An  AIA  Continuing  Education  Program  Credit  for  this  course  is  1  AIA/CES  Learning  Unit  

Course  Sponsor  Acorn  Sign  Graphics  4109  West  Clay  Street  Richmond,  VA  23230  Phone:  800-­‐770-­‐4744  E-­‐mail:  info@acornsign.com  Web:  www.acornsign.com  

Course  Number:  02SEGD  Course  Title:    Sustainability  in  Environmental  Graphic  Design  

Forward  Thinking  Solutions    is  a  Registered  Provider  with  The  American  Institute  of  Architects  Continuing  Education  Systems.  

Credit  earned  on  comple/on  of  the  program  will  be  reported  to  CES  Records  for  AIA  members.  

This  program  is  registered  with  the  AIA/CES  for  con/nuing  educa/on.  As  such,  it  does  not  include  content  that  may  be  deemed  or  construed  to  be  an  approval  or  endorsement  by  the  AIA  of  any  material  of  construc/on  or  any  method  or  manner  of  handling,  using,  distribu/ng,  or  dealing  in  any  material  or  product.  

Ques/ons  related  to  specific  materials,  methods,  and  services  will  be  addressed  at  the  conclusion  of  this  presenta/on.  

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©  Forward  Thinking  Solutions,  Inc.  2008  

Course  Objectives  

• What  is  Sustainable  Design  • Understanding  LEED  Rating  System  • Considerations  for  Environmental  Graphic  Design  (EGD)    

• Strategies  for  EGD  • Case  Study  

What  is  Sustainable  Design  

What  is  Sustainable  Design  

Sustainable  design  seeks  to  reduce  negative  impacts  on  the  environment,  and  the  health  and   comfort   of   building   occupants,   thereby  improving   building   performance.   The   basic  objectives   of   sustainability   are   to   reduce  consumption   of   non-­‐renewable   resources,  minimize   waste,   and   create   healthy,  productive  environments.  

Sustainable  Design  Principals  • optimize  site  potential    • minimize  non-­‐renewable  energy  consumption  • use  environmentally  preferable  products  • protect  and  conserve  water    • enhance  indoor  environmental  quality  • optimize  operational  and  maintenance  practices  

Sustainable  Design  Principals  

     Utilizing  a  sustainable  design  philosophy  encourages  decisions  at  each  phase  of  the  design  process  that  will  reduce  negative  impacts  on  the  environment  and  the  health  of  the  occupants.  

Sustainable  Design  Principals  

     Sustainable  design  is  an  integrated,  holistic  approach.  Such  an  integrated  approach  positively  impacts  all  phases  of  a  building's  life-­‐cycle,  including  design,  construction  and  operation    

Understanding  LEED  

Understand  LEED  Rating  System  

Points  are  awarded  for  achievement  in  six  categories:  

•  Sustainable  sites  •  Water  efficiency  •  Energy  and  atmosphere  •  Materials  and  resources  •  Indoor  environmental  quality  •  Innovation  and  design  process  

LEED  Projects/buildings  are  certified  through  a  progressive  rating  system  based  on  the  total  number  of  points  awarded  across  all  categories.  Projects  require  significant  documentation  for  evaluation,  which  can  be  costly.    

LEED  

Rating  is  in  one  of  four  categories,    from  basic  to  innovative.  

•  Certified  •  Silver  •  Gold  •  Platinum

LEED  Materials  and  Resources  -­‐  Construction  Waste  Management  (MR  Credit  2)  -­‐  Resource  Reuse  (MR  Credit  3)  -­‐  Recycled  Content  (MR  Credit  4)  -­‐  

                                                 -­‐  Local/Regional  Materials  (MR  Credit  5)                                                    -­‐  Rapidly  Renewable  Materials  (MR  Credit  6)                                                    -­‐  Certified  Wood  (MR  Credit  7)  

3form  Varia  Ecoresin  Nyloboard  VOC  free  

LEED  

Indoor  Environmental  Quality  -­‐ Low-­‐Emitting  Materials  (EQ  Credit  4)  

Innovation  and  Design  Process  -­‐  Innovation  in  Design  (ID  Credit  1)  -­‐  LEED  Accredited  Professional  (ID  Credit  2)  

EGD  Considerations  

EGD  Considerations  

     The  needs  of  the  environmental  graphic  design  community  and  the  commercial  building  industry  are  very  similar  in  regards  to  sustainability.  

The  key  to  an  Environmentally  Conscious  project  is  an  ongoing  strategy    unique  to  the  longevity,    maintenance,  and  durability    needs  of  an  EGD  project.    

EGD  Considerations  

EGD  Considerations  A.  Don’t  segregate  sustainability  from  design.  B.  Specify  locally  sourced,  sustainable  

materials  that  can  be  recycled.  C.  Integrate  green  communication  strategies.  D.  Do  more  with  less.  Design  for  less  waste.  E.  Design  easily  recycled  modular  components.  F.  Use  screws  instead  of  glues  for  assembly  

and  mounting.  G.  Use  low-­‐VOC  paints  and  energy-­‐efficient  

lighting.  

Strategies  For  EGD  

Selection  of  Materials  Most  experts  in  sustainability  believe  that  the  use  of  green-­‐certified  materials  is  only  one  small  part  of  a  sustainable  strategy.    

The  most  sustainable  approaches  are  related  to  general  material  selection,  the  fabrication  process,  and  final  disposition.  

Selection  of  Materials  Working  with  a  manufacturer  or  fabricator  that  provides  a  means  to  repurpose  or  recycle  their  materials  at  the  end  of  their  useful  life  can  contribute  significantly  to  the    decisions  made  in  the  material  selection  process.  

Strategies  For  EGD  Strategies  for  green  EGD  are  built  around  a  central  theme.  

• Longevity,  or  performance  over  time.    • Air  &  Environmental  Quality  • Resource  and  waste  management  • Energy  &  Lighting  Efficiency  • Recyclability/Modularity  

Longevity  Most  buildings  and  finishes  are  built  to  last  20  to  30  years  or  more.    

Environmental  Graphics,   generally   have   a  much  more   variable   lifespan,   from   as   brief   as   a   few  days  to  many  years  

It   is   important   to   take   this   into   consideration  when   making   material   choices   for   the   projects  that  you  are  designing.  

Longevity  While  there  is  no  specific  LEED  policy  or  code    on  longevity,  it  should  be  considered  in  projects    that  are  exposed  to  the  elements  and  extreme    wear  and  tear.    

Often,  longevity  requirements  are  at  odds    with  recyclability  and  clean  air  issues,  but    are  at  the  heart  of  environmentally  sound  design.  

Longevity  

Determining  how  long  a  design  object  is  meant  to  hold  up  over  time  and  with  constant  use  in  its  specific  environment  will  determine  the  most  appropriate  materials  and  methodologies.  

How  Long  is  the    Objects  Useful  Life  

Recyclability  and  waste  management  take  a  secondary  role  unless  the  object  is  meant  to  be  changeable.    

Long-­‐life  objects  need  user  educational  programs  to  ensure  quality  management  and  maintenance  over  a  long  period.  

How  Long  is  the    Objects  Useful  Life  

Short-­‐life  objects  require  more  extensive  planning  for  reusability  and  recycling,  along  with  greater  instruction  on  how  to  accomplish  these  goals.  

Resource  &  Waste  Management  

If  a  project  is  meant  to  have  a  limited  lifespan,  a  plan  needs  to  be  in  place  for  the  salvage,  reuse,  or  recycling  of  materials.  

This  affects  many  considerations    including  selection  of  materials,    finishes,  manufacture,    and  assembly/disassembly.  

Resource  &  Waste  Management Resource  and  waste  management  occurs    during  many  stages  in  the  life  cycle  of    built  objects.    

Considerations  include  sourcing  local    materials;  specifying  materials  with    recycled  content;    designing  within    standard  material  dimensions    to  limit  waste  during  manufacturing.    

Resource  &  Waste  Management  

Additional  considerations  include  removing  harmful  chemicals  in  the  fabrication  process;  reusing  or  recycling  packing  and  other    materials  during  installation;    and  planning  for  eventual  end    of  life  of  the  object  itself.    

One  of  the  best  strategies  is  using  less  material  or  adopting  a  material  reuse  program  in  production.  

Building  Reuse  Materials  Association  

The  fabrication  process  is  one  of  the  areas  where  sustainable  methods  can  have  the  biggest  impact.    Clear  disposability  guidelines,  labels  for  returning  manufactured  items  for  recycling,  use  of  mechanical  connection  techniques  rather  than  adhesives,  and  low-­‐VOC  paint  processes  are  some  of  the  methods  that  fabricators  can  implement.  

Resource  &  Waste  Management  

Photo  courtesy  of  Acorn  Sign  Graphics,  Richmond  VA  

End  of  Use  Life  Management  

LEED  focuses  on  having  a  salvage,  recycling,  and  reuse  plan  in  place  when  selecting  materials.    Fabricating  elements  with  modular  components  that  use  mechanical  fasteners  instead  of  adhesives  facilitates  disassembly  and  recycling  or  reuse.  

Photo  courtesy  of  Acorn  Sign  Graphics,  Richmond  VA  

Energy  &  Lighting  Efficiency  

LEED  addresses  energy  efficiency,  including  regulations  for  sourcing  local  materials  and  installation,  energy    conservation,  and  energy  use  during  manufacturing.    

Photo:  SEPCO  Solar  Electric  Power  Company  

Energy  &  Lighting  Efficiency  

City  of  Tampa  completed  a  downtown  wayfinding  project  in  2009  which  continues  on  the  Riverwalk.  

Directional  signs  and  map  kiosks  were  installed  using  solar  technology.  

Photo  MEJE:  Tampa  Riverwalk  

Solar  Street  Sign  (MSD  Visual)  

Solar  power  is  an  ever-­‐improving  technology  that  will  revolutionize  municipal  sign  lighting  in  cities.    This  solar  street  sign  has  internal  LED  illumination,  a  thin-­‐line  amorphous/  crystalline  solar  cell  module  with  built-­‐in  rechargeable  battery  pack,  and  a  smart  control  system.  This  sign  can  hold  a  charge  for  up  to  19  days,  even  with  no  sun.  Not  only  do  solar-­‐powered  signs  use  no  generated  electricity,  they  save  materials  by  requiring  no  digging  or  rearrangement  of  utilities.  

Energy  &  Lighting  Efficiency

Air  and  Water  Quality  Impact  

Graphic  design  products  traditionally  have  used  chemicals,  sealants,  vinyl,  and  paints,  all  of  which  can  have  a  direct  impact  on  the  environment.    

Air  and  Water  Quality  Impact  Today,  there  are  solutions  that  are:  

• Manufactured  from  post-­‐consumer  recycled  content    • Are  Green  Guard  Certified    • Use  low  energy  and  non  potable  water  to              manufacture.  • Waste  water  effluent  100%  biodegradable.  

While  not  all  materials  are  suitable  to  be    manufactured  in  this  manner,  it  is  important  to  be  responsible    in  our  decision  making  process.  

Air  and  Water  Quality  Impact  

Low-­‐VOC  (Volatile  Organic  Compounds)  paints  and  water-­‐soluble  products  can  have  a  positive  impact  on  your  project.  

Air  &  Environmental  Quality  VOC  rules  are  part  of  the  federal  Clean  Air  and  Water  Acts  of  1990,  but  states  vary  in  enforcement.  For  example;  California,  New  York,  and  Illinois  have  very  strict  enforcement,  while  Utah  has  minimal  enforcement.  VOC  rules  are  also  strictly  enforced  by  many  institutions,  including  universities  and  hospitals.    

Standard  paint  uses  5.5  to  6.5  pounds  VOC  per  gallon,  while  low-­‐VOC  paint  may  use  3.5  pounds  per  gallon.  California  mandates  2.8  pounds  per  gallon.  There  are  also  VOC-­‐free  paints.  

Air  &  Environmental  Quality  The  best  EGD  designers  select  products  and  processes  that  contain  reduced  levels  of  VOCs,  which  emit  pollutants  into  the  air.    

VOC  levels  can  be  reduced  during  the  final  sign  or  exhibit  installation  process  or  during  the  manufacturing  process.    

Materials  that  require  harmful  chemicals  during  fabrication  or  installation  should  have  extensive  specifications  in  place  dictating  the  appropriate  disposal  of  chemicals.  

New powder-coating techniques and paints achieve low-VOC standards with minimal paint use.

Coraflon  by  PPG  is  an  example  of  a  no-­‐VOC  coating  used  in  architectural  and  sign  applications,  such  as  those  at  the  William  J.  Clinton  Presidential  Library.    

Air  &  Environmental  Quality  

Education  &  Interpretation  

Many  LEED-­‐rated  projects  include  an  interpretive  exhibit  communicating  the  green  aspects  of  the  project.    

EGD  may  be  a  small  part  of  the  building  process,  but  an  interpretive  exhibit  on  the  sustainable  processes  and  materials  used  provides  a  big  opportunity  for  environmental  graphic  designers.  

Education  &  Interpretation  

The  sustainable  aspects  of  a  project  are  often  not  immediately  apparent  to  the  average  user.    

Providing  an  interpretive  exhibit  or  educational  signs  and  materials  that  outline  the  green  aspects  of  the  project  not  only  serves  as  a  record  of  accomplishment,  it  also  provides  an  advocacy  model  for  designers  and  manufacturers  who  want  to  advance  specific  technologies  and  methodologies.  

Education  &  Interpretation  

One  LEED  Innovation  Design  point  can  be  earned  for  providing  interpretive  or  educational  content  describing  how  the  project  serves  the  environment.    

Education  &  Interpretation  

Many  building  owners  and  clients  want  to  exploit  the  attention  they  receive  for  backing  a  green  building  approach,  and  green  educational  program  requirements  are  written  into  more  and  more  RFPs.  

Cost  Issues  In  many  cases,  environmental  graphics  do  not  play  a  significant  part  in  the  overall  material  use  in  most  buildings.  

However,  EGD  elements  and  systems  are  very  visible  to  the  public,  providing  direction,  information,  branding,  and  education.  

Photo  courtesy  of  Acorn  Sign  Graphics,  Richmond  VA  

Cost  Issues  

Most  designers  are  not  aware  of  the  manufacturing  processes  involved  in  the  development,  fabrication,  and  shipment  of  signs  and  other  EGD  components.  

Recyclability/Modularity  Using  modular  products  and  services  can  lower  the  impact  of  a  project  on  the  environment  and  the  budget.  Mechanical  elements  that  allow  signs  to  be  more  easily  changed  and  broken  down  into  their  component  parts  simplify  recycling.  

Recyclability/Modularity  Project  information:  Cannon  Wright  Blount  Application:  Signage  Industry:  Corporate  Location:  Memphis,  TN  Designer:  Helen  Bach                                        The  Crump  Firm  

Case  Study  

Case  Study  –  Green  Building  Practices  

Reclaimed  Materials  

Case  Study    Elwood  Thompsons      Natural  Foods  Grocery      Richmond,  VA  

Photo  courtesy  of  Acorn  Sign  Graphics  

Case  Study  –  Green  Building  Practices  

Reclaimed  Materials  

Clients  philosophy  was  to  be  as  sustainable  as  possible  throughout  the  business—their  products  and  their  built  environment.  The  design  challenge  was  to  make  a  modern  store  feel  like  a  farmer’s  market.  

Photo  courtesy  of  Acorn  Sign  Graphics  

Case  Study  –  Green  Building  Practices  

Reclaimed  Materials  

The  fabricator  worked  with  the  owner/architect  to  redesign  all  their  interior  and  exterior  signage.      

Notice  the  frame  system  holding  the  point  of  purchase  produce  signs  running  along  the  walls.  

Photo  courtesy  of  Acorn  Sign  Graphics  

Case  Study  –  Green  Building  Practices  

       Reclaimed  Materials  

       The  structure  is  fabricated  from  steel              rebar  reclaimed  from  a  locally  sourced  large              construction  site  in  Richmond.  The  fabricator              had  the  rebar  powder  coated  clear  to              contain  the  rusting  and  prevent  rust  from              contaminating  the  produce  or  the  hanging              signage  while  allowing  natural  rust  as  a              design  element   Photo  courtesy  of  Acorn  Sign  Graphics  

Case  Study  –  Green  Building  Practices  

     Reclaimed  Materials  

The  system  uses  mechanical  fastenings.  

       The  hanging  clips  are  anodized            aluminum  carabineers,  making  it            possible  for  the  market  to  easily            add  to  or  reduce  the  number  of  signs.    

Photo  courtesy  of  Acorn  Sign  Graphics  

Case  Study  –  Green  Building  Practices  

       Reclaimed  Materials  

The  sign  holders  are  custom  fabricated  from  clear  PETG  (recyclable  material),  heat  bent  to  form  the  sandwich  to  hold  each  sign  insert.  This  gives  the  store  complete  flexibility  to  make  their  own  changeable  8.5x11  (recycled)  paper  inserts. Photo  courtesy  of  Acorn  Sign  Graphics  

Case  Study  –  Green  Building  Practices  

Reclaimed  Materials  

This  last  photo  example  is  a  table  fabricated  for  the  site  from  recycled  highway  signs.  

The  net  result  -­‐  a  great  design  that  incorporated  reclaimed  material,  recyclable  material  (all  parts),  mechanical  fasteners,  durable  construction  and    modularity.    

Photo  courtesy  of  Acorn  Sign  Graphics  

Case  Study  –  Green  Building  Practices  

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Reclaimed  Materials  

Case  Study    Virginia  Association  of  Countries      Building  re-­‐model  which  achieved  LEED  Gold  Certification.      Richmond,  VA  

Case  Study  –  Green  Building  Practices  

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         Challenge:              Create  a  cohesive  system  of  signs  

using  sustainable  materials  which  might  contribute  to  an  Innovation  in  Design  credit  in  the  quest  for  LEED  certification.  Speak  to  both  the  old  and  the  new,  while  being  as  "green"  as  possible.  

Case  Study  –  Green  Building  Practices  

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         Deliverable:              Design,  produce  and  install  a  prominent  

lobby  installation  to  orient  visitors  to  the  green  features  of  the  renovation,  as  well  as  LEED  educational  signs  throughout  the  building  and  on  the  roof  garden  to  highlight  sustainable  practices.  Also  include  room  identification,  wayfinding  and  historic  and  LEED  plaques.  

In  this  case  study,  the  fabricator  developed  a  series  of  eco-­‐friendly  sign  systems.  The  series  was  designed  with  the  following  principles  in  mind:  

•   Modular  components  •   Eco-­‐friendly  substrates  •   Recyclable  content  and  components  •   Minimum  use  of  adhesive  and  paints  

Case  Study  –  Environmental  Signage  

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• Plyboo™  for  the  bamboo  back  plates  • FSC  certification  for  their  sustainable            moso  (timber  bamboo)  forests  • low  or  no  urea  formaldehyde        (UF)-­‐free  manufacturing  process  • applicable  LEED  credit  categories    

–   EQ  4.4  Low  emitting  materials    –  (no  added  urea  formaldehyde)  –   MR  6-­‐Rapidly  renewable  –   MR7-­‐FSC  Certified  Wood  

Case  Study  –  Environmental  Signage  

• Aluminum  was  chosen  for  the  mechanical  fastening  for  the  system,  as  it  is  durable,  recyclable  and  a  key  to  the  modularity  component  of  the  system.  • The  anodized  aluminum  standoffs  are  custom  fabricated  from  a  locally  sourced  vendor.  This  allows  a  more  cost  effective  approach,  and  reduces  transportation  cost  and  the  carbon  footprint  of  shipping.  • While  this  example  depicts  use  of  certain  materials  and  a  look  designed  for  a  specific  application,  it  is  the  methodology  used  to  create  this  sign  system  that  is  the  key  to  environmentally  conscious  design  practices.  

Case  Study  –  Environmental  Signage  

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Over  the  lifespan  of  a  building,  there  are  typically  multiple  design  changes  to  the  building’s  interior  elements  and  signage.    This  sign  system  was  designed  with  components  that  meet  the  typical  design  life  cycle.    

NovAcryl-­‐®ECR™  photopolymer  panels  were  used  to  create  the  tactile  portion  of  the  sign,  which  has  a  lifespan  of  5-­‐10  years.    

All  other  components,  including  the  mounting  system,  aluminum  pucks/strips,  and  bamboo  back  plate,  meet  or  exceed  the  5-­‐10  year  life  cycle.  

Case  Study  –  Environmental  Signage  

This  sign  system  incorporates  materials  that  do  not  outgas  high  levels  of  VOC  once  installed  in  an  interior.    Color  is  applied  to  the  tactile  images  with  low-­‐VOC  heat  transfer  foil.  No  adhesives  are  used.  

Case  Study  –  Environmental  Signage  

The  amount  of  waste  produced  in  the  fabrication  of  the  sign  system  and  its  components,  including  the  photopolymer  panel,  is  minimal.  The  effluent  from  the  photopolymer  is  100  percent  biodegradable.    

Case  Study  –  Environmental  Signage  

Summary    

• Low-­‐impact  materials:  choose  non-­‐toxic,  sustainably-­‐produced  or  recycled  materials  which  require  little  energy  to  process.    

• Energy  efficiency:  use  manufacturing  processes,  methodologies  and  materials  which  require  less  energy.    

Summary    • Quality  and  durability:  longer-­‐lasting  and  better-­‐functioning  products  will  have  to  be  replaced  less  frequently,  reducing  energy  and  cost  in  the  complete  process.  

• Design  for  reuse  and  recycling:  Products,  processes,  and  systems  should  be  designed  for  performance  in  a  commercial  afterlife.  

Challenges  

There  are  challenges  associated  with  developing  environmentally  responsible  sign  solutions.  The  sign  industry  is  one  that  is  steeped  in  the  use  of  traditional  materials  that  are  not  always  the  most  responsible  materials  to  use  on  a  sustainable  project.  For  example,  all  bamboo  is  not  created  equal  –  questions  to  ask  are  where  and  how  was  it  harvested?  

Challenges  

Another  challenge  is  reducing  the  use  of  adhesives  while  designing  ways  to  combine  components  and  then  securely  mount  the  system  to  the  walls.    

For  Example:  Can  the  project  be  designed  with  modularity  in  mind,  using  magnetic  mountings  instead  of  adhesives?  

Conclusion  

                           Think  Different!  While  there  will  always  be  challenges  on  any  project,  designing  a  project  that  is  Environmentally  Responsible  and  Sustainable  sometimes  offers  unique  “opportunities”.  

Conclusion  

Your  best  path  for  an  end  product  that  meets  everyone's  goals  is  to  work  with  a  fabricator  that  has  experience  working  hand  in  hand  with  design  firms  to  balance  client  needs  with  materials  &  methodologies  that  will  prove  beneficial  today  and  in  the    

future.  

End  of  AIA  CES  Program  

Course  Number:  02SEGD  

Course  Title:    

Sustainability  in  Environmental  Graphic  Design  

Course  Sponsor  Acorn  Sign  Graphics  4109  West  Clay  Street  Richmond,  VA  23230  Phone:  800-­‐770-­‐4744  E-­‐mail:  info@acornsign.com  Web:  www.acornsign.com  

This  concludes  The  American  Institute  of  Architects  Continuing  Education  Systems  Program