APR Front Mount Intercooler System (FMIC) - Audi B9 S4/S5 3.0T

The APR Intercooler System is a massive front mounted upgrade that dramatically reduces intake air temperature (IAT), minimizes heat soak, and provides increased performance! The system is an easy to install, direct bolt-on design, that is recommended at every stage of performance.

Quick Facts:

• Dramatically lowers intake air temp (IAT) - The factory intercooler reaches dangerously high IAT levels, even on the stock ECU!
• Massive frontal surface area and core volume
  3.125" x 5.75" x 28.25" - 162.4 in² frnt. & 507.62 in³ volume - OEM
  2.250" x 16.2" x 22.00" - 356.4 in² frnt. & 801.90 in³ volume - APR
• Highly effective core design - Bar-and-plate core with staggered and louvered fins. Rigorous testing determined core style, fin density, and size. Low pressure drop + highly effective cooling = high performance!
• Smooth cast end tanks - Engineered for low turbulence/restriction and maximum flow. Organically shaped to promote airflow across entire core. Pressure tested to prevent power robbing boost leaks.
• Easy to install - Simple plug-and-play design with no trimming or drilling necessary!
• Designed by engineers with lasers - With the best equipment and smartest engineers, it just works!

Testing:

APR’s engineers tested each intercooler in a multitude of tests to show the impact the APR intercooler has on intake air temperature. The following tests were conducted with a 2017 S4 using the stock ECU calibration on 93 octane fuel and no other modifications. Ambient conditions during the stock intercooler tests were 72.8°F and 98.4 kPa with 78.7% relative humidity. Conditions were similar later in the day during during the APR Intercooler testing with 78.4°F and 98.5 KPa with 62.8% relative humidity. This gave the APR Intercooler no added advantage over the stock system during the tests.

First, six back-to-back dyno pulls were conducted with each intercooler. Each run was conducted in 4th gear, from idle to redline, with a cool down between runs. The stock intercooler failed to combat rising IAT’s and quickly exhibited power-robbing heat soak. IAT’s started at 35°C and quickly rose to 60°C by the end of the first dyno pull. This trend continued with the final dyno pull reaching a staggering 67°C! In contrast, the APR Intercooler only reached 34°C by the end of the first dyno pull. It was then able to continue rejecting heat, only reaching 36°C by the end of the final dyno pull. The APR Intercooler performed better after 6 back-to-back dyno pulls than the factory intercooler did on it’s very first dyno pull.

Next we tested a 10-135 second sprint through the gears. With the factory intercooler, IAT quickly rose from a starting temperature of 32°C to a blistering 81°C! It was so bad, we had to abort the test as we felt it was too dangerous to continue further. However, as expected, the APR intercooler handled IAT’s extremely well. With a starting temperature of 29°C, IAT slightly climbed above the starting temperature to 42°C by the end of the sprint. A difference of 39°C was exhibited between the two units after only a single top speed. This directly translates to faster acceleration, and better performance in all conditions.

Design:

Unfortunately, to the untrained eye, many intercooler designs appear the same. However, effectiveness of the system and overall performance are greatly determined by several key metrics. Alloy selection, end tank design, construction type, fin style, fin density and overall core dimensions must be analyzed and balanced accordingly to deliver class-leading performance. While the OEM’s goal is to create a lightweight, easy to manufacture and inexpensive to produce, cross-platform design capable of supporting factory power levels, APR’s intercooler must be capable of supporting more than double the factory output. Achieving this goal took a multi-step approach focused around intercooler core selection, end tank design and install location.

Core Design:

The APR Intercooler core is a large bar-and-plate design featuring densely packed staggered and louvered fins. This design offers exceptional cooling while balancing pressure loss across the core, and maintaining critical airflow to the components behind the intercooler system. The core size was appropriately matched to the platform, minimizing pressure drop while leaving adequate space for appropriately designed end tanks. To APR’s mechanical engineering experts, the design represented the ultimate in performance, far exceeding the capabilities of the factory intercooler. To the driver, the result is simple: Repeatable performance, even in the most demanding of situations!

Core Style / Internal Fin Structure:

APR’s Engineers paid close attention to the balance between core effectiveness and pressure drop through the core, core style and fin density. With fin density too low, pressure drop decreases dramatically, but typically results in a core incapable of effectively cooling. Likewise, with fin density too great, pressure drop increases dramatically, resulting in the turbocharger working harder, and hotter, to produce the same level of airflow. By fine tuning this often unseen balancing act, as illustrated below, APR’s Engineers were able to maximize performance.

End Tank Design:

To fully utilize the massive core, APR’s mechanical engineers designed cast aluminum end tanks organically shaped for proper airflow distribution across the entire core. By correctly sizing the intercooler core, end tank design was not sacrificed. The one-piece end tanks are CNC machined to provide a slip resistant mounting surface for hoses, precise integrated mounting surfaces, and perfectly flat connecting surfaces used for TIG welding the tanks to the core. Through proper alignment in welding jigs, each unit is assembled to tight tolerances for a precise and accurate fit.

Hoses and clamps:

Hoses: The hoses are constructed from multi-ply silicone, and are wire-reinforced to prevent swelling and bursting at extreme boost pressures. Internally, the hoses are lined with fluorosilicone to protect the hoses from oil and gasoline deterioration. Finally, each hose feature’s APR’s EZ-Flow stepped design to provide a smooth airflow path at the hose transition points.

Clamps: Strong Clampco T-bolt clamps are used throughout, replacing the factory worm-gear clamps. The clamps are made from stainless steel, and are of a high-quality and high-strength design that diminishes the risk of boost leaks. Lastly, the clamp’s thick clamping style provides increased connection strength, and decreased hose slippage compared to other styles of clamps.

MAP Housing: A billet MAP sensor housing provides a secure mounting point for the factory pre-throttle MAP sensor. The precision cnc-machined housing helps to prevent leaks around the sensor, and the matte-black anodizing gives the housing a clean and attractive look within the engine bay.