Precision components require precision manufacturing techniques. The Extrude Hone® MICROFLOW abrasive flow process is designed to achieve precise results under tight tolerances.
Extrude Hone AFM MICROFLOW offers refined control of the abrasive flow process to achieve precise, consistent results for complex applications.
MICROFLOW process methodology
One step to target flow processing
Capability to target to ±2% of specified flow rate. (NOTE: Targeting to ±1% or better is possible in properly developed applications dependent on hole geometry and other factors.)
Process at a fixed media pressure for a specified time:
Fixed time — operator specified process time.
Variable time — process time is based on pre-process flow rate, target flow rate, and parameters relating flow difference and process time.
Constant pressure-fixed displacement processing
Process at a constant pressure for a specified volume of media:
Fixed volume — operator specified media volume.
Variable volume — displacement is based on pre-process flow rate, target flow rate, and parameters relating flow difference and displacement.
MICROFLOW TEST provides high precision flow measurement technology that refines control of the machining process. MICROFLOW TEST was designed as a result of decades of fuel system processing experience on large-scale automated systems.
MICROFLOW MEDIA is a formulated solution distinguishable by viscosity, particle size, particle type and density. The abrasive particles are mixed into the media solution.
Specific characteristics of our MICROFLOW process include:
- Remote service tracking and standardized components.
- Easy integration into automated production systems.
- Ability to operate in manual or automated modes.
- Media flows in one direction, same as flow through component during operation.
- Real-time monitoring of abrasive media flow through small passages.
- Achieves specific and repeatable processing that results in production stability.
- Versatility – can be utilized as a lab or production machine.
Trust our experts to manage these key process considerations:
- Pressure drop within the component during operation.
- Desired flow rate through the component during operation.
- The geometry of the flow path through the component.
- The properties of the fluid during component operation.
- Workpiece characteristics.
- Media properties.
Specific characteristics of MICROFLOW TEST include:
- Smaller footprint as a stand-alone machine when compared to other fully automated flow measuring systems.
- Scalable to production requirements.
- Reliability and precision using a platform that is easy to operate.
- Capability of maintaining repeatability of +/- 0.25% accuracy of +/- 0.1% which is ideal for high precision work such as fuel system components.
Specific characteristics of MICROFLOW MEDIA include:
- Contains an organic fluid with a low percentage of fine abrasive particles.
- Unique rheological modifiers keep the abrasive particles uniformly suspended so they flow evenly through complex contours and simultaneously work on multiple edges.
- Abrasive particles are typically comprised of materials such as silicon carbide, aluminum oxide and boron carbide.
High precision results are achievable for a full range of features and parts including entrance points and small orifices using the MICROFLOW process, MICROFLOW TEST and MICROFLOW MEDIA. This makes the Extrude Hone AFM MICROFLOW process ideal for the following surface machining applications:
Radiusing: Create a defined-edge rounding geometry for orifice diameters between 50µm and 2mm
Flow Tuning: Create defined hydraulic flow rate for orifices for flow rates up to 5000 cc/min
Together, the MICROFLOW process, MICROFLOW TEST and MICROFLOW MEDIA provide the capability to fine tune the flow characteristics through orifices within machined components.
Advantages of this process include:
Process efficiency. Flow increases of up to 60% are achievable without adversely affecting the exit hole geometry.
Flow consistency. Maintains flow consistency from part to part, and throughout all combustion chambers.
Enhanced product performance. Provides increased discharge coefficient of high precision orifices without changing the exit geometry.
Lower emissions and improved fuel economy. Improvement in atomization of fuel for both gas and diesel injection systems results in fuel that burns cleaner, and more efficiently.
Lifelong component performance. By creating geometries that are stable over time, component performance remains unchanged.