Automotive How does using a VTG help in reducing turbo lag

  • Thread starter Thread starter monty37
  • Start date Start date
AI Thread Summary
Using a Variable Geometry Turbocharger (VTG) helps reduce turbo lag by allowing for a low boost threshold, enabling the turbo to generate boost at lower RPMs. While lag cannot be completely eliminated, VTGs minimize it, particularly at higher engine speeds where traditional turbos struggle. The effectiveness of a VTG is influenced by the granularity of its geometry control, which determines how finely the turbo can adjust to varying engine RPMs. Electrically operated VTGs may have limited control steps, impacting their performance, while purely mechanical systems can offer more continuous adjustment. Overall, the control mechanism, often managed by the ECU, plays a critical role in optimizing turbo performance across the RPM range.
monty37
Messages
225
Reaction score
1
In what way does the VTG help reduce turbo lag at low speeds? and can the lag be eliminated completely?
 
Engineering news on Phys.org
So one can still feel the difference when driving at low speeds ...and when shifting to high speeds..but they are really effective only at high speeds na?
 
You might not be able to "feel" it. If the geometry control is fine grained enough, the point when the turbo starts adding power might not be noticeable, but it would be measurable. I'm not sure what you mean by the latter half of your post.
 
The link says "VGTs have a minimal amount of lag, have a low boost threshold, and are very efficient at higher engine speeds" so that's what I asked. And may I know what you mean by geometry control being fine grained?
 
monty37 said:
The link says "VGTs have a minimal amount of lag, have a low boost threshold, and are very efficient at higher engine speeds" so that's what I asked. And may I know what you mean by geometry control being fine grained?


Low boost threshold : this means they start making boost at low RPM.

Minimal lag: Same thing.

Very efficient at high engine speed: Traditional (non-variable) turbos are trade-offs and only work well at one end of the RPM range or the other. Variable turbos work well at both ends.

By fine grained I mean the degree with which the geometry can vary in relation to engine RPM. The purely membrane/mechanical ones should are infinitely variable in theory. Electric and hydraulically operated vanes will be subject to the granularity provided by the control mechanism.

An electrically operated VGT that only has two states (open and closed) would function exactly like a non-variable turbocharger. I'm not familiar enough with the systems to say if the electrically operated ones are digitially controlled, but I would bet they are, and this means there are a finite number of "steps" the vanes can be put through between fully open and (nearly) fully closed.

The more steps you have, the more fine grained the control, and the better the turbo is going to operate over the full RPM range.
 
The control has mainly got to do with the ECU then right?
 
monty37 said:
The control has mainly got to do with the ECU then right?

I would assume so on the electrically operated ones. I believe most are purely mechanical though, operated via intake manifold vacuum.
 

Similar threads

Can a turbo expander convert more heat to work than a piston expander?
Replies
2
Views
1K
Automotive Powering a turbo with intake air
Replies
12
Views
7K
Can an Anti-Lag Turbo Supercharger Increase Engine Efficiency and Performance?
Replies
13
Views
5K
Why turbos arent used in 2 wheelers?
Replies
3
Views
2K
Automotive Turbocharger in a car, thermodynamics
Replies
7
Views
8K
Torque Limiting Extension Question
Replies
14
Views
4K
Automotive Electric Turbocharger Questions
Replies
7
Views
6K
Why Did the Temperature Rise in a Sealed Automotive Cooling System?
Replies
18
Views
2K
Why not use turbine engines in cars?
Replies
48
Views
17K
Problems with lagged turbo and exhaust systems
Replies
3
Views
3K

Hot Threads

Recent Insights

Back
Top