According to the Plastics Industry Trade Association, in 2011 the U.S. plastics industry accounted for $380.4 billion in annual shipments and directly employed almost 900,000 people in over 16,200 facilities.
With such a huge economical impact, it is vital to protect the respiratory health of the plastics industry workforce.
The basics of plastics
There are two main categories in plastics processing: Thermoplastic and Thermoset materials
Thermoset materials undergo chemical reactions to melt, shape, cure and harden into objects.
Due to its chemical structure, thermosets have a higher degree of rigidity and tend to outperform other materials in regards to mechanical properties, chemical resistance, stability and durability.
However, once cured, thermosets are never able to be re-softened or reshaped.
Thermoplastics have the ability to re-melt and re-form which is why a majority of plastic products are made from these resins.
Common thermoplastic resins include:
- Polyethylene ― PE
- Polyvinyl Chloride ― PVC
- Polypropylene ― PP
- Polystyrene ― PS
- Polyethlene Terephthalate ― PET
- Acrylonitrile-butadiene-styrene ― ABS
- Styrene-Acrylonitrile ― SA
- Acrylic ― PMMA
- Polyamide ― PA (Nylon)
- Styrene-Acrylonitrile ― SAN
- Polycarbonate ― PC
During the injection molding process, these resins are melted, injected into molds, rapidly cooled and released all within a matter of minutes; all the while emitting hazardous fumes and vapors that pose health risks if inhaled.
From pellets to objects
The below graphic illustrates the basic injection molding process.
This blog focuses on three process areas of respiratory concern: Purging & Maintenance; Heating & Melting; Cooling & Removal
Before a new mold can be injected, the residual resins must be removed from the machine.
This process requires very high heat to melt resins and purging agents in order to press them through the machine.
As a result, smoke and fumes emit and enter the operator’s breathing zone.
Heating & Melting
Similar to the purging process, resin pellets are heated at high temperatures until they reach their melting point. At which time, the melted resins are pressed through a rotating screw and into the mold.
This process also emits hazardous smoke, fumes and gases that may have adverse health effects if inhaled.
The below table shows the respiratory hazards and side effects one may encounter when working with plastic materials.
|Plastic||Constituents in Fume||Exposure Limits||Side Effects|
|PVC||Hydrogen chloride||NIOSH REL: C 5 ppmOSHA PEL: C 5 ppm||Irritation to nose, throat, larynx; Cough, choking; Dermatitis; Laryngeal spasm and pulmonary edema found in animals|
|Fire-retardant ABS||Styrene||NIOSH TWA: 50 ppmOSHA TWA: 100 ppm||Irritation to eyes, nose, respiratory system; headache, weakness, exhaustion, dizziness, confusion, drowsiness, unsteady gait; narcosis; defatting dermatitis; possible liver injury; reproductive effects|
|Phenol||NIOSH TWA: 5 ppmOSHA TWA: 5 ppm||Irritation to eyes, nose, throat; anorexia, weight loss; weakness, exhaustion, muscle ache, pain; dark urine; cyanosis; liver, kidney damage; skin burns; dermatitis; ochronosis; tremor, convulsions, twitching|
|Butadiene||OSHA TWA: 1 ppm||Irritation to eyes, nose, throat; drowsiness, dizziness; teratogenic, reproductive effects; potential occupational carcinogen|
|Polypropylene||Formaldehyde||NIOSH TWA: 0.016 ppmOSHA TWA: 0.75 ppm||Irritation to eyes, nose, throat, respiratory system; lacrimation (discharge of tears); cough; wheezing; potential occupational carcinogen|
|Acrolein||NIOSH TWA: 0.1 ppmOSHA TWA: 0.1 ppm||Irritation to eyes, skin, mucous membrane; decreased pulmonary function; delayed pulmonary edema; chronic resp. disease|
|Acetone||NIOSH TWA: 250 ppmOSHA TWA: 1000 ppm||Irritation to eyes, nose, throat; headache, dizziness, central nervous system depression; dermatitis|
|Acetals||Formaldehyde||NIOSH TWA: 0.016 ppm||Same as above|
|Polyethylene (low density)||Butane||NIOSH TWA: 800 ppm||Drowsiness, narcosis, asphyxia|
|Polystyrene||Styrene||NIOSH TWA: 50 ppmOSHA TWA: 100 ppm||Same as above|
Cooling & Removal
During the final stages, curing occurs by quickly cooling the mold.
This coolant tends to send renegade mist into the air, compromising the ambient air quality in the workspace.
Lastly, when the mold is released from the machine, tiny release agents and particles may emit and enter the operator’s breathing zone.
In order to recommend the most appropriate fume extraction system, Sentry Air technical applications specialists consider the size of the molds being created and the types of fumes that must be captured.
For a majority of injection molding applications, we recommend our Model 300 Portable Floor Sentry (SS-300-PFS) with a filter combination of HEPA and 10lbs of activated carbon.
The Model 300 utilizes up to 350 CFM of airflow to pull harmful plastic fumes away from the operator’s breathing zone and directly into the filter chamber.
The HEPA filter is 99.97% efficient on particles 0.3 microns and larger while the activated carbon filter utilizes thousands of carbon granules to capture renegade odors from volatile organic compounds typically found in plastics fume.
For applications requiring a greater amount of smoke capture, we recommend our Model 400 Portable Floor Sentry (SS-400-PFS) with a filter combination of HEPA and 22lbs of activated carbon.
The Model 400 offers heavy-duty airflow up to 700 CFM.
Both the Model 300 and 400 come equipped with heavy-duty casters and portability handle, allowing easy placement around the injection molding machine.
And for removing ambient or renegade fumes from the greater work area, a Model 2000 Free Hanging Ambient Room Air Cleaner is recommended.
Contact Sentry Air
If your business is seeking a solution to fume control for plastics processing, or if you want more information about chemical fume control, give Sentry Air a call today 800.799.4609, email email@example.com, visit our website or fill out the feedback form below.
- National Network on Environments and Women’s Health – Chemical Exposure and Plastics Production: Issues for women’s health
- Health and Safety Executive – Controlling fumes during plastics processing
- RL Hudson – THERMOSET VS. THERMOPLASTIC MATERIALS
- The Plastics Industry Trade Association
- Wikipedia – Injection Molding