A New Paradigm of Energy Efficiency,

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• A New Paradigm of Energy Efficiency,
• Energy Recovery and Financial Benefits
• for the Heating and Cooling Marketplace

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ENERGY RECOVERY BACKGROUND

• Incorporated March 4, 2008.
• Bringing established technology to the North
  American market.
• The Captive Energy product line.
• Provides air conditioning, space heating, and
  domestic hot water through heat recovery.
• Working together with IMW Industries to
  manufacture our technology

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WHAT WE DO

• We are introducing technology to the North
  American market place a new product line of
  energy efficiency equipment for the heating and
  air-conditioning world.
• We offer technology that significantly improves
  industrial process efficiency, reduce costs,
  while maintaining the integrity of the
  surrounding environment.
• Our products deliver dramatic, defensible
  improvements to the profitability of the major
  products and consumers of energy.

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OUR TECHNOLOGY

• A paradigm shift in methodology regarding energy
  conservation technology for the heating and
  cooling industry.
• Ground breaking technology that is disruptive to
  legacy heating and cooling systems.
• Integrated heating and cooling design
  architecture enables one function such as heating
  to be provided as a no-cost by-product while the
  other function (cooling) operates with high
  efficiency.
• Significant reductions in capital expenditures
  compared to legacy equipment (boilers and
  chillers). This is further met with significant
  reductions in direct energy and operating costs
  compared to legacy equipment.
• Scaleable design allowing for wide uses within
  the commercial, industrial and residential
  markets employing high quality construction with
  fully certified parts and sub-systems.

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CURRENT TECHNOLOGYON THE MARKET CHILLERS
The Conventional Chiller System
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CURRENT TECHNOLOGYON THE MARKET BOILERS
Schematic Of The Conventional Boiler
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THE PROBLEM

• Millions of BTUs of heat are rejected through
  cooling towers of a water cooled Chiller system,
  while millions of BTUs of fossil fuels are
  burned in a boiler to generate heat.
• A hotel running a 400-ton Chiller continuously,
  will generate 50 billion BTUs of heat each year.
  
• Reclaiming this heat and using it to heat the
  building or the domestic hot water turns an
  unused resource into a valuable one.
• Boilers are limited in the level of efficiency
  they can achieve. The major loss in a boiler is
  the loss of heat up the flue.
• CO2 emissions are a major concern.

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THE SOLUTION HEAT RECOVERY

• What is Heat Recovery?
• DEFINITION Heat Recovery captures waste heat
  energy and reuses it by returning it to systems
  or processes.
• The heat extracted by the chillers is waste heat
  because it is warm but not hot enough to be used
• Heat recovery uses a small amount of electrical
  energy to extract heat from the warm waste water
  and move it to useful hot water
• Heat recovery systems are an ideal application
  where the use of air-conditioning and hot water
  are required simultaneously.

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THE SOLUTION HEAT RECOVERY

• Why Heat Recovery?
• Heat recovery taps a readily available and
  inexpensive energy source. As todays buildings
  work to reduce costs and increase energy
  efficiency, the use of condenser water as a
  heating resource is rarely exploited.
• A boiler releases the energy stored in the fossil
  fuel, at best 100 of the energy would end up in
  the hot water but some heat is always lost in the
  flue gases.
• Instead heat recovery uses a small fraction of
  the energy required by the boiler to move
  existing heat to a higher temperature where it is
  useful.

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ENERGY RECOVERYS OFFERING
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ENERGY RECOVERYS OFFERING

• Heat Recovery Water Heaters
• Designed to use waste heat created from
  simultaneous cooling loads to satisfy heating
  loads in a building
• Hot condenser water is used as the heat source
• Waste heat energy can be used to satisfy a
  buildings potable water heating or space heating
  loads up to 140F
• Energy is captured, therefore greatly reducing or
  eliminating the fossil fuel consumption of the
  boiler
• This unit is suitable for new installations and
  as additions to buildings with existing
  water-cooled water chillers
• COPH up to 6.01 (Heating Coefficient of
  Performance) as a stand alone unit. If used in
  conjunction with other recovery methods, this may
  increase the COPH up to 10.01

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ENERGY RECOVERYS OFFERING

• Water Cooled Chiller with Heat Recovery
• Uniquely designed to supply both requirements of
  chilled water and hot water
• Removes heat from a water source and transfers it
  to a space heating water loop or to portable
  water with water temperatures up to 140F
• Capturing waste heat can eliminate the need for
  additional heat supplied by burning fossil fuels
  in a boiler
• Can be designed with a single or dual condenser
  depending on the application

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(PATENT PENDING)
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ENERGY RECOVERYS OFFERING

• Water Cooled Chiller with Heat Recovery Single
  Condenser
• No cooling condenser required
• All heat goes into the heat recovery condenser
• Can be designed to meet 100 of the heating load
• Cooling amount uncontrolled other dedicated
  chillers will match the building load
• Combined COPHR up to 7.51 (heating plus cooling
  Coefficient of Performance)

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(PATENT PENDING)
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ENERGY RECOVERYS OFFERING

• Water Cooled Chiller with Heat Recovery Dual
  Condenser
• Chilling load controlled to match building load
• Heating load divided between heat recovery
  condenser and cooling condenser to match building
  load
• Can be designed to supply free hot water with
  heat recovery capacity up to 30 of chilling
  capacity, in a pre-heating application
• Combined COPHR up to 7.01 (heating plus cooling
  Coefficient of Performance)
• Can be designed to recover 100 of the heating
  load
• Combined COPHR up to 7.51 (heating plus cooling
  Coefficient of Performance)

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ENERGY RECOVERYS OFFERING

• Water Cooled Chiller with Heat Recovery Dual
  Condenser
• Units can operate primarily as either a water
  chiller or as a heat recovery unit
• Operator is able to change the current operating
  mode at any time to best suit the current demands
• When operating as a water chiller the cooling
  load will be satisfied and heat recovery occurs
  with minimal additional power consumption
• When operating as a heat recovery unit the full
  heating load will be satisfied with some
  additional compressor power, however the savings
  in fossil fuel costs more than offset the cost of
  additional electrical power to run the compressor

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ENERGY RECOVERYS OFFERING

• Water Cooled Chillers
• Designed to remove heat from a buildings chilled
  water loop and provide space temperature (air)
  conditioning or dehumidification
• Heat is transferred to the single water-cooled
  condenser during the refrigeration cycle and then
  rejected to the cooling loop
• A buildings cooling loop typically rejects heat
  to the ambient air through a rooftop cooling
  tower
• COPR up to 5.01 (Chilling Coefficient of
  Performance)

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MARKET OPPORTUNITY

• Given rising energy costs and increased
  environmental concerns, there has been a real
  transition in the market towards green
  buildings. Green buildings focus on resource
  efficiency, lifecycle effects and building
  performance. Smart technologies which are geared
  towards reducing lifetime maintenance costs and
  overall life cycle costs are a key part of the
  green building initiative.
• Buildings with energy efficient equipment have
  increased sales values due to lower operating
  margins and higher CAP rates.
• According to industry experts, efficiently
  recycling waste energy could reduce carbon
  dioxide emissions from service water heating by
  10-20 and provide savings of up to US70
  billion.

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MARKET OVERVIEW

• HVAC market forecast to grow at 3.2 per year to
  reach US16.8 billion in 2011.
• Commercial / Industrial market estimated at
  US8.0 billion
• HVAC accounts for 40 - 60 of energy used in
  U.S. Commercial and residential buildings.
• Mature market.
• Maintenance, including energy consumption can
  account for 80 of the cost of a building over
  its lifetime (including construction costs),
  accordingly, smart technologies can reduce
  operating costs and have a discernable effect on
  the return on investment of a building.

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MARKET TRENDS

• Advances in HVAC equipment sales expected to be
  primarily driven by strong gains in
  non-residential construction.
• Nearly three quarters of HVAC demand is
  attributable to replacements.
• Replacement sector to benefit from rising
  interest in more energy efficient building
  systems.
• Driven by rising energy prices.
• Spurring the replacement of older HVAC equipment
  with newer models.
• Changing regulations regarding minimum efficiency
  requirements for legacy systems will also affect
  sales of HVAC equipment.

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WHAT MAKES ENERGY RECOVERYS TECHNOLOGY DIFFERENT?

• One system serving multiple purposes heating,
  air conditioning hot water production.
• Emerging technology to North America.
• Space efficient
• Multi-function systems occupy less space than
  separate systems performing same functions.
• Energy efficient.
• Lower acquisition costs than separate individual
  legacy units.

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OUR COMPETITIVE ADVANTAGE

• Cost efficient.
• Units perform up to 3 functions (heating, air
  conditioning, hot water production) at no
  additional cost.
• 22 month payback.
• Streamlined company
• Quickly adapt to changing market conditions.
• Experienced management team with proven track
  record.

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CAPITAL STRUCTURE
Senior Management
External Shareholders
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75
ERSI 35,925,861 Common SharesIssued and
Outstanding
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WHY INVEST?

• Management
• We believe that PEOPLE ultimately bring value to
  a compelling idea/plan or technology. To that
  end, we have assembled a team experienced in
  building companies in the HVAC and renewable
  energy industries. We have partnered with a
  highly sophisticated manufacturing plant in
  Chilliwack, British Columbia IMW Industries a
  leading supplier of Natural Gas Compressors who
  have been in business since 1912.
• Clear Strategy and Business Model
• We have a clear and focused strategy and a
  business model that will optimize the long term
  value of our product offering. In addition, we
  are positioning the company so as to maintain a
  clear exit strategy for our investors.
• Competitive Advantage
• Our technology and product offering will have a
  sustainable advantage with our proprietary and
  patented technology.
• Large and Growing Markets
• Our target market is a well established industry
  where we will provide a compelling solution to
  the well documented need for energy efficiency,
  energy conservation and environmental solutions.
• HVAC market forecast to grow at 3.2 per year to
  reach US16.8 billion in 2011.
• Commercial / Industrial market estimated at
  US8.0 billion.

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ABOUT ERS

• Aniello Manzo - President, Chief Operations
  Officer, Director and Co-Founder
• A senior professional within the HVAC Industry,
  Mr. Manzos career spans more than 20 years in
  various and progressive roles including
  operations, inspection, design, international
  commerce and executive leadership. Prior to
  managing the growth of Energy Recovery Systems,
  he owned and operated a multi-million dollar HVAC
  design and operations firm with clients
  throughout North America. Aniello's functions
  within ERS consist of working in conjunction with
  the CEO as Co-Founder and Developer. Aniello is
  one of the Directors within ERS. Moreover Mr.
  Manzo formulates all the technical aspects of the
  company. As sole inventor of ERS' system design
  and integration (patents pending) Aniello has
  taken the conventional cooling chiller and
  engineered and designed the energy recovery unit
  to reduce the use of carbon fossil fuels. He
  continues to work closely with Professional
  Engineers to further research and develop this
  concept to share with the HVAC industry.
• Jeff Ciachurski - Chief Executive Officer,
  Director and Co-Founder
• Jeff Ciachurski is a business executive and has
  founded several public companies over the past 25
  years. He is the founder and current Chief
  Executive Officer and President of Western Wind
  Energy Corporation, a wind energy generation
  company currently trading on the Toronto Venture
  Exchange. Western Wind is the owner and operator
  of over 500 wind turbines in California.Jeffs
  functions include executive leadership, strategic
  planning, corporate policy, and execution of the
  Companys business and financial plan. He
  formulates the mission statement, corporate
  structure, appoints and designates senior
  management personnel, defines geographic areas of
  responsibility and engages senior independent
  consultants. Maintains continuous and proactive
  relationships with leading institutional and
  retail shareholders, and establishes and
  maintains close contacts within the investment
  banking and project financing community.

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ABOUT ERS

• Heidi Ciachurski - Corporate Secretary
• Heidi Ciachurski is a para-legal with over 20
  years of experience. Heidi provides corporate,
  executive, administrative and regulatory support
  to executive management and board level
  functions.Heidi is well-versed and experienced
  in corporate secretary, financial reporting,
  para-legal and investor relations
  responsibilities of public reporting companies.
• Sean Marte - Chief Technical Engineer
• Sean graduated from the University of British
  Columbia in 2003 with a combined Bachelor of
  Applied Science and Masters of Engineering in
  Electro-Mechanical Design Engineering. Over the
  past 6 years he has worked in product development
  as a design and test engineer for several
  manufacturing companies. His responsibilities
  involved designing, commissioning and operating
  test stands which, were used for testing new
  equipment designs. He is experienced with
  automation, instrumentation, data acquisition
  equipment and industrial design. In 2008 Sean
  completed his registration as a Professional
  Engineer with the Association of Professional
  Engineers and Geoscientists of British Columbia
  (APEGBC).
• Since joining Energy Recovery Systems Sean's
  experience includes design of ASME rated heat
  exchangers, refrigeration component specification
  and selection, compressor selection and
  validation, system design and optimization. His
  duties with ERS include machine design, system
  integration, design for custom installations,
  test loop design, performance verification and
  writing selection software for the various ERS
  products.

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• Thank you for your time.
• We look forward to continuing
• our discussions with you.
• Aniello Manzo President COO
• Sean Marte Chief Technical Engineer