alright, i was researching and found this... tell me if it's accurate and if it's not, please feel free to correct.... ps: no flaming if it's wrong cuz i did'nt write it...
The wise consumer makes a better purchase than th ignorant one, so if you are seriously interested in turbo performance you at least need to know the fundamentals. This portion of the ongoing discussion is dedicated to the turbocharger, ultimately the most powerful of all forced induction systems. Here I will try to identify each part in the basic turbo system, what it does and why you need it. I’ll also try to keep this on the lighter end of the technical scale, but it’s hard not to get deep into it with this subject.
TURBOCHARGER BASICS
The turbocharger is one complex little piece of work, at least until you get familiar with it. Although a turbo obviously functions as a single piece, it is commonly broken into these three sections for easy conversation…
COMPRESSOR SECTION: The compressor section is identical in function to any centrifugal supercharger, the only difference is that the turbine section of the turbo drives it. One thing to know is that turbocharger compressor sections are (generally) significantly smaller than their supercharger cousins. This all has to do with efficiency and the chosen method of powering the compressor, so just know it’s the reason why you see turbochargers spinning such high RPM when compared to their centrifugal supercharger cousins. It’s all about necessity.
TURBINE SECTION: This section bears a strong resemblance to the compressor section for a reason; it basically functions the same but backwards. The two main parts are the turbine housing and turbine wheel, and if this is an internally wastegated turbo, the wastegate also resides here (there will be more on that later). As exhaust gasses quickly move out of the cylinder and into the exhaust manifold, they are routed into the turbine housing’s scroll. If you understood the flow of air through the centrifugal compressor design discussed earlier, here it’s just the opposite occurring. As the hot and rapidly moving gasses attempt to find an airflow path through the turbine housing (with the ever decreasing scroll area), they come in contact with the turbine wheel on their way to the center outlet of the housing. As they rush through this airflow path and into the exhaust downpipe, they spin the turbine wheel, imparting a portion of their kinetic energy to the turbocharger. Especially notice that with this design comes variable RPM, the turbocharger itself is not physically strapped to any rotating part of the engine. This makes many different turbo shaft speeds possible at a single engine RPM, which is where the system’s basic performance characteristics and tunability are born.
CENTER SECTION (aka bearing section): The center section is definitely the most complex of the three portions. This is what connects both the compressor and turbine sections, and where all of the cooling and lubrication of the unit occurs. Inside the center section is the main shaft, which is what the compressor and turbine wheels are directly connected to. This main shaft undergoes a great deal of pressure, RPM and heat, so the center section is unsurprisingly very specifically engineered to deal with these. The most common and basic center sections use what’s called thrust bearings to keep the shaft spinning, and oil flow from the engine to both lubricate and cool the unit. Two common updates to this proven design are becoming more affordable and widespread; ball bearing center sections and water cooling in addition to oil. The ball bearing center is both more durable and more efficient at transmitting power to the compressor wheel, making it better for performance and longetivity. The water cooling is more for reliability than anything else, helping to stabilize temperatures and prevent oil coking in the housing. Both are worthwhile additions to your turbo purchase if at all possible.
The wise consumer makes a better purchase than th ignorant one, so if you are seriously interested in turbo performance you at least need to know the fundamentals. This portion of the ongoing discussion is dedicated to the turbocharger, ultimately the most powerful of all forced induction systems. Here I will try to identify each part in the basic turbo system, what it does and why you need it. I’ll also try to keep this on the lighter end of the technical scale, but it’s hard not to get deep into it with this subject.
TURBOCHARGER BASICS
The turbocharger is one complex little piece of work, at least until you get familiar with it. Although a turbo obviously functions as a single piece, it is commonly broken into these three sections for easy conversation…
COMPRESSOR SECTION: The compressor section is identical in function to any centrifugal supercharger, the only difference is that the turbine section of the turbo drives it. One thing to know is that turbocharger compressor sections are (generally) significantly smaller than their supercharger cousins. This all has to do with efficiency and the chosen method of powering the compressor, so just know it’s the reason why you see turbochargers spinning such high RPM when compared to their centrifugal supercharger cousins. It’s all about necessity.
TURBINE SECTION: This section bears a strong resemblance to the compressor section for a reason; it basically functions the same but backwards. The two main parts are the turbine housing and turbine wheel, and if this is an internally wastegated turbo, the wastegate also resides here (there will be more on that later). As exhaust gasses quickly move out of the cylinder and into the exhaust manifold, they are routed into the turbine housing’s scroll. If you understood the flow of air through the centrifugal compressor design discussed earlier, here it’s just the opposite occurring. As the hot and rapidly moving gasses attempt to find an airflow path through the turbine housing (with the ever decreasing scroll area), they come in contact with the turbine wheel on their way to the center outlet of the housing. As they rush through this airflow path and into the exhaust downpipe, they spin the turbine wheel, imparting a portion of their kinetic energy to the turbocharger. Especially notice that with this design comes variable RPM, the turbocharger itself is not physically strapped to any rotating part of the engine. This makes many different turbo shaft speeds possible at a single engine RPM, which is where the system’s basic performance characteristics and tunability are born.
CENTER SECTION (aka bearing section): The center section is definitely the most complex of the three portions. This is what connects both the compressor and turbine sections, and where all of the cooling and lubrication of the unit occurs. Inside the center section is the main shaft, which is what the compressor and turbine wheels are directly connected to. This main shaft undergoes a great deal of pressure, RPM and heat, so the center section is unsurprisingly very specifically engineered to deal with these. The most common and basic center sections use what’s called thrust bearings to keep the shaft spinning, and oil flow from the engine to both lubricate and cool the unit. Two common updates to this proven design are becoming more affordable and widespread; ball bearing center sections and water cooling in addition to oil. The ball bearing center is both more durable and more efficient at transmitting power to the compressor wheel, making it better for performance and longetivity. The water cooling is more for reliability than anything else, helping to stabilize temperatures and prevent oil coking in the housing. Both are worthwhile additions to your turbo purchase if at all possible.
