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Laboratory Fume Hood: Ducted Vs. Ductless - Workstation Industries

Sep. 08, 2025

Laboratory Fume Hood: Ducted Vs. Ductless - Workstation Industries

To duct or not to duct: that is the question. Or at least a question manufacturers often face when deciding which fume hood to purchase.

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Installing a fume hood in your laboratory is a major purchase - and necessary purchase - for your operation when you deal with toxic chemicals.

But, how do you know whether a ducted or ductless fume hood is best for your laboratory? Your budget, lab size and safety considerations all play a role in determining which is appropriate for meeting the needs of your lab and keeping the safety of your employees a top priority.

Here’s what you need to know about ducted and ductless fume hoods, including:

How each type works
The advantages and disadvantages of each
What you should consider before making a final decision.

How Each Type Works

One of the most reliable engineering pieces in a lab, ducted and ductless fume hoods both remove vapors, dusts, gases and fumes that are created within the hood. As air flows into the the hood, these chemicals are removed via an exhaust system.

But, how this process carries out differs between the two.

Ducted Fume Hoods

Considered the more standard choice, ducted fume hoods have ventilated enclosures and operate within the framework of your building infrastructure. They pull toxic fumes out of your laboratory through an HVAC system.

The construction of a ducted fume hood includes a base, work surface, hood, blower and ducting that carries the air outside. When installing, it’s important to consider whether your ventilation system has enough air to provide the necessary volume of ventilation to the hood.

Often, maintenance to the fume hood is performed as part of routine maintenance to the building. Generally, those who take care of the maintenance are in charge of the mechanical systems.

Ductless Fume Hoods

Ductless fume hoods, on the other hand, are considered more of an alternative choice. Though becoming more popular, they aren’t yet as widely used as ducted fume hoods.

Ductless fume hoods operate off a carbon filter system, which recirculates filtered air into your laboratory. Sometimes referred to as “recirculating range hoods,” this type of hood filters the air and then returns it back into a workspace.

Unlike ducted fume hoods, ductless hoods are self-contained and work well for laboratories where mobility is necessary. Laboratories that handle light to moderate chemical loads (no more than 10 chemicals per application, with a volume of approximately 500 mls or less) also may find ductless fume hoods to be a better choice operationally.

To understand further how a fume hood works, read our article, What Is A Fume Hood?

Advantages/Disadvantages Of Each

Whether it’s upfront cost savings, mobility or safety, both types of hoods provide distinct advantages and disadvantages in a laboratory space.

Ducted Fume Hoods

Ducted fume hoods are considered the safest for workers in laboratories, and many universities require this type of hood be installed in any facility that requires one to maintain worker and student safety. They often are the easiest for employers to maintain as well.

Other advantages include:

Can handle a variety of chemicals
Easy to operate and maintain
Little to no contamination in lab

On the other hand, ducted fume hoods may require other infrastructure improvements or additions, such as duct work, exhaust fans, changes to roofing elements and upgrades to mechanical systems. This can make them the more expensive choice up front.

Other disadvantages include:

More difficult to install
Stationary in the lab
More difficulty in moving or relocating
Use more energy

Ductless Fume Hoods

Because of its self-containing fume hood design, ductless hoods are mobile - allowing workers to use the hood in different work areas depending on the need. They’re also a great option for labs that don’t handle as many chemicals or do not have the space for a full-size ducted unit.

Other advantages include:

Easy to install
Easily movable or relocatable

Want more information on Laboratory Ventilation In HVAC? Feel free to contact us.
Use less energy
Less expensive upfront because there is not construction work needed

Ductless units, on the other hand, do have disadvantages that should be weighed carefully. Though they are a more cost-effective option from both an installation and operational perspective, one of the largest disadvantages is that workers are at a greater risk of chemical exposure because of its mobile design. Educating workers on the proper use of a ductless unit is critical in maintaining proper safety standards.

Other disadvantages include:

Handles limited chemicals
Requires certain filters for specific chemicals, with filter maintenance needed
Not as effective at removing chemical fumes
Not recommended for constant use
Can be noisy due to the internal blower
Cannot handle extreme heating of chemicals

What You Should Consider

Now that you better understand the differences between the two, as well as their advantages and disadvantages, you must determine which option is the best choice for your laboratory’s needs.

Here are some questions that may help you determine which is the better fit:

What chemicals will be used inside the hood?
How many different chemicals does your lab use?
Of these chemicals, are you working with small or large volumes?
Will the chemicals you are using adequately filter through carbon?
How experienced is your staff in working with chemicals? A university lab, for instance, may be filled with inexperienced students, providing a higher risk for exposure.
Does your building already have an HVAC system?
If so, is there a team in place to manage it and provide maintenance?
Is mobility necessary for your operation?
What is your budget - both up-front and including installation and long-term expenses?
How quickly do you need the hood installed?
Do you anticipate your facility location changing in the future?

Answering these questions before you purchase a fume hood for your laboratory will help you weigh the advantages and disadvantages of each and determine which is a better fit for how your facility operates.

Bottom Line

Ducted and ductless fume hoods play a critical role in any laboratory, removing toxic fumes from the air that can expose your workers to life-threatening chemicals.

No matter what, laboratory safety and workload should be your top considerations for any laboratory furniture. While you’ll likely take into consideration financial costs as well, keep in mind that the overall cost can change dramatically from the initial upfront fees through installation and subsequent maintenance.

Chemical Fume Hoods - Office of Environmental Health and Safety

(Printable version)

Common questions:

What is the purpose of the laboratory fume hood?

The fume hood is the most important local exhaust device used in laboratories. When used properly, it will protect the user from exposure to potentially harmful chemicals and other hazardous air contaminants. It is important to remember that the hood is part of the building's complete ventilation system, and its performance is influenced by other parts of the system.

Successful hood performance depends on the velocity of air moving through the hood. Airflow is affected by cross drafts, entrance shapes, thermal loading and objects placed in the hood.

The hood sash is meant to protect the user from exposure to harmful vapors, and to minimize the effects of explosions, fires, spills and splashes that may occur within the hood.

What is the proper function of the hood?

To adequately protect the fume hood user, the linear face velocity of air into the hood should be between 70 and 130 feet per minute (fpm).

Arrows on the side of the hood or sash stoppers indicate where the sash should be positioned to achieve the ideal airflow rate. This sash height is set between 12 and 18 inches from the bottom of the opening to protect the user and allow adequate room to work. When working in the hood, the sash must be at the height indicated by the arrows or stoppers to ensure safe operation. Lowering or raising the sash height will negatively impact the airflow.

Keep in mind that faster velocities, especially above 250 fpm, create hazardous conditions by interfering with operations such as transferring dry chemicals and flame control on burners.

A fume hood that isn't performing properly is often worse than no hood at all because the user is likely to have a false sense of security about its ability to provide protection.

What are the procedures for safe use of a chemical fume hood?

Know the health hazards of the materials you are working with and become familiar with the signs and symptoms of overexposure.
For optimum safety, use all hazardous chemicals in the hood. Always perform procedures with highly toxic materials in the hood, especially those with a permissible exposure limit (PEL) of 50 ppm or less. See the chemical specific SDS for this information.
Perform work at least 6 inches into the hood to ensure that air is being adequately exhausted away from you and protecting you from exposure to hazardous vapors.
Keep only equipment and chemicals necessary for your experiment in the hood. When possible, raise equipment at least 2 inches off of the work surface to allow for better airflow.
Eliminate clutter in the hood. Fume hoods are not meant for storage of chemicals, lab equipment, or waste.
Keep combustibles, such as paper towels, out of the hood. Besides being a fire hazard, paper items may also become drawn into the hood exhaust system, blocking or restricting airflow.
Do not block the rear hood exhaust slots with equipment or materials. Keep items at least three inches away from back baffles.
Minimize traffic near the hood to minimize airflow disruption.
Do not position fans or air conditioners in the room in a manner that will direct air flow across the face of the hood and interfere with containment.
Never stick your head into the hood or leave the sash fully open during experiments involving hazardous materials.
Chemical fume hoods should never be used as a means of evaporating old or unwanted chemicals. Submit all chemical waste disposal requests to the Office of Environmental Health and Safety (OEHS).
Completely close the hood sash or panels:
- At the end of the day
- When leaving experiments or chemicals unattended.
- When the hood is not in use.

What are the criteria for evaluating a fume hood's performance?

Chemical fume hood performance is evaluated and certified annually by OEHS. OEHS submits work orders to Facilities Planning & Management (FP&M) for hoods that do not pass certification. FP&M is responsible for adjusting and repairing fume hoods.
The sash must be able to be opened, closed, and adjusted to the appropriate working height.
Air velocity measurements are taken at five points across the opening (or face) of the hood and averaged. The average face velocity must be between 70-130 fpm to pass certification. The ideal average face velocity should be ~100 fpm at a sash height of 15 inches.
If a fume hood has an airflow monitor, it must be functioning and indicate a similar airflow as the average of measurements taken at the face of the hood.

For evaluation of a chemical fume hood, please submit an online request to OEHS: Chemical Fume Hood Certification Requests

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