Variable geometry turbochargers (VGTs)
are a family of turbochargers, usually designed to allow the effective
aspect ratio (sometimes called A/R Ratio) of the turbo to be altered as
conditions change. This is done because optimum aspect ratio at low
engine speeds is very different from that at high engine speeds. If the
aspect ratio is too large, the turbo will fail to create boost at low
speeds; if the aspect ratio is too small, the turbo will choke the
engine at high speeds, leading to high exhaust manifold pressures, high
pumping losses, and ultimately lower power output. By altering the
geometry of the turbine housing as the engine accelerates, the turbo’s
aspect ratio can be maintained at its optimum. Because of this, VGTs
have a minimal amount of lag, have a low boost threshold, and are very
efficient at higher engine speeds. VGTs do not require a waste gate.
Most common designs
The two most common implementations include a ring of aerodynamically-shaped vanes in the turbine housing at the turbine inlet. Generally for light duty engines (passenger cars, race cars, and light commercial vehicles) the vanes rotate in unison to vary the gas swirl angle and the cross sectional area. Generally for heavy duty engines the vanes do not rotate, but instead the axial width of the inlet is selectively blocked by an axially sliding wall (either the vanes are selectively covered by a moving slotted shroud, or the vanes selectively move vs a stationary slotted shroud). Either way the area between the tips of the vanes changes, leading to a variable aspect ratio.
The two most common implementations include a ring of aerodynamically-shaped vanes in the turbine housing at the turbine inlet. Generally for light duty engines (passenger cars, race cars, and light commercial vehicles) the vanes rotate in unison to vary the gas swirl angle and the cross sectional area. Generally for heavy duty engines the vanes do not rotate, but instead the axial width of the inlet is selectively blocked by an axially sliding wall (either the vanes are selectively covered by a moving slotted shroud, or the vanes selectively move vs a stationary slotted shroud). Either way the area between the tips of the vanes changes, leading to a variable aspect ratio.
Actuation
Often the vanes are controlled by a membrane actuator identical to that of a waste gate, however increasingly electric servo actuation is used. Hydraulic actuators have also been used in some applications.
Often the vanes are controlled by a membrane actuator identical to that of a waste gate, however increasingly electric servo actuation is used. Hydraulic actuators have also been used in some applications.
Main suppliers
Several companies supply the rotating vane type of
variable geometry turbocharger, including Garrett (Honeywell), Borg
Warner and MHI (Mitsubishi Heavy Industries). The rotating vane design
is mostly limited to small engines and/or to light duty applications
(passenger cars, race cars and light commercial vehicles). The only
supplier of the sliding vane type of variable geometry turbocharger is
Cummins Turbo Technologies (Holset), who are effectively the sole
supplier of variable geometry turbochargers for applications involving
large engines and heavy duty use (i.e. trucks and off highway
applications).
Other common uses
In trucks, VG turbochargers are also used to control the ratio of exhaust re-circulated back to the engine inlet (they can be controlled to selectively increase the exhaust manifold pressure exceeds the inlet manifold pressure, which promotes exhaust gas recirculation (EGR)). Although excessive engine back pressure is detrimental to overall fuel economy, ensuring a sufficient EGR rate even during transient events (e.g. gear changes) can be sufficient to reduce nitrogen oxide emissions down to that required by emissions legislation (e.g. Euro 5 for Europe and EPA 10 for the USA).
In trucks, VG turbochargers are also used to control the ratio of exhaust re-circulated back to the engine inlet (they can be controlled to selectively increase the exhaust manifold pressure exceeds the inlet manifold pressure, which promotes exhaust gas recirculation (EGR)). Although excessive engine back pressure is detrimental to overall fuel economy, ensuring a sufficient EGR rate even during transient events (e.g. gear changes) can be sufficient to reduce nitrogen oxide emissions down to that required by emissions legislation (e.g. Euro 5 for Europe and EPA 10 for the USA).
Another use for the sliding vane type of turbocharger
is as downstream engine exhaust brake (non-decompression type), so that
an extra exhaust throttle valve isn’t needed. Also the mechanism can be
deliberately modified to reduce the turbine efficiency in a predefined
position. This mode can be selected to sustain a raised exhaust
temperature to promote "light-off" and "regeneration" of a diesel
particulate filter (this involves heating the carbon particles stuck in
the filter until they oxidize away in a semi-self sustaining reaction –
rather like the self-cleaning process some ovens offer). Actuation of a
VG turbocharger for EGR flow control or to implement braking or
regeneration modes generally requires hydraulic or electric servo
actuation.
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