District Heating and Distributed Energy: Practical Experience Relevant to

1. District Heating and Distributed Energy: Practical Experience Relevant to Northeast Asia Security William Chandler Laboratory Fellow Battelle Memorial Institute Pacific Northwest National Laboratory 1

2. Outline • Technology of rehabilitation • Economics of upgrading • “Financial engineering” of projects • New solutions 2

3. Why “District Energy” Matters • Matter of survival in cold climate • Large share of heating (70 % in Russia) • Financial burden on governments and individuals • Politically sensitive • Consumer cost • Stranded assets • Economic efficiency 3

4. Russia, Poland, Ukraine, Czech Republic, China, Bulgaria Centers Created: • Functions • Policy reform • Technology transfer • Demonstration • Public information 4

5. Improvements to CHP “Nothing needs reforming quite so much as other people’s bad habits.” -- Mark Twain Before After 5

6. Back Pressure Steam Turbine Steam Driven Chillers High Pressure Steam Heat Recovery Steam Generators Heating Steam Electric Power Exhaust Heat Chilled Water Electric Power Fuel Gas or Oil PEPCO Combustion Turbines Electric Power UMCP Campus Buildings Boilers Details of the DealIntegrated Utility System Heating Steam 6

7. Results • $71M in improvements • Energy use cut by 1/3 • $120M Savings • Low cost, off-balance sheet financing 7

8. Typical Problems of District Energy:Financial Burden on Governments Pensioners protest “monetization” of utilities and other benefits, St. Petersburg, 17 January 2005 (Photo: A. Maltsev, Sipa Press, via MSNBC) 8

9. Russian Government Interest in Energy Management is Cost-Driven • Water and heat for public buildings cost $5 billion in federal subsidies, or 6 percent of budget • Savings of 30 percent could readily be obtained. • Subsidies to pensioners cost another 5 percent of GDP. • - The U.S. and Russian governments have an agreement to cooperate on “Federal Energy Management” 9

10. Typical Problems of District Energy:Low Thermal Integrity of Buildings 10

11. Typical Problems of District Energy:Low Thermal Integrity of Buildings • Shortage of funds to pay for heat services • Poor quality of heat supply • Lack of heat meters • Poor building insulation and maintenance • Lack of qualified personnel • Lack of financing to improve facilities’ energy efficiency 11

12. Typical Problems of District EnergyAging Equipment, Poor Maintenance 12

13. Major Problems of Heat Supply:Boilers • Lack of financing and low fuel stocks • Shortened heat supply season and lowered temperatures • Absence of fuel and heat metering • Shortage of qualified boiler personnel 13

14. Major Problems of Heat Supply Networks:Pipeline Maintenance Wear, failures, leaks, broken insulation, inefficient pumps, old heat exchangers, poor controls, multiple owners, non-collection of heat bills, overcharging of customers.... Source: Center for Energy Efficiency, Moscow 14

15. Russian District Heating Indicators Source: Igor Bashmakov, Center for Energy Efficiency, Moscow 15

16. Heat Transportation Problemsin Russia • Heat losses range from 20 to 70% • Maintenance requires 50% of DH costs • Only 2% of pipes are replaced annually • High leakages ratio, lack and low quality of insulation; • Buildings are overheated or under-heated 16

17. Chernobyl—Aerial View 17

18. Closing Chernobyl by Saving Energy How did it work? • U.S. AID/DOE grants through PNNL and others to develop project • $30 million financing developed for buildings • Kyiv City Administration invested $5 million • World Bank invested $17 million in buildings and $100 million in DH system • Results: ~30% savings in buildings alone • $100 million financing developed for heat supply system 18

19. District Energy Efficiency, Kyiv Source: Arena-Eco and PNNL 19

20. Upgrading District Energy:Adding Heat Controls in Buildings Source: Pacific Northwest National Laboratory 20

21. Kiev Institutional Buildings Program • KIBA, a $30 million energy efficiency project in 1,300 schools, hospitals, and cultural buildings in Kyiv • Savings equivalent to the output of a 160 MW power plant. 21

22. Source: Year 2004 Review, Austrian Federal Ministry of Agr., Env. , Water 22

23. Kharkiv District Heating Project • Add six steam turbines (84 MW) • Replace 50 km of transmission pipelines • Replace 200 km of distribution pipelines • Replace 443 old infficient boilers • Installation of 3,870 individual heat substations • Total cost = $173 million. • Saves~$37 million per year. 23

24. 50 6 40 5 30 Savings Cost (USD/GJ) 20 4 Current heat price from DH 3 10 2 1 0 0 200 400 600 800 1,000 1,200 1,400 1,600 Cost of Saved Energy in Czech Apartments 5 – Floor Insulation (2%) 6 – Thermal Windows (16%) 1 - TRV’s, Allocators, & Balancing (15%) 2 - Weatherization (3%) 3 – External Wall Insulation (19%) 4 – Roof Insulation (7%) Cost-Effective Total = 44% Saved energy (GJ/year) Note: Interactions between measures not included. 24

25. Plutonium and District Heating 25

26. 90 80 70 60 50 40 30 20 10 0 22 29 25 27 21 6 14 13 Cost of Saved Energy (CSE) Versus Energy Price, Zheleznogorsk CSE 26 $/Gcal 14,8 $/Gcal CSE, $/Gcal 9,1 $/Gcal 4,8 $/Gcal 20 5 19 1 28 12 24 3 9 4 23 2 7 11 15 10 8 16 26 Measure Number (see definitions) Source: CENEf and PNNL 26

27. Definitions of Measure Numbers, Zheleznogorsk • 22 Hydropneumatic cleaning of in-house heating pipelines • 29 DHW regulation unit upgrade in open-type district heating systems • 25 Installation of a balancing valve at the building input • 27 Replacing hydroelevators with pumps and regulation and automation control system • 21 Restoration of re-circulation in the DHW system • 6 Insulation of outer walls from the inner side • 14 Insulation of windows (installation of heat reflecting films) • 13 Insulation of windows (doors) + elimination of holes between window (door) frame and the wall • 20 Insulation of in-house DHW pipes • 5 Insulation of attic floor • 19 Installation of electric water heaters • 1 Insulation of basement from the inner side • 28 Installation of individual heating points • 12 Insulation of flat roof • 24 Installation of heat meters on the building level • 3 Insulation of the floor (1st floor) • 9 Insulation of walls from the outer side with molded board lining • 4 Insulation of floor on the logs • 23 Installation of efficient faucets • 2 Insulation of basement ceiling • 7 Insulation of walls from the outer side with mineral wool and thin plaster • 11 Installation of heat mirrors • 15 Installation of energy efficient windows • 10 Insulation of walls from the outer side with plastic or aluminum siding • 8 Insulation of walls from the outer side with thermo-insulating slabs • Installation of ceiling-mounted ventilators • Installation of thermostatic valves on the radiators 27

28. Mini CHP Technology in China How to Start a Power Company? 317 kW gas-fired combined heat and power plant 28

29. Economics of Combined Heat and Power Source: W. Chandler 29

30. New Cement Plant in Zhejiang:Potential for 13 MW Heat Recovery 30

31. Cement Plant Heat Recovery • 1. Zhejiang Cement Company, a 5,000 ton per day manufacturing plant near Hangzhou. • 2. Waste heat recovery has been proven in Wan An plant in Shanghai. • 3. Price of power is $0.065 per kWh. • 4. Notional system: 13 MWe at $1,000/kW, 85 percent capacity factor. • Investment = $13,000,000 • Internal Rate of Return = 22% • Project financial life = 5 years 31

32. Policy 32

33. What Can Government Do? • Stabilize the investment environment • Develop legal and policy infrastructure • Conduct market reforms and decentralization • Share risk (financing) • Demonstrate new approaches and technologies • Provide information 33

34. Energy Intensity Improvement in the Transition Economies, 1990-2003 Source: William Chandler, Energy and the Environment in the Transition Economies (Boulder: Westview Press, 2000), updated by the author 2005. 34

35. Reported Growth in ChineseGDP, Energy Consumption, and Power Demand Source: Jeff Logan, International Energy Agency, private communication, 2005. 35

36. Utility Bill Collections Rate, 2000 36

37. District Heating SubsidiesPercent of Local Budget, 2001 37

38. District Heat Pricing, Selected Countries 38

39. Source: U.S. Energy Information Administration, 2004. Note: Kazakh data are for 2001. 39

40. 40

41. District Energy Policy in Hungary • Mandatory purchase of cogenerated electricity up to 20 MW with favorable prices • Investment support for small scale CHP • Investment boom in gas systems • Regulatory issues in cost allocation between heat and power generation Source: International Energy Agency 41

42. Poland: Four Cities’ Experience, • 1992 – 1999 • 22% energy savings in district heat • Heat tariffs dropped more than 50%. • Consumer subsidies eliminated • Customers able to control heat level • Source: Ira Birnbaum, U.S. AID 42

43. WADE* Survey of Poland’s Electric Power Sector *World Alliance for Decentralized Energy Source: World Survey of Decentralized Energy, 2005, www.localpower.org 43

44. Steps to Reform Russian DHS markets • Mandating municipal energy plans • Transition to metered heat, gas and water • Creating associations of communal services payers (ACSePs) • Attracting ESCOs • Launching “profits-from-savings” mechanisms to pay for rehabilitation • Eliminate cross-subsidies and getting prices right • Ending “cost plus” approach Source: Igor Bashmakov, Center for Energy Efficiency, Moscow, presented to the International Energy Agency, Prague, 2004 44

45. WADE* Survey of Russia’s Electric Power Sector *World Alliance for Decentralized Energy Source: World Survey of Decentralized Energy, 2005, www.localpower.org 45

46. China CHP Barriers/Opportunities • Lack of well-prepared projects • Lenders’ inexperience with efficiency projects • Regulatory issues • Lenders’ perceived risk for small and medium borrowers and for efficiency Source: Chandler, International Finance Corporation, 2004 46

47. China CHP Investment Risks Technical risk Uncertain regulatory environment Non-transparency of customer finances Lack of collateral Source: Chandler and Gwin, International Finance Corporation, 2004 47

48. Overview of Privatization and Competition Privatization of natural monopolies requires special steps: • Determining competitive parts of the system, separating them, introducing competition. • Creating legal, institutional framework to regulate prices and return on investment. • Commercializing–introducing hard budget constraints for–all power sector enterprises. • Attracting investment through concessions or privatization. Source: Coming in from the Cold: Improving District Heating Policy in the Transition Economies (Paris: International Energy Agency, 2004) 48

49. Frontier Financing • Russia World Bank Housing Divestiture, $500 M • Czech Republic: ESCO promotion, $30 M • Ukraine: Kyiv City Buildings, $30 M 49

50. Project Financing in the Municipal Sector • Subsidy shift--from fuel to capital • Local budgets and regional efficiency funds • Heat supply company investments • Foreign, multilateral banks • Consumer expenditures Source: Center for Energy Efficiency, Moscow 50