1. 1 Green Jobs: Safety & Health Outlook for Workers and Small Employers April 1, 2010 Sanji Kanth, Safety Engineer Office of General Industry Enforcement Directorate of Enforcement Programs

2. 2 Panel Members  Don Ellenberger Environmental Hazard Training Director CPWR – The Center for Construction Research and Training  Michele Myers Manager of Labor, Health and Safety Policy American Wind Energy Association  Justin August, CIH Industrial Hygienist Covanta Energy Corporation

3. 3 Session Overview  OSHA’s green job efforts and discuss workplace hazards associated with green jobs.  Information on green processes and technologies that are incorporated into the construction, energy, and waste management and recycling industries.  Opportunities and challenges posed by green jobs.  Best practices and strategies for small businesses in reducing safety and health hazards associated with green jobs.

4. 4 What are Green Jobs?  No Widely Accepted Definition  Jobs Related to Preserving or Restoring Environment or Natural Resources  Bureau of Labor Statistics (BLS) Seeking Comments on the Green Jobs Definition http://edocket.access.gpo.gov/2010/2010-5705.htm

5. 5 Green Jobs Industry Categories  Renewable Energy  Energy Efficiency  Greenhouse Gas Reduction  Pollution Reduction and Cleanup  Recycling and Waste Reduction  Agricultural and Natural Resources Conservation  Education, Compliance, Public Awareness, and Training

6. 6 Renewable Energy  Wind  Solar  Biomass/BioFuel  Geothermal  Tidal Energy  Hydrogen Fuel Cells  Other Renewable Sources

7. 7  Falls  Confined Spaces  Fires  Lockout/Tagout  Medical and First Aid  Crane, Derrick and Hoist Safety  Electrical  Machine Guarding  Respiratory Protection, and  Other Typical Workplace Hazards Green Jobs Hazards

8. 8 Picture Source: http://simplifiedsafety.com/solutions/application/wind-turbine/  Falls  Confined Spaces  Lockout/Tagout  Crane, Derrick and Hoist Safety  Electrical  Machine Guarding  Other Typical Workplace Hazards Wind Energy Hazards

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10. 10 Wind Turbine Blade Manufacturing

11. 11 Sanding & Grinding

12. 12 Source: http://www.windaction.org/pictures/1054 Wind Energy Hazards (contd.)  Fire Hazards  Medical and First Aid

13. 13 Solar Panel Installation/Removal Hazards  Fall Hazards  Electrical Hazards  Heat/Cold Stress Hazards  Installing/Removing Photovoltaic Products containing Cadmium Telluride (carcinogen) Picture Source: http://www.coshnetwork.org/sites/default/ files/OSEIA_Solar_Safety_12-06.pdf

14. 14 Source: http://www.cdph.ca.gov/programs/ohb/Pages/New.aspx#solar Solar Energy Accidents

15. 15 http://www.coshnetwork.org/sites/default/files/OSEIA_Solar_Safety_12-06.pdf

16. 16 Weatherization and Insulation Hazards  Use of Spray Polyurethane Foam (SPF)  Chemical Hazards - Isocyanates  Confined Space Hazards  Fall Hazards  Fire Hazards  Medical and First Aid  Electrical Hazards

17. 17 BioFuel Hazards  Fire and Explosion hazards  Chemical Reactivity hazards  Toxicity hazards  Other Hazards Picture Source: http://www.nunukphotos.com/biofuels-photos.html

18. 18 Waste Management and Recycling  Collection  Traffic Safety  Ergonomics  Lead  Mercury  Precious/Rare Metals  Machine Guarding  Lockout/Tagout  Cardboard Baling

19. 19 GeoThermal Hazards  Trenching  Excavations  Silica  Electrical  Welding and cutting  Fall protection Picture Source: http://www.ecogeek.org/component/content/article/2988-us- government-surpasses-google-for-geothermal-fund

20. 20 Green Roof Hazards Picture Source: http://www.ecogeek.org/content/view/902 /  Fall Protection  Personal Protective Equipment (PPE) Related Hazards  Exposure to Silica dust  Crane Derrick and Hoist  Powered Industrial Trucks  Electrical  Heat/Cold Stress

21. 21 Hydrogen Fuel Cell Hazards  Fire and Explosion Hazards  Electrical Hazards  Other Typical Workplace Hazards

22. 22 OSHA Green Jobs Safety Web Page Greens Jobs Web SiteGreens Jobs Web Site OSHAPedia

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24. 24 OSHA Green Jobs Safety Web Page  Industry specific hazards  OSHA standards applicable to the hazards  OSHA resources addressing the hazards  Accident Information  Other outside resources

25. 25 Future Plans  Monitor Injury/Illness trends  Continuously Improve the Web Page on Green Jobs in providing necessary resources to employers and workers

26. 26 “Green jobs are good jobs only when they are safe jobs.” -- David Michaels, PhD, MPH December 16, 2009

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28. A View from under the Hard Hat Don Ellenberger, Environmental Hazard Training Director April 1, 2010 Frances Perkins Building Auditorium U.S. Department of Labor Washington, D.C. Green Jobs: Safety & Health Outlook for Workers

29. Insulators & Asbestos Workers Boilermakers Bricklayers Carpenters Plasterers & Cement Masons Electrical Workers Ironworkers Painters & Allied Trades Plumbers & Pipe Fitters Roofers Sheet Metal Workers Elevator Constructors Laborers Teamsters Operating Engineers

30. Number and percentage of construction establishments and employees, by establishment size, 2007 (Payroll establishments) Establishment size Number of % of all Total number % of all (number of employees) establishments establishments of employees employees 1 to 9 660,454 81.4% 1,711,260 23.5% 10 to 19 78,957 9.7% 1,057,733 14.6% 20 to 99 63,309 7.8% 2,457,313 33.8% 100 to 499 8,176 1.0% 1,481,955 20.4% 500 or more 556 0.1% 559,622 7.7% Total 811,452 100.00% 7,267,833 100.00% Source: U.S. Census Bureau: County Business Patterns, 2007

31. What is Green (in construction?) Building upgrades for older homes / apartments Building upgrades for older homes / apartments Windows / doors / insulation Windows / doors / insulation

32. What is Green (in construction?) Wind turbine erection Wind turbine erection

33. Are Green Jobs Safer? No statistical difference between green and non-green projects in terms of construction worker safety and health. No statistical difference between green and non-green projects in terms of construction worker safety and health. Source: Rajendran / Journal of Construction Engineering and Management, October 2009

34. USGBC says occupants are healthier and more productive in LEED buildings But what about the builders... ?

35. The LEED Building Designed to: Designed to: Reduce energy consumption Reduce energy consumption Reduce water consumption Reduce water consumption Reduce CO2 output Reduce CO2 output Improve indoor air quality Improve indoor air quality Improve resources stewardship Improve resources stewardship

37. Harold Billingsley, Ironworker

38. “How many construction site deaths should there be to make a building ‘not green’ regardless of the environmental benefits?”

39. How can safety be designed into Green Jobs? There currently is a blind spot in sustainable design practice when it comes to worker safety and health. There currently is a blind spot in sustainable design practice when it comes to worker safety and health. Tremendous focus is placed on materials, energy and the environment, but designers typically give little, if any, consideration to the safety and health of the people who install the green features or build the projects. Tremendous focus is placed on materials, energy and the environment, but designers typically give little, if any, consideration to the safety and health of the people who install the green features or build the projects. Source: Gambatese / ENR.com

40. NIOSH’s Top Compelling Activities #3 – Include OSH into green and sustainable standards as they are being updated #3 – Include OSH into green and sustainable standards as they are being updated #4 – Include OSH in procurement and construction #4 – Include OSH in procurement and construction #6 – Integrate safety and health into green elements of contractor specifications #6 – Integrate safety and health into green elements of contractor specifications #9 – Develop, validate and disseminate a LEED-like OSHA rating system #9 – Develop, validate and disseminate a LEED-like OSHA rating system

41. We can quantify LEED rates jobs on: Sustainable sites Sustainable sites Water efficiency Water efficiency Energy and atmosphere Energy and atmosphere Materials and resources Materials and resources Indoor environmental air quality Indoor environmental air quality Innovation and design Innovation and design So let US rate jobs on: Owner commitment to safety Owner commitment to safety Safety and health professionals / contracts Safety and health professionals / contracts Safety and health planning Safety and health planning Training and education Training and education Employee involvement Employee involvement There is a tool in development to do this

42. LEED-like OSH rating system

43. Project Team Selection Owner uses past safety performance when selecting a contractor Owner uses past safety performance when selecting a contractor General uses past safety performance when selecting subs General uses past safety performance when selecting subs Owner chooses designer with experience / knowledge of worker safety & health Owner chooses designer with experience / knowledge of worker safety & health

44. S & H in Contracts Safety & Health requirements in contracts Safety & Health requirements in contracts Hazards identified in drawings Hazards identified in drawings Specify less hazardous materials Specify less hazardous materials

45. S & H Professionals Competent personnel for all high hazard tasks Competent personnel for all high hazard tasks Owner safety representative Owner safety representative General contractor safety representative General contractor safety representative Sub-contractor safety representative Sub-contractor safety representative

46. S & H Planning Included during conceptual stage of project Included during conceptual stage of project Constructability review Constructability review Designing for worker safety and health Designing for worker safety and health Life cycle safety design review Life cycle safety design review Safety checklist for designers Safety checklist for designers General and Subs site specific safety plan General and Subs site specific safety plan

47. S & H Planning (cont.) Job hazard analysis Job hazard analysis Pre-task planning Pre-task planning Look-ahead schedule Look-ahead schedule Traffic plans Traffic plans Good housekeeping plan Good housekeeping plan PPE plan PPE plan

48. Training and Education Safety training for designers Safety training for designers Safety orientation for all workers Safety orientation for all workers OSHA 10 for all workers OSHA 10 for all workers Safety training for field supervisors* Safety training for field supervisors*

49. A Foreman’s Choice Commercial building HVAC / energy upgrades Commercial building HVAC / energy upgrades

52. Construction Safety Association of Ontario - Study

53. My recommendation for small employers with construction workers: Plan for safety Plan for safety Train your foremen Train your foremen Train workers, especially new and inexperienced workers Train workers, especially new and inexperienced workers Score yourself on how well you design your project from inception Score yourself on how well you design your project from inception

54. As DOL/BLS proceeds in establishing a definition of “green jobs,” it is essential that conserving our human resources receive the same consideration as conserving our natural resources. Don Ellenberger – CPWR 301-578-8500 donellenberger@cpwr.comwww.cpwr.com Our recommendations to DOL / BLS & OSHA

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56. Safety and Health Outlook: Wind Energy April 1, 2010 Michele Myers Manager, Labor, Health and Safety Policy American Wind Energy Association

57. American Wind Energy Association (AWEA) ●Founded in 1974 More than 2,500 business members Wind project developers Transportation and construction companies Manufacturers from bolts to turbines More than 8,000 parts in a turbine ●www.AWEA.org provides extensive info on wind

58. American Wind Energy Association Trade association for the wind energy industry Over 2,500 business members www.awea.org ●Develops policies and conducts analysis to support wind industry growth ●Executes wind industry’s legislative agenda ●Promotes wind energy through advocacy, advertising and media relations ●Convenes conferences and workshops to educate the public and bring industry members together

59. History of Wind Energy

60. An Age-Old Energy Source

61. Early Days ●Cretan windmill (1464 AD – mechanical water pumping) ●Dutch windmill (1500 – mechanical water pumping, grain milling) ●U.S. farm windmill (1854 – present – mechanical water pumping)

62. Early Days ●Brush Turbine (1888) First large-scale unit (17-m rotor diameter) ●Small wind electric turbines (1890s – Denmark, U.S., elsewhere) ●Sporadic experiments with turbines of ~100 kW in U.K., Italy, Germany (1920s and 1930s)

63. Early Days ●Smith-Putnam Turbine Grandpa Knob, Castleton, VT 175-foot rotor, 1.25-MW capacity Operated from late 1941 to spring of 1945 Economic failure – technological triumph Foundation footings still in place

64. Post-1973 Oil Shock ●Federal Wind R&D Program ●Outgrowth of Eisenhower- era NSF program ●Sponsored procurements in range of sizes ●Boeing MOD-2 is icon (300- foot rotor, 3-MW capacity) ●Helped build technology and engineering base

65. Post-1973 Oil Shock 1978 – Second oil shock leads to: ●Public Utility Regulatory Policies Act of 1978 (PURPA) Requires utilities to buy electricity from renewable and cogeneration facilities ●Energy Tax Act of 1978 Creates 15% Energy Investment Tax Credit (EITC) Added to existing 10% ITC Limited Partnership Structure -> Wind Farms

66. Early Wind Farm Era ●First Wind Farm – Crotched Mountain, NH, December 1980 (equipment failures, wind speed overestimated) ●California Wind Farms – Altamont, Tehachapi, San Gorgonio passes, December 1981 ●Wind begins explosive growth, ended abruptly with sunset of EITC in December 1985

67. Wind Turbines: Power for a House or City

68. Basic Supply Chain Raw Materials Suppliers Component Suppliers Major Component Suppliers Turbine Manufacturers Turbine Manufacturers create a ripple effect down the supply chain, creating even more jobs indirectly than at their facilities.

69. Fundamentals of Wind Power Rotor Nacelle Tower Turbine subsystems include: A rotor, or blades, which convert the wind's energy into rotational shaft energy A nacelle (enclosure) containing a drive train, usually including a gearbox and a generator A tower, to support the rotor and drive train; and electronic equipment such as controls, electrical cables, ground support equipment, and interconnection equipment.

70. Inside a Nacelle

71. This picture shows a Vestas 80-meter diameter, 2-MW wind turbine superimposed on a Boeing 747 jumbo jet 80 m. 59.6 m. How Big is a 2-MW Wind Turbine?

72. Towers: Towers Ladders Lifts Rotor: Hub Nose Cone Blades Composites Blade Core Pitch Mechanisms Drives Brakes Rotary Union Nacelle: Nacelle Cover Nacelle Base Heat exchanger Controllers Generator Power Electronics Lubricants Filtration Insulation Gearbox Pump Drivetrain Ceramics Shaft Foundation: Rebar Concrete Casings Other: Transformers Bolts/Fasteners Wire Paints and Coatings Lighting Lighting Protection Steel Working/Machining Communication Devices Control and Condition Monitoring Equipment Electrical Interface and Electrical Connection Batteries Bearings Brakes There are over 8,000 components in a turbine, including: 2 Turbine Components

73. Hub Height: 60-100 meters (197-328 feet) Rotor Diameter: 70- 100 meters (230-328 feet) Total Weight of Turbine: 230 - 340 tons Wind Power Technology

74. Small Wind Systems ●Range from 0.3 to 100 kW ●Installed in on- and off-grid applications ●Require 4 m/s (9 mph) average wind sites

75. Large Wind Systems ●Range in size from 660 kW to 3.6 MW ●Provide wholesale bulk power ●Require average wind speeds of 6 m/s (13 mph) ●One megawatt of wind generates about as much electricity as 225 to 300 households use

76. U.S. Wind Resource Map Copyright © 2008 3TIER, Inc. All Rights Reserved. For permission to reproduce or distribute: info@3tiergroup.com

77. Jobs - Wind Energy

78. 20% Wind Energy by 2030 ●U.S. Department of Energy: “The U.S. possesses sufficient and affordable wind resources to obtain at least 20% of its electricity from wind by the year 2030.”

79. Job Projections Under 20% Report ●Over 500,000 total jobs would be supported by the wind industry ●In 2008, wind industry added 35,000 new jobs Source: U.S. DOE, 20% Wind Energy by 2030

80. Wind Project Development 46 states would have wind development by 2030 under the 20% Vision Source: U.S. DOE, 20% Wind Energy by 2030

81. Domestically Manufactured Components 2005 2008 ~ 25% domestic components ~2,500 MW installed ~1,500 turbines installed ~50% domestic components ~ 8,500 MW installed ~5,300 turbines installed There has been a dramatic shift towards domestic manufacturing for wind turbine components 2008

82. Current Manufacturing Capacity ●There are well over 120 manufacturing facilities for turbines and large components currently online in the U.S. ●U.S. manufacturers are producing all the turbine’s components. ●In 2005, about 30% of turbine & major components were made in the U.S., but in 2008 domestically manufactured components in turbines accounted for about 50% by value.

83. Turbine Manufacturers with a U.S. Presence ●Acciona ●Clipper ●DeWind ●Gamesa ●GE Energy ●Siemens ●Suzlon ●Vestas ●Fuhrlander (Announced) ●Global Wind Systems (Announced) ●Nordex (Announced) ●Nordic (Announced)

84. U.S. Manufacturing Locations ●Over 40 U.S. states host more than 160 wind- related manufacturing facilities ●Wind manufacturing is spread across the U.S. with major turbine manufacturers operating in varied regions ●With the growth in the industry, many states have recently entered into the supply chain. 4

85. Primary States for Manufacturing States with five or more major facilities (online or announced): California Colorado Iowa Illinois Michigan Minnesota Ohio Pennsylvania South Carolina Texas

86. Turbine Manufacturer Locations Nordic Fuhrlander (announced) Suzlon Blades only Acciona, Clipper Gamesa GE Energy GE Energy, Continental (announced) Vestas DeWind Nordex, EWT, Mitsubishi (all announced) Global Wind Systems (announced) Siemens (announced)

87. New U.S. Manufacturing Capacity Between 1Q 2007 and 4Q 2008 (24 months), there was significant growth in the industry’s manufacturing capacity. 19 new facilities online 31 announced facilities 21 announced facility expansions A total of 71 facilities have come on-line, been announced, or have expanded. 3

88. Market Update

89. 2009 Highlights Nearly 10,000 MW installed in 2009 39% annual growth Total installations now above 35 GW Shattered all installation records thanks to the Recovery Act Turbine manufacturing is down compared to last year’s levels Need long-term policy certainty and market pull in order to grow manufacturing sector

90. U.S. is World Leader in Wind Power

91. U.S. Wind Industry: 2009 Second year in a row adding over 40% of US capacity Wind MW Installed Total Installation in 4Q 2009: 4,041 MW Total Installation in 2009: 9,922 MW Total U.S. Installation through 4Q 2009: 35,159 MW Source: American Wind Energy Association

92. Wind Power Installations by State

93. Top Ten States in 2009 Source: American Wind Energy Association

94. Top 10 Largest Wind Farms

95. State by State Installations (MW) Source: American Wind Energy Association

96. Market Players Turbines Installed in 2009: Acciona WP, Clipper, DeWind, Fuhrlander, Gamesa, GE Energy, Mitsubishi, Nordex, REpower, Siemens, Suzlon & Vestas The project developer list continues to diversify and change with new developers increasing their activity in 2009 and other developers decreasing market activity. Utility ownership of wind projects trending at similar rates of 2008, more community-owned projects

97. Other Half of the Market: Manufacturing ●The U.S. continues to add new manufacturing facilities, but growth is down by a third: 38 online, announced or expanded manufacturing facilities in 2009, compared to 58 facilities in 2009. ●As new turbine orders continue to come in slowly, some manufacturing production is running at significantly decreased levels compared to 2008 due to decreased demand and some excess supply. ●Establishment of a long-term, stable market is still the key to unleashing investment in manufacturing capabilities in the U.S. Countries are competing through policy for the wind industry, wind manufacturing and jobs!

98. U.S. Wind Manufacturing Source: American Wind Energy Association; Updated Through 4Q2009

99. 2008 Turbine Statistics Turbine installed the most in the U.S. in 2008 was the 1.5-MW turbine. Average turbine capacity is 1.67 MW Turbine Components Turbine Ranges

100. Occupational Safety and Health = Core Value ●Improve Worker Safety and Health ●Support of Continuous Education and Training of Employers and Employees in the Wind Industry ●Work Cooperatively with Regulating Agencies to Ensure the Safety and Health for All Workers

101. AWEA Safety and Health Committee ●AWEA Safety and Health Committee Created 3 years ago Over 450 members participating 9 subcommittees and task forces 20-50 participants on each subcommittee Monthly conference calls Address the most pressing issues within the industry

102. AWEA Safety and Health Committee ●Steering Committee ●Construction Safety Subcommittee ●Manufacturing Safety Subcommittee ●O&M Safety Subcommittee ●Training and Education Subcommittee ●Offshore Safety Subcommittee ●Safety Survey Subcommittee ●Confined Space Task Force ●LOTO Task Force

103. Safety and Health Initiatives ●Education and Understanding the Intricacies of Development and the Sustainability of Wind Generation Plants

104. Safety and Health Initiatives ●Empowering Workers to be Engaged and Take Ownership in Worker Safety and Health Programs

105. Safety and Health Initiatives ●Collect and Monitor Injury, Illness, and Fatality Data Leading Indicators Injuries, Illness, and Fatalities What are the Causes Where are the Accidents ●Identify the High Hazard Areas ●Develop Solutions to Eliminate or Significantly Reduce Hazards

106. Identify High Risk Hazards Falls Emergency Rescue Confined Space Environmental Conditions

107. Training Initiatives Create and Develop Appropriate Safety and Health Training Programs and Educational Materials for All Sectors of the Wind Industry OSHA 10 Hour OSHA 30 Hour Supervisor Emergency Rescue Confined Space

108. Thank you! More information : Michele Myers Manager, Labor, Health and Safety Policy www.awea.org | 202-383-2500 | mmyers@awea.org www.awea.org/events

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110. Waste Management and Recycling & Associated Workplace Hazards Justin August, CIH Covanta Energy Corporation

111. Largest Energy-from-Waste (EfW) operator in the world Global presence; local relationships North America, Asia & Europe 4,000 employees 45 EfW and 8 biomass to electric facilities Almost 10% of U.S. non-hydro renewable electricity Over 6% of U.S post recycled waste disposal 400,000 tons of metal recycled each year Lee County EfW, Florida 111

112. Renewable Energy U.S. EPA states that Energy-from-Waste “produces electricity with less environmental impact than almost any other source” 25 States and the federal government defined EfW as renewable A new 2,000-3,000 ton/day facility 73 to 110 MW electricity

113. Converting Waste Into Clean Renewable Power Converting Waste Into Clean Renewable Power Helps Solve Three of the Nation’s Biggest Challenges Climate ChangeOne ton of trash reduces one ton of CO 2 eq Energy SecurityLocal renewable energy available 24/7 Creates JobsTypical facility creates 1,000 construction jobs (3+ years) Metal: 50 lbs Power: 500-750 kWh Ash: 10% of original volume Municipal Solid Waste (MSW): 1 ton Energy-from-Waste is a specially designed energy generation facility that uses household waste as fuel and helps solve some of society’s big challenges

114. Energy-from-Waste reduces waste volumes by 90%

115. 115 Economic Investment  Green Jobs 1,600 ton per day facility $450 million construction cost ~ 3 years of activity 300-500 direct construction jobs per year ~$31 million annual operating budget benefits local economy 50 full time to operate facility –High paid jobs averaging more than $60K State Income Tax and Host Community benefits Goods and services purchased locally

116. Covanta - Industry Leader in VPP & EPA EPA – Environmental Performance Track 25 EPT Sites VPP - Top 7 of all Companies 39 VPP Star Sites VPP - Number of SGE/STM Participants Top 4

117. VPP Sites (39) Non-VPP Target Sites (13) Mid-Con, CT SECONN, CT Bristol, CT Wallingford, CT Hempstead, NY Huntington, NY MacArthur, NY Babylon, NY Hudson Valley, NY Essex, NJ Union, NJ WERC, NJ Alexandria, VA Fairfax, VA Niagara, NY Onondaga, NY Harrisburg, PA Delaware, PA Lancaster, PA Plymouth, PA York, PA Abington TS, PA Kent, MI Detroit, MI Hennepin, MN Indianapolis, IN Marion, OR BMP, CA MLP, CA POPI, CA Stanislaus, CA Delano, CA Mendota, CA Long Beach, CA Honolulu, HI Huntsville, AL CFS-South Southeastern, FL Pasco, FL Lake, FL Lee, FL Hillsborough, FL Tulsa, OK Covanta Facility OSHA VPP Status by OSHA Region January 2010 Jonesboro, ME West Enfield, ME Haverhill, MA SEMASS, MA Springfield, MA Pittsfield, MA CFS-North Montgomery, MD Montgomery TS, MD

118. Covanta Safety Management Systems Corporate Technical Standards & Safety Steering Committee WorkCare - Occupational Health Physicians for Injury Treatment and Exams Regional Audits: Snapshots, Corporate Audit Program Providing Support to Implement Corporate HS Policies Facility Local Occupational Health Clinic / Mobile Exam Clinic Near miss reports, Job Observations (JOB’s), Job Safety Analyses, Pre-job task briefings

119. The Covanta Safety Management and Communication Pyramid Daily Near miss reports, JOBs, Job Safety Analyses (JSAs/JHAs), Pre-job task briefings, accident reviews w/Region & Site Weekly Tailgates, Staff calls with VP HS Monthly Safety training, Field calls with Regional personnel, training material planning calls Quarterly Safety steering committee meetings, technical standards meetings, field employee meetings, Snapshots Semi-annually Performance reviews, safety metric compensation Annually Company-wide safety meeting, Trade presentations, OSHA meetings

120. Safety and Health Program Management Corporate Safety and Health Intranet Site

121. Mobile Equipment Safety Safety Upgrades Seatbelt Use

122. Focus on Leading Indicators Internal “Snapshot” audits Tracking/Trending “Near-Miss” events Job Observations Sharing of Best Practices

124. Modern Energy-from-Waste

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