The Global Food Robotics Market size is expected to reach $4 billion by 2028, rising at a market growth of 10.2% CAGR during the forecast period.
Food robotics are referred to as robots employed in the food and beverage business to carry out intricate tasks like picking, packing, and palletizing. Robots from science fiction are already a reality owing to various technological developments. Furthermore, robots are becoming a crucial component of many sectors due to the rise in demand for increased productivity and the introduction of robots to job or task automation.
Automation and robotics play a significant role in the solution. The food manufacturing business has been particularly sluggish in incorporating robotics compared to other industries. Robotics, however, has begun to penetrate practically every stage of the food supply chain in the past few years, from the farm to the kitchen. Seedling planting, identification, and sorting are examples of robotic applications.
Additionally, self-driving tractors are also present nowadays along with robots for harvesting and weeding. Robotics are also being brought to the dairy, poultry, and cattle production sectors of non-plant agriculture. Applications include self-sufficient milking and feeding, egg gathering and sorting, and self-sufficient cleaning. Despite being originally developed to lift heavy metal components, modern technology can pick up delicate items like bread loaves, cheese, and fruits without causing any harm.
Manufacturers of food are now able to keep an eye on products as well as consumer demand, then use data analysis to tailor the output to this need. Robotics and the creation of AI software enable this. Companies can better monitor food quality and safety when they are better equipped to assess crucial processes like shipping, processing, and storage, as well as whether food is accidentally contaminated, where that food was shipped, and where that food was acquired from. Several large food service companies have recently invested in robots and artificial intelligence.
The market research report covers the analysis of key stake holders of the market. Key companies profiled in the report include Mitsubishi Electric Corporation, ABB Group, Rockwell Automation, Inc., Kawasaki Heavy Industries, Ltd., Kuka AG (Midea Investment Holding Co., Ltd.), FANUC Corporation, Yaskawa Electric Corporation, Seiko Epson Corporation, Teradyne, Inc. (Universal Robots A/S) and Denso Corporation
Food robotics are referred to as robots employed in the food and beverage business to carry out intricate tasks like picking, packing, and palletizing. Robots from science fiction are already a reality owing to various technological developments. Furthermore, robots are becoming a crucial component of many sectors due to the rise in demand for increased productivity and the introduction of robots to job or task automation.
Automation and robotics play a significant role in the solution. The food manufacturing business has been particularly sluggish in incorporating robotics compared to other industries. Robotics, however, has begun to penetrate practically every stage of the food supply chain in the past few years, from the farm to the kitchen. Seedling planting, identification, and sorting are examples of robotic applications.
Additionally, self-driving tractors are also present nowadays along with robots for harvesting and weeding. Robotics are also being brought to the dairy, poultry, and cattle production sectors of non-plant agriculture. Applications include self-sufficient milking and feeding, egg gathering and sorting, and self-sufficient cleaning. Despite being originally developed to lift heavy metal components, modern technology can pick up delicate items like bread loaves, cheese, and fruits without causing any harm.
Manufacturers of food are now able to keep an eye on products as well as consumer demand, then use data analysis to tailor the output to this need. Robotics and the creation of AI software enable this. Companies can better monitor food quality and safety when they are better equipped to assess crucial processes like shipping, processing, and storage, as well as whether food is accidentally contaminated, where that food was shipped, and where that food was acquired from. Several large food service companies have recently invested in robots and artificial intelligence.
COVID-19 Impact Analysis
The COVID-19 pandemic brought on a significant economic depression. Several nations implemented strict lockdowns to contain the virus, which caused the closure of food & beverages (F&B) processing facilities and a brief disruption in the F&B supply chain. The absence of F&B products and necessities, panic buying by consumers worldwide, disruption of supply chains as a result of travel restrictions, and labor shortages had a substantial influence on the F&B supply chain. Major robot manufacturers reported lower revenue generation in the first half of 2020 due to lower sales brought on by an economic slowdown. This was brought on by quarantine and lockdown restrictions imposed by governments worldwide, as well as a temporary decrease in the demand for automation.Market Growth Factors
Demand for packaged foods is increasing
The need for ready-to-cook and ready-to-eat foods has increased in recent years, necessitating the packaging of food goods to extend their shelf life and meet consumer demand. The mass production of packaged food goods has pushed the market for food robotics, especially in nations such as the United States, Japan, France, and Italy. Most large-scale food manufacturing factories are automating their procedures to assure quality and consistency in the Stock Keeping Units (SKUs). Agriculture and food manufacturing tasks are more difficult to automate using robots, yet companies continue to implement them. As a result, the expansion of the packaged dairy products and baked goods industries is also driving the market for food robotics, as these products are mass-produced across regions.Increasing digitalization in the food and beverage industries
Digitalization is the optimization of corporate operations by emerging digital technologies, such as IT/OT convergence, big data analytics, digital twin, 3D printing, artificial intelligence, and automation technologies. IoT and AI are assisting businesses in achieving high levels of food safety, enhancing food traceability, reducing food waste, and lowering food processing and packaging-related costs and risks. In recent years, digitalization has emerged as a crucial driver for automation, where artificial intelligence (AI) pushes operational productivity through enhancing workforce productivity. Hence, the growing adoption of digitalization across the F&B industry will propel the growth of the food robotics market in the coming years.Market Restraining Factors
High cost of robotic system installation
Due to the additional installation expense, most food and beverages businesses are unwilling to implement automated procedures. Market expansion is hindered by the extra cost of integrating individual robots into a comprehensive robotic system, including peripheral equipment such as safety barriers, sensors, programmable logic controllers (PLC), human-machine interface (HMI), and safety systems. In addition, engineering expenses include installation, programming, and commissioning. These increased expenses limit the growth of the market. Small and medium-sized manufacturers are hesitant to incur substantial installation expenditures at the outset since it could delay the payback period and further increase their operational cost.Application Outlook
Based on application, the food robotics market is divided into palletizing & processing, packaging, repackaging, pick & place, and others. In 2021, the palletizing & processing segment dominated the food robotics market with maximum revenue share. Robotic palletizing ensures quick and effective operations to increase throughput, improve quality, and improve working conditions for personnel. Robotics use grippers for either cases, bags, or crates and operate with people to increase production. They smoothly integrate into the current manufacturing line. Humans do not best perform numerous tasks involved in meat preparation.Payload Outlook
On the basis of payload, the food robotics market is fragmented into low, medium and high. The low segment covered a remarkable revenue share in the food robotics market in 2021. Many of the available SCARA food robots fall under the low payload category as picking objects is considered a rather simplistic task. The expertise in food handling, pick-and-place, packaging & palletizing, sealing, labeling, and spraying, among many other things, is largely responsible for the segment's explosive expansion.Type Outlook
By type, the food robotics market is segmented into articulated, cartesian, SCARA, cylindrical, collaborative and others. The SCARA segment generated the prominent revenue share in the food robotics market in 2021. A selective compliance articulated robot arm (SCARA) robot is intended for pick-and-place applications and has a relatively high speed and a high degree of precision. SCARA robots can easily and adaptably solve a number of automated assembling applications. Demand is rising with the expanding use of food robotics in this industry.Regional Outlook
Region wise, the food robotics market is analyzed across North America, Europe, Asia Pacific and LAMEA. In 2021, the Asia Pacific region held the highest revenue share in the food robotics market. The rapid expansion of the food robotics market in this region is ascribed to the population's shift toward prepared and packaged foods as a result of growing concerns about food safety and lifestyle. The region's desire for high-tech packaged foods and beverages has been spurred by the rise in consumer income. In Asia Pacific, China is well-known as the nation that sets the standard for food robot adoption.Food Robotics Market Competition Analysis
The major strategies followed by the market participants are Product Launches. Based on the Analysis presented in the Cardinal matrix; Rockwell Automation, Inc. and ABB Group are the forerunners in the Food Robotics Market. Companies such as Mitsubishi Electric Corporation, FANUC Corporation, and Denso Corporation are some of the key innovators in Food Robotics Market.The market research report covers the analysis of key stake holders of the market. Key companies profiled in the report include Mitsubishi Electric Corporation, ABB Group, Rockwell Automation, Inc., Kawasaki Heavy Industries, Ltd., Kuka AG (Midea Investment Holding Co., Ltd.), FANUC Corporation, Yaskawa Electric Corporation, Seiko Epson Corporation, Teradyne, Inc. (Universal Robots A/S) and Denso Corporation
Strategies deployed in Food Robotics Market
Partnerships, Collaborations and Agreements:
- Jan-2022: Mitsubishi came into partnership with Cartken, a US-based developer of an outdoor delivery robot. The partnership involves jointly working to introduce Cartken's delivery robots to a Japanese mall. The partnership allows Mitsubishi to explore other applications of the technology and enables them to enter the Japanese autonomous delivery market
- Apr-2021: Rockwell Automation partnered with Comau, an Italy-based provider of industrial automation and a manufacturer of robots. The partnership involves providing businesses globally with essential tools to boost efficiency in manufacturing processes. Moreover, the integration of Rockwell's expertise in food and beverage, life sciences, automated material handling, and Comau’s competence in industrial and robotics automation benefits customers through improved value
- Feb-2021: Epson Robots, part of Seiko Epson came into partnership with Heitek Automation, a distributor of automation products and solutions. The partnership agreement involves establishing Heitek as Epson's official distributor for robot automation solutions
Product Launches and Product Expansions:
- Oct-2022: Yaskawa launched MOTOMAN-HC30PL, a collaborative robot. The new cobot features a 30 kg payload capacity, 1600 mm reach, easy connection with peripheral devices, secure design, increased safety, and is easy to operate
- Mar-2022: FANUC launched CRX-5iA, CRX-20iA/L and CRX-25iA cobots. These new cobots are a part of the CRX series. The new products are developed to serve every type of manufacturer. Further, these robots perfectly fit and align with FANUC's already existing CR and CRX series
- Mar-2022: Mitsubishi Electric introduced a system that allows robots to carry out tasks in conditions where they have had difficulty performing in the past. The new system has the potential to reduce the number of hours needed to perform a task
- Feb-2022: Yaskawa introduced two new collaborative robots, HC10DTP and HC20DTP, both equipped with six axes. The new cobots are made up of cast aluminum, are IP67-rated, are food-grade certified, and can be used in splash-prone or damp areas. The new robots have multiple applications including dispensing, machine tending, packaging, welding, etc
- Sep-2021: ABB launched GoFa CRB 15000, a collaborative robot. The GoFa CRB 15000 features, a 950mm reach and speed of up to 2.2 meters per second, and can perform multiple tasks including pick, pack-and-place, product handling, and kitting. Moreover, the new cobot caters to the evolving demand for heavy payload robots
- Feb-2021: ABB introduced GoFa and SWIFTI cobot (collaborative robot) families. The new robots features, a higher payload capacity, are faster and stronger and are simple to operate & configure. The new product expands and complements ABB's already existing cobot product offerings, and further advances the company's growth in multiple high-growth segments including, healthcare, food & beverage, electronics, etc
- Aug-2020: Mitsubishi Electric India, part of Mitsubishi Electric Corporation launched the MELFA ASSISTA Series of Collaborative Robots. The Cobot features collision detection and is ISO 10218-1 and ISO/TS15066 compliant. The new product would make the manufacturing process smooth and efficient, and would also improve productivity by working alongside the employees
Acquisitions and Mergers:
- Jul-2021: ABB acquired ASTI Mobile Robotics Group, a Spain-based provider of automated intralogistics technologies. The acquisition broadens ABB's robotics and automation portfolio. Further, the addition of ASTI aligns with ABB's external growth strategy
»Geographical Expansions:
- Aug-2022: YASKAWA India, part of Yaskawa Electric Corporation opened a new robotic solution facility in Haryana, India. The new facility focuses on advancing and promoting innovation, and further aims to develop and advance industrial robotic automation
- Jul-2022: FANUC America expanded its Michigan facility to nearly two million square feet. This expansion of the facility allows FANUC to cater to the heavy demand for its automation solutions
- Jul-2022: FANUC expanded its footprint by setting up a new 109,000-sq.-ft. a facility in Aguascalientes, Mexico which would also act as robotics and automation headquarters. This geographical expansion enables FANUC to better take care of the needs of its clients operating in the aerospace, consumer goods, and aerospace industry. Moreover, the expansion further reflects FANUC's devotion to supporting organizations in enhancing their production processes
Scope of the Study
Market Segments Covered in the Report:
By Application
- Palletizing & Processing
- Packaging
- Repackaging
- Pick & Place
- Others
By Payload
- Medium
- High
- Low
By Type
- Articulated
- Cartesian
- Scara
- Cylindrical
- Collaborative
- Others
By Geography
North America
- US
- Canada
- Mexico
- Rest of North America
Europe
- Germany
- UK
- France
- Russia
- Spain
- Italy
- Rest of Europe
Asia Pacific
- China
- Japan
- India
- South Korea
- Singapore
- Malaysia
- Rest of Asia Pacific
LAMEA
- Brazil
- Argentina
- UAE
- Saudi Arabia
- South Africa
- Nigeria
- Rest of LAMEA
Key Market Players
List of Companies Profiled in the Report:
- Mitsubishi Electric Corporation
- ABB Group
- Rockwell Automation, Inc
- Kawasaki Heavy Industries, Ltd
- Kuka AG (Midea Investment Holding Co., Ltd.)
- FANUC Corporation
- Yaskawa Electric Corporation
- Seiko Epson Corporation
- Teradyne, Inc. (Universal Robots A/S)
- Denso Corporation
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- Exhaustive coverage
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- Assured post sales research support with 10% customization free
Table of Contents
Chapter 1. Market Scope & Methodology1.1 Market Definition
1.2 Objectives
1.3 Market Scope
1.4 Segmentation
1.4.1 Global Food Robotics Market, by Application
1.4.2 Global Food Robotics Market, by Payload
1.4.3 Global Food Robotics Market, by Type
1.4.4 Global Food Robotics Market, by Geography
1.5 Methodology for the research
Chapter 2. Market Overview
2.1 Introduction
2.1.1 Overview
2.1.1.1 Market Composition & Scenario
2.2 Key Factors Impacting the Market
2.2.1 Market Drivers
2.2.2 Market Restraints
Chapter 3. Competition Analysis - Global
3.1 KBV Cardinal Matrix
3.2 Recent Industry Wide Strategic Developments
3.2.1 Partnerships, Collaborations and Agreements
3.2.2 Product Launches and Product Expansions
3.2.3 Acquisition and Mergers
3.2.4 Geographical Expansions
3.3 Top Winning Strategies
3.3.1 Key Leading Strategies: Percentage Distribution (2018-2022)
3.3.2 Key Strategic Move: (Product Launches and Product Expansions : 2020, Aug - 2022, Oct) Leading Players
Chapter 4. Global Food Robotics Market by Application
4.1 Global Palletizing & Processing Market by Region
4.2 Global Packaging Market by Region
4.3 Global Repackaging Market by Region
4.4 Global Pick & Place Market by Region
4.5 Global Others Market by Region
Chapter 5. Global Food Robotics Market by Payload
5.1 Global Medium Market by Region
5.2 Global High Market by Region
5.3 Global Low Market by Region
Chapter 6. Global Food Robotics Market by Type
6.1 Global Articulated Market by Region
6.2 Global Cartesian Market by Region
6.3 Global Scara Market by Region
6.4 Global Cylindrical Market by Region
6.5 Global Collaborative Market by Region
6.6 Global Others Market by Region
Chapter 7. Global Food Robotics Market by Region
7.1 North America Food Robotics Market
7.1.1 North America Food Robotics Market by Application
7.1.1.1 North America Palletizing & Processing Market by Country
7.1.1.2 North America Packaging Market by Country
7.1.1.3 North America Repackaging Market by Country
7.1.1.4 North America Pick & Place Market by Country
7.1.1.5 North America Others Market by Country
7.1.2 North America Food Robotics Market by Payload
7.1.2.1 North America Medium Market by Country
7.1.2.2 North America High Market by Country
7.1.2.3 North America Low Market by Country
7.1.3 North America Food Robotics Market by Type
7.1.3.1 North America Articulated Market by Country
7.1.3.2 North America Cartesian Market by Country
7.1.3.3 North America Scara Market by Country
7.1.3.4 North America Cylindrical Market by Country
7.1.3.5 North America Collaborative Market by Country
7.1.3.6 North America Others Market by Country
7.1.4 North America Food Robotics Market by Country
7.1.4.1 US Food Robotics Market
7.1.4.1.1 US Food Robotics Market by Application
7.1.4.1.2 US Food Robotics Market by Payload
7.1.4.1.3 US Food Robotics Market by Type
7.1.4.2 Canada Food Robotics Market
7.1.4.2.1 Canada Food Robotics Market by Application
7.1.4.2.2 Canada Food Robotics Market by Payload
7.1.4.2.3 Canada Food Robotics Market by Type
7.1.4.3 Mexico Food Robotics Market
7.1.4.3.1 Mexico Food Robotics Market by Application
7.1.4.3.2 Mexico Food Robotics Market by Payload
7.1.4.3.3 Mexico Food Robotics Market by Type
7.1.4.4 Rest of North America Food Robotics Market
7.1.4.4.1 Rest of North America Food Robotics Market by Application
7.1.4.4.2 Rest of North America Food Robotics Market by Payload
7.1.4.4.3 Rest of North America Food Robotics Market by Type
7.2 Europe Food Robotics Market
7.2.1 Europe Food Robotics Market by Application
7.2.1.1 Europe Palletizing & Processing Market by Country
7.2.1.2 Europe Packaging Market by Country
7.2.1.3 Europe Repackaging Market by Country
7.2.1.4 Europe Pick & Place Market by Country
7.2.1.5 Europe Others Market by Country
7.2.2 Europe Food Robotics Market by Payload
7.2.2.1 Europe Medium Market by Country
7.2.2.2 Europe High Market by Country
7.2.2.3 Europe Low Market by Country
7.2.3 Europe Food Robotics Market by Type
7.2.3.1 Europe Articulated Market by Country
7.2.3.2 Europe Cartesian Market by Country
7.2.3.3 Europe Scara Market by Country
7.2.3.4 Europe Cylindrical Market by Country
7.2.3.5 Europe Collaborative Market by Country
7.2.3.6 Europe Others Market by Country
7.2.4 Europe Food Robotics Market by Country
7.2.4.1 Germany Food Robotics Market
7.2.4.1.1 Germany Food Robotics Market by Application
7.2.4.1.2 Germany Food Robotics Market by Payload
7.2.4.1.3 Germany Food Robotics Market by Type
7.2.4.2 UK Food Robotics Market
7.2.4.2.1 UK Food Robotics Market by Application
7.2.4.2.2 UK Food Robotics Market by Payload
7.2.4.2.3 UK Food Robotics Market by Type
7.2.4.3 France Food Robotics Market
7.2.4.3.1 France Food Robotics Market by Application
7.2.4.3.2 France Food Robotics Market by Payload
7.2.4.3.3 France Food Robotics Market by Type
7.2.4.4 Russia Food Robotics Market
7.2.4.4.1 Russia Food Robotics Market by Application
7.2.4.4.2 Russia Food Robotics Market by Payload
7.2.4.4.3 Russia Food Robotics Market by Type
7.2.4.5 Spain Food Robotics Market
7.2.4.5.1 Spain Food Robotics Market by Application
7.2.4.5.2 Spain Food Robotics Market by Payload
7.2.4.5.3 Spain Food Robotics Market by Type
7.2.4.6 Italy Food Robotics Market
7.2.4.6.1 Italy Food Robotics Market by Application
7.2.4.6.2 Italy Food Robotics Market by Payload
7.2.4.6.3 Italy Food Robotics Market by Type
7.2.4.7 Rest of Europe Food Robotics Market
7.2.4.7.1 Rest of Europe Food Robotics Market by Application
7.2.4.7.2 Rest of Europe Food Robotics Market by Payload
7.2.4.7.3 Rest of Europe Food Robotics Market by Type
7.3 Asia Pacific Food Robotics Market
7.3.1 Asia Pacific Food Robotics Market by Application
7.3.1.1 Asia Pacific Palletizing & Processing Market by Country
7.3.1.2 Asia Pacific Packaging Market by Country
7.3.1.3 Asia Pacific Repackaging Market by Country
7.3.1.4 Asia Pacific Pick & Place Market by Country
7.3.1.5 Asia Pacific Others Market by Country
7.3.2 Asia Pacific Food Robotics Market by Payload
7.3.2.1 Asia Pacific Medium Market by Country
7.3.2.2 Asia Pacific High Market by Country
7.3.2.3 Asia Pacific Low Market by Country
7.3.3 Asia Pacific Food Robotics Market by Type
7.3.3.1 Asia Pacific Articulated Market by Country
7.3.3.2 Asia Pacific Cartesian Market by Country
7.3.3.3 Asia Pacific Scara Market by Country
7.3.3.4 Asia Pacific Cylindrical Market by Country
7.3.3.5 Asia Pacific Collaborative Market by Country
7.3.3.6 Asia Pacific Others Market by Country
7.3.4 Asia Pacific Food Robotics Market by Country
7.3.4.1 China Food Robotics Market
7.3.4.1.1 China Food Robotics Market by Application
7.3.4.1.2 China Food Robotics Market by Payload
7.3.4.1.3 China Food Robotics Market by Type
7.3.4.2 Japan Food Robotics Market
7.3.4.2.1 Japan Food Robotics Market by Application
7.3.4.2.2 Japan Food Robotics Market by Payload
7.3.4.2.3 Japan Food Robotics Market by Type
7.3.4.3 India Food Robotics Market
7.3.4.3.1 India Food Robotics Market by Application
7.3.4.3.2 India Food Robotics Market by Payload
7.3.4.3.3 India Food Robotics Market by Type
7.3.4.4 South Korea Food Robotics Market
7.3.4.4.1 South Korea Food Robotics Market by Application
7.3.4.4.2 South Korea Food Robotics Market by Payload
7.3.4.4.3 South Korea Food Robotics Market by Type
7.3.4.5 Singapore Food Robotics Market
7.3.4.5.1 Singapore Food Robotics Market by Application
7.3.4.5.2 Singapore Food Robotics Market by Payload
7.3.4.5.3 Singapore Food Robotics Market by Type
7.3.4.6 Malaysia Food Robotics Market
7.3.4.6.1 Malaysia Food Robotics Market by Application
7.3.4.6.2 Malaysia Food Robotics Market by Payload
7.3.4.6.3 Malaysia Food Robotics Market by Type
7.3.4.7 Rest of Asia Pacific Food Robotics Market
7.3.4.7.1 Rest of Asia Pacific Food Robotics Market by Application
7.3.4.7.2 Rest of Asia Pacific Food Robotics Market by Payload
7.3.4.7.3 Rest of Asia Pacific Food Robotics Market by Type
7.4 LAMEA Food Robotics Market
7.4.1 LAMEA Food Robotics Market by Application
7.4.1.1 LAMEA Palletizing & Processing Market by Country
7.4.1.2 LAMEA Packaging Market by Country
7.4.1.3 LAMEA Repackaging Market by Country
7.4.1.4 LAMEA Pick & Place Market by Country
7.4.1.5 LAMEA Others Market by Country
7.4.2 LAMEA Food Robotics Market by Payload
7.4.2.1 LAMEA Medium Market by Country
7.4.2.2 LAMEA High Market by Country
7.4.2.3 LAMEA Low Market by Country
7.4.3 LAMEA Food Robotics Market by Type
7.4.3.1 LAMEA Articulated Market by Country
7.4.3.2 LAMEA Cartesian Market by Country
7.4.3.3 LAMEA Scara Market by Country
7.4.3.4 LAMEA Cylindrical Market by Country
7.4.3.5 LAMEA Collaborative Market by Country
7.4.3.6 LAMEA Others Market by Country
7.4.4 LAMEA Food Robotics Market by Country
7.4.4.1 Brazil Food Robotics Market
7.4.4.1.1 Brazil Food Robotics Market by Application
7.4.4.1.2 Brazil Food Robotics Market by Payload
7.4.4.1.3 Brazil Food Robotics Market by Type
7.4.4.2 Argentina Food Robotics Market
7.4.4.2.1 Argentina Food Robotics Market by Application
7.4.4.2.2 Argentina Food Robotics Market by Payload
7.4.4.2.3 Argentina Food Robotics Market by Type
7.4.4.3 UAE Food Robotics Market
7.4.4.3.1 UAE Food Robotics Market by Application
7.4.4.3.2 UAE Food Robotics Market by Payload
7.4.4.3.3 UAE Food Robotics Market by Type
7.4.4.4 Saudi Arabia Food Robotics Market
7.4.4.4.1 Saudi Arabia Food Robotics Market by Application
7.4.4.4.2 Saudi Arabia Food Robotics Market by Payload
7.4.4.4.3 Saudi Arabia Food Robotics Market by Type
7.4.4.5 South Africa Food Robotics Market
7.4.4.5.1 South Africa Food Robotics Market by Application
7.4.4.5.2 South Africa Food Robotics Market by Payload
7.4.4.5.3 South Africa Food Robotics Market by Type
7.4.4.6 Nigeria Food Robotics Market
7.4.4.6.1 Nigeria Food Robotics Market by Application
7.4.4.6.2 Nigeria Food Robotics Market by Payload
7.4.4.6.3 Nigeria Food Robotics Market by Type
7.4.4.7 Rest of LAMEA Food Robotics Market
7.4.4.7.1 Rest of LAMEA Food Robotics Market by Application
7.4.4.7.2 Rest of LAMEA Food Robotics Market by Payload
7.4.4.7.3 Rest of LAMEA Food Robotics Market by Type
Chapter 8. Company Profiles
8.1 ABB Group
8.1.1 Company Overview
8.1.2 Financial Analysis
8.1.3 Segmental and Regional Analysis
8.1.4 Research & Development Expense
8.1.5 Recent strategies and developments:
8.1.5.1 Product Launches and Product Expansions:
8.1.5.2 Acquisition and Mergers:
8.1.6 SWOT Analysis
8.2 Mitsubishi Electric Corporation
8.2.1 Company Overview
8.2.2 Financial Analysis
8.2.3 Segmental and Regional Analysis
8.2.4 Research & Development Expense
8.2.5 Recent strategies and developments:
8.2.5.1 Partnerships, Collaborations, and Agreements:
8.2.5.2 Product Launches and Product Expansions:
8.3 FANUC Corporation
8.3.1 Company Overview
8.3.2 Financial Analysis
8.3.3 Regional Analysis
8.3.4 Research & Development Expense
8.3.5 Recent strategies and developments:
8.3.5.1 Partnerships, Collaborations, and Agreements:
8.3.5.2 Product Launches and Product Expansions:
8.3.5.3 Geographical Expansions:
8.4 Yaskawa Electric Corporation
8.4.1 Company Overview
8.4.2 Financial Analysis
8.4.3 Segmental and Regional Analysis
8.4.4 Research & Development Expenses
8.4.5 Recent strategies and developments:
8.4.5.1 Product Launches and Product Expansions:
8.4.5.2 Geographical Expansions:
8.5 Rockwell Automation, Inc.
8.5.1 Company Overview
8.5.2 Financial Analysis
8.5.3 Segmental and Regional Analysis
8.5.4 Research & Development Expenses
8.5.5 Recent strategies and developments:
8.5.5.1 Partnerships, Collaborations, and Agreements:
8.6 Universal Robots A/S (Teradyne, Inc.)
8.6.1 Company Overview
8.6.2 Financial Analysis
8.6.3 Segmental and Regional Analysis
8.7 Denso Corporation
8.7.1 Company Overview
8.7.2 Financial Analysis
8.7.3 Regional Analysis
8.7.4 Research & Development Expense
8.8 Kawasaki Heavy Industries, Ltd.
8.8.1 Company Overview
8.8.2 Financial Analysis
8.8.3 Segmental and Regional Analysis
8.8.4 Research & Development Expense
8.9 Seiko Epson Corporation
8.9.1 Company Overview
8.9.2 Financial Analysis
8.9.3 Segmental and Regional Analysis
8.9.4 Research & Development Expenses
8.9.5 Recent strategies and developments:
8.9.5.1 Partnerships, Collaborations, and Agreements:
8.10. Kuka AG (Midea Investment Holding Co., Ltd.)
8.10.1 Company Overview
8.10.2 Financial Analysis
8.10.3 Segmental and Regional Analysis
8.10.4 Research & Development Expense
Companies Mentioned
- Mitsubishi Electric Corporation
- ABB Group
- Rockwell Automation, Inc.
- Kawasaki Heavy Industries, Ltd.
- Kuka AG (Midea Investment Holding Co., Ltd.)
- FANUC Corporation
- Yaskawa Electric Corporation
- Seiko Epson Corporation
- Teradyne, Inc. (Universal Robots A/S)
- Denso Corporation
Methodology
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Table Information
| Report Attribute | Details |
|---|---|
| No. of Pages | 239 |
| Published | January 2023 |
| Forecast Period | 2021 - 2028 |
| Estimated Market Value ( USD | $ 2073.4 Million |
| Forecasted Market Value ( USD | $ 4034.4 Million |
| Compound Annual Growth Rate | 10.2% |
| Regions Covered | Global |
| No. of Companies Mentioned | 10 |
