Risk assessment on Hämeenkyrö municipal solid waste incinerator: Difference between revisions

1. Utilitarian optimizing
2. Egalitarian optimizing
3. Elitist optimizing

1. Data needed to model the PM_2.5 concentration distribution around the MSWI:
   1. The emission produced by MSWI
   2. Stack height and location of MSWI in relation to municipality
   3. Meteorological data: average (e.g. daily) temperatures, wind speeds and directions, solar radiation etc.
   4. Geographical data: vegetation, elevations, town build, lakes etc.
   5. ...
2. Data needed to convert exposure to dose:
   1. inhalable fraction of PM_2.5
   2. concentration of PM_2.5 around the person in the locations the person moves in
   3. times spend in different locations
   4. breathing rate of the person
   5. weight of the person
   6. ...

Also required: the background concentration. Some values available for comparison: Urban US highest PM_2.5 concs 20-30 mikrog/m³, concentration in Helsinki over several years 8-11 mikrog/m³, non-urban US concs 1-6 mikrog/m³ (Koistinen 2002). Thus, small Finnish town: maybe 7 mikrog/m³?

D = dose (mg/kg.day) IR = inhalation rate (m³/h) P = particle concentration in air (mg/m³) RF = respirable fraction of particles (dimensioless) ET = exposure time (hours/day) EF = exposure frequency (days/year) ED = exposure duration (years) BW = body weight (kg) AT = averaging time (days)(Schwela ym. 2002)

1. Koistinen, Kimmo (2002). Exposure of an urban adult population to PM_2.5. Methods, determination and sources. Publications of the National Public Health Institute A3/2002.
2. Schwela D, Morawska L, Kotzias D (Eds.) 2002. Guidelines for concentration and exposure-response measurement of fine and ultra fine particulate matter for use in epidemiological studies. WHO and JRC Expert Task Force meeting, Ispra, Italy, November 2002.

              daily intake: WHO-TEQ pg/kg body weight

• From the building phase of the municipal solid waste incinerator
• From operation time of the municipal incinerator
• From the traffic
  
• Things that should take account:
  
• Comparing the noise from the incinerator to the noise coming from the birds, the traffic and activities in a landfill
  
• The incinerator has planned to build in the existing industrial place.
  
  • What is the present level of the noise in that site?
    
  • What is the distance from the industrial site to the settlement?
    
• The noise disturbs the comfortability of the living
  

2. The smell:

• Probable less disturbing comparing it to the dump site.
  
• Inhabitants, who live near the landfill, think that the smell decreases the living comfortability a lot.
  

3. The social factors:

• Increasing a employment grade
  
• Decreasing the value of the property (houses, lands, summer cottages)
  
• Fear of the birds (the influenza)
  

4. Landscape:

• A minor effect
  

5. Other things that will not occur with the municipal solid waste incinerator:

• Diseases coming via the rats or birds? (This is a wild assumption)
  
• Hazardous components leaching to the ground water and/or surface water will decrease.(The incinerator processes are controlled and monitored)
  
• The inhabitants can pick berries and mushrooms with good feelings, without the fear of the hazardous components coming from the wastesite (like from the landfill).
  

http://www.viljakkalanpuolesta.net/lehdista1.html

http://www.ytv.fi/NR/rdonlyres/FDC064707E3A4FF18458C7CDE7B02C01/0/biotuhka_yva05.pdf#search=%22kaatopaikka%20lintuhaitta%22

http://www.eko-kymppi.fi/majasaari/YVA-selostus.pdf#search=%22kaatopaikka%20lintuhaitta%22

http://www.jyvaskyla.fi/paatos/kh/2004/15031400.0/txt121.htm

http://www.tapanila.fi/historia/kaatopaikka.html

• Persons employed
  • gas energy plant (24 person)
  • starting phase of the municipal solid waste incinerator (50 - 60 person-year)
  • working phase of municipal solid waste incinerator (60 - 70 persons)
  • M-Real cardboard factory (335 persons)
  • Finnforest Sawmill (? persons)
• Tax incomes
  • directly to Hämeenkyrö
  • directly to Pirkanmaa
  • indirect taxes (Sawmill, cardboard factory and waste incinerator)

• No waste incinerator or bioplant, shutdown of both factories and gas plant
  • Over 300 person less are employed

Best-case scenario:

• Waste incinerator is builded, both factories and gas plant remains
  • over 70 persons more are employed

OK-case scenario:

• Waste incinerator is builded, both factories remains, gas plant is shut down
  • about 50 persons more are employed

• Health effects related to long-term exposure
  • impairment of the immune system
  • impairment of the developing nervous system
  • impairment of the endocrine system
  • impairment of reproductive functions
  • increased cancer risk (evidence from animal studies, weak carcinogens in humans)

Sensitive subgroups: foetuses, newborns, individuals with high fish consumption, individuals working in incineration plants etc. (For health effects related to short-term exposure R↻ )

PM_2.5 are fine particles less than 2.5 μm in diameter.

• Health effects related to short-term exposure
  • respiratory symptoms
  • adverse cardiovascular effects
  • increased medication usage
  • increased number of hospital admissions
  • increased mortality
• Health effects related to long-term exposure (more relevance to public health)
  • increased incidence of respiratory symptoms
  • reduction in lung function
  • increased incidence of chronic obstructive pulmonary disease (COPD)
  • reduction in life expectancy
    • increased cardiopulmonary mortality
    • increased lung cancer mortality

Sensitive subgroups: children, the elderly, individuals with heart and lung disease, individuals who are active outdoors

• PM_2.5 emissions in Hämeenkyrö
• PM_2.5 emissions from MSWI, biofuel plant, amd natural gas plant in Hämeenkyrö
• Baseline PM_2.5 exposure in Hämeenkyrö
• PM_2.5 exposure due to MSWI in Hämeenkyrö
• PM_2.5 exposure-response function on population level

Dioxin variables:

• Dioxin emissions in Hämeenkyrö
• Baseline dioxin exposure in Hämeenkyrö
• Dioxin exposure due to MSWI in Hämeenkyrö
• Dioxin exposure-response function on population level

PM_2.5: change in mortality hazard per each 10 µg/m³ elevation in PM_2.5

• effective dose resulting in a 0.01 increase in lifetime risk of cancer mortality (ED₀₁): 45 pg/kg body weight (95% CI 21-324 pg/kg body weight)
• tolerable daily intake (TDI): 1-4 pg/kg body weight

PM_2.5

• 6% change in mortality hazards (95% CI 2-11%) per each 10 µg/m³ elevation in PM_2.5 air pollution

Health aspects of air pollution. Results from the WHO project "Systematic review of health aspects of air pollution in Europe". World Health Organization, 2004. http://www.euro.who.int/document/E83080.pdf

Pope et al. 2002. Lung cancer, cardiopulmonary mortality, and long-term exposure to fine particulate air pollution. JAMA 287 (9), 1132-1141.

Service Contract for Carrying out Cost-Benefit Analysis of Air Quality Related Issues, in particular in the Clean Air for Europe (CAFE) Programme. Volume 2: Health Impact Assessment. AEA Technology Environment, 2005. http://ec.europa.eu/environment/air/cafe/pdf/cba_methodology_vol2.pdf

Tuomisto et al. 1999. Synopsis on dioxins and PCBs. Publications of the National Public Health Institute B17/1999.