Before you install a Local Exhaust Ventilation (LEV) system, there’s one fundamental principle that determines its effectiveness:
π‘ “LEV systems are only as effective as your understanding of the processes and sources of airborne contaminants.” — HSE HSG258, Chapter 4
In other words, if you don’t fully understand how hazardous substances are generated — your LEV system might be targeting the wrong area, capturing too little, or simply failing to protect your workers.
In this article, we’ll break down:
What are contaminant sources in industrial settings
Why understanding process emissions matters
How it shapes LEV system design
What Malaysian factories can do to stay compliant and safe
According to HSE’s HSG258 Guidelines (used globally as a best practice, including by DOSH Malaysia):
A process refers to how airborne contaminants are generated
A source is where the contaminant is released into the air
For example:
In woodworking, the process could be sanding or cutting
The source is the point where dust escapes into the air
In spray painting, the process is atomisation of liquid
The source is the tip of the spray gun
β
Understanding the process = understanding the pattern, timing and intensity of exposure
β
Understanding the source = knowing exactly where to capture the contaminant
1οΈβ£ Buoyant Sources
Example: hot fumes from furnaces or soldering
These rise naturally with temperature
Needs canopy or rising capture hoods
2οΈβ£ Injected into Moving Air
Example: spray guns, atomisers
High-speed particles move with air current
Needs close-capture LEV and enclosure
3οΈβ£ Mechanically Moved
Example: grinding, sanding, cutting
Particles are thrown off mechanically
Capture hoods must be placed close to emission point
4οΈβ£ Still Air Releases
Example: slow chemical evaporation
Diffuses into room air
Needs enclosures or extracted cabinets
β
Improves Hood Placement
Wrong placement = wasted airflow = poor capture efficiency.
β
Determines Airflow Volume Needed
Each source type needs different capture velocity (fpm or m/s) and static pressure (in.wg or Pa).
β
Shapes Duct Sizing & Fan Selection
Overdesign = high energy cost. Undersize = non-compliance.
β
Ensures Legal Compliance (USECHH 2000 Reg. 17)
DOSH requires your LEV to effectively control airborne exposure — backed by engineering calculations and inspections.
At ZABSI, we don’t guess airflow. We engineer it.
β
Step 1: Site Walk & Process Observation
We identify the emission points, task duration, and operator movement.
β
Step 2: Source Classification
We categorize the source (hot fume, mechanical dust, etc.) and choose the correct capture method.
β
Step 3: Airflow Calculation
We calculate required capture velocity using HSG258, ACGIH, and DOSH guidelines.
β
Step 4: Custom LEV Design
Using AutoCAD or CFD modeling, we design the entire duct-fan-filter system to match your process flow.
β
Step 5: Commissioning & Performance Testing
Smoke tests, airflow meters, static pressure checks — all documented for DOE/DOSH approval.
That’s why cookie-cutter LEV systems don’t work.
If your contractor doesn’t ask how, when and where contaminants are generated — it’s time to reconsider.
π Need a Properly Engineered LEV System?
Whether it’s a new process line or an upgrade to an existing LEV, ZABSI ensures your system is:
β Based on real source analysis
β Compliant with USECHH Reg. 17
β Efficient in performance & energy
β Backed by testing reports and support
π§ Email: [email protected]
π Visit: www.zabsi.com
LEV design Malaysia, airborne contaminant sources, LEV system engineering, HSG258 Malaysia, DOSH LEV compliance
Malaysia
