Chemical Fume Hoods

The University of Mississippi, Department of Health & Safety (DHS) has adopted the following policies and procedures for the use, design, installation, renovation, maintenance, and dismantling of chemical fume hoods on the UM campus and affiliated facilities.

These guidelines reflect federal, state, local, and University health and safety regulations and policies. The guidelines do not stand alone, but must be incorporated with other applicable standards into the design and construction of a fume hood.  Any questions not addressed here should be addressed by consulting the references cited at the end of this guide; particularly the ANSI/AIHA National Standard for Laboratory Ventilation.  In this way, those who use and maintain chemical fume hoods will be ensured of an adequate level of protection from the possible harmful effects of laboratory chemicals.   

Use of a Chemical Fume Hood

Laboratory Chemical Fume Hoods are designed to protect personnel by reducing or eliminating exposure to hazardous chemicals, dusts, mists, and fumes.  Chemical Fume Hoods can also act as a physical barrier to help protect lab personnel from the hazardous properties of some materials.  To work properly chemical fume hoods must be evaluated each year or at least before the next planned use of hazardous materials.

The primary purpose of this information is to let an average person know what a fume hood is designed for, how it can be used safely, what it cannot be used for, and who do you call if you have a question about a fume hood or if you think it is not working properly.  

Questions and Answers

Some of the most common problems encountered in the use of fume hoods are included below.  If you have any other problems concerning a fume hood, please call DHS (5433).

Who do I call if my fume hood does not appear to be working?

The Electric Shop of the University of Mississippi Physical Plant Department performs all fume hood maintenance.  Your department needs to submit a notification with the Electric Shop to have the hood maintenance performed.

If your fume hood has an Airflow Indicator, check it to see if it operating in the normal range.  If the Airflow Indicator shows that the hood is not working properly or you feel the indicator is incorrect, Call DHS (5433).  If your hood does not have an airflow indicator, call DHS (5433).

Can I use a strip of tissue paper to see if my hood is working?

What is the proper flow rate of a hood where hazardous materials are used?  I thought that the faster the flow rate the safer it will be.

The alarm on my airflow monitor is constantly buzzing, can I just tape down the mute button?

What is wrong with my hood if I can hear the motor running but the hood is not working?

I can smell the halogenated solvent in the lab, whenever I use it in the hood.  The hood was checked recently and it was fine.  What is wrong with the hood?

My hood has recently failed a survey and I was told that the reason is because there is too much equipment and chemical containers in my hood.  How can I do my work if I clean out my hood?

My hood is near a door that is always open.  Sometimes I have had colleagues tell me that they can smell chemicals in the hallway near my lab.  Is my hood not working properly?

I work with some pretty smelly chemicals and I need to keep them in a hood or the whole building will stink.  Is this a problem?

Special Uses

I. Perchloric Acid

A. Chemical Fume hoods designated for use with perchloric acid should be clearly identified with a warning sign.

B. All exposed hood and duct construction materials must be suitable for use with perchloric acid, (inorganic, non-reactive, acid resistant, and relatively impervious).

C. The hood surface must be watertight, with all-welded construction and accessible rounded corners for cleaning ease.

D. The fume hood and exhaust ducting design should include washdown facilities for frequent use. Duct configuration must permit the thorough washdown of all duct surfaces. The baffle must be removable to allow for periodic cleaning and inspection.

E. Each perchloric acid hood must have an individually designated duct and exhaust system.

F. The duct system should be straight, vertical, and as short as possible.

G. Use only an acid resistant metallic fan.

H. Do not use lubricants, caulking compounds, gaskets, or other materials in the fan, which are not compatible with perchloric acid. Use fluorocarbon type grease.

I. The fan motor must be located outside of the air stream.

II. Radioactive Materials

The RSO also recommends Iodination Cabinets or Mini Hoods for iodination procedures.  The RSO should be consulted on all matters involving iodination procedures and safeguards including the installation and relocation of iodination mini hoods.  

A. Iodination mini hoods must be located within an already operative chemical fume hood.

B. The mini hood should be compatible with the chemical fume hood with respect to size and airflow.

C. Airflow through the arm portals should be maintained at 150 linear feet per minute.

D. Plexiglas construction is recommended.  Information regarding the proper selection, installation, and use of other types of specialty containment hoods can be obtained from the DHS.

NOTE: If you are unsure of the suitability or performance of a chemical fume hood anytime prior to or during the use of radioactive materials, please call DHS (5433).

III. Carcinogens

NOTE: If you have any question regarding the safety of a chemical fume hood in which carcinogens are to be used, please call DHS (5433).    

Construction, Installation, and Renovation

Listed below are policies and procedures to be followed as part of the fume hood construction, installation, or renovation process. These guidelines are divided into nine categories: Laboratory Design, Supply Air, Fume Hood Construction and Installation, Ductwork, Exhaust Fan, Exhaust Stack, Plumbing, Electrical and Sashes. A justification for each requirement is provided as appropriate.  

I. Laboratory Design

A. Laboratories with fume hoods must be designed to have no recirculation of air to that lab or any other spaces.  Recirculation of laboratory air will result in indoor air quality problems.

B. Fume hoods must be located so that persons exiting the lab do not have to pass in front of the hood.  The potentially dangerous portion of an experiment is usually conducted in a fume hood. Many lab fires and explosions originate in fume hoods.  A fire or explosion in a fume hood located adjacent to a path of departure may trap someone in a lab.  Also, turbulence from passing traffic can adversely affect hood performance.

C. There must be two exits from rooms where new fume hoods are to be installed. If this is not feasible, the fume hood must be situated on the side of the room furthest from the door.  A fire or chemical hazard, both of which often start in a fume hood, can render an exit impassable. For this reason, all labs with fume hoods are required to maintain two unblocked exit routes.

D. Fume hoods must not be situated directly opposite occupied workstations.  Materials splattered or forced out of a hood could seriously injure anyone seated across from it.

E. Windows in labs containing fume hoods must be fixed closed.  Breezes coming in through open lab windows can adversely affect the proper functioning of a hood. Turbulence caused by these wind currents can easily bring the contaminated air inside the hood out into the lab.

II. Supply Air

A. Before a new fume hood is put into operation an adequate supply of make-up air must be provided to the lab.  A fume hood exhausts a substantial amount of air. For this reason additional make-up air must be brought into the room to maintain a proper air balance.

B. Supply and exhaust volumes should be such that the lab is slightly negative (~10%) in pressure relative to corridors and outside.  The air balance should be adjusted so that air flows into the room through openings, including open doors.  Negative relative pressure will restrict any hazardous materials releases to inside the lab.

C. Ceiling and wall diffusers for distribution of make-up air should be directed so that the incoming supply airflow has no influence on the directional airflow at the fume hood.  Misdirected air currents could cause turbulence at the fume hood opening impairing its proper operation.

D. Supply air diffusers must be designed so as to provide less than 50 fpm terminal throw velocity at 6 feet above the floor.  Larger velocities can disrupt laboratory work at benchtops, lower fume hood performance, interact with lab instruments and cause discomfort to lab personnel.

E. New fume hoods will not have an on/off control accessible in the laboratory.  Fume hoods are an integral part of the entire room's air balancing system, which must be maintained. When a fume hood is turned off, the lab can develop positive pressure. Labs must be maintained under negative pressure.

F. Supply air intake locations must be located a minimum of 50 feet from the discharge point of any fume hood.  Intakes should also not be located in the vicinity of loading docks, generators or other devices generating harmful emissions.  Re-entrainment of emissions will cause obvious indoor air quality problems.  

III. Fume Hood Construction and Installation

A. Chemical storage cabinets directly under a newly installed or renovated fume hood shall be ventilated to the fume hood exhaust.  Cabinets shall be vented using stainless steel flexible ducting connected above the hood at the exhaust duct collar.   All penetrations must be sealed.

B. Supply or auxiliary air hoods are unacceptable.  It is very difficult to keep the air supply and exhaust of supply hoods properly balanced. In addition, the supply air is intemperate, causing discomfort for those working in the hot or cold air stream. As a result, the supply vent is often either shut or blocked off. Finally, the presence and movement of the user's body in the stream of supply air creates turbulence that degrades the performance of the hood.

C. Constant volume bypass fume hoods are recommended.  These hoods permit a stable air balance between the lab's ventilation systems and fume hood exhaust by incorporating an internal bypass feature. This allows a constant volume of air to be exhausted through the hood regardless of sash position.  Variable volume systems may be acceptable if properly designed.

D. Portable, non-ducted fume hoods are not allowed except for limited uses as approved by the DHS.  Non-ducted fume hoods use filters, which may become overwhelmed in the event of a spill. Breakthrough can also occur as the contaminant is dislodged with the sudden change in airflow velocity associated with turning the blower on and off. In addition, an adequate level of protection cannot be assured for different classes of chemicals.

E. Interior fume hood surfaces must be constructed of corrosion-resistant, non-porous, non-combustible materials such as stainless steel or special composite or polymer materials.  Corrosive materials can eat through many types of materials, shortening fume hood life. In addition, some materials, when exposed to direct flame, emit noxious and toxic fumes.

F. The work surface inside the fume hood must be of the recessed type. With a recessed work surface, the retaining lip can effectively contain spills.

G. Plastic or fiberglass hoods are unacceptable for use with flammable solvents or open flames.  Although some plastic and fiberglass containing construction materials may be non-combustible, when involved in a fire they generate large quantities of dense, potentially toxic smoke. This smoke presents a safety hazard to both building occupants and fire fighters.

H. An airflow indicator is provided with all new fume hoods.  It is advisable, to have an airflow indicator added to older hoods.  Significant changes in a needle deflection or an indicator can allow the user to know when a hood needs to be serviced.  Manufacturer instructions should be followed regarding installation, minimum and maximum airflow, etc.

I. There must be a horizontal bottom airflow inlet at the front of the hood.  The airfoil at the front of the hood floor assures a good sweep of air across the hood floor toward the back of the hood. This minimizes the generation of turbulent eddy currents at the entrance to the hood.

J. Baffles with adjustable horizontal slots should be present at the rear and top interior of the fume hood to provide at least two (preferably three) slots, with adjustable openings, to help maintain a reasonably uniform face velocity.  Baffles assist in maintaining a unidirectional airflow.

K. Air velocity at the hood face must average 100 - 150 linear feet per minute (sash fully open for hoods with bypass feature).  All measurements (9 minimum) must fall within 75 - 200 fpm.  A smoke test should be performed to verify that unacceptable turbulence is not occurring.

L. If the sash height is adjusted to maintain an adequate hood face velocity, a sticker will be attached to show how high a sash can be opened without causing the hood face velocity to go below 100 linear feet per minute.  The minimum face velocity should be present with the sash no lower than 12 inches.

M. Instrumentation used to measure air pressure or air velocity shall have been calibrated within one year of their use.

N. Baffles should be adjusted in such a way that less than a +10% variation in face velocity measured with the sash in its maximum open position can be obtained.

O. Where feasible, chemical fume hood exhaust fans should be connected to emergency power in case of a power failure.  If hood exhaust fans are placed on emergency power, an equivalent volume of supply air must also be provided, otherwise it may be difficult or impossible to open the laboratory doors for emergency exiting.  Less than full speed operation of the hood fans while on emergency power is an option but the DHS must be consulted for approval.

P. Noise from fans, ductwork and air velocities shall not exceed 65 dBA inside the lab area.

IV. Ductwork

A. Gang ducting of fume hoods is not recommended unless required by special conditions or in new buildings properly designed for this purpose. These must be properly designed with final approval from the DHS.  It is difficult to keep each fume hood on a common duct balanced and working properly. If the fume hoods are in different ventilation zones within the building, air balancing becomes virtually impossible. Additionally, if the fan serving a gang-ducted system shuts down, chemical contaminants can  "backflow" from one lab to another. The entire system must be shut down during servicing and repair work, causing considerable user inconvenience.

B. Fume hood ducts connected to new fume hood installations or renovations must meet current fire codes regarding fire shafting, where applicable.

C. Slope all horizontal ducts down towards the fume hood (Guideline: 1/8" to the foot).  Liquid pools, which result from condensation, can create a hazardous atmosphere if allowed to collect.

D. Design criteria for fume hood exhaust duct construction include:

• Minimum 18 gauge, Type 316 stainless steel. Coated galvanized steel may be considered for non-hospital installations under special conditions.  However, special attention to quality control is required.
• Heliarc inert gas with Type 316 welded seams.
• Follow Sheet Metal and Air Conditioning Contractors' National Association (SMACNA) Round Industrial Duct Construction Standards for duct supports and reinforcement using stainless steel material.
• Follow SMACNA 1985 HVAC Duct Construction Standards using Type 316 stainless steel for exhaust stack on roof.

E. New duct installations must be tested at negative pressure, 1 1/2 times its operating pressure (per SMACNA). Test should show zero leakage.

F. Fire dampers are not allowed in hood exhaust ducts.

G. A damper for adjusting the hood air velocity may be incorporated into the ductwork.  Consult the DHS for details.  Dampers should not be easily accessible to laboratory personnel.

H. Duct velocities should be maintained below 1,600 feet per minute (fpm) to minimize noise.

V. Exhaust Fan

A. New exhaust fans should be oriented to exhaust in an upward direction.  Any other type of fan orientation increases the workload required from the fan.

B. Exhaust fans must be located at the point of the final discharge. An exhaust fan located at other than the final discharge point can pressurize the duct with contaminated air.  Fume hood ducts must be maintained under negative pressure.

C. Fans shall be constructed of materials compatible with the chemicals being transported in the air through the fan.  If flammable gas, vapor or combustible dust is present in concentrations above 20% of the Lower Explosive Limit (LEL), the fan construction shall be as recommended by AMCA’s Classification for Spark Resistant Construction.  

VI. Exhaust Stack

A. Fume hood exhaust stacks must extend at least seven feet, (10 ft. is preferred) above the roof or at least two feet above the top of a parapet wall, whichever is greater. Discharge must be directed vertically upward.

B. Discharge from exhaust stacks should have a velocity of at least 3,000 fpm. However, tall stacks may be permitted to have a lower exit velocity, if justified.  A sufficient discharge velocity is necessary to adequately disperse contaminants.

C. Hood exhausts on the roof should be located at least 50 ft. away from air intakes to prevent the re-entrainment of exhaust fumes.

D. Rain caps, which divert the exhaust toward the roof, are not allowed; high velocity discharge or concentric duct self-draining stacks, or equivalent, may be used.

E. Exhaust stacks should be secured with earthquake restraints, where applicable.

VII. Plumbing

A. All plumbing utilities must have a shut-off valve or cock adjacent to the hood.

B. If remote control fittings are used for hood utilities, the extension rod shall be solid four-sided stainless steel with a monel coupling and set screw.

C. Hot or cold water supplies must be connected to a non-potable industrial water system. If industrial water is not available in the building, then a reduced pressure type backflow device shall be used on each water system. A single device may serve several hoods.

D. Waste outlet should be connected into the building's acid resistant laboratory waste system, if present.

VIII. Electrical

A. Electrical outlets must be outside the hood.  The atmosphere inside a fume hood may contain flammable gases or vapors, which can ignite, resulting in a fire or explosion. For this reason, any activity—including plugging into and unplugging from an electrical outlet—which may produce a spark, must be performed outside the hood.

B. Lighting fixtures should be of the fluorescent type.  Fluorescent bulbs give off less heat than conventional bulbs.  They help maintain a safe and comfortable work area inside the hood.

C. Light fixtures should be sealed and vapor tight, UL-listed, and protected by a transparent impact resistant shield.  The potential for flammable or combustible atmospheres requires explosion-proof electrical equipment.  

IX. Sashes

A. Sashes may be horizontal, vertical, or a combination, and should have the capability to completely close off the hood face.

B. Horizontally sliding sash panels may not be less than twelve inches, nor more than fifteen inches, in width.  Such sashes may offer extra protection to lab workers as they can be positioned to act as a blast shield.

C. Sashes should be made of safety glass:

• Laminated safety glass, when internal temperature is anticipated to be less than 160° F.
• Tempered safety glass when high internal temperatures are anticipated that will result in sash surface temperatures greater than 160°F.

Servicing and Dismantling

I. Before a fume hood is serviced or dismantled Lab personnel must:

A. Remove all equipment in the hood, which may impede or impair access. B. Remove all chemicals and radioactive materials in the hood, which may pose a hazard. C. If necessary, decontaminate the interior of the hood as appropriate. D. If necessary, don PPE (Personal Protective Equipment:  such as goggles, respirator, gloves, coveralls or arm guards). E. If the hood fume needs to be turned off, notify laboratory workers and post an “Attention, This Hood is Being Repaired” Notice on the hood.

Note : The iodination mini hood housed within a fume hood should be shut down and covered with plastic whenever the fume hood requires servicing, this includes servicing at the roof.

A designated person from the laboratory is responsible for ensuring that the procedures mentioned above have been done. Upon completion of the necessary decontamination procedures, the responsible party must notify the person listed at the bottom of the Hood Repair Notice so that repair work may begin.

The DHS may be consulted regarding appropriate decontamination procedure.  

II. Fume Hood Service Procedure

A. Locate the appropriate fan or motor on the roof that needs service and the room in which the fume hood is housed.  Electricians should have hood-to-fan information.  A specific fume hood and the room in which it is housed can be identified by either a fan number marked on the fume hood structure or a room number marked on the fan housing.

B. Communicate to lab personnel the need to service the fan or hood and obtain permission to shut down the hood. If lab personnel are not available, contact the building manager or Department Chair to obtain permission to shut down the hood.

Do Not Turn Off Fan Without Permission From An Authorized Person and after all hazardous materials have been removed from the fume hood.

C. Fill out a Hood Repair Notice and fix it to the hood sash.  Then shut down the fan.  Note: Information on the tag should include:

1. Date of shutdown
2. Building location
3. Room number
4. Estimated time period when hood will be off
5. Your name or your supervisor's name and phone number

D. If the fan to be worked on is located near hood exhaust stacks, which do not have a 7 to 10 ft. extension, those fans must also be turned off. If this is not possible, an appropriate respirator and safety glasses supplied by your supervisor are to be used (consult DHS at 5433).

E. After service is completed, restart the fan and remove the Hood Repair Notice from the fume hoods.

Testing and Certification

A. DHS is responsible for performing the annual testing and certification of campus fume hood performance to meet campus requirements.   DHS is responsible for maintaining testing and certification records.

B. Once a hood has been certified, DHS will attach a small inspection tag.  This tag will list the class, average face velocity and date of testing.  Each hood will also be provided with a green sticker, which contains helpful reminders concerning the use of your hood and who to contact in an emergency.

C. If hood performance is significantly outside the limits of acceptable performance, DHS will post the hood as Out of Service for continued use and inform lab personnel.  The Department in charge of the lab submits the work order for the repair of a hood.  After Physical Plant has performed repairs or adjustments to the hood, DHS will retest and certify the hood.

D. If you have a fume hood that has not been inspected in the past year, or still has an Out of Service notice and has not been repaired, please contact the DHS office (5433).

References

American Industrial Hygiene Association, American National Standard for Laboratory Ventilation, 1992

American Conference of Governmental Industrial Hygienists (ACGIH), Industrial Ventilation Manual, 1989 edition.

American National Standard Institute, Laboratory Ventilation, ANSI Z9.5-1992.

American Society of Heating, Refrigerating, and Air Conditioning Engineers (ASHRAE), Fundamental Handbook.

American Society of Heating, Refrigerating, and Air Conditioning Engineers (ASHRAE), ASHRAE 110, Methods of Testing Performance of Laboratory Fume Hoods.

National Fire Protection Association (NFPA), Blower and Exhaust Systems, NFPA No. 91-1973.

National Fire Protection Association (NFPA), Fire Protection for Laboratories Using Chemicals, NFPA 45.

Sheet Metal and Air Conditioning Contractors National Association, Inc. (SMACNA)

Hood Information Sticker

The following reminder label should be affixed to your fume hood. It highlights the most frequently asked questions. If your sticker is missing or damaged, contact Health and Safety (5433) for a replacement.