- Achieving Sustainable Site Design through Low Impact Development Practices
- Aesthetic Challenges
- Aesthetic Opportunities
- Air Barrier Systems in Buildings
- Air Decontamination
- Balancing Security/Safety and Sustainability Objectives
- Building Integrated Photovoltaics (BIPV)
- Cool Metal Roofing
- Cost Impact of the ISC Security Criteria
- Designing Buildings to Resist Explosive Threats
- Distributed Energy Resources (DER)
- Electric Lighting Controls
- Electrical Safety
- Energy Analysis Tools
- Energy Codes and Standards
- Energy Efficient Lighting
- Evaluating and Selecting Green Products
- Extensive Vegetative Roofs
- Facility Performance Evaluation (FPE)
- Fuel Cells and Renewable Hydrogen
- Glazing Hazard Mitigation
- High-Performance HVAC
- Life-Cycle Cost Analysis (LCCA)
- Mold and Moisture Dynamics
- Natural Ventilation
- Passive Solar Heating
- Reliability-Centered Maintenance (RCM)
- Retrofitting Existing Buildings to Resist Explosive Threats
- Security and Safety in Laboratories
- Seismic Design Principles
- Solar Water Heating
- Sun Control and Shading Devices
- Sustainable Laboratory Design
- Sustainable O&M Practices
- Therapeutic Environments
- Threat/Vulnerability Assessments and Risk Analysis
- Windows and Glazing
Sustainable O&M Practices
Last updated: 07-21-2010
Within This Page
"Operations and maintenance" (O&M) includes all aspects of running a building over the course of its useful life. Because of the far-reaching nature of O&M, a well-designed and properly executed program is critical to the overall success of a "sustainably-designed" facility.
Such a program should:
- Set demanding performance goals on both a daily and ongoing basis;
- Measure performance so that the building can be benchmarked against other buildings;
- Adjust to changing occupant needs by modifying the HVAC, lighting, electrical, telecommunications, safety, housekeeping, and building automation control systems, as needed;
- Repair, upgrade, and recommission building systems to ensure that they are working to meet current needs;
- Extend the useful service life of materials and equipment;
- Prevent disruptive failures in the building and its systems; and
- Promote greater productivity.
The architectural entries of the EPA Kansas City Regional Office are designed to capture dirt, mud, pollen, snow, salt, and other contaminants from footwear and prevent them from entering the building. Originally conceived as a permanent grating "walk-off system," an easier to maintain stone floor with walk-off carpets was ultimately selected. This system can reduce the frequency of vacuuming, cleaning, stripping, and recoating of floors, and extend the life of floors and mechanical equipment, contributing to lower operational costs.
Courtesy of GSA and Koll Construction.
An effective, properly designed O&M plan includes upkeep of the HVAC and building systems so that building energy efficiency targets are met over the life of the building. It can also foster achievement of a facility's pollution prevention goals, which aim to reduce use of hazardous materials, minimize solid waste, and eliminate the use of ozone depleting substances.
One goal of effective O&M is to achieve the intent of the original building design team, i.e., so that building systems deliver services (including the appropriate amount of outside air) to building occupants. O&M is also the discipline through which long-term goals of economy, energy efficiency, resource conservation, and pollution prevention can be achieved, while meeting the comfort, health, and safety requirements of the tenants.
The following should be incorporated into an effective O&M plan:
- Master schedules for operations and preventive/predictive maintenance (see also WBDG Reliability-Centered Maintenance);
- Continuous monitoring of equipment performance;
- Early detection of defects or failures in equipment through use of service alarms or other means;
- Minimization of equipment failures by use of preventive maintenance, standbys, etc. so that the failed component can be isolated and repaired without interrupting system performance; and
- Use of internal and external test systems to locate faults and fix problems quickly.
Proactive O&M can yield benefits such as reduced solid and hazardous waste generation, less hazardous air pollution, extended service life of equipment and building materials, reduced absenteeism and worker's compensation claims, better indoor air quality, and fewer occupant complaints.
Effective O&M strategies for high performance buildings should:
- Integrate indoor environmental quality (IEQ), energy efficiency, and water conservation into established policies and procedures;
- Provide regular professional development and training for O&M personnel (e.g., 24 hours/annually which includes on-site, hands-on training on the building systems and sustainability aspects);
- Establish a facility-wide team to evaluate and improve on O&M practices; and,
- Incorporate environmentally-protective features into all contracts, maintenance, and procurement practices.
As part of the O&M plan, procedures, and manuals should be prepared and updated in a timely fashion, including:
- A written best practices equipment preventive maintenance program.
- A master equipment list, with model and serial numbers, required spare parts, equipment specifications, and parts suppliers list.
- An equipment history record file, noting dates of installation and repair history.
- Operating manuals and specifications for equipment.
- Air balancing reports and airflow specifications.
- As-built blueprints of mechanical, electrical, and plumbing systems and control blueprints showing how the systems operate.
- Building commissioning results.
- Preventive maintenance charts for each piece of equipment and work orders for those activities.
Effective O&M practice should address waste reduction, reuse, and recycling:
- Source reduction, eliminating the use of hazardous materials, is the first step in an overall waste reduction strategy.
- Once this is accomplished, materials that can be recycled should be favored.
- Only when these two options are exhausted should other materials be considered.
Effective O&M practice should stress indoor environmental quality (IEQ):
- Acceptable IEQ is often easiest to achieve if "source control" is practiced, not only during building construction, but also over the life of the building. For example, the designer may select building products that do not produce noxious or irritating odors. The O&M and cleaning staff can also avoid creating IEQ problems when they are provided with safer maintenance and cleaning products. While HVAC systems may be designed to isolate operations (kitchens, dry cleaners, etc.) from other occupancies, the O&M staff should check to see that pressure differentials are in fact maintained, to avoid the undesirable flow of contaminants from restrooms, kitchens, parking garages, laboratories, etc. to occupied spaces. See also WBDG High Performance HVAC.
- O&M can also be the first line of defense in controlling moisture and mold growth in buildings.
O&M should promote Pollution Prevention (P2) goals by eliminating pollution through process changes, recycling, and substitution of non-hazardous or less hazardous materials:
- P2 practices can affect buildings in many ways, including better public image, enhanced productivity, reduced regulatory burden, lessened liability, and improved environmental and air quality.
- Conventional O&M practice includes setting up and running the facility's recycling program for office paper, cans, glass, etc. Advanced recycling programs, such as the Sunnyvale Recycling Program, now include fluorescent lamps, batteries, carpet and ceiling tile takeback programs, and recycling of electronic equipment.
Responsibility for effective O&M is shared by a number of individuals, at various stages of the building's life, from conceptual design through renovation or demolition.
The Original Building Design Team should:
- Lay out the HVAC system so that maintenance and inspection will be easy to accomplish, including enough room to repair equipment in mechanical rooms, and including access doors in ceilings or walls to reach air handling units, filter banks, fan-coil units, terminal boxes, and controllers or sensors that require regular maintenance and calibration. See WBDG Functional/Operational.
- Provide proper storage facilities in the building, such as a separately exhausted central chemical supply area near the loading dock, janitor's closets on each floor, dedicated recycling storage areas, and handling and transport mechanisms.
- Include permanent walk-off grilles or mats at all entrances to eliminate tracked-in dirt. Use landscaping or railings to keep people on the pavement near the building entrances.
- Select durable, low-maintenance, soil-resistant, low-emitting building materials, equipment, and furnishings. In heavily trafficked areas, carpet tiles may be preferable to broadloom because small stained sections can be replaced and recycled, avoiding use of powerful carpet cleaners. See WBDG Evaluating and Selecting Green Products.
- Provide documentation of design intent for building systems.
- Incorporate controls and feedback systems for building systems to inform the facility manager.
The Facility Manager should:
- Oversee building commissioning and recommissioning.
- Procure preventive HVAC maintenance services if qualified in-house staff are not available.
- Schedule regular and preventive/predictive maintenance for all HVAC equipment. See Reliability-Centered Maintenance (RCM).
- For lighting, assess the relative advantages and disadvantages of group re-lamping programs. Particularly in large installations, periodic replacement of all lamps can be more cost-effective than replacing individual lamps.
- Provide waste reduction and management (sorting, salvaging, recycling, disposal) planning, and contractor oversight.
- Carefully schedule disruptive work such as plumbing, carpentry, painting, and renovation.
- If possible, schedule during unoccupied periods.
- Inform building occupants about major activities that may affect health or comfort and be sure to maintain acceptable indoor air quality.
- Seek opportunities to recycle and/or reuse construction and demolition waste.
- See IAQ Guidelines for Occupied Buildings Under Construction by Sheet Metal and Air Conditioning Contractors' National Association, 1995.
- Coordinate housekeeping and custodial operations with building ventilation schedules to ensure that adequate ventilation is provided both during and after these activities.
- Institute an integrated pest management (IPM) program that creates the least possible risk to people, property, and the environment.
The Procurement Officer should:
- Institute purchasing policies that promote resource efficiency and toxicity reduction. One example would be instituting a lamp purchasing program which specifies that lamps contain less than 80 picograms of mercury per lumen hour of light output.
- Establish cleaning practices that favor products with low toxicity and minimal environmental impacts. This may involve contractual changes with the cleaning service as well as special training for custodial staff.
- Work with maintenance staff to determine the types of cleaning agents needed. Conventional cleaning supplies often contain harsh, irritating chemical ingredients that, especially in concentrated form, can cause harm to employees.
- Consider use of appropriate portion control devices such as mechanical dispensers for safe mixing of cleaning solutions, to reduce worker exposure to chemicals, save packaging, and reduce chemical consumption.
- Restrict heavy-duty cleaners to heavy-duty jobs.
- In the case of flooring, it may not be critical to use a disinfectant; a mild detergent at neutral pH may suffice.
- In areas where disinfectant is required, a dilute solution of an intermediary grade disinfectant (e.g., phenolic disinfectant) or a quaternary ammonium ("quat") disinfectant at a neutral pH may be appropriate.
- Seek less toxic substitutes that have been proven to do the job.
- Products labeled non-toxic, non-petroleum based, water-based, free of ammonia, phosphates, dye or perfume, readily biodegradable, and using recyclable containers, are options to consider.
- Products labeled "WARNING", "CAUTION", "DANGER", "FLAMMABLE", "POISON", "REACTIVE" should be avoided, unless there are compelling reasons for their use.
- Pump sprays should be favored over aerosol cans that contain propellants.
- When applicable, one way of determining the general hazard associated with a product is to review its National Fire Protection Association (NFPA) label.
- When appropriate, select "certified" environmental cleaning products. Lists of these products are available from the government and third party certifiers. Evaluate the basis for certification to ensure that the attributes selected are important to the facility.
- EPA's Database of Environmental Information for Products and Services includes cleaning supplies and equipment that have "environmentally preferable" attributes. Information is also included on chemicals to avoid.
- Third party certification services: Green Seal has standards for operations and maintenance criteria for green facilities, for industrial/institutional and household cleaning products, and for floor care products, which set performance, environmental, and packaging requirements. Scientific Certification Systems (SCS) provides product testing for specific environmental attributes, to verify the accuracy of specific environmental claims such as biodegradability. It has also evaluated products for indoor air quality performance based on a test method recently developed in California. Product listings and their attributes are provided according to construction specification categories, facilitating use in specifications. The European Union Community also has an Eco-Label program which includes all-purpose cleaners.
- California's South Coast Air Quality Management District (SCAQMD) has a Clean Air Solvent (CAS) Certification Program that is useful for selecting cleaners that do not contain volatile organic compounds (VOCs).
- It should be noted that most cleaners are water-based and the issues of concern are often related to the extreme pH of the cleaner (e.g., highly alkaline floor stripping solution or hydrochloric acid bowl cleaner) or respiratory irritancy (e.g., ammonia, bleach) rather than VOC content.
- The SCAQMD product list identifies cleaning materials used in maintenance operations containing no more than 25 grams of VOC per liter of cleaning solvent. The most common and effective cleaners that meet this criteria are water-based or aqueous cleaners.
Maintenance Staff: The input of the personnel who use the cleaning products is critical to a successful transition to lower toxicity materials. The custodial and maintenance staff should:
- Participate in selecting cleaning products, by, for example, attending vendor demonstrations, and participating in trial use of lower toxicity materials.
- Minimize use of cleaning products. Overusing an ineffective product can be worse, and more expensive, than using a limited amount of a very effective one. Alternatively, better equipment such as automatic floor scrubbers that require little or no detergent should be requested.
- Follow safe handling, disposal, and storage practices.
- Stop using products that do not work.
- Purchase products with less packaging by ordering supplies in bulk or in concentrated form.
- Produce less waste, for example, by using "paperless" electronic communications, reusable silverware, and cups.
- Recycle glass, paper, and mixed waste.
No matter what the building's use or size is, it is important to operate it responsibly and maintain it properly. Below are some operational and maintenance practices for a facility.
- Select low-emitting, low-toxicity caulks, solvents, paints, adhesives, sealants, and cleaning agents (the Low Emitting Materials Table for the Collaborative for High-Performance Schools is one listing of products that meet indoor air quality testing criteria emission levels for chemicals of concern as identified by the California Environmental Protection Agency Office of Environmental Health Hazard Assessment [OEHHA]).
- Develop safe handling, disposal, and storage practices including procedures for spill control.
- Establish maintenance practices to minimize exposure to hazardous materials by substituting less hazardous materials.
- Maintain barrier floor mats.
- Use high efficiency air filtration.
- Use high efficiency vacuum cleaners (see Carpet and Rug Institute for list of vacuum cleaners tested for particulate removal).
- For carpets, follow guidelines of the Carpet and Rug Institute or the Institute of Inspection, Cleaning, and Restoration Certification.
- Prevent excess moisture or cleaning residue accumulation.
Moisture, Leaks, and Spills
- Dry surfaces promptly. Water-damaged, porous building materials or furnishings, if not dried and cleaned within 24 hours, may have to be replaced.
- Prevent moisture condensation.
- Maintain the building envelope, including the roof.
- Use integrated pest management (IPM) methods of pest control as part of the overall building maintenance program.
- Shut down ventilation system(s) and remove occupants until pesticide applications are completed.
Relevant Codes and Standards
- Energy Policy Act of 2005 (PDF 1.9 MB)
- Executive Order 13101—Greening the Government Through Waste Prevention, Recycling, and Federal Acquisition directs federal agencies to use recycled content and environmentally preferable products.
Building / Space Types
Products and Systems
Operations and Maintenance
- ASHRAE Guideline 4: Preparation of Operating and Maintenance Documentation for Building Systems. Atlanta, GA: ASHRAE, 1993.
- Energy-Efficient Operation of Commercial Buildings: Redefining the Energy Manager's Job by Peter Herzog. New York, NY: McGraw-Hill, 1997.
- Green & Clean: The Designer's Impact on Housekeeping and Maintenance by Stephen Ashkin in Environmental & Economic Balance: The 21st Century Outlook. Washington, DC: The American Institute of Architects, 1998.
- Greening Federal Facilities: An Energy, Environmental and Economic Resource Guide for Federal Facilities Managers, Section 8: The Role of Operations and Maintenance by U.S. Department of Energy. Washington, DC. 1997.
- How Buildings Learn: What Happens After They're Built by Stewart Brand. Viking Press. 1994.
- HVAC Characteristics and Occupant Health (PDF 430 KB) by W.K. Sieber, M.R. Petersen, L.T. Stayner, R. Malkin, M.J. Mendell, K.M. Wallingford, T.G. Wilcox, M.S. Crandall, and L. Reed. ASHRAE Journal, September 2002.
- New York City High Performance Building Guidelines (PDF 2.2 MB). 1999. Part Three, Chapter on Operations and Maintenance.
- O&M Best Practice Series (PDF 1.2 MB) by Portland Energy Conservation, Inc. Includes fifteen O&M best practices for energy-efficient buildings, stressing management, teamwork, and resource- and energy-efficiency.
- Standard Guide on Stewardship for Cleaning Commercial and Institutional Buildings, E1971-98 by ASTM International.
- Waste Reduction and Recycling: A Guide for the Workplace (PDF 210 KB) by Wisconsin Department of Natural Resources.
Trainings and Programs
- EPA Energy Star programs—From this home page, links are provided to Energy Star web pages on a variety of subjects relevant to O&M (e.g., lighting maintenance, building tune-ups, HVAC, system upgrades).
- EPA's Environmentally Preferable Purchasing Program—includes information on several cleaning product pilot projects, including case studies and a database with contract specifications.
- International Facility Management Association (IFMA) Certification Program—for facility managers. Maintenance and operations management is one of eight competency areas evaluated in becoming a Certified Facility Manager (CFM).
- U.S. Green Building Council's Leadership in Energy and Environmental Design–LEED® 2009 for Existing Buildings: Operation & Maintenance.
- Closing the Circle Awards—Federal facilities can qualify for these awards which focus on waste prevention, recycling, and green purchasing activities under E.O. 13101, environmental management under E.O. 13148, and green/sustainable buildings under both executive orders.
- EPA's Building Education and Assessment Model (I-BEAM) computer software—integrates IEQ, energy efficiency, and building economics into a management tool for commercial buildings. Among other features, it includes an IAQ management and maintenance program, and a tool for calculating the cost, revenue, and productivity impacts of various IAQ activities.
- EPA's Environmentally-Preferable Purchasing Tool Suite—provides contract language, specifications, policies, environmental standards and guidelines, other useful references, and product brand lists.
- EPA's Large Buildings IAQ Management Practices Guidance—provides an action plan for implementing a well-designed O&M program (see Step 5).
- Office of the Federal Environmental Executive, Green Purchasing—contract language, implementation guidance, case studies, links to products and services that have successfully been used by others, and expert contacts are provided for green janitorial products and services.
- Operations and Maintenance—Federal Energy Management Program (FEMP)—provides up-to-date information including definition of terms, advanced metering, and other essential concepts.
- Presidential Green Chemistry Challenge Awards—Provides national recognition of outstanding chemical technologies, like environmentally preferable O&M products, that incorporate the principles of green chemistry into chemical design, manufacture, and use, and that have been or can be utilized by industry in achieving their pollution prevention goals.