2. Eco-Industrial Development

3. State of the Environment Increasing environmental stress caused by pollution DepletingDepleting of natural resources Threats to human health

4. GLOBAL IMPACT Population (2.6B) Resource Use Efficiency of Production = xx World Population increased from 2.6 billion in 1950 to 5.8 billion in 1995 Traditionally, efficient production means maximum output at the least cost, and often at the expense of a degraded environment.

5. … more consumption requires increased agricultural production

6. … faster rate of extraction and use of resources…

7. … need for more space that involves sacrificing of natural ecosystems …

8. … to build our homes and service infrastructures, to provide a place for business or trade.

9. …and to put our garbage in.

10. greater demand for transportation and electricity that means greater fuel consumption

11. … and increased pollution of water and air that can have far-reaching effects on human health.

12. Rapid industrialization adverse environmental impacts (pollution, resource depletion, etc.) defeats Sustainable Development meeting the needs of the present generation without compromising the ability of future generations to meet their own needs.

13. Potential environmental impacts Contaminated soil and lost future land use Spills Landscape disturbance Habitat degradation Air pollution Ozone-depleting and greenhouse gases Disposal of solid wastes Freshwater pollution Marine pollution Risks from hazardous waste Exposure to toxic chemicals Local nuisances such as noise, lighting and transport

14. Product Life Cycle System Earth & Biosphere Raw Material Acquisition Bulk Processing Engineered & Specialty Materials Manufacture & Assembly Use & Service Retirement Treatment Disposal Open Loop Recycling Material downcycling Into another product system Reuse Closed-Loop Recycling Remanufacturing Recycling Transfer of materials Between stages Untreated residuals

15. The Human Consumption Pattern Mass Production & Customization Mass Consumption & Mass Disposal

16. The concept of Industrial Ecology «The traditional model of industrial activity should be transformed in a more integrated model: an industrial ecosystem.» (…) R. Frosch & N. Gallopoulos, General Motors Laboratories, 1989

17. Industrial Ecology as a metaphor «The industrial ecosystem would function similar to a biological ecosystem» R. Frosch & N. Gallopoulos, General Motors Laboratories, 1989

18. First idea: «industrial food chains» «In such a system the consumption of energy and materials is optimized and the effluents of one process serve as the raw material for another process.» R. Frosch & N. Gallopoulos, 1989

19. Industrial Ecology’s Approach: CLOSE THE LOOP Upstream Production Downstream Production RE-USE RECYCLE

20. Greenhouses Sulphuricacid maker sulfur hotwater surplus gases StatoilRefinery. One of Denmark‘s largest refineries with a capacity of 3-4 million tons / year process steam sulphur gases cooling water AsnaesPowerStation gypsum condensate Cement maker Fly ash hotwater CityofKalundborg Provides district heating services to 500 Kalundbotrg homes process steam NovoNordisk Produces a significant amount of the world`s insulin supply and certain industrial enzymes ASNEAS fishfarm. warm water fertilizer Localfarmers Hundreds of farms producing a variety of crops are located within the area sludgefertilizer Gyproc Manufactures gypsum-based wall board Commissioned in 1959, the coal-fired plant has a capacity of 1,500 MW Kalundborg, Denmark

21. Utilities Farms Households Service & commercial sectors Government facilitation and regulation Collector Eco-industrial park Resource recovery facility Processor 1 Manuf. 1 Manuf. 2 Services Construction & demolition Collector Manufacturing INTEGRATED MANAGEMENT OF DISCARDS Government Operations Finance Education & research Communications © 1997 Indigo Development

22. WASTE MANAGEMENT HEIRARCHY Source Reduction Most Desirable Least Desirable recycling Waste treatment disposal

23. Industrial Ecology Approach to managing human activity on a sustainable basis by: essential integration of human systems into natural systems; Minimizing energy and materials usage; Minimizing the ecological impact of human activity to levels natural systems can sustain.

24. Energy Water Waste/recovery/recycling/substitution Information Regulatory functions Transportation systems Marketing Other covenants What can be shared?

25. Looking beyond … Regional Metabolism Industry Process Wastes Recycling Reuse Product 1 Product 2 Product n... Resource 1Resource 2Resource 3Resource n... Source: Erkman & Ramaswamy

26. Industrial Metabolism: conceptual framework Translocations Input Minerals, ores, energy carriers WaterAir Harvested biomass, hunting, fishing Output Waste deposits Waste Water Emissions to air Fertilizer, pesticides, dissipative losses Industrial System Biosphere Source: Wuppertal Institut

27. WASTE = RESOURCE RESOURCE

28. Why participatory ? It ’ s complicated enough! creates  Participation  Ownership creates  Commitment  Apropriate Solutions creates

30. PALAWAN SEAWEED INDUSTRY Some Issues and Opportunities

31. PROBLEMS OF INDUSTRY 1.Production 2.Marketing 3.Finance 4.Other concerns

32. Distribution Channels of Seaweed Farmer Barangay Traders Small Traders/ Viajeros Export Traders Processors Big Traders/ Buying Stations

33. PRODUCTION STATISTICS developed area for production – 7,748 ha - Class A – 322 ha - Class B total potential area –9,333 ha - Class A –1,883 ha - Class B –1,150 ha - Class C

34. BIOLOGY OF SEAWEED Seaweed is a mass of marine algae simple structured organisms with no true leaves, stems, roots and wood vessels reproduces through spore production

35. PRODUCTION AREA Palawan as main Philippine producer 8,070 ha developed for production 12,366 ha potential area Production’s annual increase of 16%. grnweed.jpg / 216 x 254 pixels - 16.7kB carrageenan.cebu.ph/seaweed.html

36. PRODUCTION 1998 production –Province - 141,301 MT –Total Philippines - 643,043 MT Major markets are Manila and Cebu

37. Annual production of dried seaweed in Palawan in Palawan by municipality MUNICIPALITY ANNUAL PRODUCTION (TONS) 19981999200020012002 Agutaya7,2008,3859,76611,37413,247 Araceli180210246286334 Balabac6006998149481,104 Busuanga60718397114 Cagayancillo4,8005,5916,5127,5848,834 Culion3035414857 Cuyo8409781,1401,3291,548 Linapacan1821242833 Quezon60718397114 Roxas480559651759884 Taytay360420489570665 TOTAL 14,62817,04019,84923,12026,934

38. PALAWAN SEAWEED INDUSTRY Two largest producing municipalities: –Agutaya share - 49.2% –Cagayancillo share -32.8%

39. PALAWAN SEAWEED INDUSTRY –Classification of municipalities based on number of months of production Class A Class B Class C

40. PRODUCTION STATISTICS developed area for production – 7,748 ha - Class A – 322 ha - Class B total potential area –9,333 ha - Class A –1,883 ha - Class B –1,150 ha - Class C

41. Systems make it possible, People make it happen.