EXAIR Products in the Semiconductor Industry

Manufacturers in semiconductor assembly and PCB production face strict cleanliness, throughput, and thermal-control requirements. EXAIRs compressed-air products, specifically our Air Knives and Vortex Tubes, and air amplifiers are proven, compact, and energy-efficient tools for precise blow-off, controlled cooling and heating for spot thermal conditioning and fume extraction. This Blog explains how EXAIR Super Air Knives and Vortex Tubes and Air Amplifiers address three common production needs: 

  1. Drying and particulate removal during lead frame processing with air knives. 
  1. Localized cooling/heating for functional PCB testing using Vortex Tubes. 
  1. Fume extraction during etching, cleaning and plating processes

I’ll cover technical fit, typical performance characteristics, and measurement/ROI considerations so engineers and plant managers can evaluate and implement these solutions. 

Intellistat Ion Air Nozzle in clean room, cleaning microchip parts before installation.

Super Air Knife and Success in the semiconductor lead frame manufacturing process.  

Typical use cases 

  • Removing rinse water or flux residues after cleaning 
  • Blowing off foreign matter, over spray, or machining debris prior to plating or die bonding. 
  • Drying prior to molding or coating operations. 
  • Static-assisted blow-off when combined with static eliminating product for electrostatically attracted particles. 

Why Super Air Knives? 

  • Uniform Laminar Sheet of air: delivers consistent, even blow-off across the width of a lead frame, reducing localized hot spots or mechanical damage. 
  • Adjustable force and flow: adjusting air pressure and shim size allow you to control force and volume so fragile wires or plated surfaces aren’t damaged. 
  • Entrainment & Efficiency: The knives are engineered so they entrain ambient air, increasing total developed flow and reducing compressed-air consumption compared to open pipes. 

Vortex Tubes for functional PCB testing / burn-in and thermal cycling

During in-line or bench functional testing, specific components or integrated circuits may overheat or require temperature conditioning to verify performance at the full range of the rated temperature specifications. Vortex Tubes give fast, localized cooling (or heating) without coolant loops, chillers, or plumbing intricacy. Subjecting devices to burn-in and thermal cycling stress helps products enter the field with confidence there will not be any preventable failures. Normally, environmental chambers are used for burn-in processes, but vortex tubes can help facilitate localized thermal ramps, corner stressing, or temporary additional cooling/heating when size, cost or availability of a full environmental chamber isn’t feasible.  

Why Vortex Tubes fit testing 

  • Instant cold/hot air from regular compressed air: no refrigeration system or refrigeration cycle; instantaneous on/off.  
  • No moving parts: high reliability and low maintenance for test fixtures. 
  • Local spot conditioning: focus cooling on integrated circuits or other small areas without cooling the entire board or fixture. 
  • Adjustable cold fraction: Vortex tubes can be tuned via the control valve to trade flow vs. temperature drop to meet testing conditions. 
Cooling or Heating with the Vortex Tube

Air Amplifiers for fume extraction and partial heat control during etching, cleaning and plating processes.

In semiconductor lead frame manufacturing, maintaining clean, particle-free environments is essential to ensure consistent product quality and process reliability. Processes such as flux cleaning, plating, molding, and soldering generate vapors, fumes, and fine particulates that can contaminate delicate components or compromise yields. EXAIR’s Super Air Amplifier provides an efficient, quiet, and maintenance-free solution for capturing and removing fumes, vapors, and airborne contaminants from sensitive production areas.

Why the Super Air Amplifier?
High-Volume Airflow Through Amplification

  • It uses a small amount of compressed air to entrain large volumes of ambient air multiplying total flow by up to 25 times.
  • Creates a strong, consistent vacuum draw ideal for capturing fumes and fine particulates at their source.

Energy Efficiency

  • Dramatically reduces compressed-air consumption compared to traditional vacuum or exhaust systems.
  • No electricity, motors, or moving parts, maintenance-free operation and long service life.

Compact and Versatile

  • Easy to integrate above process lines, in tool enclosures, or at conveyor transfer points.
  • Available in aluminum, stainless steel, and high-temperature materials for compatibility with cleanroom or chemical environments.
Model 120024 4″ Super Air Amplifiers are commonly used to exhaust smoke and fumes.

ROI and how to show value quantitatively  

  • Baseline metrics: scrap/rework rate, cycle time, compressed-air consumption, downtime for cleaning, and throughput. 
  • Pilot run: instrument a section of line with flow/force and temperature sensors for a 30 day trial. 
  • Key calculations: 
  • Reduced rework % × cost per part = direct savings. 
  • Throughput increase (parts/hr) × margin = additional revenue. 
  • Compressed-air energy reduction (compared to previous blow-offs) = kW savings (U.S. Department of Energy offers a benchmark of $0.25 per 1,000 SCF). 
  • Tangible benefits: throughput improvement, energy savings, reduced capital cost (vs. chillers/chambers), lower maintenance and smaller footprint. 

Conclusion  

EXAIR Super Air Knives, Vortex Tubes and air amplifiers are compact, reliable, and flexible products that can improve cleanliness, thermal testing, and throughput in semiconductor processes.  

  1. Select a process you think could be helped with an air knife, Vortex Tube or an air amplifier and take advantage of our 30-day money-back guarantee.  
  1. Validate throughput and quality improvements and calculate ROI. 
  1. Rollout with appropriate controls, filtration, and operator training.  

If you think any of our products can help you in your process, please reach out. We have a team of application engineers here M-F to answer your questions!

Jordan Shouse, CCASS

Application Engineer

Send me an email
Find us on the Web 

Cooling a Thermal Manikin After a Fire

Not to be persnickety, but there is a difference between mannequins, life size model for displaying or tailoring clothes, and manikins, an anatomical model used for testing and teaching, usually with movable joints. (The enunciation is exactly the same though).  A lab designed a test for thermal protective clothing.  They had a manikin that was 6 feet in height and had 120 copper slug sensors located all over its body. The sensors would record the temperature gradients on the surface of the manikin, representing skin exposure to heat.  They would dress their manikin with thermal protective clothing from head to toe and expose it to intense fires at various temperatures and exposure times.  After each test was completed, they would record the results and cool the manikin to 26 deg. C before they started the next fire test.  These results were used for safety limits to protect wearers from second and third degree burns, very important in keeping firefighters safe.

Fire Suit under test
Fire Suit under test

In their application, they were looking to cool the sensors on the manikin as quickly as they can to increase test cycle rates. Initially they used a “cool down” area fitted with fans to blow air across the manikin.  The problem was that it took too long to cool to the 26 deg. C mark required in their testing protocol.  They decided to manually use an air gun to blow compressed air across the sensors to increase cooling.  This did reduce the cycle time, but because of the force created by the air gun, some sensors would shift and be out of calibration.  This was a huge concern for the test lab.

The design of the copper slug sensor has a small piece of copper set inside a silicone holder. To isolate the copper metal, there are small ruby spheres between the holder and copper slug.  This creates an air gap around the copper slug to help increase sensitivity to temperature changes.  A thermocouple is attached to the back side of the copper slug for analytical measurements.

Adjustable Spot Cooler
Adjustable Spot Cooler

After they discussed their application with me, I suggested the model 3725 Adjustable Spot Cooler. This base unit comes without a magnetic base and hose kit, which makes it lighter in weight. The customer could easily attach it directly to their compressed air line, replacing the air gun that was damaging the sensors.  The Adjustable Spot Cooler incorporates the Vortex Tube which makes standard compressed air into cold air.  With a turn of a knob, they could control the temperature and the velocity of the cold air.  This feature was key in determining just the right amount of force to not affect the calibration of the sensors.  An added benefit of the Adjustable Spot Cooler is if you reduce the amount of outlet cold air, the temperature will decrease even more.  This feature allowed the customer to reach their target much more quickly and without damaging the sensors.

If you need to cool things down in your application, you can contact an Application Engineer at EXAIR. We have many different styles and combinations of Vortex Tubes and Spot Coolers to give you the right form of cooling, whether it is a mannequin or a manikin.

John Ball
Application Engineer
Email: johnball@exair.com
Twitter: @EXAIR_jb

 

DDI-2007-Burning Man by Interpretive Arson.  Common License.