سوق دورة رانكين العضوية (ORC) لتوليد الطاقة من الحرارة المهدرة في أمريكا الشمالية، حسب الحجم (صغير، متوسط، كبير)، السعة (أقل من 1000 كيلو واط، 1001-4000 كيلو واط، 4001-7000 كيلو واط، أكثر من 7000 كيلو واط)، النموذج (حالة ثابتة، ديناميكي)، التطبيق (توربينات الغاز أو ICE، تحويل النفايات إلى طاقة، إنتاج المعادن، صناعة الأسمنت والجير، صناعة الزجاج، تكرير البترول، الصناعة الكيميائية، ICE في مكبات النفايات، أخرى) - اتجاهات الصناعة والتوقعات حتى عام 2029.
تحليل وحجم سوق دورة رانكين العضوية لتوليد الطاقة من الحرارة المهدرة في أمريكا الشمالية
إن دور الحرارة المهدرة الناتجة عن دورة رانكين العضوية (ORC) في تحويل الحرارة الحرارية للسوائل أو الغازات لإنتاج طاقة خالية من الكربون بكفاءة. يتم توليد الحرارة من مصادر الطاقة الحرارية الأرضية أو الحرارة المهدرة الصناعية أو التجارية. تساعد الحرارة المهدرة الناتجة عن دورة رانكين العضوية (ORC) الشركات على إنتاج المزيد من الكهرباء لتلبية الطلب المتزايد. يقلل التبني المتزايد لتقنية دورة رانكين العضوية (ORC) من الوقود المستخدم لتوليد الطاقة، وتستخدم العديد من الشركات الكبيرة هذه التقنيات لتوليد الطاقة من استعادة الحرارة المهدرة.
تحلل شركة Data Bridge Market Research أن سوق تحويل الحرارة المهدرة إلى طاقة باستخدام دورة رانكين العضوية (ORC) في أمريكا الشمالية من المتوقع أن تصل قيمته إلى 1,379,245.87 ألف دولار أمريكي بحلول عام 2029، بمعدل نمو سنوي مركب قدره 9.2% خلال الفترة المتوقعة. يغطي تقرير سوق تحويل الحرارة المهدرة إلى طاقة باستخدام دورة رانكين العضوية (ORC) أيضًا تحليل الأسعار وتحليل براءات الاختراع والتقدم التكنولوجي بشكل شامل.
|
تقرير القياس |
تفاصيل |
|
فترة التنبؤ |
2022 إلى 2029 |
|
سنة الأساس |
2021 |
|
سنوات تاريخية |
2020 (قابلة للتخصيص حتى 2019 - 2015) |
|
وحدات كمية |
الإيرادات بالألف دولار أمريكي، التسعير بالدولار الأمريكي |
|
القطاعات المغطاة |
حسب الحجم (صغير، متوسط، كبير)، السعة (أقل من 1000 كيلو واط، 1001-4000 كيلو واط، 4001-7000 كيلو واط، أكثر من 7000 كيلو واط)، الطراز (حالة ثابتة، ديناميكي)، التطبيق (محركات الاحتراق الداخلي أو توربينات الغاز، تحويل النفايات إلى طاقة، إنتاج المعادن، صناعة الأسمنت والجير، صناعة الزجاج، تكرير البترول، الصناعة الكيميائية، محركات الاحتراق الداخلي في مكبات النفايات، أخرى). |
|
الدول المغطاة |
الولايات المتحدة وكندا والمكسيك في أمريكا الشمالية. |
|
الجهات الفاعلة في السوق المشمولة |
ميتسوبيشي للصناعات الثقيلة المحدودة، كايشان الولايات المتحدة الأمريكية، ستريبل إنيرجي بي تي إي المحدودة، أوركان إنيرجي إيه جي، ألفا لافال، فوجيان سنومان المحدودة، أورمات، رانك، تي إم إي آي سي، تريوجين، إيه بي بي، سيمنز إنيرجي (سيمنز إيه جي)، مجموعة دور، إليكتراثيرم إنك. (مجموعة بيتزر)، إنيرباسك، إنيرتايم، إينوجيا، إكسيرجي، كليمون، إنتيك إنجنيرينج جي إم بي إتش، زوكاتو إنيرجيا إس آر إل، أوبل إنيرجي سيستمز بي في تي المحدودة، مجموعة كوريكوس، سي تي إم آي - توربينات البخار، بورجوارنر إنك. |
تعريف السوق
تُستخدم أنظمة دورة رانكين العضوية (ORC) لإنتاج الطاقة من مصادر الحرارة المنخفضة إلى المتوسطة عند 80 إلى 350 درجة مئوية وللتطبيقات الصغيرة والمتوسطة عند أي درجة حرارة. تسمح هذه التقنية باستغلال الحرارة المنخفضة الدرجة التي كانت لتضيع لولا ذلك. يشبه مبدأ عمل محطة الطاقة التي تعمل بدورة رانكين العضوية العملية الأكثر استخدامًا لتوليد الطاقة، وهي دورة كلاوزيوس-رانكين.
The main difference is using organic substances instead of water (steam) as a working fluid. The organic working fluid has a lower boiling point and a higher vapor pressure than water and is, therefore, able to use low-temperature heat sources to produce electricity. The organic fluid is chosen to best fit the heat source according to their differing thermodynamic properties, thus obtaining higher efficiencies of both cycle and expander.
North America Organic Rankine Cycle (ORC) Waste Heat to Power Market Dynamics
This section deals with understanding the market drivers, advantages, opportunities, restraints, and challenges. All of this is discussed in detail as below:
Drivers
- Upsurge in the reduction of usage of primary energy in industrial operations
Waste heat to power is one of the adoptable renewable sources to generate electricity. This technique is found to be the most efficient resource to generate power as it helps to reduce the usage of energy or fuels for industrial processes, and the waste heat generated is used to generate emission-free electricity, which is further used in the normal industrial process or sold to the grid for distribution.
The waste heat generated is considered a by-product in most industries, such as steel paper manufacturing, refineries, chemical, and general manufacturing, as the waste heat is produced in industrial operations. Thus, the energy or the cost involved in running the main industrial operation will also generate waste heat that can be dumped into the environment.
- Increased focus on improving the power plant efficiency
The world's electricity generation is majorly dependent on the fossil fuel resources such as coal, natural gas, and oil. The number of installed fossil-fired power generation plants has increased in North America, and the development of such power plants is trending across the globe. However, waste heat is discharged in a power plant and can be dumped in the environment. How recovering the waste heat is the main approach to improve thermal efficiencies further and reduce greenhouse gas emissions for fossil-fired power plants.
Moreover, it is found that adopting technologies to recover waste heat is gaining importance to improve power plant efficiency. Thus, a waste heat ORC system is applied, based on a closed loop thermodynamic cycle for generating electricity and thermal power, which is suitable for plant operations. This system has been found to support various power plant functions such as economizer, heat pump, rotary heat exchanger, regenerator, and many others. This will support the functioning of the power plant and improves its efficiency.
Opportunities
- Rapid industrialization and climate change concerns
Industrialization is a process of adopting an economy based on manufacturing. This step involves many changes that help the society's economy grow and prosper. Industrialization does not seem to have a sudden change, but it takes a gradual change that happens over a period. Thus, indirectly there will be a large number of fossil fuels, which in turn generate the climate.
The cause of climate change has been a serious issue that has been changing with the rapid increase in industrialization. However, industrialization is the route to economic development, but climate change is one of the major concerns that must be controlled. This will lead to adopting sustainable and efficient technologies in the industrial process, including the WHP system. The adoption of such technologies with the increase in industrialization along with the climate change concerns will help to protect the environment.
Restraints/Challenges
- High cost of installation and maintenance
Although waste heat recovery systems have significant advantages, installation costs limit the market growth. The waste heat recovery can be done through various techniques such as steam rankine cycle (SRC), organic rankine cycle (ORC), or kalina cycle. These technologies will cost differently based on the production and industrial sector scale.
Moreover, the total cost to install or adopt the waste heat to power (WHP) systems in any industry includes various factors and equipment such as waste heat recovery equipment, power generation equipment, and power conditioning and interconnection equipment. The total cost would also include the soft costs associated with designing, permitting, and constructing the system. However, the maintenance requirements of the heat recovery boilers and balancing the plant are also included, which can vary according to technology and site conditions.
- Lack of awareness about the technology
The need for waste heat recovery is gaining importance, but knowledge about the awareness, technology, and financial aspects of WHP systems is essential for decision-making. The ultimate goal is to optimize the overall energy efficiency and, thus, maximize the economic and environmental benefits.
However, most industries are adopting the WHP system in industrial operations as most of the industry professionals are unaware of the technical aspects, leading to a misconception, perception, and wrong method implementation, resulting in inefficiency and negative results.
Post COVID-19 Impact on North America Organic Rankine Cycle (ORC) Waste Heat to Power Market
COVID-19 created a negative impact on the organic rankine cycle (ORC) waste heat to power market due to lockdown regulations and rules at manufacturing facilities.
The COVID-19 pandemic has impacted the organic rankine cycle (ORC) waste heat to power market to an extent in a negative manner. However, increasing adoption of organic rankine cycle (ORC) waste heat to power in the energy sector has helped the market grow after the pandemic. Also, the growth has been high since the market opened after COVID-19, and it is expected that there will be considerable growth in the sector.
Manufacturers are making various strategic decisions to bounce back post-COVID-19. The players are conducting multiple research and development activities to improve the technology involved in the organic rankine cycle (ORC) waste heat to power. With this, the companies will bring advanced technologies to the market. In addition, government initiatives for the use of recycling technologies have led to the market's growth
Recent Development
- In September 2020, BorgWarner Inc. entered into a partnership with Plug and Play. The main objective behind this strategic partnership was to enhance inventive ideas in the automotive and tech sector to boost the sector's capabilities to new heights. Through this company expanded its automotive and tech sector market.
- In December 2018, Corycos Group partnered with Clean Energy Technologies, Inc. The partnership aimed to develop an innovative organic rankine cycle (ORC) heat recovery generator for the biogas industry. Through this partnership, both companies strengthen their market and regional presence.
North America Organic Rankine Cycle (ORC) Waste Heat to Power Market Scope
North America organic rankine cycle (ORC) waste heat to power market is segmented on the basis of size, capacity, model, and application. The growth amongst these segments will help you analyze meagre growth segments in the industries and provide the users with a valuable market overview and market insights to help them make strategic decisions for identifying core market applications.
Size
- Small
- Medium
- Large
On the basis of size, the North America organic rankine cycle (ORC) waste heat to power market is segmented into small, medium, and large.
Capacity
- Less Than 1000 kW
- 1001-4000 kW
- 4001-7000 kW
- More than 7000 kW
On the basis of capacity, the North America organic rankine cycle (ORC) waste heat to power market has been segmented into less than 1000 kW, 1001-4000 kW, 4001-7000 kW, and more than 7000 kW.
Model
- Steady-State
- Dynamic
On the basis of the model, the North America organic rankine cycle (ORC) waste heat to power market has been segmented into steady-state and dynamic.
Application
- ICE or Gas Turbine
- Waste to Energy
- Metal Production
- Cement and Lime Industry
- Glass Industry
- Petroleum Refining
- Chemical Industry
- Landfill ICE
- Others
On the basis of application, the North America organic rankine cycle (ORC) waste heat to power market is segmented into ICE or gas turbine, waste to energy, metal production, cement and lime industry, glass industry, petroleum refining, chemical industry, landfill ICE, and others.
تحليل/رؤى إقليمية لسوق تحويل الحرارة المهدرة إلى طاقة باستخدام دورة رانكين العضوية في أمريكا الشمالية
تم تحليل سوق دورة رانكين العضوية (ORC) لتوليد الطاقة من الحرارة المهدرة في أمريكا الشمالية، وتم توفير رؤى حجم السوق واتجاهاته حسب البلد والحجم والقدرة والنموذج والتطبيق كما هو مذكور أعلاه.
الدول التي يغطيها تقرير سوق الحرارة المهدرة لإنتاج الطاقة من دورة رانكين العضوية (ORC) هي الولايات المتحدة وكندا والمكسيك.
تهيمن الولايات المتحدة على سوق دورة رانكين العضوية (ORC) لإنتاج الطاقة من الحرارة المهدرة بسبب ارتفاع أهمية توليد الطاقة من استعادة الحرارة المهدرة.
يقدم قسم الدولة في التقرير أيضًا عوامل فردية مؤثرة على السوق والتغيرات في تنظيم السوق التي تؤثر على الاتجاهات الحالية والمستقبلية للسوق. نقاط البيانات مثل تحليل سلسلة القيمة المصب والمصب، والاتجاهات الفنية، وتحليل قوى بورتر الخمس، ودراسات الحالة هي بعض المؤشرات المستخدمة للتنبؤ بسيناريو السوق للدول الفردية. أيضًا، يتم النظر في وجود وتوافر العلامات التجارية في أمريكا الشمالية والتحديات التي تواجهها بسبب المنافسة الكبيرة أو النادرة من العلامات التجارية المحلية والمحلية، وتأثير التعريفات الجمركية المحلية، وطرق التجارة أثناء تقديم تحليل تنبؤي لبيانات الدولة.
تحليل حصة السوق في أمريكا الشمالية لإنتاج الطاقة باستخدام دورة رانكين العضوية (ORC) في المشهد التنافسي
يوفر المشهد التنافسي لسوق تحويل الحرارة المهدرة إلى طاقة باستخدام دورة رانكين العضوية في أمريكا الشمالية (ORC) تفاصيل حسب المنافس. تتضمن التفاصيل نظرة عامة على الشركة، والبيانات المالية للشركة، والإيرادات المولدة، وإمكانات السوق، والاستثمار في البحث والتطوير، ومبادرات السوق الجديدة، والحضور في أمريكا الشمالية، ومواقع الإنتاج والمرافق، والقدرات الإنتاجية، ونقاط القوة والضعف للشركة، وإطلاق المنتج، وعرض المنتج ونطاقه، وهيمنة التطبيق. ترتبط نقاط البيانات المذكورة أعلاه فقط بتركيز الشركات فيما يتعلق بسوق تحويل الحرارة المهدرة إلى طاقة باستخدام دورة رانكين العضوية (ORC).
بعض اللاعبين الرئيسيين العاملين في سوق دورة رانكين العضوية (ORC) لتوليد الطاقة من الحرارة المهدرة في أمريكا الشمالية هم MITSUBISHI HEAVY INDUSTRIES, LTD.، Kaishan USA، Strebl Energy Pte Ltd، ORCAN ENERGY AG، ALFA LAVAL، Fujian Snowman Co.، Ltd.، Ormat، Rank، TMEIC، Triogen، ABB، Siemens Energy (Siemens AG)، Dürr Group، ElectraTherm Inc. (BITZER Group)، Enerbasque، Enertime، Enogia، EXERGY، CLIMEON، INTEC Engineering GmbH، Zuccato Energia srl.، Opel Energy Systems Pvt. Ltd.، Corycos Group، CTMI - Steam Turbines، BorgWarner Inc.
SKU-
احصل على إمكانية الوصول عبر الإنترنت إلى التقرير الخاص بأول سحابة استخبارات سوقية في العالم
- لوحة معلومات تحليل البيانات التفاعلية
- لوحة معلومات تحليل الشركة للفرص ذات إمكانات النمو العالية
- إمكانية وصول محلل الأبحاث للتخصيص والاستعلامات
- تحليل المنافسين باستخدام لوحة معلومات تفاعلية
- آخر الأخبار والتحديثات وتحليل الاتجاهات
- استغل قوة تحليل المعايير لتتبع المنافسين بشكل شامل
Table of Content
1 INTRODUCTION
1.1 OBJECTIVES OF THE STUDY
1.2 MARKET DEFINITION
1.3 OVERVIEW OF NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET
1.4 CURRENCY AND PRICING
1.5 LIMITATIONS
1.6 MARKETS COVERED
2 MARKET SEGMENTATION
2.1 MARKETS COVERED
2.2 GEOGRAPHICAL SCOPE
2.3 YEARS CONSIDERED FOR THE STUDY
2.4 DBMR TRIPOD DATA VALIDATION MODEL
2.5 PRIMARY INTERVIEWS WITH KEY OPINION LEADERS
2.6 DBMR MARKET POSITION GRID
2.7 VENDOR SHARE ANALYSIS
2.8 MARKET APPLICATION COVERAGE GRID
2.9 MULTIVARIATE MODELING
2.1 SIZE TIMELINE CURVE
2.11 SECONDARY SOURCES
2.12 ASSUMPTIONS
3 EXECUTIVE SUMMARY
4 PREMIUM INSIGHTS
5 MARKET OVERVIEW
5.1 DRIVERS
5.1.1 RISE IN IMPORTANCE FOR GENERATING POWER FROM WASTE HEAT RECOVERY
5.1.2 UPSURGE IN THE REDUCTION OF USAGE OF PRIMARY ENERGY IN INDUSTRIAL OPERATIONS
5.1.3 INCREASED FOCUS ON IMPROVING THE POWER PLANT EFFICIENCY
5.1.4 RISING STRINGENT EMISSION NORMS
5.2 RESTRAINTS
5.2.1 HIGH COST OF INSTALLATION AND MAINTENANCE
5.2.2 SUPPLY DEFICIT OF RAW MATERIALS
5.3 OPPORTUNITIES
5.3.1 RAPID INDUSTRIALIZATION AND CLIMATE CHANGE CONCERNS
5.3.2 RISE IN LARGE-SCALE ORC-BASED GEOTHERMAL POWER PROJECTS
5.3.3 GOVERNMENT INCENTIVES TO PROMOTE GREEN ENERGY CHANGES
5.3.4 INCREASE IN THE ADOPTION OF SUSTAINABLE TECHNOLOGIES ACROSS INDUSTRIES
5.4 CHALLENGES
5.4.1 LACK OF AWARENESS ABOUT THE TECHNOLOGY
6 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE
6.1 OVERVIEW
6.2 MEDIUM
6.3 SMALL
6.4 LARGE
7 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY CAPACITY
7.1 OVERVIEW
7.2 LESS THAN 1000 KW
7.3 1001-4000 KW
7.4 4001 - 7000 KW
7.5 MORE THAN 7000 KW
8 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY MODEL
8.1 OVERVIEW
8.2 STEADY-STATE
8.3 DYNAMIC
9 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY APPLICATION
9.1 OVERVIEW
9.2 ICE OR GAS TURBINE
9.2.1 MEDIUM
9.2.2 SMALL
9.2.3 LARGE
9.3 WASTE TO ENERGY
9.3.1 MEDIUM
9.3.2 SMALL
9.3.3 LARGE
9.4 METAL PRODUCTION
9.4.1 MEDIUM
9.4.2 SMALL
9.4.3 LARGE
9.5 CEMENT AND LIME INDUSTRY
9.5.1 MEDIUM
9.5.2 SMALL
9.5.3 LARGE
9.6 GLASS INDUSTRY
9.6.1 MEDIUM
9.6.2 SMALL
9.6.3 LARGE
9.7 PETROLEUM REFINING
9.7.1 MEDIUM
9.7.2 SMALL
9.7.3 LARGE
9.8 CHEMICAL INDUSTRY
9.8.1 MEDIUM
9.8.2 SMALL
9.8.3 LARGE
9.9 LANDFILL ICE
9.9.1 MEDIUM
9.9.2 SMALL
9.9.3 LARGE
9.1 OTHERS
10 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION
10.1 NORTH AMERICA
10.1.1 U.S.
10.1.2 CANADA
10.1.3 MEXICO
11 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: COMPANY LANDSCAPE
11.1 COMPANY SHARE ANALYSIS: NORTH AMERICA
12 SWOT ANALYSIS
13 COMPANY PROFILE
13.1 ORMAT
13.1.1 COMPANY SNAPSHOT
13.1.2 REVENUE ANALYSIS
13.1.3 COMPANY SHARE ANALYSIS
13.1.4 PRODUCTS PORTFOLIO
13.1.5 RECENT DEVELOPMENTS
13.2 SIEMENS ENERGY
13.2.1 COMPANY SNAPSHOT
13.2.2 REVENUE ANALYSIS
13.2.3 COMPANY SHARE ANALYSIS
13.2.4 SOLUTION PORTFOLIO
13.2.5 RECENT DEVELOPMENTS
13.3 BORGWARNER INC.
13.3.1 COMPANY SNAPSHOT
13.3.2 REVENUE ANALYSIS
13.3.3 COMPANY SHARE ANALYSIS
13.3.4 PRODUCTS PORTFOLIO
13.3.5 RECENT DEVELOPMENTS
13.4 ALFA LAVAL
13.4.1 COMPANY SNAPSHOT
13.4.2 REVENUE ANALYSIS
13.4.3 COMPANY SHARE ANALYSIS
13.4.4 PRODUCTS PORTFOLIO
13.4.5 RECENT DEVELOPMENTS
13.5 MITSUBISHI HEAVY INDUSTRIES, LTD
13.5.1 COMPANY SNAPSHOT
13.5.2 REVENUE ANALYSIS
13.5.3 COMPANY SHARE ANALYSIS
13.5.4 PRODUCTS PORTFOLIO
13.5.5 RECENT DEVELOPMENT
13.6 ABB
13.6.1 COMPANY SNAPSHOT
13.6.2 REVENUE ANALYSIS
13.6.3 PRODUCTS PORTFOLIO
13.6.4 RECENT DEVELOPMENTS
13.7 CLIMEON
13.7.1 COMPANY SNAPSHOT
13.7.2 REVENUE ANALYSIS
13.7.3 PRODUCTS PORTFOLIO
13.7.4 RECENT DEVELOPMENTS
13.8 CORYCOS GROUP
13.8.1 COMPANY SNAPSHOT
13.8.2 PRODUCTS PORTFOLIO
13.8.3 RECENT DEVELOPMENTS
13.9 CTMI - STEAM TURBINES
13.9.1 COMPANY SNAPSHOT
13.9.2 PRODUCTS PORTFOLIO
13.9.3 RECENT DEVELOPMENTS
13.1 DÜRR GROUP
13.10.1 COMPANY SNAPSHOT
13.10.2 REVENUE ANALYSIS
13.10.3 PRODUCTS PORTFOLIO
13.10.4 RECENT DEVELOPMENT
13.11 ENERBASQUE
13.11.1 COMPANY SNAPSHOT
13.11.2 PRODUCT PORTFOLIO
13.11.3 RECENT DEVELOPMENTS
13.12 ENERTIME
13.12.1 COMPANY SNAPSHOT
13.12.2 PRODUCTS PORTFOLIO
13.12.3 RECENT DEVELOPMENT
13.13 ENOGIA
13.13.1 COMPANY SNAPSHOT
13.13.2 PRODUCTS PORTFOLIO
13.13.3 RECENT DEVELOPMENT
13.14 EXERGY INTERNATIONAL SRL
13.14.1 COMPANY SNAPSHOT
13.14.2 PRODUCTS PORTFOLIO
13.14.3 RECENT DEVELOPMENT
13.15 ELECTRATHERM (ACQUIRED BY BITZER)
13.15.1 COMPANY SNAPSHOT
13.15.2 PRODUCT PORTFOLIO
13.15.3 RECENT DEVELOPMENTS
13.16 INTEC ENGINEERING GMBH
13.16.1 COMPANY SNAPSHOT
13.16.2 PRODUCT PORTFOLIO
13.16.3 RECENT DEVELOPMENTS
13.17 KAISHAN USA
13.17.1 COMPANY SNAPSHOT
13.17.2 PRODUCTS PORTFOLIO
13.17.3 RECENT DEVELOPMENT
13.18 OPEL ENERGY SYSTEMS PVT. LTD.
13.18.1 COMPANY SNAPSHOT
13.18.2 PRODUCTS PORTFOLIO
13.18.3 RECENT DEVELOPMENTS
13.19 ORCAN ENERGY AG
13.19.1 COMPANY SNAPSHOT
13.19.2 PRODUCTS PORTFOLIO
13.19.3 RECENT DEVELOPMENT
13.2 RANK ORC, S.L.
13.20.1 COMPANY SNAPSHOT
13.20.2 PRODUCTS PORTFOLIO
13.20.3 RECENT DEVELOPMENT
13.21 STREBL ENERGY PTE LTD
13.21.1 COMPANY SNAPSHOT
13.21.2 PRODUCTS PORTFOLIO
13.21.3 RECENT DEVELOPMENT
13.22 SRMTEC
13.22.1 COMPANY SNAPSHOT
13.22.2 PRODUCT PORTFOLIO
13.22.3 RECENT DEVELOPMENTS
13.23 TMEIC
13.23.1 COMPANY SNAPSHOT
13.23.2 PRODUCTS PORTFOLIO
13.23.3 RECENT DEVELOPMENTS
13.24 TRIOGEN
13.24.1 COMPANY SNAPSHOT
13.24.2 PRODUCT PORTFOLIO
13.24.3 RECENT DEVELOPMENTS
13.25 ZUCCATO ENERGIA SRL.
13.25.1 COMPANY SNAPSHOT
13.25.2 PRODUCTS PORTFOLIO
13.25.3 RECENT DEVELOPMENTS
14 QUESTIONNAIRE
15 RELATED REPORTS
List of Table
TABLE 1 EXISTING WHP PROJECTS AND POWER GENERATION CAPACITY BY DIFFERENT INDUSTRIES IN THE U.S.
TABLE 2 ENERGY GENERATION POTENTIAL THROUGH WASTE HEAT IN DIFFERENT SECTORS IN INDIA
TABLE 3 WHP COST COMPARISON
TABLE 4 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 5 NORTH AMERICA MEDIUM IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 6 NORTH AMERICA SMALL IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 7 NORTH AMERICA LARGE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 8 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY CAPACITY, 2020-2029 (USD THOUSAND)
TABLE 9 NORTH AMERICA LESS THAN 1000 KW IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 10 NORTH AMERICA 1001-4000 KW IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 11 NORTH AMERICA 4001-7000 KW IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 12 NORTH AMERICA MORE THAN 7000 KW IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 13 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY MODEL, 2020-2029 (USD THOUSAND)
TABLE 14 NORTH AMERICA STEADY-STATE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 15 NORTH AMERICA DYNAMIC IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 16 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY APPLICATION, 2020-2029 (USD THOUSAND)
TABLE 17 NORTH AMERICA ICE OR GAS TURBINE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 18 NORTH AMERICA ICE OR GAS TURBINE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY TYPE, 2020-2029 (USD THOUSAND)
TABLE 19 NORTH AMERICA WASTE TO ENERGY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 20 NORTH AMERICA WASTE TO ENERGY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY TYPE, 2020-2029 (USD THOUSAND)
TABLE 21 NORTH AMERICA METAL PRODUCTION IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 22 NORTH AMERICA METAL PRODUCTION IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY TYPE, 2020-2029 (USD THOUSAND)
TABLE 23 NORTH AMERICA CEMENT AND LIME INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 24 NORTH AMERICA CEMENT AND LIME INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY TYPE, 2020-2029 (USD THOUSAND)
TABLE 25 NORTH AMERICA GLASS INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 26 NORTH AMERICA GLASS INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY TYPE, 2020-2029 (USD THOUSAND)
TABLE 27 NORTH AMERICA PETROLEUM REFINING IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 28 NORTH AMERICA PETROLEUM REFINING IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY TYPE, 2020-2029 (USD THOUSAND)
TABLE 29 NORTH AMERICA CHEMICAL INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 30 NORTH AMERICA CHEMICAL INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY TYPE, 2020-2029 (USD THOUSAND)
TABLE 31 NORTH AMERICA LANDFILL ICE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 32 NORTH AMERICA LANDFILL ICE INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY TYPE, 2020-2029 (USD THOUSAND)
TABLE 33 NORTH AMERICA OTHERS IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY REGION, 2020-2029 (USD THOUSAND)
TABLE 34 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY COUNTRY, 2020-2029 (USD THOUSAND)
TABLE 35 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 36 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY CAPACITY, 2020-2029 (USD THOUSAND)
TABLE 37 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY MODEL, 2020-2029 (USD THOUSAND)
TABLE 38 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY APPLICATION, 2020-2029 (USD THOUSAND)
TABLE 39 NORTH AMERICA ICE OR GAS TURBINE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 40 NORTH AMERICA WASTE TO ENERGY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 41 NORTH AMERICA METAL PRODUCTION IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 42 NORTH AMERICA CEMENT AND LIME INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 43 NORTH AMERICA GLASS INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 44 NORTH AMERICA PETROLEUM REFINING IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 45 NORTH AMERICA CHEMICAL INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 46 NORTH AMERICA LANDFILL ICE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 47 U.S. ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 48 U.S. ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY CAPACITY, 2020-2029 (USD THOUSAND)
TABLE 49 U.S. ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY MODEL, 2020-2029 (USD THOUSAND)
TABLE 50 U.S. ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY APPLICATION, 2020-2029 (USD THOUSAND)
TABLE 51 U.S. ICE OR GAS TURBINE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 52 U.S. WASTE TO ENERGY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 53 U.S. METAL PRODUCTION IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 54 U.S. CEMENT AND LIME INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 55 U.S. GLASS INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 56 U.S. PETROLEUM REFINING IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 57 U.S. CHEMICAL INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 58 U.S. LANDFILL ICE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 59 CANADA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 60 CANADA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY CAPACITY, 2020-2029 (USD THOUSAND)
TABLE 61 CANADA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY MODEL, 2020-2029 (USD THOUSAND)
TABLE 62 CANADA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY APPLICATION, 2020-2029 (USD THOUSAND)
TABLE 63 CANADA ICE OR GAS TURBINE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 64 CANADA WASTE TO ENERGY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 65 CANADA METAL PRODUCTION IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 66 CANADA CEMENT AND LIME INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 67 CANADA GLASS INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 68 CANADA PETROLEUM REFINING IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 69 CANADA CHEMICAL INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 70 CANADA LANDFILL ICE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 71 MEXICO ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 72 MEXICO ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY CAPACITY, 2020-2029 (USD THOUSAND)
TABLE 73 MEXICO ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY MODEL, 2020-2029 (USD THOUSAND)
TABLE 74 MEXICO ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY APPLICATION, 2020-2029 (USD THOUSAND)
TABLE 75 MEXICO ICE OR GAS TURBINE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 76 MEXICO WASTE TO ENERGY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 77 MEXICO METAL PRODUCTION IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 78 MEXICO CEMENT AND LIME INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 79 MEXICO GLASS INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 80 MEXICO PETROLEUM REFINING IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 81 MEXICO CHEMICAL INDUSTRY IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
TABLE 82 MEXICO LANDFILL ICE IN ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET, BY SIZE, 2020-2029 (USD THOUSAND)
List of Figure
FIGURE 1 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: SEGMENTATION
FIGURE 2 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: DATA TRIANGULATION
FIGURE 3 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: DROC ANALYSIS
FIGURE 4 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: NORTH AMERICA VS REGIONAL MARKET ANALYSIS
FIGURE 5 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: COMPANY RESEARCH ANALYSIS
FIGURE 6 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: INTERVIEW DEMOGRAPHICS
FIGURE 7 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: DBMR MARKET POSITION GRID
FIGURE 8 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: VENDOR SHARE ANALYSIS
FIGURE 9 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: MARKET APPLICATION COVERAGE GRID
FIGURE 10 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: MULTIVARIATE MODELING
FIGURE 11 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: SIZE TIMELINE CURVE
FIGURE 12 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: SEGMENTATION
FIGURE 13 RISE IN IMPORTANCE FOR GENERATING POWER FROM WASTE HEAT RECOVERY IS EXPECTED TO DRIVE THE NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET IN THE FORECAST PERIOD 2022-2029
FIGURE 14 MEDIUM SEGMENT IS EXPECTED TO ACCOUNT FOR THE LARGEST SHARE OF THE NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET IN 2022 & 2029
FIGURE 15 DRIVERS, RESTRAINTS, OPPORTUNITIES, AND CHALLENGES OF NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET
FIGURE 16 REAL GROSS DOMESTIC PRODUCT (GDP) GROWTH RATE OF INDIA
FIGURE 17 GEOTHERMAL POWER GENERATION IN THE NET ZERO SCENARIO, 2000-2030
FIGURE 18 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET : BY SIZE, 2021
FIGURE 19 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET : BY CAPACITY, 2021
FIGURE 20 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET : BY MODEL, 2021
FIGURE 21 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: BY APPLICATION, 2021
FIGURE 22 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: SNAPSHOT (2021)
FIGURE 23 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: BY COUNTRY (2021)
FIGURE 24 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: BY COUNTRY (2022 & 2029)
FIGURE 25 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: BY COUNTRY (2021 & 2029)
FIGURE 26 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: BY SIZE (2022-2029)
FIGURE 27 NORTH AMERICA ORGANIC RANKINE CYCLE (ORC) WASTE HEAT TO POWER MARKET: COMPANY SHARE 2021 (%)
منهجية البحث
يتم جمع البيانات وتحليل سنة الأساس باستخدام وحدات جمع البيانات ذات أحجام العينات الكبيرة. تتضمن المرحلة الحصول على معلومات السوق أو البيانات ذات الصلة من خلال مصادر واستراتيجيات مختلفة. تتضمن فحص وتخطيط جميع البيانات المكتسبة من الماضي مسبقًا. كما تتضمن فحص التناقضات في المعلومات التي شوهدت عبر مصادر المعلومات المختلفة. يتم تحليل بيانات السوق وتقديرها باستخدام نماذج إحصائية ومتماسكة للسوق. كما أن تحليل حصة السوق وتحليل الاتجاهات الرئيسية هي عوامل النجاح الرئيسية في تقرير السوق. لمعرفة المزيد، يرجى طلب مكالمة محلل أو إرسال استفسارك.
منهجية البحث الرئيسية التي يستخدمها فريق بحث DBMR هي التثليث البيانات والتي تتضمن استخراج البيانات وتحليل تأثير متغيرات البيانات على السوق والتحقق الأولي (من قبل خبراء الصناعة). تتضمن نماذج البيانات شبكة تحديد موقف البائعين، وتحليل خط زمني للسوق، ونظرة عامة على السوق ودليل، وشبكة تحديد موقف الشركة، وتحليل براءات الاختراع، وتحليل التسعير، وتحليل حصة الشركة في السوق، ومعايير القياس، وتحليل حصة البائعين على المستوى العالمي مقابل الإقليمي. لمعرفة المزيد عن منهجية البحث، أرسل استفسارًا للتحدث إلى خبراء الصناعة لدينا.
التخصيص متاح
تعد Data Bridge Market Research رائدة في مجال البحوث التكوينية المتقدمة. ونحن نفخر بخدمة عملائنا الحاليين والجدد بالبيانات والتحليلات التي تتطابق مع هدفهم. ويمكن تخصيص التقرير ليشمل تحليل اتجاه الأسعار للعلامات التجارية المستهدفة وفهم السوق في بلدان إضافية (اطلب قائمة البلدان)، وبيانات نتائج التجارب السريرية، ومراجعة الأدبيات، وتحليل السوق المجدد وقاعدة المنتج. ويمكن تحليل تحليل السوق للمنافسين المستهدفين من التحليل القائم على التكنولوجيا إلى استراتيجيات محفظة السوق. ويمكننا إضافة عدد كبير من المنافسين الذين تحتاج إلى بيانات عنهم بالتنسيق وأسلوب البيانات الذي تبحث عنه. ويمكن لفريق المحللين لدينا أيضًا تزويدك بالبيانات في ملفات Excel الخام أو جداول البيانات المحورية (كتاب الحقائق) أو مساعدتك في إنشاء عروض تقديمية من مجموعات البيانات المتوفرة في التقرير.
