Pollution prevention strategies used by Oregon hospitals

Patel, Neha T.

24 September 2002

Waste generated by the health care industry has been cited as a major source of toxic pollution, including mercury and dioxins, which poses a serious threat to public health. The purpose of this study was to investigate pollution prevention activities of health care facilities in Oregon related to environmentally preferable purchasing practices, recycling, mercury reduction efforts, and written policy. Surveys were sent to 57 hospitals in Oregon, 24 facilities responded (42.1 %). Results indicate that the following environmentally-preferable purchasing practices are being implemented: purchasing reduced hazardous material (92%); using recycled packaging (75%); and, using products made from recycled content material (83%). Other practices, such as the purchasing of cadmium-free red bags (25%), supplies shipped in reusable shipping containers (34%), and using minimal packaging (46%) are being implemented in a few hospitals. None of the hospitals are purchasing chlorine-free office paper. The majority of participating Oregon hospitals are recycling paper (96%), cardboard (96%), clear glass (67%), linens (87.5%), batteries (67%) and X-ray film (83%). Fewer hospitals are recycling plastics: #1 PET and #6 polystyrene (37.5%), #2 HDPE (42%), #5 polypropylene (33%). Fewer hospitals are also composting food (46%), computers and equipment (42%), fluorescent lamps (21%) and solvents/fixers (29%). Major barriers to recycling in hospitals include lack of established markets for some materials, limited space to collect the materials, and low employee participation. The majority of participating hospitals are reducing the purchasing of mercury containing products, replacing mercury blood pressure units and gauges, replacing lab and housekeeping chemicals, and pharmaceuticals. Fewer than 50% of then participating hospitals are replacing switches, recycling batteries and conducting an inventory of mercury sources. Few hospitals are checking drains and pipes for mercury contamination (13%), recycling fluorescent lamps (21%) and requiring vendors to disclose mercury content below 1% (17%). While most hospitals no longer purchase new mercury-containing devices, the cost associated with disposal of mercury as a hazardous waste is a major barrier to elimination. Hospitals located in urban areas in Oregon are more likely to implement pollution prevention strategies than rural hospitals. Nearly all Oregon hospitals lack a corporate policy on pollution prevention/source reduction, or written goals on waste volume reduction or waste toxicity reduction efforts. The few hospitals (8%) that have put policies in place have done so voluntarily, and with the full support from upper-level management. Based on theses findings recommendations include the following: 1) Establish a "Green Team" of hospital staff from diverse departments. This group can then strategize about courses of action for the facility with input from all responsible sectors. 2) Conduct a waste audit. This establishes a baseline of existing hospital waste and will help determine how to shape a waste minimization program and pollution prevention plan. 3) Pollution prevention education should be a top priority for all departments within each hospital including purchasing, nursing, housekeeping and top management. Many health care professionals are not aware of the link between the products and practices they choose and the environmental consequences of these choices. 4) Rural hospitals can join pollution prevention email list serves such as the Oregon Health Care Without Harm list (HCWHoregon-health.org) or the H2E list serve (www.h2e-online.org) to share, learn and identify practical strategies for pollution prevention and waste minimization. 5) Approach and involve upper level management to work with hospital "green teams" to develop and implement a hospital policy on pollution prevention. / Graduation date: 2003

Pollution prevention -- Oregon

Hospitals -- Waste disposal -- Oregon

Pollution prevention in Oregon's electronics industry

Jones, Cynthia L.

17 January 1995

Pollution prevention is promoted by the Environmental Protection Agency (EPA) and other governmental agencies as a method of reducing the generation of wastes and pollutants. Pollution prevention is also called source reduction because it reduces wastes early in the production process. Source reduction has been used by some industries to comply with governmental regulations and decrease costs associated with the management of hazardous materials. Nationally, the electronics industry generates a large quantity of hazardous waste. Similarly in Oregon, the electronics industry has recently been identified by the DEQ as one of the top five polluters in the state. The purpose of this research was to identify pollution prevention strategies that are currently being used by the electronics industry in Oregon and to assess the industry's interest in switching to less hazardous practices. A questionnaire was distributed to 180 businesses, which included all industries affiliated with the Oregon Electronics Association and additional electronics firms listed in Oregon phone directories. From those responding to the survey, the results indicated that electronics organizations in Oregon manufacture a wide variety of products including circuit boards, cable assemblies, software, laser equipment, printers, and control panels. Over half of those participating in the survey reported that the largest quantity of hazardous materials were generated early in the manufacturing process. Forty-seven percent of the respondents indicated they had attempted incorporating less hazardous compounds to those used previously. Common problems encountered which discouraged the industry from switching to less hazardous products or processes were revealed by the participants to include: The new product/process did not work as well (37%), did not believe current practices were harmful (18%), cost factors (14%), pressure from governmental agencies (3%), and other factors (28%). Fifty percent of those responding revealed that their company recycles materials within the facility. Participants indicated the products which were most likely to be recycled included cardboard (19%), office paper (18%), tin/aluminum (13%), newspaper (12%), and used chemicals (11%). The largest number of participants (43%) defined "green" or "environmentally safe/friendly" products as those that contain no known hazardous chemicals. Using this chosen definition, sixty-five percent of those responding indicated their organization did use these "green" products. It was indicated by those returning completed surveys that one reason the industry has attempted to incorporate less hazardous products and processes into their production process is primarily because of long term financial benefits. Other factors influencing the use of less hazardous materials included ethical concerns and the desire to find safer products that work as well as current products. A vast majority of respondents indicated more should be done in the area of pollution prevention and want leadership to come from within the industry itself. It is recommended that top executives in this field meet to share methods of overcoming obstacles to pollution prevention, clarify current terminology as it relates to new products, develop a system of rewarding those who are engaging in pollution prevention activities and promote technology transfer. / Graduation date: 1995

Pollution prevention -- Oregon

Evidence Supporting Treatment Practice Based Delineation of Stormwater Runoff Zones

Gorski, Jacob J.

01 October 2013

Particles mobilized by stormwater negatively affect receiving surface waters. Stormwater best management practices (BMPs) can reduce solids along with associated pollutants in runoff but engineers and environmental managers have been long vexed by the problem of choosing the optimal BMP for a given situation. A common BMP process for solids removal is sedimentation. This thesis addresses the question of whether the effectiveness (and thus choice) of a sedimentation device can be estimated (and thus optimized) from the particle size properties of runoff, which, in turn, could be associated with specific runoff zones or land uses. Presented here is a series of experiments to determine the solids-removal capabilities of a manufactured oil-water separator that also removes solids via sedimentation. A statistical model developed from the experimental data shows that, under normal operating conditions, influent particle size can be used to accurately estimate effluent total suspended solids (TSS) for BMPs of this type. Relationships between particle size and particle-bound metal concentrations for Cu, Zn and Pb were then obtained from the literature and incorporated into the model to allow estimates of metal removal efficiencies based on TSS and PSD. The model can be used with an arbitrary particle size distribution (PSD); this allows effluent quality predictions to be made considering that particle sizes entering stormwater BMPs could vary due to anthropogenic, hydraulic or hydrologic factors. To place these experimental and modeling results in the context of an urban environment, samples of deposited stormwater solids were collected from residential areas, commercial areas and an industrial zone in Portland, Oregon, and the PSD of each sample was determined using light obstruction particle sizing. PSDs ranging over sizes from 3μm to 200μm vary among these locations. Areas with high anthropogenic impact were found to have PSDs skewed toward the smallest particle sizes. The statistical model developed here was then used to show that the effluent quality of the BMP tested would differ depending on the locations where solids were collected. The evidence presented in this thesis thus indicates that device performance will correlate with geographic locations or land use zone and validates further investigation into delineating the City of Portland's characteristic runoff zones and using the runoff characteristics of each zone to map it to the most desirable treatment practices.

Sedimentation analysis

Land use -- Oregon -- Portland

Environmental Engineering

Urban Studies and Planning