K060-AAD116E1-A. Head Office Mitsubishi Heavy Industries Head Office Building Konan, Minato-ku, Tokyo, , Japan Phone:

Transcription

1 Head Office Mitsubishi Heavy Industries Head Office Building Konan, Minato-ku, Tokyo, , Japan Phone: Yokohama Building Minatomirai, Nishi-ku, Yokohama-shi, Kanagawa, , Japan Issued November 2016 K060-AAD116E1-A

2 For more than 130 years the MHI Group has been pursuing technological innovations to meet both the opportunities and challenges presented by our world. MHI continues to expand its global footprint, enhance its profitability and corporate governance, and prepare itself for the future investment opportunities that lie ahead. The MHI Group continues to make a lasting difference in the communities we serve. GROUP STATEMENT At Mitsubishi Heavy Industries Group, we channel big thinking into solutions that move the world forward advancing the lives of everyone who shares our planet. By bringing people and ideas together as one, we continue to pave the way to a future of shared success. Passionately finding new, simpler and sustainable ways to power our cities, improve infrastructure, innovate manufacturing and connect people and businesses around the globe with ever-increasing speed and efficiency. This is the power of true harmony. This is what moving the world forward is all about. This is today s Mitsubishi Heavy Industries Group. BUSINESS DOMAINS ENERGY & ENVIRONMENT COMMERCIAL AVIATION & TRANSPORTATION SYSTEMS INTEGRATED DEFENSE & SPACE SYSTEMS MACHINERY, EQUIPMENT & INFRASTRUCTURE

3 ENERGY & ENVIRONMENT DOMAIN STATEMENT Energy makes the world go round. As one of the global leaders in the energy plant industry, we re helping produce the stable and efficient power supply needed to keep it moving. Driven by engineering expertise and technologies in both electricity generation and chemical process plants, we are securing clean, safe and sustainable power sources to communities across the world. Enriching people s everyday lives in order to Move the world forward. While needs may vary, our wide range of products, engineering capacity and continuous R&D provide the flexibility required to meet any and all customer demands. Allowing us to drive growth and prosperity for each society, along with the people who live there. It s a story of success that continues to be written. One that will fuel hope and wellbeing for generations to come. THE CHALLENGE TO GENERATE The MHI Group is a global leader in the energy plant industry, offering optimal solutions in the fi elds of thermal power, nuclear energy and renewable energy. This is underpinned by dynamic and a wide range of products, engineering capacity, and research and development initiatives. Through the group s engineering expertise and technologies, we are providing clean, safe and sustainable power sources for communities across the world, and long into the future. 1 THERMAL POWER GENERATION SYSTEMS Thermal Power Generation Systems PW POWER SYSTEMS, INC. TURBODEN S.R.L. Geothermal Power Generation TURBODEN S.R.L. Fuel Cells 7 NUCLEAR ENERGY SYSTEMS DIVISION Pressurized Water Reactor (PWR) Plants Advanced Reactor Plant Nuclear Fuel Cycle Facilities Nuclear Fuel 13 CHEMICAL PLANTS Chemical Plants ENGINEERING HEADQUARTERS 19 RENEWABLE ENERGY BUSINESS DIVISION Renewable Energy Power Plants MHI VESTAS OFFSHORE WIND A/S Pumps 21 MARINE MACHINERY & ENGINES Marine Machinery & Engines MITSUBISHI HEAVY INDUSTRIES MARINE MACHINERY & ENGINE CO., LTD.

4 Conventional Power Plants (Boiler and Turbine) Conventional boiler- and turbine-driven power plants use a variety of resources such as coal, oil and natural gas as fuel, and there is global demand for these facilities. MHPS has an extensive record in high-efficiency ultra-supercritical pressure boilers with an output of over 1,000 MW. We also have unique technology that enables the efficient burning of lignite (low-grade coal), deemed difficult due to its high water content. On top of this, we lead the world in technology to keep the gas emitted from thermal power plants clean, and are contributing to both the effective utilization of fossil fuels and preservation of the global environment with our high-efficiency thermal-power and environmental technologies. Vattenfall Boxberg Power Plant (Germany) THERMAL POWER GENERATION SYSTEMS Mitsubishi Hitachi Power Systems, Ltd. (MHPS) was jointly established by MHI and Hitachi, Ltd. through the integration of the two parent companies strengths in thermal power generation systems. MHI has further augmented its capabilities in the sector with the strategic acquisitions of Pratt & Whitney Power Systems and its affiliate Turboden S.r.l., specialists in aero-derivative gas turbines and Organic Rankine Cycle turbines, respectively. Drawing on the world s most advanced thermal power generation and environmental technologies, MHPS intends to develop a wide global lineup of high-performance products, including gas turbines, steam turbines and boilers. By taking full advantage of these comprehensive strengths, it aims to become the number-one global player in the thermal power generation system and environmental project markets. Integrated coal Gasification Combined Cycle (IGCC) Power Plants The IGCC system is a next-generation thermal power system with significantly enhanced power generation efficiency and environmental performance due to its combination with coal gasification and the Gas Turbine Combined Cycle system. Large-type IGCC systems can improve power generation efficiency by approximately 20% and reduce CO2 emissions compared with conventional coal-fired thermal power systems. MHPS retains two types of coal gasification technology, namely, air-blown and oxygen-blown technologies, and leads the world in terms of technological capability. In line with expectations that the need for the IGCC system will increase further owing to its ability to both effectively utilize coal resources and protect the environment, this system has been gaining attention around the world. Heat Recovery Steam Generator Gas Turbine / Steam Turbine / Generator Central Control Room No. 10 Unit at Joban Joint Power s Nakoso Power Plant Gasifier Gas Cleanup Unit GTCC AND CONVENTIONAL PLANTS & SERVICE THERMAL POWER PLANTS AERO-DERIVATIVE GAS TURBINE PLANTS PW POWER SYSTEMS, INC. Gas Turbine Combined Cycle Power Plants (GTCC) GTCC power plants utilize fossil fuels to deliver the cleanest and most efficient power generation. In addition to power generation with a gas turbine, the system also combines a steam turbine to create power through the use of waste heat to ensure excellent power generation efficiency. Plants employing MHPS s state-of-the-art J-series gas turbines have a 20% higher power generation efficiency than conventional coal-fired thermal power generation systems and achieve the world s highest level of efficiency at 63% or more. In addition, this enables CO2 emissions to be reduced by around 50%. PW Power Systems, Inc. (PWPS), formerly Pratt & Whitney Power Systems, has more than 2,000 aero-derivative gas turbines installed in over 50 countries. The FT4000 SWIFTPAC is the world s largest aero-derivative gas turbine with the highest power output by any aeroderivative gas turbine package. The FT4000 SWIFTPAC gas turbine package is available in both single and twin engine configurations, which offer greater than 41 percent simple-cycle efficiency and a nominal or megawatts of power with a modular design that is built utilizing over 50 years of superior aero-derivative technology and packaging experience. Aero-derivative Gas Turbine FT4000 SWIFTPAC (Argentina) TEPCO Fuel & Power, Inc. Kawasaki Power Plant (Japan) 1 ENERGY & ENVIRONMENT THERMAL POWER GENERATION SYSTEMS 2

5 ORGANIC RANKINE CYCLE POWER SYSTEM BOILERS TURBODEN S.R.L. Turboden S.r.l., which has superior Organic Rankine Cycle (ORC) technology, became an MHI Group company in The ORC system vaporizes a high-molecular-mass organic fl uid, resulting in clean and stable electric performance. Turboden produces ORC generators for the combined generation of electric power and heat, employing renewable resources such as geothermal, biomass and solar thermal, as well as heat recovery from industrial processes, waste incinerators, engines and gas turbines. MHPS supplies boilers that boast world-leading quality and performance around the globe based on stable quality built up over many years and state-of-the-art technological development. Amid rising demand for coal-fi red thermal power generation, we boast power generation effi ciency at a world-class level and have a proven record in ultra-supercritical pressure thermal power facilities. Organic Rankine Cycle Power System TURBINES Gas Turbines Coal-fi red Supercritical Variable Pressure Operation Once-through Boiler, Chugoku Electric Power Company, Incorporated Misumi Power Plant Unit 1, 1,000 MW Coal-fi red Supercritical Variable Pressure Operation Once-through Boiler, Pacifico Power Plant 700 MW, Mexico Gas turbines, the core in Gas Turbine Combined Cycle power plants, incorporate a number of critical leading-edge technologies. MHPS has ENVIRONMENTAL EQUIPMENT worked on the development of gas turbines for many years and has integrated the latest advances in aerodynamics, cooling design and material technologies to create a variety of products that realize high effi ciency and high reliability. Environment-related equipment is indispensable to The state-of-the-art J-series gas turbines have consistently led the world, achieving the largest capacity and highest effi ciency with a turbine inlet temperature of 1,600 C. J-series Gas Turbine power generation plants as global environmental awareness rises. Thus Japan s technology, which is a global leader in emissions purifi cation, has been gaining a great deal of attention worldwide. As a MHPS has a power plant for verifi cation testing at the Takasago Works pioneer in fl ue gas treatment technology, MHPS (Takasago City, Hyogo Prefecture), a site for gas turbine development, has spent more than 40 years developing and and is conducting test operation of the latest equipment there. The manufacturing Flue Gas Desulfurization (FGD) plants operational data is quickly fed back into R&D and design divisions, and Selective Catalyst Reduction (SCR) plants. We which makes it possible to conduct highly reliable and effi cient research are one of only a few manufacturers worldwide able and development into gas turbines. H-25 Gas Turbine Power Plant to provide integrated fl ue gas treatment systems on the back of the state-of-the-art technology we have Air Quality Control System, Hirono Thermal Power Station, Japan, TEPCO Fuel & Power, Inc. Steam Turbines Nuclear Turbines accumulated over this period. Driven by independent technology amassed over many years, MHPS In addition to turbines for plants installed in Japan, we also manufacture develops technology for realizing higher performance blades, long turbines for overseas nuclear power plants. integral shroud blades and higher temperatures, and materials development. As a result, we have achieved outstanding levels of GENERATORS performance and reliability in our steam turbines. In addition, we provide high-quality products in a timely manner by making eff ective use of our global production sites. We have delivered over 2,500 steam turbines to 70 countries worldwide. MHPS has supplied over 1,000 turbine generators worldwide to date. Our product reliability has been rated highly based on operating results. We currently supply turbine generators that employ a variety of cooling systems, including an air cooling system, a hydrogen cooling system, and a water and hydrogen cooling system, as well as special generators such as short circuit generators designed to exactingly meet a wide range of needs. In addition, we provide solutions for the entire product lifecycle, including service and maintenance. 1,120 MVA Turbine Generator Double Extraction Condensing Steam Turbine LP Turbine Rotor with 54-inch Blades 3 ENERGY & ENVIRONMENT THERMAL POWER GENERATION SYSTEMS 4

6 CONTROL SYSTEMS TURBODEN S.R.L. Plant Control System Control systems supporting power generation plants are core equipment requiring exceptional reliability and operating efficiency. We provide optimal control systems aimed at maximizing plant performance by leveraging our extensive experience and know-how in a high number of power generation plants. In addition, the importance of control systems is increasing as we head toward the era of the IoT,¹ driving the need to realize both openness and high security. MHPS has developed a control system compliant with functional safety standards.² This system has been positioned as a key device for the ICT platform supporting the era of the IoT, and we will contribute to maximizing customers management value in the operation of power generation plants through the provision and analysis of big data related to electric power. Turboden has supplied many binary power plants. A hybrid system combining MHPS s flash plant with Turboden s binary system is also available. The MHI Group can provide a wide range of products and services for geothermal power generation systems. Kirchstockach Power Plant (Germany) Operating Data Analysis 1. IoT: Internet of Things. 2. Functional safety standards refer to standards that comply with international standards (IEC61508: 2010) related to functional safety. GEOTHERMAL POWER PLANTS GEOTHERMAL POWER SOLID OXIDE FUEL CELL (SOFC) FUEL CELLS Geothermal power generation refers to a system of creating high efficiency, clean power by extracting heat energy from the ground in its natural state. MHPS was the first in the world to apply a combined system, consisting of a two-phase flow transportation system and a double flash cycle, which has become the global standard in geothermal power generation. Our geothermal power generation system continues to be installed globally, and we have achieved the world s top delivery record. Reykjavik Energy Hellisheidi Geothermal Power Plant (Iceland) The implementation of new power generation systems that optimally combine the utilization of renewable energies and new energies is a pressing issue in order to both reduce CO2 emissions and ensure a stable supply of power. MHPS is pushing ahead with the development of a hybrid power system that combines solid oxide fuel cells (SOFCs) with various power generation systems and has now entered the demonstration stage, moving toward practical application. SOFCs possess many advantageous characteristics such as high-efficiency power generation, potential use with a large variety of fuels, and outstanding durability. Due to these advantages, we expect that SOFCs will be used in the future for a wide array of power generation systems, ranging from small to medium-scale cogeneration units for distributed electrical power systems to replacements for large-scale centralized power units for commercial thermal power plants. SOFC-Micro Gas Turbine (MGT) Hybrid Verification System (Ito Campus, Kyushu University) Kyushu Electric Power Co., Inc., Hatchobaru Power Plant (Japan) 5 ENERGY & ENVIRONMENT THERMAL POWER GENERATION SYSTEMS 6

7 Mechanism and Features of the PWR Plant Reactor Containment Vessel Pressurizer Secondary Coolant System Steam Power Transmission Control Rods Water Turbine Generator Steam Generator NUCLEAR ENERGY SYSTEMS DIVISION As one of the world s finest comprehensive plant manufacturers, MHI offers ideal solutions in the field of nuclear power generation and is able to provide a full range of services from plant development through manufacture, operation and maintenance. Based on advanced monozukuri (manufacturing) skills cultivated through more than 50 years of experience with a variety of pressurized water reactor (PWR) plants and major plant equipment, the company is developing the most advanced technology in the world both domestically and overseas. In addition, MHI is proactively working on spent fuel reprocessing and other fields related to the nuclear fuel cycle. The company is contributing to the provision of a stable power supply, the improved reliability of nuclear power, the effective use of energy resources and the realization of a low-carbon society. Fuel Reactor Vessel Coolant Pump Primary Coolant System Reliable Plant Components At PWR plants, high reliability is essential for such main components as the reactor vessel, steam generator, reactor coolant pump, steam turbine, and main control board. MHI has a solid track record in this regard by implementing strict quality control at its large-component factories in Kobe, Futami Water Feedwater Pump 4 Condenser To Discharge Channel Circulating Water Pump Coolant (Seawater) 5 PWRs account for about 70% of more than 400 plants operating worldwide. By pressurizing the inside of the reactor, the PWR allows heat exchange to generate steam in the steam generator to isolate contaminated primary coolant in the containment vessel. What differentiates the PWR is its secondary system, which rotates the turbine and can be maintained like a thermal power plant because it is installed in a non-radiation zone. and Takasago. As a result, MHI has compiled LIGHT WATER REACTORS (DOMESTIC AND GLOBAL) / NUCLEAR FUEL CYCLE & ADVANCED SOLUTIONS outstanding references in Japan and overseas and has become Japan s leading exporter of PWR plant components. 6 7 PWR PLANTS In December 2009, Japan s 24th and newest PWR plant came into operation: Hokkaido Electric Power Co., Inc. s Tomari Unit 3 (912 MWe). For the U.S. and European markets, MHI has launched the US-APWR and the EU-APWR, 1,700 MWe-class, large-scale reactors that have been developed based on the Advanced PWR designed for Tsuruga Units 3 and 4 to be operated by the Japan Atomic Power Company. These reactors are designed to meet respective countries regulations. As for 1,200 MWe-class medium-capacity reactors, MHI is promoting ATMEA1 in the global market. ATMEA1 is the latest reactor jointly developed with AREVA and has world-leading, top-level safety. Development is also underway for new light water reactors, i.e., next-generation PWRs. For emerging countries and remote islands where large-scale power transmission infrastructure is not available, MHI develops small PWRs (IMR, etc.), which have potential as a source of regionally distributed power Hokkaido Electric Power Co., Inc., Tomari Power Station 2 Generation III+ Pressurized Water Reactor ATMEA1 3 IMR (Integrated Modular Water Reactor) 4 Reactor Vessel 5 Steam Generator 6 Main Control Board 7 Reactor Internals 8 Reactor Vessel Closure Head 9 Steam Turbine 7 ENERGY & ENVIRONMENT NUCLEAR ENERGY SYSTEMS DIVISION 8

8 Integrated Technical Capacity Supporting Safety and Reliability Rich Experience in Plant Construction MHI capitalizes on its integrated technical capacity in all the processes for the PWR plant, from design and manufacturing to construction, Maintenance Technology MHI owns various technologies for maintenance, including statutory Utility Company Plant Name Commercial Operation Output (MWe) Utility Company Plant Name Commercial Operation Output (MWe) maintenance and operational support, in order to ensure safe and reliable operation. Key Technologies Supporting Our Nuclear Energy Systems periodical inspections, repair and replacement of main components (e.g., the steam generator, reactor internals) of aging plants to ensure component integrity. Through extensive use of mechatronics technologies, we also realize remotely operated inspection devices and repair robots to improve inspection accuracy and shorten processes. Mihama Mihama Mihama Takahama Kyushu Electric Power Co., Inc. Genkai Genkai Genkai ,180 Genkai ,180 Maintenance Installation & Commissioning R & D Project Management Integrated Technical Capacity for Plants Basic Plan Basic Design The Kansai Electric Power Co., Inc. Takahama Takahama Takahama Ohi ,175 Ohi ,175 Ohi ,180 Hokkaido Electric Power Co., Inc. The Japan Atomic Power Company Sendai Sendai Tomari Tomari Tomari Tsuruga ,160 Manufacturing & Inspection Detailed Design Ohi , units, 20,278 MWe Manufacture State-of-the-art equipment and machining technologies are employed to manufacture components which require high precision. For example, we use electron beam welding systems that do not use filler material; and a large-scale, high-precision milling machine known as the Super Miller, which facilitates precision machining of a huge reactor vessel weighing about 400 tons while holding it in a standing position to avoid material deformation. Replacement of Integrated Water Jet Peening Reactor Internals Maintenance Training MHI emphasizes the development of human resources through detailed simulation training using full-scale mockup facilities at the Maintenance Training Center in its own factory. By improving accuracy and workability, we seek to increase safety for operators, reduce their occupational exposure to radiation, and enhance plant safety. Shikoku Electric Power Co., Inc. Ikata Ikata Ikata ADVANCED REACTOR PLANT DEVELOPMENT OF THE FAST BREEDER REACTOR (FBR) The FBR is a reactor that generates electricity while producing more nuclear fuel than it consumes. It is expected to contribute to improving Japan s energy self-sufficiency by dramatically increasing the efficiency with which uranium resources are used. MHI has been selected to play a key role in the realization of demonstration/commercial reactors as Japan s leading developer of FBRs. In 2007, we established Mitsubishi FBR Systems, Inc., a company that focuses on conceptual design and other activities related to FBR development. Super Miller - Large-scale, Precision Machine Tool for Reactor Vessel Machining Construction MHI is promoting a modular construction method using heavyduty cranes. This method, by which the upper dome of the reactor containment vessel (weighing about 600 tons) is entirely installed, enables safe and efficient work onsite. Ultrasonic Testing Equipment for Reactor Vessel (A-UT machine) Operational Support MHI has been developing various types of full-scale simulators for operator training. Also, an online monitoring system provides advanced core management and operational support. In addition, we have also participated in the Advanced Sodium Technological Reactor for Industrial Demonstration (ASTRID) project in France Prototype Reactor Monju (Electrical Output: 280 MWe) (Courtesy of The Japan Atomic Energy Agency) 2 Experimental Reactor Joyo (Reactor Output: 140 MWt) (Courtesy of The Japan Atomic Energy Agency) Construction at Hokkaido Electric Power s Tomari Power Station Unit 3 Full-scale Simulator for Operator Training 9 ENERGY & ENVIRONMENT NUCLEAR ENERGY SYSTEMS DIVISION 10

9 FUSION REACTOR AS A FUTURE SOURCE OF ENERGY Power generation systems based on fusion reactors are expected to serve as next-generation energy sources in terms of resource and environmental preservation. Planning of the International Thermonuclear Experimental Reactor (ITER*) is progressing, and among the components and equipment supplied by Japan, the superconducting Schematic View of ITER System Cryostat toroidal field (TF) coils, large welded precision structures, are key components of the ITER. We are committed to the development and manufacture of the challenging TF coils by using our expertise and facilities for manufacturing large structures. Toroidal Field Coil (about 300 tons) NUCLEAR FUEL Mitsubishi Nuclear Fuel Co., Ltd. (MNF) is responsible for the development, design, manufacture and sale of nuclear fuel. In coordination with our plant core design, MNF supplies nuclear fuel that excels in economy and reliability. In 2009, we made a significant contribution to Japan s first use of MOX fuel in a thermal reactor, marking an important step toward the establishment of a nuclear fuel cycle Top Nozzle 14m Poloidal Field Coil Vacuum Vessel Blanket 9m Fuel Rod Guide Thimble Tube Instrumentation Tube Main Specification of ITER Divertor Main Grid [Approximate Dimensions of System] Height x Width: 30 m x 30 m Total Weight: about 23,000 tons Bottom Nozzle [Plasma Specifications] Fusion Power Output: 500 MW (with no electricity generation) Plasma Current: 15 MA Plasma Duration: 400 sec or more * ITER also means road in Latin. Central Solenoid (Source: National Institutes for Quantum and Radiological Science and Technology) NUCLEAR FUEL CYCLE FACILITIES In a nuclear fuel cycle, spent fuel is reprocessed for recycling. The establishment of a nuclear fuel cycle will lead to the effective use of uranium resources and to the improvement of Japan s energy security. MHI is working on the construction of the Rokkasho Reprocessing Plant, the key facility for Japan s nuclear fuel cycle, and the Rokkasho MOX Fuel Fabrication Plant, while providing related products, such as intermediate storage casks Cask 2 Rokkasho Reprocessing Plant, Japan Nuclear Fuel Limited 3 Spent Fuel Intermediate Storage Facility 4 Rokkasho MOX Fuel Fabrication Plant, Japan Nuclear Fuel Limited WORKING FOR DECOMMISSIONING AT TEPCO S FUKUSHIMA DAIICHI NUCLEAR POWER STATION At the Fukushima Daiichi Nuclear Power Station, operated by Tokyo Electric Power Co. Inc. (TEPCO), the MHI Group is focusing on applying its comprehensive technological capabilities to improve the environmental conditions at the site. Specifically, the Group has developed robots that can readily move and operate in areas where people cannot enter, such as high-radiation areas. MHI is also participating in a national project intended to deal with contaminated water and problems caused by the accident and is undertaking technical development aimed at retrieving fuel debris.* * Nuclear fuel that has solidified after melting inside one part of the reactor core structure. 5 Fuel Assemblies (UO 2 fuels) 6 Diagram of Fuel Assemblies 7 MOX Fuel Loading Opening for Replacing Control Rod Drive Mechanisms X-6 Penetration Pressure Vessel Containment Vessel Equipment Hatch Airtight Cell Airtight Cell 8 MHI-MEISTeR 9 MHI-Super Giraffe 10 Contaminated Water Storage Tank 11 Method for Collecting Fuel Debris in Nuclear Plant Cleanup Work Manipulator Robotic Arm (for Collecting Rail Debris Outside the Pedestal) Pedestal Robotic Arm Fuel Debris (for Collecting Debris Inside the Pedestal) 11 ENERGY & ENVIRONMENT NUCLEAR ENERGY SYSTEMS DIVISION 12

10 Ammonia and Methanol Co-production Plants MHI is a unique engineering fi rm with a proven track record of delivering simultaneous ammonia and methanol production facilities using Haldor Topsoe s technology. Co-production plants share a synthesis gas reformer and utility facilities to optimize ammonia and methanol production concurrently. Ammonia and Methanol Co-production Plant (Tatarstan) CHEMICAL PLANTS ENGINEERING HEADQUARTERS CHEMICAL PLANTS MHI has gained an excellent reputation among customers for providing a wide spectrum of plants around the world, particularly fertilizer and methanol plants, as well as various types of petrochemical plants. Other facilities include oil and gas plants, water treatment and desalination plants, LNG tanks and receiving terminals, and fl ue gas CO2 recovery plants. Responding to a broad range of industrial infrastructure needs, the MHI Group is applying its project management skills and advanced technological capabilities gained through extensive experience to provide highly dependable and safe plants. METHANOL PLANTS MHI has constructed large-scale methanol plants in Saudi Arabia, Venezuela and Brunei. For these projects, MHI used the Mitsubishi methanol process, jointly developed by Mitsubishi Gas Chemical Company, Inc. and MHI, for methanol synthesis and distillation. The Mitsubishi methanol process features synthesis reactors (super-converters), high-performance catalysts, and Mitsubishi Advanced Compressors (MACs), delivering high effi ciency, low energy consumption and high reliability. Ammonia and Methanol Co-production Plant (Malaysia) FERTILIZER PLANTS Since delivering its fi rst fertilizer plant in 1958, MHI has deployed many fertilizer plants around the world and developed fertilizer plant technology and know-how through our longterm association with the licensors. MHI s plants make use of technologies licensed by Denmark s Haldor Topsoe A/S (ammonia), Italy s Saipem S.p.A. (urea), and the Netherland s Uhde Fertilizer Technology B.V. (urea granulation). World s Largest Class Methanol Plant (Saudi Arabia) Ammonia/Urea Plant (Oman) Methanol Plant (Brunei) Methanol Plant (Venezuela) Ammonia/Urea Plant (Indonesia) 13 ENERGY & ENVIRONMENT CHEMICAL PLANTS 14

11 PETROCHEMICAL PLANTS SEAWATER DESALINATION AND WATER TREATMENT MHI has an extensive and proven track record of constructing a propane/butane/dehydrogeneration, acrylic acid, styrene monomer, Water Solutions wide range of petrochemical plants. Its technological prowess allows it to off er handling facilities for such petrochemical products as ethylene glycol, and methyl methacrylate (MMA) throughout the world. Over the years, MHI has supplied many water treatment plants worldwide. These include seawater and brine desalination plants energy recovery from sludge by-products during water treatment, water reclamation, and recycling and renewing technology to further enhance to meet ever-increasing global demand for water, water treatment energy effi ciency. With a globally expanding population, driven by plants and effl uent treatment plants, and converting effl uent from population growth in emerging countries and progressive urbanization power generation plants or other factories into clean water. Besides and industrialization, the global demand for water is growing while element water treatment technology, MHI also has a long track record water pollution due to improper effl uent discharge is increasing. MHI will of developing other water treatment technologies. Examples include continue to contribute toward solving these problems. MHI s Water Solutions Ethylene-Oxide/Ethylene Glycol Plant (Kashima, Japan) Acrylic Acid Plant (Indonesia) MTBE PDH Plant (Malaysia) 2-Ethylhexanol Plant (Indonesia) Seawater Desalination Plants Polyethylene Plants MHI has been one of the major authorized bidding contractors in the Water Treatment Plants Desalination Purification Reclamation UNIPOL (polyethylene, polypropylene) process since 1980, having deployed many polyethylene and polypropylene plants across the world. Seawater Desalination Plant Industrial Water Supply Plant Waste Water Treatment Plant Water Reclamation Plant Seawater Desalination Plants We have a strong track record in developing new water resources, as well as manufacturing and building a large number of water processing plants. Based on our advanced technologies developed in these fi elds, we delivered the world s largest reverse osmosis desalination plant. In addition, we have developed a new pretreatment method for polluted Polyethylene Plant (Mexico) Polyethylene/Polypropylene Plant (Philippines) seawater, meeting the diversifi ed needs of users. Purified Terephthalic Acid Plants MHI has supplied several purifi ed terephthalic acid (PTA) plants (a process developed by Mitsubishi Chemical Corporation) worldwide. MHI products incorporated in the plants include large air compressors that form a core component of the plants and have been highly rated by our global customers. Reverse Osmosis Seawater Desalination Plant (Madina-Yanbu, Phase Ⅱ, Saudi Arabia, 8,530 m 3 /day 15 units) Reverse Osmosis Seawater Desalination Plant (Rabigh, Saudi Arabia, 12,000 m 3 /day 16 units) PTA Plant (Poland) 15 ENERGY & ENVIRONMENT CHEMICAL PLANTS 16

12 FLUE GAS CO2 RECOVERY PLANTS OIL & GAS PLANTS As a leading global CO2 recovery technology provider, MHI supplies energyeffi cient equipment to recover CO2 from fl ue gas. MHI has developed CO2 recovery technology (KM-CDR Process ) jointly with Kansai Electric Power Co. (KEPCO) boasting the following advantages: [1] Absorbent solution requires less regeneration energy; [2] Absorbent is less prone to degradation; [3] No corrosion inhibitor required; and [4] Signifi cant energy savings. The CO2 collected is effectively used for enhanced oil recovery and coal bed methane recovery in addition to chemical use when manufacturing urea and methanol. Note: The KM CDR Process is a registered trademark of Mitsubishi Heavy Industries, Ltd., in Japan, the United States of America, the European Union (CTM), Norway, Australia and China. MHI has broad experience in EPC (Engineering, Procurement and Construction) for oil and gas production both onshore and off shore in oil producing countries. Moreover, MHI is able to accommodate a wide variety of client needs, ranging from the construction of grassroot refi neries to modifi cation of existing facilities for the optimization of energy consumption or minimization of waste emissions. Compressor Station for Gas Lifting (Algeria) Flue Gas CO2 Recovery Plant (Bahrain) 450 tons/day Flue Gas CO2 Recovery Plant (Malaysia) 160 tons/day Large-scale Coal-fi red Flue Gas CO2 Recovery Demonstration Plant (United States) 500 tons/day Enhanced Oil Recovery (EOR) CO2 Recovery and Usage CO2 is recovered from fl ue gas in power plants and factories through chemical absorption, transported through pipelines to oil fi elds, and utilized for EOR. Ebullient Residual Hydrocracking Plant (Slovakia) LNG RECEIVING TERMINAL Natural Gas Compressor Station (Nagano, Japan) CO2 Compressor Crude Oil Pipeline Natural gas in the form of LNG continues to meet growing global energy needs, and LNG receiving terminals play an important role in the future to meet this demand. Thermal Power Plant CO2 Recovery Plant CO2 Injection Well Production Well Oil Reservoir CO2 Crude Oil CO2 Collected Through Chemical Absorption Absorbed CO2 Used Efficently Integration with Power Generation Facilities MHI is capable of supplying all of the following equipment, from power generation facilities to environmental measures at thermal power generation plants. LNG Receiving Terminal (Niigata, Japan) Steam Turbine Boiler SCR (DeNOx) Dust Removal Desulfurization CO2 Recovery Clean Flue Gas Power Generation Plant Flue Gas Desulfurization Plant CO2 Recovery Plant Centrifugal Compressor CO2 Compressor CO2 Storage LNG Receiving Terminal (Sakai, Japan) LNG Receiving Terminal (Chita-midorihama, Japan) 17 ENERGY & ENVIRONMENT CHEMICAL PLANTS 18

13 PUMPS PUMP APPLICATIONS Power Generation Pumps As an all-round manufacturer of pumps for thermal and nuclear power plants, we have earned an outstanding reputation for our wide-ranging experience, state-of-the-art research and development, manufacturing technology and quality assurance RENEWABLE ENERGY BUSINESS DIVISION The MHI Group provides a wide range of energy-related technologies that realize low environmental load, including largescale wind power systems and a broad selection of pumps. The Group has supplied approximately 4,200 onshore wind turbines around the world. MHI has jointly established a company with the Danish fi rm Vestas Wind Systems A/S to operate in the off shore wind power systems market, which is growing rapidly, and is supplying approximately 750 turbines particularly in Europe. The Group has supplied over 17,500 pumps for use in countless applications, such as power stations, plants and ships, to companies and other organizations around the world involved in infrastructure support. 1 Boiler Feedwater Pump 2 Variable Vane Circulating Water Pump for Nuclear Power Plant 3 Reactor Coolant Pump for PWR Nuclear Power Plant 4 Circulating Water Pump for Thermal Power Plant 5 Variable Pitch Vane Slurry Pump for Flue Gas Desulfurization Plant Other Pumps 2 5 By concentrating its technologies in various fi elds, the MHI Group is working to realize a low-carbon society. Our outstanding pump technology is also widely used for industrial and marine applications. Our research and development eff orts are focused on new fi elds, including WIND TURBINES water resource facilities such as desalination, and environmental equipment such as CCS and EOR. WIND POWER SYSTEMS Offshore Wind Power Systems MHI has teamed up with Vestas Wind Systems A/S, a Danish manufacturer of wind power turbines, to establish a joint-venture company specializing in off shore wind power systems. With this full-scale entry in the off shore wind power systems market, which is projected to grow rapidly in the future, the company intends to become a global leader by drawing on the strengths of both MHI and Vestas Semi-lean Solution Pump for Fertilizer Plant 7 Hydraulic Power Recovery Turbine 8 CO2 Injection Pump 9 Water Jet Propulsion Unit; 2,000-Ton-type Patrol Vessel HIDA 10 Pipeline Pump 11 Cooling Water Pump for Desalination Plant V MW Wind Turbines (Belgium) V MW Wind Turbine (Denmark) 19 ENERGY & ENVIRONMENT RENEWABLE ENERGY BUSINESS DIVISION 20

14 Marine Engines UE Eco Engine 7UEC80LSE-Eco-B1 (Electronically Controlled Engine) 6UEC50LSH-Eco 45LSE-Eco-B2 (Low-pressure Exhaust Gas Recirculation Model Compliant with Tier III Emission Standards) Turbochargers MET turbochargers can be customized with high-speed power generators and other equipment to meet various needs. MARINE MACHINERY & ENGINES MITSUBISHI HEAVY INDUSTRIES MARINE MACHINERY & ENGINE CO., LTD. About half of the world s large merchant fl eets are equipped with MHI-brand marine products. The MHI Group produces its own independently developed UE engines as well as MET turbochargers, propellers and other equipment, while responding to a wide range of customer needs with highvalue-added products. Off ering optimal solutions geared toward the environment and saving energy through its project MEET, MHI is helping to make marine transport more economical while reducing the environmental load. MET Turbocharger Hybrid Turbocharger WHRS (Waste Heat Recovery System) Variable Turbine Inlet (VTI) Turbocharger with Changeable Nozzle ORC (Organic Rankine Cycle) Electric Assist Turbocharger Boilers and Turbines MARINE MACHINERY & ENGINES PROJECT MEET (MITSUBISHI MARINE ENERGY & ENVIRONMENT TECHNICAL SOLUTION-SYSTEM) Through Project MEET, the MHI Group off ers solutions to the challenges of saving energy and protecting the environment in today s maritime shipping industry, drawing on the leading-edge technologies developed by Mitsubishi Heavy Industries Marine Machinery & Engine Co., Ltd. Marine Main Diesel Engine Waste Heat Recovery System Fin Stabilizers Low-medium Temperature Waste Heat Recovery System Screw Propellers Auxiliary Boiler MEET-1 CO2 Reduction MEET-2 NOx, SOx Reduction MEET-3 LNG as Fuel MHI Shipbuilding Division MHI Research Centers Marine Generator Turbine Coordination MITSUBISHI HEAVY INDUSTRIES MARINE MACHINERY & ENGINE CO., LTD. Mitsubishi Advanced Propeller (MAP) Mark-W Ultra Steam Turbine (UST) Propulsion Plant for Ships Turbines 2 Steering Gears 3 Propellers 4 Marine Engines 5 Boilers 6 Deck Crane (Sales and Leasing) 7 Fin Stabilizers 8 MET Turbochargers 9 Water Jet (Sales and Leasing) 10 Deck Machinery (Sales and Leasing) Steering Gears Marine Boiler and Steam Turbine for FPSO/FSO/FSRU/FLING Main Turbine Solutions Ship Owners Shipyards Marine Boiler Steam Turbine Main Boiler 21 ENERGY & ENVIRONMENT MARINE MACHINERY & ENGINES 22