So you've decided to run an oil cooler....I didn’t want to fit an oil cooler behind the drivers side fog light- there is a lot of room here, but its position means it is more likely to be damaged in the event of an accident, plus I have Raptor’s CAI sitting at home waiting to go on and didn’t want to be heating up the air that the intake would be drawing from. I already see IAT’s 40+c above ambient on track!
I also wanted to keep the cooler out of the air stream for the radiator, which only left the minimal amount of space behind the passenger fog light, sitting in the space between the washer bottle and the bottom of the front bumper. Because of the limited space I was only able to fit a small cooler there, but with a surprising large amount of fresh air available to it and a good path for its exhaust it has proved to be quite efficient!
As space was limited I settled on a Fenix 10 row plate-and-fin style oil cooler, as these tend to be the most efficient and impose as little restriction to flow as possible. This cooler uses -AN10 style fittings for as little flow restriction as possible, and makes designing and constructing your own custom hoses very straightforward.
As the oil hoses will be running the full width of the car I chose to get double-braided lines to suit the -AN10 fittings. The downside of these is they aren’t particularly flexible, but with a Nylon inner braid and a woven stainless-steel outer braid it should help prevent any impacts cutting such an important hose.
I didn’t want to do any major modifications to the oiling system on the engine itself, which meant a sandwich plate with a built-in thermostat for the oil take-off was perfect. I used one made by Mishimoto, and I got the one that has dual 1/8” NPT ports so I didn’t have to use a ‘T’ for oil temperature and pressure sensors (part number MMOP-SPTR). The thermostat in this opens at 85c.
The layout of these is quite clever. The thermostat, when below its set temperature, holds open a bypass through the sandwich plate, but still allows a small amount of oil to flow through the oil cooler. Then ensures that when the bypass closes there isn’t a large amount of cold, thick oil that was already in the cooler getting dumped into a warm engine. When the oil is up to temperature this bypass is blocked off, forcing the full oil flow through the cooler.
I initially used Teflon tape to try and seal the adaptors that go from the M20x1.0 sandwich plate fittings to -AN10. However, these fittings seeped about 50-100ml of oil between services and made a bit of a mess. I have since redone these fittings with proper Dowty bonded seals, which are showing no signs of seepage after 20k kms. These seals are quite pricey but totally worth the money in situations like this.
I learnt the hard way that cheap -AN fittings are cheap for a reason. The ones that came with the hose both failed as I was tightening them, so I ended up going all in on some stunning Raceworks fittings! These worked great even with the double-braided hoses, and I have had zero issues with leaky fittings in the 18ish months I’ve been running the cooler.
These are very straightforward to assemble. I found an angle grinder to be the best tool for cutting the stainless braided hose, with minimal deburing required afterwards. The end of the hose can then be forced into the threaded end of the fitting, and then the whole assembly threads together. Tape around the hex sections helps prevent scratching the anodised aluminium, and a wrap of tape around the hose right after the fitting helps make sure it’s obvious if the hose is pushed out while the fitting is threaded together. A small drop of oil on the threaded sections of the fittings helps stop the relatively soft aluminium from galling as the assembly is tightened up.
A draw wire was used to drag small pieces of rag through the assembled lines to remove as much gunk as possible before filling the system with oil. I ended up also flushing the lines with some spare oil as well to ensure they were as clean as possible.
The hoses were run from the oil filter and behind the front aluminium smash bar to try and protect them as much as possible- the lines don’t extend out past any of the front crash protection at any point. I used -AN10 hose separators, modified so I could bolt them to the aluminium crash bar with riv-nuts. This is one thing that could be potentially improved upon- the hard mounting of the oil lines and cooler transfers a fair bit of vibration into the aluminium front bar, and causes quite a bit of noise. Some custom 3D printed flexible mounts are on the cards to see if this noise can be reduced- it sounds like a fairly loud hum that changes with changing engine RPM.
The cooler itself was mounted using a bracket made of aluminium, with the idea being to allow the cooler to be able to move fairly easily in the case of an accident and hopefully prevent it from rupturing. There is not much room in my chosen location; I had to change the angle of the windscreen washer pump, redo some of the pump and fog light wiring and change the routing of the washer hoses to get this to fit.
As the cooler was sitting well below where the factory under-tray extension of the wheel arch liners sits these plastic guards had to be cut off. As I did not want the cooler to be exposed to things possibly bouncing up and impacting it I made a guard out of 5mm thick 7075 aluminium, for its very high strength to weight properties. This guard bolts on to the wheel liner and the bumper, giving a smooth surface to protect the cooler from sticks and rocks, as well as smaller impacts, and funnels air through the cooler from the hollowed-out fog light surround.
The passenger fog light surround had its hexagons hollowed out to allow for easy airflow into the cooler area. As this left the surround looking quite empty, and had the possibility of letting sticks or rocks into the cooler area I also plastic-welded in some metal mesh to give the area another layer of protection. This has the additional benefit of making the hollowed-out section much harder to see! I now have two different guards; one hollowed out for track or hot summer days, and one closed off for cold weather freeway driving where I need every degree of oil temperature!
This guard has been tested late one night up in the Alpine National Park, where an unfortunate run-in with an approx 2kg rabbit at almost 100km/h right in the middle of the oil cooler’s location saw zero damage to the precious cooler! I have since also beefed up the front bumper in this location with some strips of aluminium bar and extra layers of fibreglass.
This small cooler has made a significant difference to the trackability of my car! With a small drop in ambient temperature (I have never had consistent track day temps….) the hottest I’ve seen my oil temperature is 126c. This is quite a significant drop for such a small cooler; I put this down to a relatively optimised placement and good air ducting; and I have never seen oil temperatures above 118c through the hills on even the hottest of days. Paired with a triple core 42mm thick alloy radiator this setup allows for consistent hot laps (until brake or tyre fade anyway) with zero cooling issues.
Another benefit of this is an increase in oil capacity- an oil change now takes the best part of 7 litres, and accompanied with the PBMS baffled sump plate the setup offers great piece of mind regarding oil starvation in higher g corners. The increase in oil capacity also helps dampen out sudden temperature fluctuations, where short sprints don’t get the oil as hot as it used to.
The downside to this is oil temperatures on the highway- these are only borderline warm enough and are another downside to a dedicated oil cooler. On these colder nights the car struggles to get the oil above 85c, and this is with the thermostatic sandwich plate and even going as far as blocking off the airflow through the cooler with tape. If the ambient temperature is above 20c the oil temps hover around 92-95c, which is much more comfortable.
I have also switched to a high-flow 84c coolant thermostat, with the intention of increasing coolant temps while on the highway, with subsequent increase in oil temperatures thanks to the factory oil warmer. This thermostat sees the coolant sit around 88-90c while cruising on the highway, but being high-flow allows the system to better utilise the larger volume of the upgraded radiator, and through the hills I have actually seen a reduction in coolant temperatures compared to the stock thermostat with the upgraded radiator.