Garrett GT3076R Turbocharger
**This turbo was Superceded by GTX3076R.**
- Ball bearing
- Oil & Water-cooled bearing system
- Upgrade turbocharger for GT3071R non-wastegated ball-bearing turbocharger; turbine housing flanges are outline interchangeable
- Ideal for medium displacement engines making up to 525 hp
- Turbine housing kit options available
- 56 trim compressor wheel
- 0.60 AR compressor housing
- 84 trim turbine wheel
- T3 or T4 twin scroll housings, see options below.
For High Power/High Flow Twin Scroll 30R applications, Full-Race recommends:
- Cut down the bolts that attach the straps/CHRA to the turbine housing. The 12 point chra bolts that come with the turbo are extra long and the threads protrude into the volute, creating a small restriction. By cutting down the bolts and removing any extra threads, flow increases since the bolt head is not blocking it
- Hand port out the inside of the housing — there is a lot of material here and flow can be improved through porting
- Extrude hone the volute — this is recommended by Garrett engineers, since the extrude hone process will reach part of the housing that a grinder can not
.82 AR T3 twin scroll turbine housing.
1.06 AR T4 twin scroll turbine housing.
**Click on thumbnail pictures above for larger images**
About Twin Scroll:Twin-scroll turbo system design addresses many of the shortcomings of single scroll turbo systems by separating those cylinders whose exhaust gas pulses interfere with each other. Similar in concept to pairing cylinders on race headers for N/A engines, twin scroll design pairs cylinders to one side of the turbine inlet so that the kinetic energy from the exhaust gases is recovered more efficiently by the turbine. For example, if a four-cylinder engine’s firing sequence is 1-3-4-2, cylinder 1 is ending its expansion stroke and opening its exhaust valves while cylinder 2 still has its exhaust valves open (while in its overlap period, where both the intake and exhaust valves are partially open at the same time). In a single scroll AKA undivided manifold, the exhaust gas pressure pulse from cylinder 1 is therefore going to interfere with cylinder 2’s ability to expel its exhaust gases, rather than delivering it undisturbed to the turbo’s turbine the way a twin scroll system allows.
The result of the superior scavenging effect from a twin scroll design is better pressure distribution in the exhaust ports and more efficient delivery of exhaust gas energy to the turbocharger’s turbine. This in turn allows greater valve overlap, resulting in an improved quality and quantity of the air charge entering each cylinder. In fact, with more valve overlap, the scavenging effect of the exhaust flow can literally draw more air in on the intake side while drawing out the last of the low-pressure exhaust gases, helping pack each cylinder with a denser and purer air charge. As we all know, a denser and purer air charge means stronger combustion and more power… but the benefits of twin scroll design don’t end there. With its greater volumetric efficiency and stronger scavenging effect, higher ignition delay can be used, which helps keep peak combustion temperature in the cylinders down. Since cooler cylinder temperatures and lower exhaust gas temperatures allows for a leaner air/fuel ratio, twin-scroll turbo design has been shown to increase turbine efficiency by 7-8 percent (faster spool, quicker response) and result in fuel efficiency improvements as high as 5 percent. It is wise to size the turbine housing A/R larger than the single scroll turbine A/R typically used!
For additional information and/or related questions, feel free to contact us.
- [email protected]
- (866) Full-Race