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Utilising patented Active Flow Control technology, Ogab® has developed a breakthrough system that reduces aerodynamic drag on trains, road and track vehicles.

OGAB®

Advance TRS®

Cutting through the air with our patented invisible air splitter.

By harnessing the power of Active and Reactive Aerodynamics we can significantly reduce the effect of drag.

A breakthrough innovation in drag reduction technology to increase performance, cut fuel consumption and significantly reduce harmful CO2 emissions.

Ogab Wind Tunnel

Where, Fdrag is drag force, ρ is air density, V is vehicle velocity, A is vehicle frontal area and Cdrag is drag coefficient. As evident from this equation, drag force is directly proportional to the air density and vehicle frontal area. Therefore, decreasing these two parameters will reduce the drag force. In conventional active or passive drag reduction methods, these two parameters are considered as constant terms and often designers have no control on them.

On the contrary, our proposed technology manipulates the flow field surrounding the vehicle so that these two parameters (i.e. density and frontal area) become dynamic terms and in favour of drag reduction.

This goal of Advanced TRS® is achieved by injecting high temperature and high velocity air in the front region of vehicle. By injecting the high temperature, high velocity air in this way the air ahead of the vehicle is split into two streams, leading to an effective lower area of impact (frontal area) and hence reduce this value in the above equation.

Further, by injecting hot air in the front region, low density air surrounds the vehicle body and results in less frictional resistance and hence lower drag force. Since, drag coefficient is directly proportional to drag force, any reduction in drag force will yield a lower drag coefficient.

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Road

Aerodynamic excellence that offers increased performance and reduced fuel consumption for a sustainable future.

Rail

A groundbreaking reduction in aerodynamic losses on passenger trains to cut journey times and fuel costs.

Motorsport

Breakthrough technology that offers faster lap times, reduced fuel loads and the upper hand on strategy planning.

OGAB®

Distribution of Power Consumption at Various Speeds

When calculating drag force, vehicle speed is clearly an important part of the equation. At stop-and-go speeds, drag isn’t a major factor, but the faster you go, the more it matters. At 70 mph, a vehicle must overcome four times the drag than the same vehicle at 35 mph.

The table below indicates the percentage ratios of the key factors that impact a vehicles power consumption at given speeds. These are attributed to two specific  consumptive causes which are; aerodynamic losses (drag force) and direct power demand from the engine to propel the vehicle forward (rolling and accessories).

As you can see, at speeds of 60 mph and above less than 40% of power consumption is attributed to propelling the vehicle, meaning drag force plays a hugely significant role in the amount of power the vehicle consumes to maintain that speed (62% at 60 mph). Furthermore, at 70 mph, 70% of power consumption is attributed to aerodynamic losses with just 30% attributed to rolling and accessories.

OGAB®

Distribution of Power Consumption at Various Speeds

When calculating drag force, vehicle speed is clearly an important part of the equation. At stop-and-go speeds, drag isn’t a major factor, but the faster you go, the more it matters. At 70 mph, a vehicle must overcome four times the drag than the same vehicle at 35 mph.

The table below indicates the percentage ratios of the key factors that impact a vehicles power consumption at given speeds. These are attributed to two specific consumptive causes which are; aerodynamic losses (drag force) and direct power demand from the engine to propel the vehicle forward (rolling and accessories).

As you can see, at speeds of 60 mph and above less than 40% of power consumption is attributed to propelling the vehicle, meaning drag force plays a hugely significant role in the amount of power the vehicle consumes to maintain that speed (62% at 60 mph). Furthermore, at 70 mph, 70% of power consumption is attributed to aerodynamic losses with just 30% attributed to rolling and accessories.

We Can Reduce Drag Force Of Any Train, Road or Track Vehicle By 10%.​

The Advanced TRS® delivers benefits such as:

How We Recover And Harness Energy That Would Otherwise Be Lost

Ogab®’s patented solution for recovering energy that would otherwise be lost centres around our state-of-the-art Motor Generator Unit – Pelton (MGU-P). Situated within the turbocharger, the MGU-P has a unique Pelton wheel design that works to generate superior levels of torque that can then create exceptional levels of power. The MGU-P makes it possible to harness this captured energy to power vehicle functions. Consequently, our patented solution can sustainably reduce energy consumption while maximising vehicle performance.

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Get the full facts and insight on the positive impact of a 20% reduction of fuel consumption.

To learn more or to obtain a manufacturing license agreement for our breakthrough technology
get in touch today via the contact us page.

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