Chapter 6 : Smart District heating/cooling, Summer Course, AUST 2015

Smart  City  Concept  and  Solu2on    AUST  Summer  Course  2015  

Chapter  6  :  Smart  District  hea2ng/cooling  Professor  Isam  SHAHROUR    Isam.shahrour@univ-­‐lille1.fr  

Organiza(on  of  the  chapter    

-­‐  Hea(ng/cooling  energy  consump(on    -­‐  The  district  hea(ng/cooling  system  -­‐  Key  figures  -­‐  The  Smart  hea(ng/cooling  system  -­‐  Strict  hea(ng  pilot  –  SunRise  project  

Energy  Consump2on  by  buildings    

United  States  :  50%  Europe  :  40%  UAE  :  70%      

Energy  consump2on  in  US    

ANNUAL  ENERGY  OUTLOOK  2015  

Hea2ng/cooling:    •  65  %  in  2013  •  50%  in  2040    

Pollu2on  emission  in  London    

71  %  from    Buildings  

Energy  consump2on  in  Ireland    

Household  consump2on  in  the  Middle  East  

Hea2ng/cooling:  58%    

Electricity  demand  in  MENA  Countries  (Middle  East  and  North  Africa)    

SA  

Iran  

Egypt  

Energy  consump2on  in  UAE  

HVAC  accounts  for  60  to  70  %  of  the  energy  consump2on  

Lebanon  –  Energy  consump2on  

ABC  mall  Energy  consump2on    Energy  expenses  in  2007  =  $2,280,000      

Hotel  Dieu  de  France  Hospital  (HDF)    Energy  expenses  in  2007  =  $1,872,000      

Organiza(on  of  the  chapter    

-­‐  Hea(ng  cooling  energy  consump(on    -­‐  The  district  hea(ng/cooling  system  -­‐  Key  figures  -­‐  The  Smart  hea(ng/cooling  system  -­‐  Strict  hea(ng  pilot  –  SunRise  project  

Industrial  buildings  

Offices,  Services  

Provide  hea2ng/cooling  Energy  ?    

District    

Households  

Industrial  buildings  

Offices,  Services  

Energy  plant  

Households  

Industrial  buildings  

Offices,  Services  

Energy  plant  

Heated  Water    

Households  

Households  

Industrial  buildings  

Offices,  Services  

Energy  plant  

Cooled  Water    

Households  

Industrial  buildings  

Offices,  Services  

Energy  plant  

Cooled  Water    

Conven2onal  energy:    •  Coal,    •  Natural  gas,  •   Oil    

Energy  source  

Energy  recovery:  •  waste  incinera(on,  •   waste  water,    •  data  centers  •  Industrial  process    

Renewable  energy:  •  biomass,    •  deep  geothermal  •  Solar  (Denmark  and  Germany)  

Energy  sources  

Sweden  faces  a  lack  of  garbage  for  energy  genera2on.    It  has  to  import  garbage.  

Video  :  A2  Impor(ng  garbage  for  energy  is  good  business  for  Sweden  

Energy  sources  

•  Conven(onal  energy  for  high  temperature  •  Industrial  heat  recovery:  intermediate  temperature  •  Geothermal  and  waste  water  for  low  temperature  (10-­‐30  °  C)  

District  hea2ng  lines  

District  hea2ng  lines    

District  hea2ng  lines    

h^p://news.thermaflex.com/district-­‐hea(ng-­‐and-­‐cooling/tallinn-­‐summary  

Reduc2on  of  the  heat  losses  

Reduc2on  of  leakages      

Over-­‐heated  water  (110  °  C  and  180°  C):    Buildings  requiring  high  temperature  (laundries,  industries  

Heat  transfer  fluids  Hot  water  (between  60  °  C  and  110  °  C):  

 Residen(al  buildings  or  offices  

Steam  (200  °  C  to  300  °  C)    :  Mainly  used  for  industry  Used  in  Paris  

Substa2on  

Substa2on  -­‐  Heat  exchanger  

Includes  a  heat  exchanger  that  transfers  heat  between  the  primary  network  and  the  building.  

Sub-­‐Sta2on  

Used  for  monitoring  the  district  hea(ng:  -­‐  Temperature  -­‐  Pressure  -­‐  Heat  consump(on    

Equipped  by  a  regula(on  unit  that  controls  the  energy  transfer  

Advantages  of  the  district  hea2ng/cooling  system  

Scale  effect  (system  efficiency)  

Cogenera(on  (produc(on  of  electricity)  

Could  be  used  as  energy  storage  (heat  is  stored  more  easily  than  electricity).  

Integra(on  of  renewable  energy    

District  Hea2ng  Challenges    

District  Hea2ng  Challenges    

Break  in  a  hea(ng  pipe,  Paris,  May  2009      

Challenges  in  Smart  Hea2ng  :  Security      

Movies  :  A1  District  Hea2ng    A2  Wonderful  World  of  District  Hea2ng  A2  Impor2ng  garbage  for  energy  is  good  business  for  Sweden  A3  CHP  Overview    A4  District  hea(ng  &  cooling  from  Denmark  A5  The  cogenera(on  and  district  hea(ng  plants  in  Turin,  Italy  A6  District  Cooling  Plant  Abu  Dhabi,  UAE  A8  Thermal  Chicago  district  cooling  system    B1  SmartPower  Combined  Heat  and  Power  (CHP)  B2  Smart  Celsius  Project    

Organiza(on  of  the  chapter    

-­‐  Hea(ng  cooling  energy  consump(on    -­‐  The  district  hea(ng/cooling  system  -­‐  Key  figures  -­‐  The  Smart  hea(ng/cooling  system  -­‐  Strict  hea(ng  pilot  –  SunRise  project  

District  hea2ng  in  some  countries  :  

District  hea2ng  in  Europe  :  

•  Around  5000  heat  networks  •  11%  of  electricity  is  produced  by  cogenera(on  

•  10%  of  the  hea(ng  market.  §  Finland,  Lithuania,  Denmark,  Sweden:  nearly  50%  

§  UK  and  Netherlands:  4%  

District  hea2ng  in  Europe  

District  hea2ng  in  Europe  

Cogenera2on  

Cogenera2on  in  Danemark  

2009  1985  

District  hea2ng  in  France:  

•  450  hea(ng  networks  •  Two  million  of  unites  deserved    •  26  TWh  of  the  final  energy  •  6%  of  the  hea(ng  

This  ra2o  is  low  compared  to  other  European  countries  

District  hea2ng  in  France:  

District  hea2ng  in  Russia  

•  55%  of  the  district  hea(ng  in  the  world.  •  more  than  17  000  district  hea(ng  systems.  •  44  million  customers.  •  98%  of  fossil  energy  (75%  natural  gas).  

Evolu2on  of  the  heat  Consump2on  in  Poland  

District  hea2ng  in  United  States  •  4%  of  the  hea(ng  demand  •  New  York  network  district  hea(ng  (1882)  is  the  

largest  in  the  world      

District  cooling  (DC)  in  Gulf  Countries  

District  cooling  (DC)  in  Gulf  Countries  

District  cooling  (DC)  in  Gulf  Countries  

Yearly  increase  in  the  DC  market  in  GCC  :  16%    

District  cooling  (DC)  in  Gulf  Countries  

Organiza2on  of  the  chapter    

-­‐  Hea(ng  cooling  energy  consump(on    -­‐  The  district  hea(ng/cooling  system  -­‐  Key  figures  -­‐  Smart  hea2ng/cooling  system  -­‐  Strict  hea(ng  pilot  –  SunRise  project  

« Radiator » Building distribution

Sub-station

Piping

Buffers

and Storage

Conversion Energy

Sources

Buildings

Network

Heat production

Confort and human behavior

Consumers

Smart  District  hea2ng  System  

Infrastructure  and  Customer  Layer    

56  

« Radiator » Building distribution

Sub-station

Piping

Buffers

and Storage

Conversio

n Energy

Sources

Buildings

Network

Heat production

Confort and human behavior

Consumers

Communica2on  layer    

Plateform  Informa2on  System  

Smart  District  hea2ng  System  

57  

« Radiator » Building distribution

Sub-station

Piping

Buffers

and Storage

Conversio

n Energy

Sources

Buildings

Network

Heat production

Confort and human behavior

Consumers

Communica2on  layer    

Plateform  Informa2on  System  

Smart  District  hea2ng  System  

Analy2cal  tools  •  Op2mal  management    •  Security  

58  

« Radiator » Building distribution

Sub-station

Piping

Buffers

and Storage

Conversio

n Energy

Sources

Buildings

Network

Heat production

Confort and human behavior

Consumers

Communica2on  layer    

Plateform  Informa2on  System  

Smart  District  hea2ng  System  

Analy2cal  tools  •  Op2mal  management    •  Security  

Communica2on      web  Servor  

•  Customers  •  Technical  team  

Governance  team    •  Public  data  

Advantages  of  the  smart  district  hea2ng  

For  the  district  managers:    •  Reduce  the  heat  losses    •  Improve  the  balance  produc(on  -­‐  demand  •  An(cipate  the  hea(ng  peaks  •  Increase  the  network  reliability  •  Reduce  the  pumping  expanses    •  Rapid  detec(on  of  leakage  •  Improve  the  management  of  the  energy  Storage    

For  the  Ci2es  §   Mapping  the  heat  consump(on  in  the  city  (renova(ons  priori(es)  

§ Mapping  the  heat  loss  in  the  network  (network  renova(on  priori(es)  

§  Improve  the  asset  management  

Advantages  of  the  smart  district  hea2ng  

For  customers    Real  (me  informa(on  on  the  heat  consump(on  •  Energy  savings  based  on  data  and  saving  incen(ve    •  Benchmarking  

Apport  des  réseaux  intelligents  

Organiza2on  of  the  chapter    

-­‐  Hea(ng  cooling  energy  consump(on    -­‐  The  district  hea(ng/cooling  system  -­‐  Key  figures  -­‐  The  Smart  hea2ng/cooling  system  -­‐  Strict  hea2ng  pilot  –  SunRise  project  

SunRise  District  Hea2ng  

Primary  network:  9  km  Secondary  network:  8    km  primary  substa(ons  :  37  

District heating - SunRise

64  

Présentation

Pipes

Sub Stations (37)

Hea2ng  Center  

3  hea2ng  units    (35  MW)  

Primary  network-­‐  SunRise  (9  km)  

65  

Secondary  network  (8  km)  

66  

Primary                        Secondary                          

Substa(on  Secondary  Network                          

37 Substation

68  

Heat Exchanger

37 Substation

69  

Heat Exchanger

Electronic Valve

Sensors : •  Temperature •  Pressure •  Debit •  Heat Consumption

Control Unit

The  substa2on:  •  Equipped  by  a  local  management  unit  •  Connected  to  a  bi-­‐direc(onal  data  transmission  fiber  •  Transmits    data  concerning  flow,  power,  valve  status,  ...  •  On-­‐line  controlled  

Data  transmission  

Sensors  

GPRS  

Server    

Internet  

Storage  

Technical  team  Management  Team  

Radio  transmission  

Antenna  

72  

Hourly  Consump2on  –  Building  M1  (January  2012)  

Heat  Consump2on  –  Building  M1  (2009)  

Heat  Consump(on    

External  Temperature    

Heat  Consump2on  –  Building  M1  Working  day  

RMSE  =  1.199  R²              =  0.854  

74  

Heat  Con

sump2

on  

External  Temperature  

RMSE  =  1.181  R²              =  0.827  

75  

Heat  Consump2on  –  Building  M1  Week  -­‐  end  

Heat  Con

sump2

on  

External  Temperature  

Real  Consump2on    

Consump2on  based  on  op2mal  control      

Poten2al  saving  based  on  op2mal  management    -­‐Regula(on  according  to  the  building  usage  with  hourly  (me  control    19°  working  (me,  15°  non  working  (me  

Conclusion    Hea2ng/Cooling  cons2tutes  a  major  issue  in  the  world    

-­‐  High  energy  consump(on  -­‐  High  pollu(on  emission  -­‐  Quality  of  life  -­‐  Big  market        

Conclusion    District  Hea2ng/Cooling  presents  major  advantages;  -­‐  Energy  saving  (scale  effect)  -­‐  Integra(on  of  renewable  energy  -­‐  Co-­‐genera(on  (hea(ng  +  electrical  produc(on)  -­‐  Increase  in  safety    -­‐  Energy  storage  

Conclusion    Smart  district  Hea2ng/Cooling  offers  major  advantages:  

•  Real  (me  data  and  control  •  Be^er  understanding  of  the  system  (produc(on,  heat  transport,  substa(on  and  consump(on)  

•  Improves  the  balance  heat  produc(on  –  demand  •  Op(mize  the  hea(ng  temperature    •  Reduces  the  heat  losses    •  Increases  the  network  reliability  •  Reduces  the  pumping  expanses    •  Rapid  detec(on  of  leakage  

Movies  :  A1  District  Hea2ng    A2  Wonderful  World  of  District  Hea2ng  A3  CHP  Overview    A4  District  hea(ng  &  cooling  from  Denmark  A5  The  cogenera(on  and  district  hea(ng  plants  in  Turin,  Italy  A6  District  Cooling  Plant  Abu  Dhabi,  UAE  A7  Saudi  Tabreed  Corporate  Video  A8  Thermal  Chicago  district  cooling  system  B1  SmartPower  Combined  Heat  and  Power  (CHP)  B2  Smart  Celsius  Project    

THANK  YOU