© 2003 BY CRC PRESS LLC CHAPTER 7 Maintenance Martha J. Boss, Dennis W. Day, and Marwan Bader CONTENTS 7.1 Fungi Control 7.2 Stachybotrys 7.2.1 Level I: 2 Square Feet or Less 7.2.2 Level II: More than 2 Square Feet but Less than 30 Square Feet 7.2.3 Level III: More than 30 Square Feet 7.2.4 Level IV 7.3 Immediate Worker Protection 7.3.1 Skin and Eye 7.3.2 Respiratory Protection 7.3.3 Disposable Clothing 7.4 Decontamination 7.4.1 Method 1: Wet Vacuum 7.4.2 Method 2: Damp Wipe 7.5 Abatement 7.6 Cleaning Sequence and Hazardous Materials Considerations 7.6.1 Double Containment 7.6.2 HVAC System Wetting 7.6.3 System Steam Cleaning and Disassembly 7.7 Ventilation Troubleshooting 7.8 Ductwork Maintenance and Cleaning 7.8.1 Duct-Cleaning Industrial Standards and Limitations 7.8.2 Dry Preventive Maintenance 7.8.3 Wet Preventive Maintenance 7.8.4 Mold Detection and Cleaning Confirmation 7.8.5 Cleaning Tasks 7.8.6 Example of Cleaning Sequence 7.9 Chemical Treatment 7.9.1 Biocides and Ozone 7.9.2 Sealants 7.10 Insulated Ducts 7.11 Clean Confirmation Checklist © 2003 BY CRC PRESS LLC 7.12 Ductwork Access and Zoning 7.13 Air Cleaners 7.13.1 Contaminant Removal 7.13.2 Types 7.13.3 Performance Assessment 7.13.4 Additional Factors 7.13.5 Installation and Maintenance 7.13.6 Efficiency Ratings 7.14 Filtration 7.15 House Dust 7.16 Dust Mites 7.17 Molds in the Air 7.18 Containment 7.18.1 Limited Containment 7.18.2 Full Containment 7.19 Residential Sanitation and Prevention 7.20 Flood Event Sanitation 7.20.1 Remove Standing Water 7.20.2 Dry 7.20.3 Remove Wet Materials 7.20.4 Clean-Up 7.21 Good Maintenance Programs 7.21.1 Periodic Inspections 7.21.2 Training 7.21.3 Microorganisms 7.22 Carpet 7.22.1 Carpet Studies 7.22.2 Carpet: Special Considerations 7.22.3 Old Carpets 7.22.4 Installation of Carpet 7.22.5 Maintenance Resources Maintenance may involve sterilization, disinfection, decontamination, or dilution. Of these, only sterilization attempts to kill all biological contaminants. Disinfection attempts to kill sufficient numbers in order to lessen the infective potential of contaminants. Decontamination and dilution seek to lessen the numbers of biological contaminants to some defined limit. For molds, fungi, and yeasts, various limits are considered acceptable given the use of the buildings or areas and the health status of the people potentially exposed. 7.1 FUNGI CONTROL Mold growth can eventually cause structural damage if a mold or moisture problem remains unaddressed for a long time. In the case of a long-term roof leak, for example, molds can weaken floors and walls as the molds feed on wet wood (Figures 7.1 and 7.2). Indoor mold growth may not be obvious. Mold may be growing on hidden surfaces, such as the back side of drywall (Figures 7.3 and 7.4), wallpaper (Figure 7.5), or paneling; the top of ceiling tiles (Figure 7.6); the underside of carpets and pads; pipe chases and utility tunnels with leaking or condensing pipes; walls behind furniture where condensation forms; condensate drain pans inside air-handling units; porous thermal © 2003 BY CRC PRESS LLC Figure 7.1 Typical mold patterns on walls. (Courtesy of Aerotech Laboratories, Phoenix, AZ.) Figure 7.2 Typical mold patterns on walls. (Courtesy of Aerotech Laboratories, Phoenix, AZ.) Figure 7.3 Mold growing on and into wood. (Courtesy of Aerotech Laboratories, Phoenix, AZ.) © 2003 BY CRC PRESS LLC Figure 7.4 Mold growing on and into wood. (Courtesy of Aerotech Laboratories, Phoenix, AZ.) Figure 7.5 Mold under wallpaper. (Courtesy of Aerotech Laboratories, Phoenix, AZ.) Figure 7.6 Mold on ceiling (be sure to check electrical fixtures also). (Courtesy of Aerotech Laboratories, Phoenix, AZ.) © 2003 BY CRC PRESS LLC or acoustic liners inside ductwork; or roof materials above ceiling tiles due to roof leaks or insufficient insulation. Assess the size of the mold and/or moisture problem and the type of damaged materials before planning the remediation work. The remediation plan should: include steps to fix the water or moisture problem to prevent the problem from returning, cover the use of appropriate personal protective equipment (PPE), and include steps to carefully contain and remove moldy building materials to avoid spreading the mold. The highest priority must be to protect the health and safety of the building occupants and remediators. Communication must be established with building occupants when mold problems are identified. Temporary relocation of some or all of the building occupants may be required. The decision to relocate occupants should consider the size and type of the area affected by mold growth, the type and extent of health effects reported by the occupants, the potential health risks that could be associated with debris, and the amount of disruption likely to be caused by remediation activities. If possible, remediation activities should be scheduled during off-hours when building occupants are less likely to be affected. Some building materials, such as drywall with vinyl wallpaper or wood paneling, may act as vapor barriers, trapping moisture underneath their surfaces and thereby providing a moist environ - ment where mold can grow. Removal of this wallpaper can lead to a massive release of spores from mold growing on the underside of the paper. The standing rules are: • Bleach what you can bleach. • Use biocides with caution. • Throw out what you can throw out. If you are unsure as to any of these protocols, get help. Moisture, heat, and dirt or dusts are the ingredients needed to grow fungi. As part of routine building maintenance, buildings should be inspected for evidence of water damage and visible mold. Conditions causing mold (such as water leaks, condensation, infiltration, or flooding) should be corrected. Good preventive maintenance can reduce the risk of a problem with molds growing inside the home and other buildings. Homes and buildings with water damage should be repaired, and all moldy material should be removed. Avoiding or diminishing other contributors of humidity may help. Some causes and contributors of high humidity may include leaking pipes, water-damaged drywall and ceiling tile, leaking roofs, flooding, faulty or obstructed dryer vent connections, use of steaming hot water in washing machines, many showers, faulty or obstructed bathroom/kitchen ventilation fans, boiling water for long periods of time, canning or pressure cooking, hand washing and rack drying laundry, use of humidifiers, and excessive sealing of homes so inadequate air exchange occurs. 7.2 STACHYBOTRYS Some molds can be killed by cleaning the moldy surface with chlorine; however, Stachybotrys often has a germ mycelium that is buried inside the water-damaged surface and may be inaccessible to chlorine. Changing the humidity may lead to death of the Stachybotrys colony; however, changing the humidity can also induce heavy sporulation. While the spores may die quickly, these spores can remain toxic and continue to cause allergic reactions; therefore, it is best to remove all of the water-damaged material. Visual identification of black mold in a chronically wet area is considered to be a possible indicator of mold amplification in interiors. The New York City Department of Health (NYCDOH) convened an expert panel on Stachybotrys chartarum (SC) in © 2003 BY CRC PRESS LLC 1993, which recommended different methods of mold removal depending on the size of the mold problem. Their recommendations based on mold surface area are presented as an example of response decision logic. 7.2.1 Level I: 2 Square Feet or Less The area can be cleaned by individuals who have received training on proper clean-up methods, protection, and potential health hazards. These individuals should be free from asthma, allergy, and immune disorders. Gloves and a half-face respirator should be worn. Contaminated material should be placed in a sealed plastic bag before being taken out of the building to prevent contamination of other parts of the building. Surrounding areas should be cleaned with household bleach. 7.2.2 Level II: More than 2 Square Feet but Less than 30 Square Feet The recommendations are the same as Level I, with the added precaution that moldy materials should be covered with plastic sheets and taped before any handling or removal is done. For instance, in the case of a moldy panel of gypsum board (measuring 4 × 8 ft), plastic sheeting should be taped on the wall over the affected area before the wallboard is cut to remove the contaminated section. Once cut from the wall, that section should be placed within another layer of plastic before being carried through the building for disposal. 7.2.3 Level III: More than 30 Square Feet Personnel conducting decontamination efforts must be trained in the handling of hazardous materials. Decontamination planning must assume hazardous materials may be present. 7.2.4 Level IV The Level IV designation indicates that Stachybotrys is present in the HVAC system. Precautions are the same as those for Level III (NYCDOH, 2000). 7.3 IMMEDIATE WORKER PROTECTION Whenever possible, use remote methods for clean-up. At a minimum, entry where any invasive activities will occur requires use of respirators with high-efficiency particulate air (HEPA) filters and dermal protection for hands. All material worn or used must be either decontaminated or properly disposed. If the remediation job disturbs mold and mold spores become airborne, then the risk of respiratory exposure increases. Actions that are likely to disturb mold include break- up of moldy porous materials, such as wallboard; invasive procedures used to examine or remediate mold growth in a wall cavity; active stripping or peeling of wallpaper; and the use of fans to dry items. The primary function of full-face respirators is to avoid inhaling mold and mold spores and to avoid mold contact with the skin or eyes. The following sections discuss the different types of personal protective equipment that can be used during remediation activities. Please note that all individuals using certain PPE, such as half-face or full-face respirators, must be trained, have medical clearance, and be fit-tested by a trained professional. In addition, the use of respirators must follow a complete respiratory protection program as specified by the Occupational Safety and Health Administration (OSHA). © 2003 BY CRC PRESS LLC 7.3.1 Skin and Eye Gloves are required to protect the skin from contact with mold allergens (and in some cases mold toxins) and from potentially irritating cleaning solutions. Long gloves that extend to the middle of the forearm are recommended. The glove material should be selected based on the type of materials being handled. If a biocide (such as chlorine bleach) or a strong cleaning solution is used, select gloves made from natural rubber, neoprene, nitrile, polyurethane, or polyvinylchloride (PVC). If you are using a mild detergent or plain water, ordinary household rubber gloves may be used. To protect your eyes, use properly fitted goggles or a full-face respirator with a HEPA filter. Goggles must be designed to prevent the entry of dust and small particles. Safety glasses or goggles with open vent holes are not acceptable. 7.3.2 Respiratory Protection Respirators protect clean-up workers from inhaling airborne mold, mold spores, and dust. Their use is classified as follows: • Minimum — When cleaning up a small area affected by mold, you should use an N-95 respirator. This device covers the nose and mouth, filters out 95% of the particulates in the air, and is available in most hardware stores. In situations where a full-face respirator is used, additional eye protection is not required. • Limited — Limited PPE includes use of a half-face or full-face air-purifying respirator (APR) equipped with a HEPA filter cartridge. These respirators contain both inhalation and exhalation valves that filter the air. Half-face APRs do not provide eye protection. HEPA filters do not remove vapors or gases. • Full — In situations where high levels of airborne dust or mold spores are likely or intense or long-term exposures are expected (e.g., the clean-up of large areas of contamination), a full-face, tight-fitting, powered air-purifying respirator (PAPR) is recommended. Full-face PAPRs use a blower to force air through a HEPA filter. The HEPA-filtered air is supplied to a mask that covers the entire face. The positive pressure within the hood prevents unfiltered air from entering through penetrations or gaps. Individuals must be trained to use their respirators before remediation begins. 7.3.3 Disposable Clothing Disposable clothing is recommended during a medium or large remediation project to prevent the transfer and spread of mold to clothing and to eliminate skin contact with mold. Their use is classified as follows: • Limited — Disposable paper overalls • Full — Mold-impervious disposable head and foot coverings and a body suit made of a plastic- coated material with all gaps, such as those around ankles and wrists, sealed with duct tape 7.4 DECONTAMINATION 7.4.1 Method 1: Wet Vacuum Wet vacuums are vacuum cleaners designed to collect water. Wet vacuums can be used to remove water from floors, carpets, and hard surfaces where water has accumulated. They should not be used to vacuum porous materials, such as gypsum board and should be used only when materials are still wet, as wet vacuums may spread spores if sufficient liquid is not present. The tanks, hoses, and attachments of these vacuums should be thoroughly cleaned and dried after use because mold and mold spores may stick to the surfaces. © 2003 BY CRC PRESS LLC 7.4.2 Method 2: Damp Wipe Whether dead or alive, mold is allergenic, and some molds may be toxic. Mold can generally be removed from nonporous (hard) surfaces by wiping or scrubbing with water or water and detergent. These surfaces should be dried quickly and thoroughly to discourage further mold growth. Instructions for cleaning surfaces, as listed on product labels, should always be read and followed. Porous materials that are wet and have mold growing on them may have to be discarded. Because molds will infiltrate porous substances and grow on or fill in empty spaces or crevices, the mold can be difficult or impossible to remove completely. Do not paint or caulk moldy surfaces. Clean and dry surfaces before painting. Paint applied over moldy surfaces is likely to peel. Decontamination may consist of washing with chlorinated or other oxidizing chemicals (e.g., bleach, oxidizing color-safe bleach, or ozone). Biocides may also be used; however, the biocide used should be proven effective for the particular biologicals present. All of these decontamination chemicals pose some risk to workers. At a minimum, Material Safety Data Sheets (MSDS) should be obtained to communicate this risk to workers. For porous surfaces, including fiberglass liners inside ducts, encapsulation of the porous surface may be required prior to removal. Contaminated fiberglass liners cannot be cleaned. The HVAC system should not be operating during mold removal. The system may be contaminated or may spread contamination. In many buildings, fiberglass-lined ductwork lofts due to continual airflow. These lofted spaces collect dirt and become microbial nests. The microbes grow and multiply and then are blown all over the building to infest other areas. Furnace filters may be subject to breakthrough, where mold spores pass though filter sections and reenter the airstream. As the filters become dirtier, the filter material may catch the microbes, provide a growth location, and transfer the microbial contamination into the airstream. Another hot spot for microbial growth is the humidifier assembly on furnaces. Typical reservoir humidifiers contain pools of standing, stagnant water throughout much of the year that allow mold to grow and infiltrate surrounding ductwork. 7.5 ABATEMENT Biologicals grow and reproduce. In that regard, concentrations of biologicals are not equivalent to such things as chemical concentrations. A dilute concentration of biologicals in a good growth environment will result in a concentrated level of contamination over time. All abated buildings must be sampled and certified as suitable for reentry prior to normal building usage. This certifi - cation states that the biological contamination of the building has been diminished through abate- ment activities and the level is now equivalent or below the ambient exterior conditions or interior baseline conditions previously agreed upon. Certification does not state that the building cannot be recontaminated in the future. Always ask for recommendations as to how to prevent future con - tamination. Any porous materials that have been contaminated and removed from the facility and will be returned at a later date must be decontaminated prior to the return, or facility users must be advised that recontamination may be inevitable. 7.6 CLEANING SEQUENCE AND HAZARDOUS MATERIALS CONSIDERATIONS Health, safety, and environmental factors are of primary concern in any undertaking. Where hazardous materials are known to exist, administrative procedures that address these hazards must be considered at the outset of any decontamination process. These administrative procedures assure that compliance with all federal, state, and local laws and regulations are met; appropriate permits are obtained; and the entire project is adequately documented and reviewed. Workers must be © 2003 BY CRC PRESS LLC specially trained prior to doing the work. A walk-through of the work area as well as a review of hazards and work practices has to be conducted at each project site prior to the start of work each day. Work practices must also protect those not involved in the decontamination from hazards. Appropriate signage and the use of roped-off work areas are required. Work is performed during hours when the usual work force is absent or at a minimum. 7.6.1 Double Containment As a general precaution, double containment is always employed. When working in areas with concrete floors, cover the floor with plastic sheeting. Although this increases the amount of waste generated, a spill may penetrate the concrete, and clean-up then becomes very difficult. Take precautions while working to prevent the spread of contamination of any kind. 7.6.2 HVAC System Wetting Some HVAC systems must be made wet during cleaning. Aggressive penetration of any system is always preceded and accompanied by thorough wetting with water or steam. When opening seams, a spray is continuously directed into the fold. Screws and bolts are often rusted, so sufficient time must be allowed following wetting to permit penetration of the water behind the screw heads and nuts. Cutting sheetmetal is preferred in some cases, rather than attempting to remove screws and bolts that are severely corroded. Contaminated parts are bagged in plastic to maintain a moist environment. Parts to be discarded as well as those that may be scheduled for reinstallation are decontaminated. 7.6.3 System Steam Cleaning and Disassembly Steaming as a decontamination procedure is useful only when a system is known to be intact. Systems appearing to be intact by visual inspection often are not. Where the entire system has no leaks, steaming the system without dismantling is practical; however, steaming is limited to systems where sections are joined by smooth welds. In most of the systems encountered, the joints are fastened by draw bands. In these cases, even if steam had penetrated the joints, much of the contamination would be left in place. Disassembly of the system for decontamination has been found to be cost effective in most situations. Considerable amounts of contamination may be found on the tops of chemical fume hoods. The tops of hoods are defined as the hood interior casement tops that surround the portal to the exhaust ductwork. Accumulated contamination penetrates improperly installed or damaged ductwork connections. For aesthetic reasons, many fume hood systems are installed with faces that extend to the ceiling. Concealed contamination may be present behind this paneling and must be considered. 7.7 VENTILATION TROUBLESHOOTING Ventilation systems are designed and installed in buildings to replace stale, contaminated air with fresh air from the outside. Air also enters and leaves in other ways. Air can enter by infiltration, through construction joints and cracks around windows and doors and through the foundation and crawl spaces. Air also enters through natural ventilation openings, such as open doors and windows. An approach to lowering the concentrations of any indoor air pollutants is to increase the amount of outdoor air coming indoors. Opening windows and doors, operating window or attic fans (when the weather permits), or running a window air conditioner with the vent control open increases the outdoor ventilation rate. Local bathroom or kitchen fans that exhaust outdoors remove contaminants directly from the room where the fan is located and also increase the outdoor air ventilation rate. © 2003 BY CRC PRESS LLC Often the essence of indoor air quality (IAQ) problems lies in a singular phenomenon: lack of sanitation. Because air-handling systems often seem to be invisible, we tend to forget that the air we breathe did not magically appear in the room. Most systems, even if inspected by normal maintenance means, are not accessible for visual observation along many ductwork and plenum runs. Telescopic, fiberoptic, or camera scoping of these systems is sometimes the only means to determine levels of contamination. The following are some of the problems often identified in air-handling systems: • Adequate spaces are often not provided to access items that require maintenance such as filters, coils and drain pans, and strainers. These areas, in addition to accumulating the normal dust and dirt associated with airstreams, may accumulate water through condensation events and become hospitable areas for mold and bacterial amplification (i.e., rapid growth). Biocide application is not effective without thorough mechanical cleaning of these areas and system alteration to prevent moisture accumulation. Biological amplification may then migrate to ductwork, plenums, and habitable spaces served by the system. • Renovation activities may lead to unbalanced HVAC systems as ductwork and other air-handling appurtenances are added. Positive and negative pressure areas within a building and within HVAC systems may become different from the design intent. This problem is especially dangerous where infection control or chemical source reduction is required. • Permanently sealing fresh-air intakes by welding plates to the intake faces, permanently closing dampers within ductwork, or programming control systems eliminate the fresh air intake and cause carbon dioxide to build up. Thus, buildings receive make-up air only through doors being opened or seepage through construction materials (e.g., cracks in walls, up the sides of foundations to basement window casings with gaps). In addition to the potential for excess carbon dioxide, this situation encourages the infiltration of radon gas up the sides of foundations and into building structural gaps or openings. • Intake air for the general structure interior is usually of poor quality if supplied by attic space air and/or crawl space air. Obvious problems with air quality occur when air is supplied from damp crawl spaces frequented by rodents or from attic spaces frequented by birds and sometimes even bats. Even without animal habitation, degradation of building materials and water intrusion into these spaces surrounding habitable spaces can lead to indoor air problems associated with both particulates and biological growth (molds, bacteria). These problems can be present even if the only make-up air supplied from the crawl spaces or attics is through cracks or other openings to these spaces. • Dirty air plenums and building spaces are also used as make-up air sources and supply dirty air to HVAC systems. Vertical or horizontal air plenums may contain paint chips (lead, cadmium), accumulated dusts, and biological risk factors (spores, bacteria, animal droppings). Some plenums and building spaces are used as overflow storage for a wide variety of real property. This real property may be in various stages of degradation and is often laden with soil particulate (dirt and dust). Stored paper materials and boxes may contribute to biological growth and dispersal of cellulose fibers or general particulate laden with spores and mold vegetative structures. • Air intakes that are sometimes located in tunnels or crawl spaces where sewage and water pipes are also located may supply aerosolized components from the pipes to the HVAC system. In a worst-case scenario, these spaces may also contain delaminated asbestos mixed with leakage from sewers. Given that hepatitis B and other biological organisms can remain pathogenic for weeks, these air supply areas may provide air laden with human pathogens. • Air intakes for furnace blower systems that obtain make-up air at the base of the system (floor) are sometimes located near condensate pans, stored chemicals, maintenance shops with wood and paint dusts, and areas of debris. These intakes will ultimately provide poor-quality make-up air. More complicated sanitation methods may require chemical and mechanical cleaning and/or mechanical encapsulation of dirty system. Chemical and particulate outfall from these sanitation events may also be of concern if the HVAC system being treated cannot be partitioned (i.e., shut down, separated by critical barriers) during the chemical application or mechanical cleaning event. [...]... supply fan and ending at the supply diffuser Clean return air ducts starting at the outer ends of the return air system and concluding at the mixed-air chamber and the exhaust stack • Grilles and diffusers — Clean outside air-intake grill and shaft Vacuum diffusers, grills, and registers Reset as needed • Heat exchangers and heating and cooling coils • Condensate drain pans (drip pans) • Fan motor and fan... housing • Air-handling unit housing — Clean the interior of the air-handling unit Remove interior insulation Reinstall according to manufacturer’s directions Failure to clean a component of a contaminated system can result in recontamination of the entire system, thus negating any potential benefits of decontamination 7. 8.1 Duct-Cleaning Industrial Standards and Limitations Duct-cleaning industry standards... mold and bacteria will grow in the fibers and backing and under the carpeting If that happens, remove and throw away the carpeting and pad Also, clean and disinfect the floor • Tear out soaked wall materials, ceiling tiles, and wet insulation and disinfect the area Wear protective eyewear, gloves, and a mask In the case of flooding, look above the flood line Water may have run through materials and/ or... wall-to-wall carpeting, and plaster Fiberboard, fibrous insulation, and disposable filters present in a heating and air conditioning system should be replaced after contact with water If a filter was designed to be cleaned with water and was in contact with clean rainwater only, ensure that it is thoroughly cleaned before reinstalling 7. 20.4 Clean-Up The clean-up process involves thorough washing and. .. 50%, mites thrive and produce waste pellets In less than ideal conditions, mites can go into dormancy Upon death, their bodies disintegrate into small fragments that can be stirred into the air and inhaled 7. 17 MOLDS IN THE AIR Molds are persistent and eventually land on surfaces and settle into the tiniest cracks and crevices of carpets, furniture, draperies, insulation, rough textures and smooth surfaces... current status of carpets used in schools and offices Carpet is porous material that will absorb and adsorb other contaminants of concern These contaminants may include biological risk agents such as mold spores and bacteria, heavy-metal particulates such as lead and cadmium, and volatile organics adsorbed during painting or other maintenance events Carpet padding and adhesives will contribute to IAQ issues... rotary brushes and vacuum, and air pressure wash and vacuum • Remove exterior insulation to gain access to ductwork; reinstallation may be required • Design sound attenuation modification, if needed • Wash and vacuum clean each duct section using well-controlled brushing of duct surfaces in conjunction with contact vacuum cleaning to dislodge dust and other particles; for fiberglass duct board and sheetmetal... and mounts 6 Pressure wash and hand scrub each HVAC unit as needed, using EPA-approved cleansing agents 7 Clean all the internal surfaces of the HVAC unit housing; all the internal components of the HVAC unit; all fan surfaces, inside and outside; cooling and heating coil banks, including both upstream and downstream coil faces; filter bank support frames; and contiguous control damper assemblies 8 Rinse... fitted over each register, grille, and diffuser in the duct system to intercept any migrating loose dirt and debris © 2003 BY CRC PRESS LLC Table 7. 1 Clean Confirmation Checklist System access and cleaning Did the service provider obtain access to and clean the entire heating and cooling system, including ductwork and all components (drain pans, humidifiers, coils, and fans)? Has the service provider... curves, operating instructions, and other papers generated during design, construction, and testing 7. 21.1 Periodic Inspections The type and frequency of inspection depend on the operation of the system and other factors: • Daily — Visual inspection of hoods, ductwork, access and clean-out doors, blast gate positions, hood static pressure, pressure drop across air cleaner, and verbal contact with users . Factors 7. 13.5 Installation and Maintenance 7. 13.6 Efficiency Ratings 7. 14 Filtration 7. 15 House Dust 7. 16 Dust Mites 7. 17 Molds in the Air 7. 18 Containment 7. 18.1 Limited Containment 7. 18.2. Disassembly 7. 7 Ventilation Troubleshooting 7. 8 Ductwork Maintenance and Cleaning 7. 8.1 Duct-Cleaning Industrial Standards and Limitations 7. 8.2 Dry Preventive Maintenance 7. 8.3 Wet Preventive. 7. 2.3 Level III: More than 30 Square Feet 7. 2.4 Level IV 7. 3 Immediate Worker Protection 7. 3.1 Skin and Eye 7. 3.2 Respiratory Protection 7. 3.3 Disposable Clothing 7. 4 Decontamination 7. 4.1