Global Robotics in Shipbuilding Market Size study & Forecast, by Type (Articulated Robots Cartesian Robots, SCARA Robots, Cylindrical Robots, Others), by Application (Handling, Welding, Assembling, Inspection, Others), by Lifting Capacity (Less than 500 kg, 500 to 1000 kg, Over 1000 kg) and Regional Analysis, 2023-2030
Global Robotics in Shipbuilding Market is valued at approximately USD 1.26 billion in 2022 and is anticipated to grow with a healthy growth rate of more than 4.9% over the forecast period 2023-2030. Robotics in shipbuilding refers to the application of robotic systems and automation technologies in the construction and assembly of ships. It involves the use of advanced robotic tools, machinery, and computer-controlled systems to streamline and optimize various shipbuilding processes. The integration of robotics in shipbuilding brings numerous benefits, including increased productivity, improved precision, enhanced worker safety, reduced construction time, and better overall quality of the vessels. It enables shipyards to optimize operations, streamline workflows, and meet the growing demands of the maritime industry. The Robotics in the Shipbuilding market is expanding because of factors such as increased usage of robotics to plug labor gap in the shipbuilding industry and increasing shipbuilding demand.
The shipbuilding industry has historically relied on specialized workers for tasks including cutting, welding, and painting. Therefore, shipbuilders are embracing robot technology to save time and money. Additionally, robot technology is remarkably efficient and is demonstrating its ability to eliminate the labour shortage in the shipbuilding industry. For instance, Daewoo Shipbuilding & Marine Engineering (DSME) developed an innovative strategy in January 2023 to address the persistent manpower and talent shortages in the shipbuilding industry. The shipyard said that it has started implementing a collaborative robot-based automatic welding technology. In addition, the use of automation to streamline processes and the rise in demand for collaborative robotics and rising technological advancement in robotics technology is further creating lucrative opportunities for market growth. However, high initial investment and maintenance cost stifles market growth throughout the forecast period of 2023-2030.
The key regions considered for the Global Robotics in Shipbuilding Market study includes Asia Pacific, North America, Europe, Latin America, and Middle East & Africa. North America dominated the market in 2022 owing to factors such as an increase in shipbuilding activities in the region, rising investment in the adoption of automation technologies, and rising research and development projects in the region. Whereas, Europe is projected to grow significantly owing to factors such as the rising adoption of robotics technology in the industry, the rising development of new technologies in the region.
Major market player included in this report are:
ABB Group
The Fanuc Corporation
Comau S.p.A.
Yaskawa America, Inc.
Kuka AG
Sarcos Technology And Robotics Corp.
Seiko Epson Corporation
Universal Robots
Kawasaki Heavy Industries, Ltd.
Stдubli International AG
Recent Developments in the Market:
The report also caters detailed information about the crucial aspects such as driving factors & challenges which will define the future growth of the market. Additionally, it also incorporates potential opportunities in micro markets for stakeholders to invest along with the detailed analysis of competitive landscape and product offerings of key players. The detailed segments and sub-segment of the market are explained below:
By Type:
Articulated Robots
Cartesian Robots
SCARA Robots
Cylindrical Robots
Others
By Application:
Handling
Welding
Assembling
Inspection
Others
By Lifting Capacity:
Less than 500 kg
500 to 1000 kg
Over 1000 kg
By Region:
North America
U.S.
Canada
Europe
UK
Germany
France
Spain
Italy
ROE
Asia Pacific
China
India
Japan
Australia
South Korea
RoAPAC
Latin America
Brazil
Mexico
Middle East & Africa
Saudi Arabia
South Africa
Rest of Middle East & Africa
The shipbuilding industry has historically relied on specialized workers for tasks including cutting, welding, and painting. Therefore, shipbuilders are embracing robot technology to save time and money. Additionally, robot technology is remarkably efficient and is demonstrating its ability to eliminate the labour shortage in the shipbuilding industry. For instance, Daewoo Shipbuilding & Marine Engineering (DSME) developed an innovative strategy in January 2023 to address the persistent manpower and talent shortages in the shipbuilding industry. The shipyard said that it has started implementing a collaborative robot-based automatic welding technology. In addition, the use of automation to streamline processes and the rise in demand for collaborative robotics and rising technological advancement in robotics technology is further creating lucrative opportunities for market growth. However, high initial investment and maintenance cost stifles market growth throughout the forecast period of 2023-2030.
The key regions considered for the Global Robotics in Shipbuilding Market study includes Asia Pacific, North America, Europe, Latin America, and Middle East & Africa. North America dominated the market in 2022 owing to factors such as an increase in shipbuilding activities in the region, rising investment in the adoption of automation technologies, and rising research and development projects in the region. Whereas, Europe is projected to grow significantly owing to factors such as the rising adoption of robotics technology in the industry, the rising development of new technologies in the region.
Major market player included in this report are:
ABB Group
The Fanuc Corporation
Comau S.p.A.
Yaskawa America, Inc.
Kuka AG
Sarcos Technology And Robotics Corp.
Seiko Epson Corporation
Universal Robots
Kawasaki Heavy Industries, Ltd.
Stдubli International AG
Recent Developments in the Market:
- In January 2022, The South Korean shipbuilding company Daewoo Shipbuilding & Marine Engineering developed a collaborative robot (cobot) to boost productivity. Cobots are robots designed specifically for face-to-face interaction with humans in public spaces or other settings where humans and robots coexist.
- In July 2023, Italian shipbuilder Fincantieri and Italian robotics firm Comau have a contract for the development of robots and other solutions for use in heavy construction and other applications. At the Fincantieri shipyard, the two corporations would collaborate to create and test novel applications.
- Historical Data – 2020 - 2021
- Base Year for Estimation – 2022
- Forecast period - 2023-2030
- Report Coverage - Revenue forecast, Company Ranking, Competitive Landscape, Growth factors, and Trends
- Segments Covered – Type, Application, Lifting Capacity, Region
- Regional Scope - North America; Europe; Asia Pacific; Latin America; Middle East & Africa
- Customization Scope - Free report customization (equivalent up to 8 analyst’s working hours) with purchase. Addition or alteration to country, regional & segment scope*
The report also caters detailed information about the crucial aspects such as driving factors & challenges which will define the future growth of the market. Additionally, it also incorporates potential opportunities in micro markets for stakeholders to invest along with the detailed analysis of competitive landscape and product offerings of key players. The detailed segments and sub-segment of the market are explained below:
By Type:
Articulated Robots
Cartesian Robots
SCARA Robots
Cylindrical Robots
Others
By Application:
Handling
Welding
Assembling
Inspection
Others
By Lifting Capacity:
Less than 500 kg
500 to 1000 kg
Over 1000 kg
By Region:
North America
U.S.
Canada
Europe
UK
Germany
France
Spain
Italy
ROE
Asia Pacific
China
India
Japan
Australia
South Korea
RoAPAC
Latin America
Brazil
Mexico
Middle East & Africa
Saudi Arabia
South Africa
Rest of Middle East & Africa
CHAPTER 1. EXECUTIVE SUMMARY
1.1. Market Snapshot
1.2. Global & Segmental Market Estimates & Forecasts, 2020-2030 (USD Billion)
1.2.1. Robotics in Shipbuilding Market, by Region, 2020-2030 (USD Billion)
1.2.2. Robotics in Shipbuilding Market, by Type, 2020-2030 (USD Billion)
1.2.3. Robotics in Shipbuilding Market, by Application, 2020-2030 (USD Billion)
1.2.4. Robotics in Shipbuilding Market, by Lifting Capacity, 2020-2030 (USD Billion)
1.3. Key Trends
1.4. Estimation Methodology
1.5. Research Assumption
CHAPTER 2. GLOBAL ROBOTICS IN SHIPBUILDING MARKET DEFINITION AND SCOPE
2.1. Objective of the Study
2.2. Market Definition & Scope
2.2.1. Industry Evolution
2.2.2. Scope of the Study
2.3. Years Considered for the Study
2.4. Currency Conversion Rates
CHAPTER 3. GLOBAL ROBOTICS IN SHIPBUILDING MARKET DYNAMICS
3.1. Robotics in Shipbuilding Market Impact Analysis (2020-2030)
3.1.1. Market Drivers
3.1.1.1. Increased usage of robotics to plug labor gap in shipbuilding industry
3.1.1.2. Increasing shipbuilding demand
3.1.2. Market Challenges
3.1.2.1. High initial investment and maintenance cost
3.1.3. Market Opportunities
3.1.3.1. Use of automation to streamline processes
3.1.3.2. Rise in demand for collaborative robotics
3.1.3.3. Rising technological advancement in the robotics technology
CHAPTER 4. GLOBAL ROBOTICS IN SHIPBUILDING MARKET INDUSTRY ANALYSIS
4.1. Porter’s 5 Force Model
4.1.1. Bargaining Power of Suppliers
4.1.2. Bargaining Power of Buyers
4.1.3. Threat of New Entrants
4.1.4. Threat of Substitutes
4.1.5. Competitive Rivalry
4.2. Porter’s 5 Force Impact Analysis
4.3. PEST Analysis
4.3.1. Political
4.3.2. Economical
4.3.3. Social
4.3.4. Technological
4.3.5. Environmental
4.3.6. Legal
4.4. Top investment opportunity
4.5. Top winning strategies
4.6. COVID-19 Impact Analysis
4.7. Disruptive Trends
4.8. Industry Expert Perspective
4.9. Analyst Recommendation & Conclusion
CHAPTER 5. GLOBAL ROBOTICS IN SHIPBUILDING MARKET, BY TYPE
5.1. Market Snapshot
5.2. Global Robotics in Shipbuilding Market by Type, Performance - Potential Analysis
5.3. Global Robotics in Shipbuilding Market Estimates & Forecasts by Type 2020-2030 (USD Billion)
5.4. Robotics in Shipbuilding Market, Sub Segment Analysis
5.4.1. Articulated Robots
5.4.2. Cartesian Robots
5.4.3. SCARA Robots
5.4.4. Cylindrical Robots
5.4.5. Others
CHAPTER 6. GLOBAL ROBOTICS IN SHIPBUILDING MARKET, BY APPLICATION
6.1. Market Snapshot
6.2. Global Robotics in Shipbuilding Market by Application, Performance - Potential Analysis
6.3. Global Robotics in Shipbuilding Market Estimates & Forecasts by Application 2020-2030 (USD Billion)
6.4. Robotics in Shipbuilding Market, Sub Segment Analysis
6.4.1. Handling
6.4.2. Welding
6.4.3. Assembling
6.4.4. Inspection
6.4.5. Others
CHAPTER 7. GLOBAL ROBOTICS IN SHIPBUILDING MARKET, BY LIFTING CAPACITY
7.1. Market Snapshot
7.2. Global Robotics in Shipbuilding Market by Lifting Capacity, Performance - Potential Analysis
7.3. Global Robotics in Shipbuilding Market Estimates & Forecasts by Lifting Capacity 2020-2030 (USD Billion)
7.4. Robotics in Shipbuilding Market, Sub Segment Analysis
7.4.1. Less than 500 kg
7.4.2. 500 to 1000 kg
7.4.3. Over 1000 kg
CHAPTER 8. GLOBAL ROBOTICS IN SHIPBUILDING MARKET, REGIONAL ANALYSIS
8.1. Top Leading Countries
8.2. Top Emerging Countries
8.3. Robotics in Shipbuilding Market, Regional Market Snapshot
8.4. North America Robotics in Shipbuilding Market
8.4.1. U.S. Robotics in Shipbuilding Market
8.4.1.1. Type breakdown estimates & forecasts, 2020-2030
8.4.1.2. Application breakdown estimates & forecasts, 2020-2030
8.4.1.3. Lifting Capacity breakdown estimates & forecasts, 2020-2030
8.4.2. Canada Robotics in Shipbuilding Market
8.5. Europe Robotics in Shipbuilding Market Snapshot
8.5.1. U.K. Robotics in Shipbuilding Market
8.5.2. Germany Robotics in Shipbuilding Market
8.5.3. France Robotics in Shipbuilding Market
8.5.4. Spain Robotics in Shipbuilding Market
8.5.5. Italy Robotics in Shipbuilding Market
8.5.6. Rest of Europe Robotics in Shipbuilding Market
8.6. Asia-Pacific Robotics in Shipbuilding Market Snapshot
8.6.1. China Robotics in Shipbuilding Market
8.6.2. India Robotics in Shipbuilding Market
8.6.3. Japan Robotics in Shipbuilding Market
8.6.4. Australia Robotics in Shipbuilding Market
8.6.5. South Korea Robotics in Shipbuilding Market
8.6.6. Rest of Asia Pacific Robotics in Shipbuilding Market
8.7. Latin America Robotics in Shipbuilding Market Snapshot
8.7.1. Brazil Robotics in Shipbuilding Market
8.7.2. Mexico Robotics in Shipbuilding Market
8.8. Middle East & Africa Robotics in Shipbuilding Market
8.8.1. Saudi Arabia Robotics in Shipbuilding Market
8.8.2. South Africa Robotics in Shipbuilding Market
8.8.3. Rest of Middle East & Africa Robotics in Shipbuilding Market
CHAPTER 9. COMPETITIVE INTELLIGENCE
9.1. Key Company SWOT Analysis
9.1.1. Company
9.1.2. Company
9.1.3. Company
9.2. Top Market Strategies
9.3. Company Profiles
9.3.1. ABB Group
9.3.1.1. Key Information
9.3.1.2. Overview
9.3.1.3. Financial (Subject to Data Availability)
9.3.1.4. Product Summary
9.3.1.5. Recent Developments
9.3.2. The Fanuc Corporation
9.3.3. Comau S.p.A.
9.3.4. Yaskawa America, Inc.
9.3.5. Kuka AG
9.3.6. Sarcos Technology And Robotics Corp.
9.3.7. Seiko Epson Corporation
9.3.8. Universal Robots
9.3.9. Kawasaki Heavy Industries, Ltd.
9.3.10. Stдubli International AG
CHAPTER 10. RESEARCH PROCESS
10.1. Research Process
10.1.1. Data Mining
10.1.2. Analysis
10.1.3. Market Estimation
10.1.4. Validation
10.1.5. Publishing
10.2. Research Attributes
10.3. Research Assumption
1.1. Market Snapshot
1.2. Global & Segmental Market Estimates & Forecasts, 2020-2030 (USD Billion)
1.2.1. Robotics in Shipbuilding Market, by Region, 2020-2030 (USD Billion)
1.2.2. Robotics in Shipbuilding Market, by Type, 2020-2030 (USD Billion)
1.2.3. Robotics in Shipbuilding Market, by Application, 2020-2030 (USD Billion)
1.2.4. Robotics in Shipbuilding Market, by Lifting Capacity, 2020-2030 (USD Billion)
1.3. Key Trends
1.4. Estimation Methodology
1.5. Research Assumption
CHAPTER 2. GLOBAL ROBOTICS IN SHIPBUILDING MARKET DEFINITION AND SCOPE
2.1. Objective of the Study
2.2. Market Definition & Scope
2.2.1. Industry Evolution
2.2.2. Scope of the Study
2.3. Years Considered for the Study
2.4. Currency Conversion Rates
CHAPTER 3. GLOBAL ROBOTICS IN SHIPBUILDING MARKET DYNAMICS
3.1. Robotics in Shipbuilding Market Impact Analysis (2020-2030)
3.1.1. Market Drivers
3.1.1.1. Increased usage of robotics to plug labor gap in shipbuilding industry
3.1.1.2. Increasing shipbuilding demand
3.1.2. Market Challenges
3.1.2.1. High initial investment and maintenance cost
3.1.3. Market Opportunities
3.1.3.1. Use of automation to streamline processes
3.1.3.2. Rise in demand for collaborative robotics
3.1.3.3. Rising technological advancement in the robotics technology
CHAPTER 4. GLOBAL ROBOTICS IN SHIPBUILDING MARKET INDUSTRY ANALYSIS
4.1. Porter’s 5 Force Model
4.1.1. Bargaining Power of Suppliers
4.1.2. Bargaining Power of Buyers
4.1.3. Threat of New Entrants
4.1.4. Threat of Substitutes
4.1.5. Competitive Rivalry
4.2. Porter’s 5 Force Impact Analysis
4.3. PEST Analysis
4.3.1. Political
4.3.2. Economical
4.3.3. Social
4.3.4. Technological
4.3.5. Environmental
4.3.6. Legal
4.4. Top investment opportunity
4.5. Top winning strategies
4.6. COVID-19 Impact Analysis
4.7. Disruptive Trends
4.8. Industry Expert Perspective
4.9. Analyst Recommendation & Conclusion
CHAPTER 5. GLOBAL ROBOTICS IN SHIPBUILDING MARKET, BY TYPE
5.1. Market Snapshot
5.2. Global Robotics in Shipbuilding Market by Type, Performance - Potential Analysis
5.3. Global Robotics in Shipbuilding Market Estimates & Forecasts by Type 2020-2030 (USD Billion)
5.4. Robotics in Shipbuilding Market, Sub Segment Analysis
5.4.1. Articulated Robots
5.4.2. Cartesian Robots
5.4.3. SCARA Robots
5.4.4. Cylindrical Robots
5.4.5. Others
CHAPTER 6. GLOBAL ROBOTICS IN SHIPBUILDING MARKET, BY APPLICATION
6.1. Market Snapshot
6.2. Global Robotics in Shipbuilding Market by Application, Performance - Potential Analysis
6.3. Global Robotics in Shipbuilding Market Estimates & Forecasts by Application 2020-2030 (USD Billion)
6.4. Robotics in Shipbuilding Market, Sub Segment Analysis
6.4.1. Handling
6.4.2. Welding
6.4.3. Assembling
6.4.4. Inspection
6.4.5. Others
CHAPTER 7. GLOBAL ROBOTICS IN SHIPBUILDING MARKET, BY LIFTING CAPACITY
7.1. Market Snapshot
7.2. Global Robotics in Shipbuilding Market by Lifting Capacity, Performance - Potential Analysis
7.3. Global Robotics in Shipbuilding Market Estimates & Forecasts by Lifting Capacity 2020-2030 (USD Billion)
7.4. Robotics in Shipbuilding Market, Sub Segment Analysis
7.4.1. Less than 500 kg
7.4.2. 500 to 1000 kg
7.4.3. Over 1000 kg
CHAPTER 8. GLOBAL ROBOTICS IN SHIPBUILDING MARKET, REGIONAL ANALYSIS
8.1. Top Leading Countries
8.2. Top Emerging Countries
8.3. Robotics in Shipbuilding Market, Regional Market Snapshot
8.4. North America Robotics in Shipbuilding Market
8.4.1. U.S. Robotics in Shipbuilding Market
8.4.1.1. Type breakdown estimates & forecasts, 2020-2030
8.4.1.2. Application breakdown estimates & forecasts, 2020-2030
8.4.1.3. Lifting Capacity breakdown estimates & forecasts, 2020-2030
8.4.2. Canada Robotics in Shipbuilding Market
8.5. Europe Robotics in Shipbuilding Market Snapshot
8.5.1. U.K. Robotics in Shipbuilding Market
8.5.2. Germany Robotics in Shipbuilding Market
8.5.3. France Robotics in Shipbuilding Market
8.5.4. Spain Robotics in Shipbuilding Market
8.5.5. Italy Robotics in Shipbuilding Market
8.5.6. Rest of Europe Robotics in Shipbuilding Market
8.6. Asia-Pacific Robotics in Shipbuilding Market Snapshot
8.6.1. China Robotics in Shipbuilding Market
8.6.2. India Robotics in Shipbuilding Market
8.6.3. Japan Robotics in Shipbuilding Market
8.6.4. Australia Robotics in Shipbuilding Market
8.6.5. South Korea Robotics in Shipbuilding Market
8.6.6. Rest of Asia Pacific Robotics in Shipbuilding Market
8.7. Latin America Robotics in Shipbuilding Market Snapshot
8.7.1. Brazil Robotics in Shipbuilding Market
8.7.2. Mexico Robotics in Shipbuilding Market
8.8. Middle East & Africa Robotics in Shipbuilding Market
8.8.1. Saudi Arabia Robotics in Shipbuilding Market
8.8.2. South Africa Robotics in Shipbuilding Market
8.8.3. Rest of Middle East & Africa Robotics in Shipbuilding Market
CHAPTER 9. COMPETITIVE INTELLIGENCE
9.1. Key Company SWOT Analysis
9.1.1. Company
9.1.2. Company
9.1.3. Company
9.2. Top Market Strategies
9.3. Company Profiles
9.3.1. ABB Group
9.3.1.1. Key Information
9.3.1.2. Overview
9.3.1.3. Financial (Subject to Data Availability)
9.3.1.4. Product Summary
9.3.1.5. Recent Developments
9.3.2. The Fanuc Corporation
9.3.3. Comau S.p.A.
9.3.4. Yaskawa America, Inc.
9.3.5. Kuka AG
9.3.6. Sarcos Technology And Robotics Corp.
9.3.7. Seiko Epson Corporation
9.3.8. Universal Robots
9.3.9. Kawasaki Heavy Industries, Ltd.
9.3.10. Stдubli International AG
CHAPTER 10. RESEARCH PROCESS
10.1. Research Process
10.1.1. Data Mining
10.1.2. Analysis
10.1.3. Market Estimation
10.1.4. Validation
10.1.5. Publishing
10.2. Research Attributes
10.3. Research Assumption
