here, (opens in a new window), gives a few examples of how we can identify the initial cause of a turbocharger failing!

The Impotent Turbine Shaft

Why is there a howling noise from my turbo when I accelerate?

There are a few possibilities such as a momentary lack of oil slightly wearing the bearings and causing imbalance or impact damage to one of the wheels, however the most common cause for a howling type noise is head-droop...

It is a problem most of us males have experienced at some point in our life due to excessive alcohol, however it differs in cause for the turbocharger. Head-droop in a turbocharger is when the head of the turbine wheel droops and is no longer perpendicular to the turbine shaft to which it was welded via a process called friction welding.

In nearly all cases this occurs due to repeated hot shut downs and extreme temperature, fatigue or combination of both. The turbine wheel head is made from a casting and is relatively heavy in comparison to the shaft. If it is repeatedly shut down when extremely hot it may drop slightly and it only need drop a few thousands of an inch to result in a very loud howling noise which is caused by the resulting imbalance. A turbocharger with head-droop will eventually fail.

If having your turbocharger repaired, remember to advise the turbocharger specialist of any noises as it is quite difficult to measure head-droop given there are few if any flat surfaces on a turbine wheel when trying to micrometer such a small amount of movement. If I find a turbine wheel is near or over 0.10g of imbalance I suspect head-droop as the most likely possible cause and contact the customer to enquire whether the turbocharger was noisy or not.

It is possible to balance a turbine wheel with head droop however the wheel will obviously still be offset and it is unlikely the noise will disappear hence its very wise to replace it. I always advise a customer of this circumstance and highly recommend replacing the turbine wheel as it will void any warranty if the customer insists on taking a chance with a suspect turbine wheel.

It is far cheaper to replace a turbine wheel rather than chance one with head-droop only to find yourself removing the turbocharger again to replace it anyway!

Do's & Don'ts when Refitting a Turbocharger

Any tips before I refit my turbocharger!

Yes, firstly I would recommend employing a qualified mechanic and I would also recommend your mechanic read this article if he is unfamiliar with fitting turbochargers...

Safety:

Prior to the removal of the turbocharger, firstly follow the manufacturers' guidelines such as removing battery terminal(s) etc. This may  vary from vehicle to vehicle which can't be covered here but mechanics generally know the common safety procedures before starting any major work on a vehicle.

Precautions:

Cover any holes on the inlet and exhaust or wherever something could be accidently dropped into whilst the turbocharger is being removed,  is away being repaired and during reinstallation. It' s also very important to remember to remove any covers or rags during installation, I have found many a rag in the inlet side of the turbo jammed up against the compressor wheel and on the pressure side of the turbocharger plus the odd socket, bolt or nut in the turbine housing which has consequently destroyed the turbine wheel. Anyone seen the 19mm socket?

Cleaning & Inspection:

First of all work in a clean enviroment with clean tools and hands.

I can't emphasise enough how critical it is that the oil supply pipe or hose and oil drain pipe or hose is thoroughly clean, and I mean absolutely thoroughly, 100% clean! There are small oil galleries in turbochargers in which the smallest speck of any foreign matter could block. If a pipe has a lot of bends in it and your not sure if it is clean, your better off replacing it rather than risking a turbocharger failure. "When in doubt, toss it out!" In extreme cases I have found the fitting or oil supply hole from the engine to the turbocharger also blocked with carbon and/or the sump return hole blocked or partially blocked as well, also insure these are clear of any restriction or carbonisation.

Try cleaning as much excess oil as possible from the inlet pipes and exhaust if the turbo has been leaking oil. If the exhaust manifold is removed, feel in each port with your finger to see if any ports are wet which may indicate a problem with a particular cylinder and a possible cause for the turbocharger leaking or failing initially.

Check all surfaces are flat and they generally are as the materials used to make turbo components are made from high quality alloys if manufactured by a reputable company and rarely bend or crack, however some may due to a vehicle running excessive exhaust temperatures or from a design fault by the manufacturer which creates "hot-spots" from trapped exhaust gases and consequential cracking may occur. Also be wary of exhaust manifold studs, due to prolonged heat they can become brittle and break when tightening and Murphy's Law insists it is the last one you tighten when the job is near complete which will break.

Turbocharger Installation:

Now again, installation may vary from vehicle to vehicle so this is a general guide. If possible fit the oil drain pipe to the turbocharger on the bench, most use 2 bolts, gasket & plate. Make sure the surfaces are flat and DO NOT use silastic as it will restrict the inner side of the oil drain once tightened. If anything use the slightest smear of a non-hardening gasket cement just to hold the gasket in place whilst tightening the bolts. Loosely bolt the turbocharger to the exhaust manifold and again loosely on the engine and check all the intake pipes, oil pipes and engine pipe are going to align up correctly. It's best to find out something is misaligned at this point rather than tighten everything up only to find out you have to pull it all back off again.

If it is a water-cooled turbocharger, again pending the vehicle type, attach these pipes which in most cases use a threaded bolt in a banjo type fitting. I have always used liquid Teflon on the threads to help seal them, Loctite is one company which makes liquid Teflon. If everything was marked for realignment during disassembly you can tighten them all up however if they weren't marked you will have to sit the turbo on the exhaust manifold and see if there is room to tighten them on the vehicle, if not, carefully mark them and remove the turbocharger to tighten. If the water pipes are a 2 bolt plate setup you may use silastic on the water gaskets ONLY but there is still no need to overdo it.

Before fitting the oil supply pipe or hose prime the turbocharger with the aid of an oil can. I assemble our turbochargers with lubricant but some turbocharger specialists assemble them dry so it's just good practise to prime them regardless. If the oil supply pipe is a 2 bolt, plate type like the oil drain above follow the same procedure carefully, again DO NOT use silastic. If it is a flare nut type pipe and fitting again I use a small amount of liquid Teflon on the thread, push the pipe flare downwards onto its mating flare inside the oil feed of the turbocharger for proper alignment then tighten the flare nut.

Installation of Ancillary Components:

At this stage the exhaust manifold, turbo, oil supply , oil drain and water pipes (if applicable) should be all installed and tightened.

Recheck and clean the intake system, air cleaner assembly and pipes are all thoroughly clean and replace any soft or split hosing. Bolt up the engine pipe and heat shields etc. Change the oil, oil filter, air filter and fuel filter as mandatory. Use the grade of oil recommended for your vehicle and it's best to measure the amount of oil your putting into the engine as the oil level can be critical if over-filled by the smallest amount on some vehicles.

Start-Up:

If possible, prevent the engine from firing and crank the engine for 10 – 15 seconds to prime the turbocharger.

Start the vehicle and allow it to idle for a few minutes checking for any oil or water leaks allowing time for the turbocharger to be properly lubricated before slowly revving the engine. This is always a good practise for the owner to do as well when first starting his vehicle as the hot oil will drain from the turbocharger once the vehicle is turned off. Starting it and "revving the ring" out of it before the turbocharger has obtained proper oil pressure will insure an early failure.

Switch off the engine and re-check the oil and water levels.

Test drive the vehicle to insure it's running the correct boost as per the manufacturer's specifications. A dyno tune is advisable to insure the vehicle isn't running lean or rich under idle, cruise and boost conditions and check ignition timing.

Hopefully the original cause for the turbocharger failure was diagnosed and corrected, if not get ready to remove it again. Never replace a turbocharger without diagnosing why it failed in the first place.

Disclaimer:

All the above information I have learnt over many years and applies to turbocharger installations in general , however manufacture design may cause some slight variations to the above guide for specific vehicles. Torque settings, oil types and other specific details should be sourght from the vehicle manufacturer.

The Turbo Blues

I just fitted the turbo & it's still blowing smoke, why?

The most frequent question I've been asked over many years and more often than not by mechanics because in fairness they may rarely repair a turbocharged vehicle...

Unfortunately in most cases where mechanics aren’t familiar with turbocharged vehicles, analytics is limited to, "the turbo is leaking oil so it must be the turbo!” The dilemma is although the turbo was indeed leaking oil it is usually due to some other factor causing it to leak or inflict damage to it. Don't resolve the actual primary source of the problem and you will be back to where you started, oil leakage from the turbo and/or blue smoke after you have replaced it coupled with total frustration as to what to do next. I'm sure most mechanic's initial response is, "I'm going to exterminate the dude who rebuilt this turbo!”

I've spent many hours, months, years on the phone going through a check list of tests due to the turbocharger being the most misunderstood, victimised and cursed component on any vehicle when in fact it is one of the most reliable. Most of the tests listed below won't be found in any workshop manual as turbo fault diagnosis is not taught at trade school, it’s learnt from experience, theorised during many a sleepless night, and tested over the years. In most cases, one of the tests below will find the cause of your smoke quandary unless it falls under the category, “other possibilities”.

What's a Piston Ring Seal Anyway?

Briefly, most turbochargers use piston ring seals¹ & when installed there is a specified minimum / maximum measureable installed gap² as per the turbo manufacturer's specifications to allow for expansion caused by heat. In addition to the seals the machining design on the rear of the turbine wheel shaft³ & front collars are intended to throw any oil in the vicinity of the seals back towards the centre of the bearing housing as it spins, loosely termed as an "oil slinger".

If there is fault causing oil to be forced or build-up against these piston ring seals they will indeed leak as technically their not oil seals,  their primary purpose is to prevent boost on the inlet side & exhaust gases on the turbine side from entering into the bearing housing, the reversal of what is commonly presumed.

Technically a turbocharger fitted on a good engine with correct oil pressure, adequate oil drain and well designed breather systems etcetera, could operate with no seals installed at all and would not leak.

Pressurised oil enters the bearing housing and stabilises the turbine shaft. After the oil passes through the bearings it falls into a cavity at the bottom of the bearing housing making it's way back to the sump via an oil drain system, the flow rate back to the sump is governed solely by gravity.

A common statement I hear from many customers; "My turbo must have faulty seals" is not in fact a realistic possibility.

The following image displays the manner in which oil flows to the turbocharger from the engine oil supply under pressure then returns to the sump via gravity, it is then picked up by the oil pump and the cycle keeps repeating itself whilst the engine is running.

1. Unburnt oil in the inlet or exhaust system / condensation:

Quite often after a turbocharger is fitted back onto a vehicle the installer will start the engine, observe smoke from the exhaust, turn off the engine then ring me. The turbocharger was removed because it was leaking oil so naturally there will be puddles of oil in either the inlet system, exhaust system or both. Sometimes there may be as much as half a muffler full of oil and this will take quite some time to dissipate before smoke stops being emitted from the exhaust system therefore allow plenty of time for smoke to clear.  On more than one occasion I've found the problem was as simple or silly as condensation on a coldish day. It's important to remember oil burns bluish/white when it leaks from the inlet side and is partially burnt in the combustion chamber, conversely oil burns whitish/blue when it leaks out of the exhaust side onto a hot exhaust, fuel burns black and condensation white. Also condensation will evaporate into the air very quickly where oil or fuel will linger around or be blown into the distance by wind. Oil quite often is also accompanied with a pungent smell.

2. Valve cover smoke test:

Very simple yet very reliable provided the engine oil isn't well overdue for an oil change and lost all of its viscosity. While the engine is running at operating temperature, with rag in hand, undo the oil filler cap carefully so as to not get splashed with oil. It is best to tilt your head level with the valve cover and check if there are any signs of visible fumes being emitted whilst giving the engine a few light revs. You may feel some pressure which is usually normal on some vehicles but no signs of fumes or smoke whatsoever which is generally the signature of engine blow-by which is oil making its way into the combustion chamber, partially burning then returning back  as smoke out through the open oil filler via the timing cover.

Blow-by will cause pressure in the sump restricting the oil being returned from the turbocharger, a bit like putting your thumb over the oil drain pipe. Oil enters the turbo under engine oil pressure; however after it has left the turbo bearings there is no oil pressure at all on its journey back to the sump. If there is any sump pressure, no matter how minuscule, it will prevent oil returning to the sump and force it out of the turbo through the piston ring seal(s). Pressure in the sump increases as boost increases & the smoke from the valve cover also increases but you can only test this under boost with the aid of a chassis dyno although having said that I have to admit I have tested vehicles on the road by installing a very long breather hose into the passenger side window. Anyway on the dyno under full boost it is better to remove the breather hose to try and view any fumes rather than the oil filler cap to avoid oil being splashed around the engine bay.

3. Too much oil, over-filled:

Should the sump oil level be above or equal to the oil drain outlet from the turbo into the sump, the oil in the sump will restrict the oil flowing back into it and consequently force oil to leak out of the turbo piston ring seal(s), so one of the first and simplest things to first check is the oil level and importantly on level ground. This is more critical on some engines than others pending where the oil drain in the sump or engine block is located, "just above or well above" the oil level in the sump. Porsche 924T & Nissan 300zx are just two examples of some vehicles where the amount of oil needs to be carefully measured when changing oil.

Two mechanics pulled up in a VL commodore which I had just reconditioned the turbocharger for, I think, ready to rip my arms off gauging by the bulging veins in their eyes. After checking for blow-by as above, (Step 2), I checked the dip stick & found it was well above the maximum oil level mark and whispered to myself "there is a God after all"! Quite pale looking in the face by now, they looked at each other & asked in sync "did you fill it up with oil?" & sure enough they both replied in sync "yes", the maths part was easy, 10 litres of oil in the engine; problem solved.

A lady from the country dropped off a Nissan 300ZX twin turbo which used to blow blue-white smoke more out of the left exhaust pipe when turning right on a long sweeping bend and vice-versa when turning left; I'll leave that one with you to ponder about. As a clue, similarly a young chap’s Nissan Exa E15T, only smoked going down a couple of very long, steep hills on his way to work but no sign of smoke on his way home.

4. Blocked air filter or intake pipe(s) / intake hose(s):

Any restriction at the intake side of an engine such as a heavily clogged air filter will result in oil leaking from the inlet side of the turbo. The compressor wheel, whilst spinning to generate boost will attempt to source large volumes of air from wherever possible, if it cannot acquire enough air via the intake system, it will tend to pull oil from within itself through the front piston ring seal.

It may also drag oil from the breather hose pending its location.

If there is a severe blockage it may also cause thrust bearing wear allowing excessive end-float from a pressure imbalance leading to a severe turbocharger failure.

I have seen "soft" intake hoses collapsing under higher RPM as the inner walls of the hose pull inwards, touch and act as a seal.

If leaking oil puddles in the bottom of the compressor cover to the point where the compressor wheel blades are "scooping" oil, it will tend to pull the compressor wheel downwards wearing the bearings and other turbo components, again causing severe turbocharger failure.

Should there be a leak in the air cleaner assembly, split hose or loose pipe due to an unfastened clip or clamp, dust will be drawn into the intake system, damage the compressor wheel and score the cylinder bores of the engine requiring both an engine and turbocharger rebuild.

5. Blocked or kinked breather hose(s), blocked PCV valve:

All engines must breathe as the action of the pistons travelling up and down act as an inverted air compressor on the sump side of the pistons which must be vented. Check the breather connections aren't blocked, hose's are not kinked or softened and any breather filter, canister or air filter assembly is free from oil, dust, dirt or debris. Breather system designs vary from vehicle to vehicle but the principle of removing pressure is a common denominator.

On many “extreme” race vehicles it’s common for a vacuum pump to be fitted to the lower part of the engine block or upper sump area, pumping and directing any pressure generally into the exhaust system.

A regular customer popped in with his twin turbo Toyota Soarer emitting smoke profusely from the exhaust system. He had fitted a "high performance catch-can" with an oil bleeder to his vehicle the night before and presumed he had installed it incorrectly. We checked the vehicle on the chassis dyno and sure enough clouds of smoke were bucketing out of the exhaust. It didn't take long at all to diagnose the problem; the original Soarer breather hose is 1 inch in diameter and the catch-can kit was fitted in line with the original, as per the instructions. We discovered the 1” hose entering the catch-can and a 5/16 of an inch fitting and hose exiting it thus the engine couldn't breathe properly, sump pressure was introduced because of the design of the catch-can and consequently oil leaked from both piston ring seals of the turbocharger resulting in smoke.

We had a flood a phone calls shortly thereafter by Soarer owners with the same problem due to the breather kit being promoted as a “must have “on the Soarer Club forums. We just quickly explained how to solve their problem over the phone and the problem soon went away.

6. Spark Plug test: (Consider doing Test # 11 whislt the plugs are removed)

Reading spark plugs can give some very detailed signs about your engine condition, individual cylinders, tuning etc. Any oil fowled plug(s) will indicate probable blow-by via the engine piston rings or valve guides consequently causing your turbocharger to leak oil. A damaged spark plug(s) can cause impact damage to the turbine wheel causing imbalance and eventual turbocharger failure. Remove your spark plugs numbering them and check them against the chart below.

7. Engine oil quality:

Replace a turbo, replace the oil & filter. If the oil is rarely replaced, it soon loses its viscosity due to the heat it acquires when cooling the turbocharger. Once it loses viscosity it has the characteristics of water which will result in a possible variety of problems. I have solved many a "smoking" vehicle after a turbo replacement by replacing the new "cheap" oil, if it was changed at all, with turbo quality oil and correct grade. Also on a turbocharged engine, synthetic oils need to be changed more frequently rather than every 20,000 Km or more as advertised.

Occasionally a customer will use a particular oil in his vehicle from the day it was first purchased, change the brand & the car emits smoke via the exhaust, put the original brand back in & it stops; rare but it has happened to me a handful of times and I have no idea why! One case I clearly remember was a vehicle which had always used Penrite HPR30, the owner for some reason supplied Castrol GTX, we changed the oil and the vehicle smoked profusely, we replaced the Castrol with Penrite and the vehicle stopped smoking almost instantly; go figure! This is in no way a bad reflection on Castrol as the reverse has also occurred.

8. Oil drain restriction: silastic, kinked hose, carbonised pipes:

Many a turbo will leak oil or fail due to carbonisation caused by lack of oil changes and/or repeated hot shut downs which I will cover in more detail elsewhere since carbon build-up in the turbo is removed during the reconditioning process and not related to installation. However if the turbocharger was heavily carbonised it's very likely the oil supply and oil drain pipes were also carbonised, some totally. What is carbon? Think of it as lethal, heat treated, hardened, black kryptonite which if not completely removed will destroy your turbocharger. It may be relatively easy, very difficult , or virtually impossible to remove pending how long the lack of maintenance and/or hot shuts downs continued for.

Soaking in a cold or hot acidic* bath over night, preferably sonic, should soften the carbon although sometimes it only softens a small amount at each end in extreme cases. Digging with wire, tapping with a dolly, applying heat, drilling, an industrial jack hammer or TNT may also assist. The oil feed pipe can sometimes be near impossible to clean properly if at all as they are smaller in diameter, around 1/4"  in most cases and can be long with many bends. The oil supply is probably best replaced in most cases. Oil drain pipes generally are much larger in diameter and a tad easier to clean but not always. Anyway the point is both pipes have to be completely cleaned or replaced with no doubt of cleanliness attached whatsoever!!!

Be cautious of some vehicles, particular some front wheel drives, where the vehicle manufacturer, not caring or not knowing, ran the oil supply pipe directly along the top of the exhaust manifold to insure carbonisation occurs, In these cases the turbo maybe fairly clear of carbon but destroyed due to no oil yet the oil supply pipe maybe partially or totally blocked. Fit a new turbo without cleaning the pipe and the new turbo will fail immediately.

*DO NOT fool around with acid unless you follow all the safety precautions, have all the required protective clothing, proper ventilation, stored in a safe place etc. In fact it’s best left to professionals.

9. Oil drain removal test for sump pressure:

Another way to test for sump pressure is to remove the oil drain pipe / hose if easily accessible. Requires two buckets and a hoist is handy if available. Whilst the engine is running allow the oil to drain into a bucket, not too much of course to starve the engine of oil, then switch buckets and pour the engine oil back into the running engine via the oil filler. Continue to do this for about 15 mins to test if the smoke being emitted from the exhaust starts to reduce. Since we have eliminated the sump from the equation, should the smoke reduce you now know the problem lay with sump pressure & then analyse why. This method is only good for a vehicle emitting smoke at idle as we are not introducing boost, some vehicles only emit smoke at idle, some only under boost and some under both conditions which requires a different type of test.

10. Sump pressure test under boost conditions:

This test is best conducted on a chasis dyno but can also be conducted on the road with a passenger. Using a good quality vacuum hose, slip it over & cable tie it to the dip-stick tube, (remove dip-stick first :) ). Insert the other end onto a good quality, vacuum / pressure gauge which displays small increments of pressure and vacuum. Run the car up on the dyno, or if on the road, pass the gauge through a gap in the bonnet then through the passenger window. Obtain full boost whilst watching the gauge and the indicator arm should never travel into the positive side of zero. Any reading, no matter how small above zero will point to sump pressure causing the turbo to leak oil.

*Insure the oil drain pipe/hose in properly connected when using this method as a test!

11. Compression & leak-down tests:

Most mechanics would have completed a compression or better still a leak down test well prior to the above tests I have already mentioned, however I have found them to sometimes give a false positive i.e. all is ok when in fact all maybe not ok. If the turbo was leaking oil profusely then it's likely all cylinders will have a fair degree of oil in them. Under compression or leak down test the oil will tend to disperse outwards then downward the skirts of the pistons and effectively act as a seal between the engine piston rings and bore consequently indicating compression is good which may not be the case, (unless you have a damaged piston). However I do rely on a leak down test to test valves and guides with a fair degree of confidence. Oil leakage through valve guides into the combustion chamber will also cause smoke and most mechanics will presume it’s once again the turbocharger at fault.

12. Too much or not enough oil pressure / flow:

Not very common and occurs mainly due to lack of maintenance in the case of a sticky oil pressure relief valve or as a result of high pressure oil pumps in race applications. More pressure, more volume; too much oil will flood the bearing housing as it can't drain quick enough back into the sump and consequently oil will leak from the turbo piston ring seal(s). Obviously removal and cleaning or replacing the oil pump relief valve should solve that problem. Conversely not enough oil pressure will cause a turbo to self destruct rather than leak. Oil pressure can be lost elsewhere in an engine for any number of reasons causing low oil pressure at the turbo as well. Too test whether there is too much or not enough oil flow follow the directions in bold below.

In the case of the race engine where the owner requires higher oil pressure for other reasons a restrictor can be placed in the line to the turbo however this must be done with much care as not enough oil will obviously cause the turbo to fail in a major way. In order to fit a restrictor you first need to source the required information; "the flow per minute of oil for the turbocharger from the turbo manufacturer and measure this amount out of the turbo oil drain pipe". Start with larger inside diameter restrictors and gradually decrease in size until you find the correct size restrictor that meets the turbo manufacturers specifications at the correct given engine rpm.

If oil pressure needs to be checked it's best done at the oil entry to the turbocharger and will require a fitting to be made for the oil pressure gauge which will vary pending the brand of turbo.

13: Other possibilities:

Some vehicles have their own quirks from the manufacturer such as the oil drain pipes being located only a smidgen above the engine oil level as mentioned earlier.

Another which caught out a mechanic mate of mine and a very good mechanic at that, his son has won Bathurst a few times, was on a Volvo which had an oil strainer inside the sump on the oil drain which was blocked; I rebuilt the turbo twice and finally, yet reluctantly gave him a new turbo as I couldn't find any problem with the original after which the actual fault in the sump was finally found.

On a RB30ET engine you have to be careful the moulded bend in the oil drain hose is not kinked and the bend is above the oil return hole in the sump otherwise it will puddle in the bend of the hose and cause the turbo to leak.

Hardened valve stem seals, fairly common with older vehicles, will allow oil into the combustion chamber causing smoke and causing the mechanic to think it is the turbo only to find removal and repair of the turbo didn’t solve the problem. Some cylinder head experts reuse the old valve stem seals and as a consequence they prematurely harden or even pop off.

I've had the wrong dipstick fitted to one vehicle causing it to be always over filled with oil hence measuring the amount of oil when draining it from a vehicle is a good practise before removing the turbocharger.

A Mazda was towed to our premises from a rotary specialist, the vehicle was smoking at idle after an engine and  turbo rebuild, we found the oil squirter lever for the pistons cable tied & feeding too much oil causing the smoke.

Another rotary specialist, another turbo rebuild causing smoke. After removal of the oil drain we found the oil splash tray inside the engine pushed up hard against the oil drain hole, we bent the splash tray back and problem solved.

Same customer above fitted a new T4 turbo to a rotary, it started leaking oil due to high oil pressure, the factory Hitachi turbo oil feed pipe has a built in oil restrictor to compensate for high oil pressure which the Garrett T4 retrofit doesn't have.

Yet another RB30ET was towed in after a turbo refit and we found the diaphragm on the automatic transmission was leaking oil which was attached to the inlet manifold via a very long pipe; when the inlet manifold saw vacuum, transmission fluid would leak upstream into it causing smoke.

A Pulsar was towed in this time not for smoke but it wasn't making any boost, the Nissan specialist mechanic replaced the air filter but didn't remove the zip pull cardboard packaging from the bottom side of it, no air = no boost.

I sold a new turbo to a workshop who retrofitted it to a Holden 202; they drove the vehicle around to our premises because of smoke bellowing out the exhaust. I popped the bonnet and found the turbo fitted in a vertical launch position similar to a space shuttle prior to take-off at NASA. Oil was leaking straight out the rear seal into the exhaust.

Another Holden 202, carburetted, used for speedway with a new turbo, new engine and a high pressure oil pump fitted. Since it was running very rich I initially thought it maybe blow-by causing the problem, (polished bore from too much fuel), so I advised him to disconnect the oil drain & drain the oil into buckets as per test # 9 above. He rang back and said that didn't help, he also said he found it easier to run a hose from the oil drain uphill into the valve cover oil filler. I then explained why an apple falls out of a tree and oil won't flow up hill. It turned out to be both, glazed bore and too much oil pressure.

I wish I had a dollar for every time I was told ”I just rebuilt the engine it can’t be blow-by” as I’m looking at smoke from the removed oil filler cap, (See Test 2), hovering around the ceiling of the building and an air cleaner assembly full of oil from the breather hose.

Patched up used cars, I’m not even going to go there as I won’t live long enough to finish this paragraph if I do!

The list goes on and on, too many to mention and the possibilities probably infinite. I could certainly embarrass some well know performance mechanics and probably should as prior to having a vehicle towed to me for diagnosis I would usually receive a scathing phone call by the mechanic who has assured me it’s definitely the turbocharger as everything else has been thoroughly checked and in return rarely even a thank you when the actual fault was diagnosed, fixed and towed back.

However I'm human as well and not impervious to err, “people who live in glass houses ...” Anyway I'm drifting off topic a tad as I reminisce whist reaching for an indigestion tablet when the main point of this long paragraph is to try and encourage you to think outside the box rather than jump to the obvious conclusion being, "the turbo is leaking oil so it must be the turbo" as mentioned somewhere above. In addition, these days you can search the internet also for any paranormal activities common to a specific vehicle which hopefully will solve your problem before removing the turbocharger.

14: The Turbocharger:

Although extremely unlikely it is possible that the turbocharger wasn't properly micro-metered when it was rebuilt. The piston ring seals, centre housing seal hub, turbine seal hub, thrust assembly, end float and radial play etcetera all have minimum and maximum tolerances which require measuring which is standard procedure when rebuilding a turbocharger. I personally balance and micro-meter every turbocharger before assembly and have done so for many years and guarantee no turbocharger leaves our premises with incorrect specifications or is out of balance.

In addition to this I have the necessary equipment to test and double check a core as an assembled unit as added insurance.

Source: http://www.procharge.com.au/