CAPABILITY STATEMENT Consultancy Services within Offshore Wind Energy

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CONTENTS

1. Introduction 2 2. The ramboll group 2 3. Ramboll offshore wind 2 4. Consultancy services 2 4.1 Project Development 2 4.2 Permitting, Approval and Project Certification 4 4.3 Site Investigations and Site Assessments 4 4.4 Wind Turbine Technology 5 4.5 Design Services 6 4.5.1 Design of Foundations for Wind Turbines 6 4.5.2 Design of Transformer Platforms 7 4.5.3 Design of Electrical Infrastructure 7 4.5.4 Design for Decommissioning 8 4.6 Design Risk Assessments 8 4.7 Project Enquiry and Contracting 8 4.8 Fabrication Supervision 8 4.9 Construction Management and Supervision 8 Supplements

Supplement 1 Selected project references

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1. INTRODUCTION

To design, construct, operate and maintain an offshore wind farm located in a harsh environment, and often far from shore, requires a multitude of skills and experiences, and represents management of many interfaces and risks, to be identified, considered and managed years before they become concrete. By investing in the necessary investigations, and engineering and design exercises at the "right" point in time for the actual project, many resources and much money can be saved throughout the lifetime of a project providing an overall minimum lifetime cost. Ramboll Offshore Wind strives to engage in - and to perform such services.

2. THE RAMBOLL GROUP

The Ramboll Group is amongst the leading consultancy groups on a European level. From the establishment in 1945 we are now a little than 9,000 employees in 190 permanent offices in 24 countries. The Ramboll Group is an independent and multidisciplinary consulting group offering primarily engineering and design services, but is also engaged in architecture, management consultancy, socioeconomics and other related services. The Ramboll Group is owned by a foundation and is independent of external interests.

3. RAMBOLL OFFSHORE WIND

Ramboll Offshore Wind (ROW) has been engaged in onshore wind projects designing turbine towers and foundations since 1986, and has been involved in offshore wind projects since 1989 participating in the design of the first Danish test project at Vindeby. Today ROW operates as a division within Ramboll Energy and has existing offices in Copenhagen and Esbjerg in Denmark, and in London in the UK. ROW opens an office in Hamburg in Germany in Q2 of 2011, and in New Jersey in USA in Q3 of 2011. Currently ROW employs more than 70 permanent staff, and draw on additionally 35 full time staff from other disciplines in the Ramboll Group, such as environmental impact assessments, geotechnology, risk analysis, electrical design, design of larger transformer platforms, and supervision of manufacturing. In addition to our own permanent staff ROW draws on the competencies, resources and staff of our many offices, and thereby, ensures that we also consider best local practice and local legislation.

4. CONSULTANCY SERVICES

As a multidisciplinary consulting firm and with more than 25 years of experience within planning of energy projects and design of offshore oil & gas structures, and with 65 years of experiences with design of large infrastructure projects we are in a very good position to offer a huge variety of consulting services within offshore wind, as follows.

4.1 Project Development Energy Planning As part of the Energy Unit in Ramboll we perform overall planning of energy supply of local - and of regional areas, and work with optimising the mix of energy sources to provide the best possible solutions with respect to efficiency, local resources, cost of energy and to the environment. As part of these studies we work with, amongst others, storage of surplus energy produced by wind farms, and with energy carriers other than the traditional consumption.

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Trade and Transmission of Electricity As an extension of the work with energy planning we perform studies concerning trade and transmission of electricity to enable our clients to decide market strategies for the trading of the produced electricity. These studies look into available market opportunities and price forecasts for the respective markets. Technical and Financial Risk Analysis and Management To assist our clients in identifying and to manage and mitigate technical and financial risks associated with offshore wind projects we perform technical and financial risk assessments, with respect to costs, income and time. In such a risk assessment we define, in close cooperation with the client, the various risk elements we estimate the probability of the occurrences and estimate the consequences. All this information is then inserted into a Monte Carlo simulation giving e.g. project costs or net present value of the entire project as a function of the probability. Delays of the time schedule for the project can either be modelled directly, or a more simple approach capitalizing delays can be applied by estimating the loss of revenue. Navigational Risk Analysis For input to the permitting phase and to the service life phase of the projects we estimate the risk of vessels entering into the project area and colliding with wind turbines or transformer platforms. The potential consequences of a vessel entering into the project area are several: collisions with installation vessels, spillage of e.g. oil, damages to the hull of the vessel, loss of wind turbines because of structural collapse or damages to or collapse of the transformer platform. The consequences of the various collisions are varying from everything to small damages to vessels or structures and up to temporary shutdown of the electricity production for a year or two because of loss of the transformer platform. In the latter case we use the navigational risk analysis to estimate the probability of a collision for various ship sizes, and thereby the structural loads to be considered in the design of the transformer platform. Scheduling and Planning Development, permitting and implementing an offshore wind project may easily take 5 to 8 years and needs proper planning and scheduling to ensure that information is available when required, and that physical elements, e.g. long lead items, have been designed and ordered in due time. Therefore, it is important that a proper time schedule is established at an early stage and maintained throughout the various project stages. Such a time schedule should contain all dependencies to be able to assess impacts from variations to the planning. As a multi disciplinary firm we are capable of establishing such time schedules including all elements of the projects, and we are, further, capable of applying the results from the technical and financial risk assessment into these schedules. Wind Studies We are currently capable of performing wind studies and production estimates for wind farms applying more simplified software sufficient for early feasibility studies estimating potential income and expenses for the new projects. We are further capable of assessing wind measurements with respect to statistical validity compared to long term measurements from other stations. For performance of more detailed wind studies and micro siting, where it is a requirement to be considered bankable, we would usually contract a sub consultant, but still act as a single point of contact. Feasibility Studies, Due Diligence and Project Budgets We perform feasibility studies and due diligence for assessment of projects from early stages of the projects and up to where projects may be traded after implementation and start of service. The degree of detailing will depend on the amount of information available, or whether we are able to locate information ourselves. In connection with these studies we usually breakdown the projects into smaller cost – and income elements to better be capable of estimating the variability/uncertainty of each element. If more factual information is available we can also model the feasibility of a project by the technical and financial risk assessment. Turbine Foundation Budgets

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Based on our vast experience within turbine foundation design and on the large number of designs we have performed we have developed an in-house Foundation Budget Tool to be used for cost estimation and investigation of cost variability in feasibility studies. In the budget tool we are capable of varying: wind turbine size and type, foundation concept, ground conditions, water depth, wave size, ice/no ice, weather down time during installation, and to consider variations in water depth over an entire project. The output from the budget tool is material quantities and costs broken down into design, investigations, fabrication, installation, risk, insurance and profit. When tested against competitive pricing from real projects we have usually been within an uncertainty of +/- 10% to 15%.

4.2 Permitting, Approval and Project Certification Environmental Impact Studies and Assessments Most countries require performance of an environmental impact assessment, EIA, and delivery of an environmental impact statement, EIS, in which the various impacts on the environment are investigated, estimated and reported. The EIS includes a number of investigations of the flora and fauna on the project site, and considers the impacts on the flora, the fauna, and on the human population as well. As a multi disciplinary consultant we are capable of performing all the investigations and to assess the impacts from the project both during the implementation as well as during the service life and finally the decommissioning, as we do have in-depth knowledge of all the designs and the processes. We further perform the follow-up monitoring of impacts to document fulfilment of the requirements. BSH Approval In Germany the authority BSH is involved in the permitting process in addition to the environmental authorities and to the certifying bodies performing the project specific certification. Via our performance of German projects and our dealings with the BSH we are well suited and experienced in communicating with - and obtaining approvals from the BSH. Project Certification Most projects require a project certification in order to have them approved by the financial community, the insurers or if they are to be sold off at a later stage. As of March 2011 we have performed detailed foundation design and obtained certification of 21 offshore wind projects, which constitutes more than half the existing projects Worldwide, and are, therefore, very experienced in dealing with the independent certifying bodies, such as DNV, Germanische Lloyd and SGS.

4.3 Site Investigations and Site Assessments Geophysical Investigations Geophysical investigations are used for a relatively fast mapping of the seabed contours, bathymetry, and of the foundation soil layers usually involved in the support of the foundation structures for the wind turbines and the transformer platforms. The geophysical investigations are also applied in connection with the mapping for the environmental impact assessment, EIA, and for studies of seabed sediment movements as travelling sand dunes. We are in a position to offer these services performed by our own staff, or to specify, contract and supervise the work on behalf of the client. From being multi disciplinary we are capable of considering all aspects to be investigated in defining the scope for these investigations: environmental investigations as well as early investigations for determination of the foundation structures, and thereby, achieve an optimized survey program. Geotechnical Investigations In order to properly assess the strength of the foundation soil for the design of the structures for the wind turbines and the transformer platforms, and to properly estimate excavation works for the cables, and finally to evaluate issues concerning the installation works geotechnical investigations are performed using drilling of boreholes and measurements such as cone penetration tests, CPT tests. From many years of experience within offshore soil mechanics we

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are well positioned to specify, contract, supervise and interpret such investigations and laboratory tests. Metocean Studies and Reports Metocean data in the form of long-term information concerning wind and waves, and their respective correlation with the wind, is of importance to the structural design, and when assessing access and constructional conditions with respect to sea states. This metocean data can be made available by numerical modelling or measurements by a buoy, or in a combination thereof. For conceptual - and for FEED design foundation studies a numerical model will suffice in every respect. For detailed foundation designs for construction, it is best to apply verified long-term data to calibrate the numerical model, to achieve the best possible accuracy and for not to be too conservative in the design. In case verified data is readily available, this data can be used to calibrate the model without further measurements. In case this data is not available, measurements will have to be made to support the numerical model. We operate our own numerical models, the MIKE suite of programs, to be capable of developing basis for design and for evaluation of sea states for constructional and access purposes. Local – and Global Scour and Erosion Installation of structures and cables in the seabed changes the flow regime for the sea water and may course local erosion around the structures and the cables by removal of seabed material, depending on the type of seabed sediments. As the seabed forms the support of the structures and the cables, it is important to either prevent this erosion by deploying stones or to estimate the extent of the erosion, so that it can be considered in the design. We usually design for both situations to be able to make a cost benefit analysis to investigate which of the two options is the most cost optimal. This investigation will also consider probable future cost of inspecting and maintaining the erosion protection. In detailed foundation designs we will usually perform such an investigation for each individual wind turbine foundation and structure, to achieve an overall optimisation of the cost.

4.4 Wind Turbine Technology Functional and Technical Specifications The choice of wind turbine is not trivial, as it is impacted by many different factors such as: "proven technology", performance under certain conditions such as average wind, cut-in/cut-out wind speeds, early production for lower wind speeds, requirements to operation and maintenance and organisation to perform the O&M, interaction with the public grid etc. ROW has established such functional and technical requirements for several projects, and incorporated these into project enquiries and into contracts. O&M Requirements and Monitoring As part of the definition of the functional and technical requirements we define the requirements to the operation and maintenance of the wind turbines. We also deliver requirements into to the O&M procedures for the structures, erosion protection and cabling. Following the implementation of an offshore wind project we can either perform inspections ourselves, or we can monitor the performance by others. Test and Commissioning When involved on the developer side of the projects we act on behalf of the developer during the test and commissioning, and the handing over of the projects, to ensure that the project fulfils the contractual requirements, and that this is properly documented. Cold Climate Conditions Cold climate conditions for the wind turbines are often associated with onshore wind farms locate in cold climate areas, and not with offshore projects. However, the increasing interest in developing offshore wind farms in the north eastern Baltic area, and in the Great Lakes in USA and Canada, means that there is now a requirement for considering these climatic conditions when defining the technical and the functional requirements. From our previous experiences in the northern Nordic regions we have experiences in establishing such requirements and in reviewing the proposed solutions concerning the wind turbines.

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4.5 Design Services

From being a multidisciplinary consultant and design firm we are capable of designing most objects and to consider many different impacts on the structures to be designed. We are further capable of designing for a multitude of materials and according to many different codes and standards, such as e.g. Euro Code, API, ABS, ASTM, DIN and ISO. We are one of the very few designers having vast experiences within both offshore oil and gas and within offshore wind.

4.5.1 Design of Foundations for Wind Turbines Ramboll is currently one of the leading consultants within design of foundations for offshore wind turbines, and have a profound experience within design of jackets for, amongst others, transformer platforms. We apply state-of-the-art in-house software for the designs. Our capabilities originally stems from more than 30 years of experience within the offshore oil & gas industry, but has within the last 15 years also been developed to include offshore wind energy, and the many issues applicable to design of offshore wind turbine foundations only. Our references include design of foundations for megawatt type turbines for offshore projects in:

Denmark Sweden Ireland UK Germany Holland Belgium France USA The Philippines and Russia.

We have performed conceptual and tender designs for developers, turbine manufacturers and foundation contractors. The foundation concepts have included gravity base structures of both steel and concrete, monopiles, tripod - and jacket foundations, and suction buckets. Ramboll has carried out detailed design of 35 offshore jackets in Denmark, Qatar and Germany in waters varying from 10 to 65 meters depth. Ramboll has further carried out numerous conceptual studies for jackets for a long list of clients. We have completed detailed design of monopile foundations and for gravity concrete cones for 20 Offshore Wind Farms, all approved by a third party certification agency. (DNV or GL). A list of the designs we have or are currently carrying out is shown below.

Location

Status

Loc.

Park Size

[MW]

Turbine

Water Depth

[m LAT]

Client

Developer

Klasarden On Hold SE

44 NM92 4-8 PNB Entreprenad NEG Micon

Burbo Bank Completed UK 90

SWP-3.6-107 2-8 MTH DONG

Lynn & I. Dowsing

Completed UK 194,4

SWP-3.6-107 8-12 MTH Centrica

Kentish Flats Completed UK 90 Vestas V90 5-8 MTH Vattenfall Robin Rigg Completed UK 180 Vestas V90 13 MTH Eon C&R Rhyl Flats Completed UK

90 SWP-3.6-

107 4-12 MTH RWE

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Nordergrunde On-going DE 90 RePower 5M 15 Energiekontor Energiekontor Greater Gabbard

U. Constr. UK 504

SWP-3.6-107 22-31 Fluor SSE & RWE

Thanet U. Constr. UK 300 Vestas V90 20-30 Vattenfall Vattenfall Bligh Bank U. Constr. BE 165 Vestas V90 16-31 Van Oord Belwind Sheringham Shoal

U. Constr. UK 316,8

SWP-3.6-107 15-22 MTH Statoil

Walney U. Constr. UK 183,6

SWP-3.6-107 20-22 DONG DONG

Walney II On-going UK 183,6

SWP-3.6-120 22-30 DONG DONG

Lincs On-going UK 284,4

SWP-3.6-120 8-16 MTH Centrica

Gwynt Y Môr On-going UK 576

SWP-3.6-107 13-30 RWE RWE

Gwynt Y Môr II

On-going UK 576

SWP-3.6-120 13-30 RWE RWE

Anholt On-going DK 400

SWP-3.6-120 14-18 DONG DONG

Teeside On-going UK 90

SWP-2.3-101 8-15 EDF EDF

Amrumbank On-Going DE 80

SWP-3.6-120 19-24 E.On E.On

Sandbank 24 On-Going DE 288

Vestas V 112 20-35

Sandbank Power

Sandbank Power

For all of the above projects we have been the designers of both primary and secondary steel and liaised with the wind turbine manufacturer and certification agencies as necessary. The number of jacket projects that Ramboll has carried out has provided us with extensive expertise and experience with the requirements of the certifying agencies, installation contractors and marine warranty surveyors. Ramboll is the only company in the world that has carried out detailed design of 20 twenty offshore wind farms for five different turbines, including Vestas V90, Vestas V112, Siemens SWP-36-107, Siemens SWP-36-120 and Repower 5MW, and we are currently the only design firm capable of performing load iterations with the turbine manufacturers. Hence we offer unprecedented experience in the design process.

4.5.2 Design of Transformer Platforms Based on our design experiences within both offshore oil and gas structures, and within offshore wind projects we perform design of transformer platforms of sizes from the marginal platforms holding two decks and placed on a steel monopole, to real steel jackets or concrete gravity base structures holding multi storey topsides with modules, helipads and accommodation quarters. We always aim at finding the optimal solution. Especially our experience within design of oil and gas structures is important for our work with the larger size transformer platforms, as we are very experienced within the safety philosophies, all the mechanical and electrical equipment, and all issues about arrangement of decks and J-tubes.

4.5.3 Design of Electrical Infrastructure We design the electrical infrastructure within the wind farm, including collection system, transformers and export cable, up to and including conceptual design level, where the results can be used for budgeting of the infrastructure, and as input to the environmental impact assessment. In case of performance of detailed designs we contract sub-consultants and still acts as one-point contact towards the client. Based on our large experience with design and laying of offshore pipelines and cables we perform design and consultancy concerning installation and protection of cables, and are also capable of performing supervision and inspection of these project elements.

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4.5.4 Design for Decommissioning The permits granted by the authorities contain, for most projects, a requirement for decommissioning of the entire project upon the end of the service life. The cost of decommissioning of a project is in most cases equal to, at least, the installation costs, so this requires careful consideration in the design phase in order to minimize the costs. From our close cooperation with fabricators and installation contractors, we have good experience in designing the structures for both construction and for decommissioning, and have a good knowledge of impacts from the choice of various materials.

4.6 Design Risk Assessments Considering the harsh environment the wind turbines are installed and located in, where weather, sea state and access conditions is often a challenge a safe working environment is important for the staff. Some countries have their own set of rules for Health & Safety, but the basic rules are, in most cases, all based on the rules from the oil and gas industry, amongst others the UK CDM Regulations. From our long experience with design of both oil and gas structures and offshore wind structures awe have developed our own best practice, and included this in our in-house tool for performance of design risks, Soter. We further perform the design risk assessments using our full 3D models of the access facilities, platforms and other places accessed by people.

4.7 Project Enquiry and Contracting Based on our many different experiences in offshore wind projects we have drafted full enquiry documents and performed pre-qualification of tenderers and tender evaluations. The tenders have concerned anything from geophysical – and geotechnical investigations, to turbine supply contracts and full turnkey contracts for complete offshore wind farms. We are capable of handling both the general conditions of contract as well as the special conditions and technical requirements.

4.8 Fabrication Supervision We perform supervision of fabrication of elements for the projects. The supervision can be constituted of review of method statements for fabrication, review of quality control plans and standards, check and monitoring of fabrication and quality audits of the manufacturers. Our supervision is not a substitute for any certifying agencies monitoring of the fabrication, but can assist the client in the everyday management of the project.

4.9 Construction Management and Supervision We are capable of contributing with engineering and design services to all phases of the construction work: Design of sea fastening and lifting arrangements Inspection of structural elements upon transportation Supervision and monitoring of installation of structures and cables Design changes during installation works Elaboration of as-built documentation Contact: Søren Juel Petersen Director Business Development sjp@ramboll.com +45 5161 8760

Henrik Carstens Director Projects and Technology hec@ramboll.com +45 5161 7124

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SUPPLEMENT 1 SELECTED PROJECT REFERENCES

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