Ask Joe Mechanic: Turbocharging Part 1

Over the next several weeks, we are going to discuss turbocharging and supercharging.

Compressor Section of an Automobile

We’ll start with the history of turbocharging, followed by how it works and its main parts. We will then do the same for supercharging. After completing these, we will discuss the advantages and disadvantages of each in a comparison.

            Alfred Buchi of Switzerland who developed a compressor driven by exhaust gas to force air into the intake of a diesel engine to create more power patented the first turbocharger in 1905. It still took another twenty years though before an actual operating turbocharger was built for vehicular use. There were several attempts by the French to turbocharge some types of airplane engines in World War I with limited success. Turbocharging of aircraft engines was perfected by the early 1920s and a short time later the same thing took place on diesel engines on ships. 

The two biggest problems to developing a turbocharger for automotive use were the ability to scale down the size and manufacturing a seal that could be small enough but withstand the pressure and heat inherent to turbocharging. There were some applications to racecars during the 1940s and 1950s, but many of these were adapted aircraft turbochargers. The first manufacturer to produce a production built vehicle with turbocharging was Saab in 1977. Other manufacturers followed, unfortunately, many of the early turbochargers failed due to heat and seal problems. Saab started using a turbocharger which was cooled by antifreeze in 1986, and this proved much more reliable. Since that time, and especially in the last few years, turbocharging has become very popular because of the ability to derive the same or more power from a much smaller displacement engine, thereby achieving a much higher gas mileage without sacrificing performance, and in many cases bettering it.

The theory behind turbocharging is actually quite simple. In most internal combustion engines, the intake mixture of gas and air is actually drawn into the engine by the downward movement of the piston. In a turbocharged engine, that intake charge is forced into the engine by the turbocharger, resulting in a much larger volume of intake charge, which when ignited by the spark plug, creates much more power. The pressure to force that charge into the intake comes from the other half of the turbocharger, which is spun by the exhaust gases that are escaping from the engine. Also, the use of pressurizing the charge causes it to burn more fully, which increases the fuel efficiency of the vehicle.

The control of turbocharging has evolved dramatically in the last few years and is now quite complex. Many manufacturers now use knock sensors, all use waste-gates and blow off valves. And many use variable geometry and intercooling. 

            Boost is the term applied to the amount of pressure created by the turbocharger above normal atmospheric pressure. The level of boost is normally indicated on a pressure gauge in bar, psi or kPa. Boost pressure must be controlled so that the design of the engine is not exceeded which would cause it to fail prematurely. Over-boosting can damage the engine by overheating, over-stressing of parts or by detonation. Detonation or preignition means that due to the amount of heat and pressure, the intake charge ignites before the piston is near the top of its cycle. This exerts undue stress and heat on the internal parts. This is controlled with a knock sensor, which if it detects detonation, signals the computer to open to blow-off valve, which will release the boost pressure. The same thing can be achieved by the waste-gate which is vacuum controlled.

            The main components of the turbocharger are the turbine, which is a radial flow design to build pressure on the intake side. The compressor section is where the exhaust gas passes through to build the pressure. The center housing is where the seals, lubrication and cooling are contained. The size and design of the compressor components dictate how much boost it will create and how quickly it will build to maximum boost. In some turbochargers, it is possible for the impellor to spin at speeds of up to 250,000 rpm. This is the reason that seal design, heat dissipation and lubrication are so important.

Next week we will discuss the types of turbochargers and the other related technologies. Some information for this article was sourced from www.wikipedia.org.