RAVERY is a rare phenomenon in the automotive industry.
Sure, every brand will tell you it follows its own unique engineering ethos, but take a more critical look and few makers today actually stray from the pack and risk losing sales in the process.
Take engine efficiency, for example. The general industry consensus is downsized turbo engines are the way to save fuel and reduce emissions with a conventional combustion engine.
It’s certainly true that the average small turbo donk is terrific at delivering impressive fuel consumption… in the official test.
Countless road tests have suggested, however, that in some cases the realworld efficiency of these engines isn’t much better than that of a bigger naturally aspirated engine, especially in urban driving.
We didn’t think manufacturers were actually bending the rules – not until Dieselgate, anyway – we just figured the canny engineers had worked out how to optimise their engines to deliver during the test.
We’re sure Mazda’s engineers are capable of doing just the same – as the industry, we mean, not B Volkswagen. Yet, instead it has largely persevered with the naturally aspirated engine.
There was plenty of scope for improvement because historically the brand has been off-the-pace in the low fuel consumption race. But recent developments have delivered genuine gains with its Skyactiv engines since 2011. So much so that Hiroshima gives us a 6.1L/100km performance car without a snail or battery in sight.
Now there’s geographical influence in Mazda’s engine approach. Legislation in parts of Europe classifies engines based on cubic capacity. This means that, say, a 1.4-litre falls into a less costly bracket than a 2.0-litre. The 1.4 needs a turbo to provide atmo 2.0-
litre performance (or better) and there you have it: a pretty convincing case for the downsized turbo engine, and the reason you’re hard pressed to find a non-turbo Fiat, Renault or Volkswagen these days.
Why doesn’t Mazda, as a global player, follow suit? Well, its cars aren’t that popular in Europe (for no good reason, as far as we’re concerned). Sure they sell there; they’re just not the best-sellers they are here and in their native Japan.
Local legislation doesn’t drill down to cubic capacity like it does in Europe for figuring out registration and other ownership costs, so Mazda plays by a different set of rules.
There’s more to it, though. Even a cursory glance at Mazda’s history reveals it to be the only brand, to this day, to give the world a truly different mass-produced internal combustion engine, the Wankel rotary.
There’s your real reason. This trailblazing manufacturer didn’t hesitate to take its own path because if it didn’t, well, it wouldn’t be Mazda.
Against the backdrop of Mazda history, the brand’s largely naturallyaspirated approach to fuel saving and power making, when most of the industry is agreed on smaller turbocharged engines, actually isn’t that bold at all. M
MAZDA rotary engines are rarely mentioned in the same sentence as ‘low fuel consumption’. So if it is to depart from its petrol piston engine approach and create a lean, green Wankel for a future sports car, it will likely mean re-adopting the turbo, which went on hiatus during the RX-8 era (2003-2012) after featuring in three generations of RX-7. Since the early 1990s, Mazda has worked tirelessly at reducing rotary engine consumption and emissions, including developing hydrogen prototypes and pressing them into trial service. More recent developments have incorporated direct-injection, laser ignition and all-aluminium construction (rather than aluminium/cast iron) in a larger 1.6-litre two-rotor engine.
All-aluminium Skyactiv petrol engines rely on direct fuel injection, a high 13.0 or 14.0:1 compression ratio, lightweight, low-friction internals and 4-2-1 exhaust systems.
Diesels, conversely, use a lower than normal compression ratio, which allows lighter-duty (and weight) components, including the block and connecting rods.
High compression is good, because it breeds efficiency – more power with less fuel – but the limiting factor is detonation, where combustion happens before the spark, which can lead to engine failure.
High cylinder temperatures cause detonation, which Mazda systematically avoids in its Skyactiv-G engine. Petrol directly injected under high pressure through multi-hole injectors creates a fine atomisation of fuel, cooling the cylinder.
Staging the injection allows the flame front to be carefully controlled, with help from specially designed piston cavities.
Clever valve timing phasing allows Mazda to rid more hot gas on each stroke, aiding cooling. A 4-2-1 exhaust also reduces residual hot gas, as cylinders are paired to keep out-of-phase exhaust pulses apart, which could otherwise push exhaust gases back into a neighbouring port. The result is a happy 14:1 compression (same as a Ferrari 458 Speciale) for petrol variants (or 13:1 in Oz, to run on 91 octane).
Think a 14:1 compression ratio is high?
Mazda, which has more than 150 patents on its Skyactiv tech, has played with even higher compression petrol prototypes, from 15:1 to 18:1 compression.
A Homogeneous Charge Compression Ignition engine – a compression rather than spark ignition petrol engine, sort of like a diesel – is the logical conclusion and could be here in a few years.