Cleanroom Air Shower Product

Overview

An air shower is an airlock chamber at the threshold of a cleanroom: personnel or material entering the cleanroom passes through the air shower where high-velocity jets of HEPA-filtered air blow away dust, fibers, and loose particles from their clothing or packaging. For 10–30 seconds, all four walls discharge jets at 8–15 m/s, dislodging contamination. When the cycle completes, the exit door unlocks and the user enters the cleanroom; the entry door remains locked during this time, preventing bypass. Air showers are a standard feature in ISO Class 5 semiconductor fabs, pharmaceutical cleanrooms, and hospital operating suites, with payback measured in prevented product contamination and yield loss.

The air shower is a sealed Air Shower Chamber with Entry & Exit Doors with Interlock on two sides (entry from the corridor, exit to cleanroom), a Fan & HEPA Filter Unit with HEPA filter overhead, Air Nozzle Array on the walls, and Control & Sequencing System that sequence the cycle. A typical unit is 1.5 × 1.5 × 2.2 m and fits in a hallway or doorway opening.

Chamber design and sealing

The Air Shower Chamber is constructed of stainless-steel (304 or 316 grade) or epoxy-coated steel panels, welded or bolted together, forming a sealed box. The Chamber Floor is non-slip grating or sloped stainless with a drain pan underneath that collects condensation and discharged water from decontamination sprays (if equipped). Sealing Gaskets of silicone or polyurethane caulk at all seams maintain airtightness during the high-velocity shower phase.

The Chamber Ceiling is an open structure or soffit that allows the supply air from the Fan & HEPA Filter Unit to flow into the plenum above the nozzles.

Doors and interlock logic

The Entry Door and Exit Door are swing or sliding doors sealed with Door Gasket Seal gaskets. Each door has a {{air-shower-door-closer}} that gently closes it after each use. The critical safety feature is the Interlock Controller — a solenoid-operated lock on each door that is electrically interlocked by the Cycle Timer Controller: When the entry door opens, the exit-door solenoid is energized and locks the exit door; when the entry door closes, the Cycle Timer Controller starts a cycle, energizes the nozzles, and then de-energizes the entry-door lock while energizing the exit-door solenoid unlock.

This ensures that both doors can never be open simultaneously, preventing contaminated corridor air from entering the cleanroom directly.

Supply filtration

The Fan & HEPA Filter Unit is a compact unit, similar to a standard Fan Filter Unit, mounted in the ceiling soffit above the chamber. It contains a Blower Motor, an EC brushless motor of 100–300 W, and a HEPA Filter Cartridge, typically HEPA H14 (99.995% @ 0.3 µm). The blower pulls supply air from a Supply Plenum that is fed by the facility's cleanroom supply air ductwork (via Supply Ductwork Connection).

The air passes through the HEPA filter and is discharged downward into the chamber Supply Plenum above the nozzles.

Nozzle jets and particle removal

The Air Nozzle Array consists of 12–24 small stainless or plastic nozzles mounted on the four Chamber Walls. Typically there are 3–6 nozzles per wall. When the Cycle Timer Controller activates the shower, all nozzles discharge at once. The Discharge Nozzle accelerates filtered air through a small opening, creating a high-velocity jet (8–15 m/s) that hits exposed skin and clothing at an intensity sufficient to dislodge particles, loose fibers, and dust.

The Nozzle Supply Manifold distributes supply air equally to each nozzle via internal tubing. The Nozzle Flow Control can modulate the overall air speed to balance decontamination effectiveness with user comfort.

Exhaust and return

As air jets dislodge particles, the entire airflow in the chamber becomes contaminated with dust and fibers. This contaminated air is exhausted through Exhaust Ductwork Connection back to the facility return-air system or outdoor exhaust, NOT back into the cleanroom. Some facilities include an optional Exhaust Pre-Filter (MERV 13) at the return entrance to prevent re-circulation of dislodged particles.

The pressure in the chamber rises briefly during the nozzle-active phase, driving air out through the exhaust. When nozzles ramp down and stop, exhaust pressure returns to neutral.

Control sequence and timing

The Cycle Timer Controller orchestrates the entire sequence:

1. User approaches the entry door (green light signals "shower ready").
2. User opens Entry Door and enters the chamber.
3. Door closes; the controller starts a programmable cycle, typically:
   • 2–5 sec: Nozzles ramp up to full speed
   • 10–20 sec: Full nozzle spray
   • 2–5 sec: Nozzles ramp down
4. Exit-door unlock solenoid is de-energized (lock opens).
5. User exits through Exit Door into the cleanroom.
6. Exit door closes; entry-door lock re-energizes.

The Status Indicator Lights guide the user: green (ready), blue (shower active), green again (exit ready). Some units include a Motion Sensor that aborts the cycle if the user leaves early, saving cycle time.

Decontamination effectiveness

Air-shower effectiveness depends on flow velocity, cycle time, and particle size distribution. High-velocity jets (15 m/s) remove coarse fibers and loose dust effectively but can be uncomfortable. Low-velocity jets (8 m/s) are gentler but less effective. Most facilities use 10–12 m/s as a compromise. Cycle time of 15–20 seconds is a practical balance between decontamination and throughput.

Studies show that a well-designed air shower reduces cleanroom particulate contamination from clothing by 60–80%, justifying its installation in any semiconductor or pharmaceutical facility. The remaining 20–40% of clothing contamination is managed by cleanroom garments (bunny suits, gloves, footwear).

Maintenance and upkeep

Air showers require annual maintenance:

• Inspection and replacement of the HEPA Filter Cartridge if pressure drop is high
• Cleaning of all {{air-shower-nozzle-unit}} to prevent blockage
• Checking door gasketing and solenoid function
• Verifying Cycle Timer Controller logic and cycle timing
• Testing the Interlock Controller to confirm doors cannot open simultaneously

Neglected air showers suffer from algae growth in the drain pan, nozzle blockage from dust settling, and stuck solenoid locks — all of which compromise decontamination.