ロボット溶接の世界市場：タイプ別、可搬重量別、用途別、地域別の分析、規模、動向、COVID-19の影響、予測（～2028年）

世界のロボット溶接の市場規模は、2022年の60億1,000万米ドルから2028年までに115億7,000万米ドルに達し、2023年～2028年の予測期間中にCAGRで約11.5%の成長が予測されています。新興経済諸国（東南アジア・中国・インド・日本・ラテンアメリカ）の急速な発展や、製造部門におけるオートメーションの動向の高まり、IIoTの出現などが、溶接ロボットの需要の増加に寄与しています。

当レポートでは、世界のロボット溶接市場について調査分析し、市場動向、セグメント分析、地域分析、企業プロファイルなどを提供しています。

目次

第1章 エグゼクティブサマリー

第2章 イントロダクション

• ロボット溶接：概要
  • ロボット溶接の定義
  • ロボット溶接の利点
• ロボット溶接セグメンテーション：概要
  • ロボット溶接のセグメンテーション

第3章 世界市場の分析

• 世界のロボット溶接市場：分析
  • 世界のロボット溶接市場：概要
  • 世界のロボット溶接市場（金額）
  • 世界のロボット溶接市場：タイプ別（スポット溶接、アーク溶接、その他）
  • 世界のロボット溶接市場：可搬重量別（50kg未満、50kg～150kg、150kg超）
  • 世界のロボット溶接市場：用途別（自動車・輸送、電気・電子、金属・機械、建設、その他）
  • 世界のロボット溶接市場：地域別（北米・欧州・アジア太平洋・その他の地域）
• 世界のロボット溶接市場：タイプの分析
  • 世界のロボット溶接市場：タイプ別、概要
  • 世界のアークロボット溶接市場（金額）
  • 世界のスポットロボット溶接市場（金額）
  • 世界のその他のロボット溶接市場（金額）
• 世界のロボット溶接市場：可搬重量の分析
  • 世界のロボット溶接市場：可搬重量別、概要
  • 世界の50kg未満のロボット溶接市場（金額）
  • 世界の50kg～150kgのロボット溶接市場（金額）
  • 世界の150kg超のロボット溶接市場（金額）
• 世界のロボット溶接市場：用途の分析
  • 世界のロボット溶接市場：用途別、概要
  • 世界の自動車・輸送向けロボット溶接市場（金額）
  • 世界の電気・電子向けロボット溶接市場（金額）
  • 世界の金属・機械向けロボット溶接市場（金額）
  • 世界の建設向けロボット溶接市場（金額）
  • 世界のその他のロボット溶接市場（金額）

第4章 地域市場の分析

• アジア太平洋のロボット溶接市場：分析
  • アジア太平洋のロボット溶接市場：概要
  • アジア太平洋のロボット溶接市場（金額）
  • アジア太平洋のロボット溶接市場：タイプ別（アーク溶接、スポット溶接、その他）
  • アジア太平洋のロボット溶接市場：地域別（中国・インド・日本・その他のアジア太平洋）
• 北米のロボット溶接市場：分析
  • 北米のロボット溶接市場：概要
  • 北米のロボット溶接市場（金額）
  • 北米のロボット溶接市場：地域別（米国・カナダ・メキシコ）
  • 米国のロボット溶接市場（金額）
  • カナダのロボット溶接市場（金額）
  • メキシコのロボット溶接市場（金額）
• 欧州のロボット溶接市場：分析
  • 欧州のロボット溶接市場：概要
  • 欧州のロボット溶接市場（金額）
  • 欧州のロボット溶接市場：地域別（ドイツ・フランス・イタリア・その他の欧州）
  • ドイツのロボット溶接市場（金額）
  • フランスのロボット溶接市場（金額）
  • イタリアのロボット溶接市場（金額）
  • その他の欧州のロボット溶接市場（金額）
• その他の地域のロボット溶接市場：分析
  • その他の地域のロボット溶接市場：概要
  • その他の地域のロボット溶接市場（金額）

第5章 COVID-19の影響

• ロボット溶接市場に対するCOVID-19の影響
• ロボット溶接市場に対するCOVID-19後の影響

第6章 市場力学

• 成長促進要因
  • 自動車・エレクトロニクス産業の急拡大
  • 産業用ロボットの設置の増加
  • 製造業の高い賃金
  • インダストリー4.0原則の採用の増加
  • 新興市場における需要の拡大
• 課題
  • 高い設置とメンテナンスのコスト
  • 離職に関する懸念の高まり
• 市場動向
  • AIと機械学習（ML）の統合
  • ロボット技術の継続的な進歩
  • ハイブリッド溶接プロセスの普及
  • レーザー・プラズマ溶接技術の出現

第7章 競合情勢

• 世界のロボット溶接市場の企業：財務の比較

第8章 企業プロファイル

• Panasonic Corporation (Panasonic Connect Co., Ltd. )
• ABB Group
• DENSO Corporation (DENSO WAVE INCORPORATED. )
• Kawasaki Heavy Industries, Ltd.
• Yaskawa Electric Corporation
• Fanuc Corporation
• KUKA Group
• Nachi-Fujikoshi Corporation
• Stellantis N.V. (Comau S.p.A. )
• The Lincoln Electric Company
• DAIHEN Corporation
• United ProArc Corporation

List of Figures

• Figure 1: Robotic Welding Segmentation
• Figure 2: Global Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 3: Global Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 4: Global Robotic Welding Market by Type; 2022 (Percentage, %)
• Figure 5: Global Robotic Welding Market by Payload; 2022 (Percentage, %)
• Figure 6: Global Robotic Welding Market by Application; 2022 (Percentage, %)
• Figure 7: Global Robotic Welding Market by Region; 2022 (Percentage, %)
• Figure 8: Global Arc Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 9: Global Arc Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 10: Global Spot Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 11: Global Spot Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 12: Global Others Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 13: Global Others Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 14: Global Less than 50kg Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 15: Global Less than 50kg Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 16: Global 50kg-150kg Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 17: Global 50kg-150kg Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 18: Global More than 150kg Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 19: Global More than 150kg Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 20: Global Automotive and Transportation Robotic Welding Market by Value; 2018-2022 (US$ Billion)

Figure 21:Global Automotive and Transportation Robotic Welding Market by Value; 2023-2028 (US$ Billion)

• Figure 22: Global Electrical and Electronics Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 23: Global Electrical and Electronics Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 24: Global Metal and Machinery Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 25: Global Metal and Machinery Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 26: Global Construction Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 27: Global Construction Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 28: Global Others Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 29: Global Others Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 30: Asia Pacific Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 31: Asia Pacific Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 32: Asia Pacific Robotic Welding Market by Type; 2022 (Percentage, %)
• Figure 33: Asia Pacific Arc Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 34: Asia Pacific Arc Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 35: Asia Pacific Spot Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 36: Asia Pacific Spot Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 37: Asia Pacific Others Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 38: Asia Pacific Others Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 39: Asia Pacific Robotic Welding Market by Region; 2022 (Percentage, %)
• Figure 40: China Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 41: China Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 42: India Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 43: India Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 44: Japan Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 45: Japan Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 46: Rest of Asia Pacific Robotic Welding Market by Value; 2018-2022 (US$ Billion)
• Figure 47: Rest of Asia Pacific Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 48: North America Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 49: North America Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 50: North America Robotic Welding Market by Region; 2022 (Percentage, %)
• Figure 51: The US Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 52: The US Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 53: Canada Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 54: Canada Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 55: Mexico Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 56: Mexico Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 57: Europe Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 58: Europe Robotic Welding Market by Value; 2023-2028 (US$ Billion)
• Figure 59: Europe Robotic Welding Market by Region; 2022 (Percentage, %)
• Figure 60: Germany Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 61: Germany Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 62: France Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 63: France Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 64: Italy Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 65: Italy Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 66: Rest of Europe Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 67: Rest of Europe Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 68: Rest of the World Robotic Welding Market by Value; 2018-2022 (US$ Million)
• Figure 69: Rest of the World Robotic Welding Market by Value; 2023-2028 (US$ Million)
• Figure 70: Global Automotive Manufacturing Industry Revenue; 2020-2022 (US$ Trillion)
• Figure 71: Global Electronics Market Revenue; 2020-2025 (US$ Billion)
• Figure 72: Global Annual Installation of Industrial Robots; 2019-2021 (Thousand Units)
• Figure 73: The US Average Hourly Wages in Manufacturing; July 2022 - May 2023 (US$ Per Hour)
• Figure 74: Global Artificial Intelligence Market Size; 2021-2025 (US$ Billion)
• Table 1: Global Robotic Welding Market Players: Financial Comparison; 2023
• Figure 75: Panasonic Corporation Net Sales by Segments; 2022 (Percentage, %)
• Figure 76: ABB Group Revenues by Business Areas; 2022 (Percentage, %)
• Figure 77: DENSO Corporation Revenue by Region; 2022 (Percentage, %)
• Figure 78: Kawasaki Heavy Industries, Ltd. Total Sales by Segment; 2022 (Percentage, %)
• Figure 79: Yaskawa Electric Corporation Revenue by Segments; 2021 (Percentage, %)
• Figure 80: Fanuc Corporation Sales by Business; 2022 (Percentage, %)
• Figure 81: KUKA Group Sales Revenue by Segment; 2022 (Percentage, %)
• Figure 82: Nachi-Fujikoshi Corporation Sales by Business Segment; 2022 (Percentage, %)
• Figure 83: Stellantis N.V. Net Revenues by Segment; 2022 (Percentage, %)
• Figure 84: The Lincoln Electric Company Net Sales by Segment; 2022 (Percentage, %)
• Figure 85: DAIHEN Corporation Net Sales by Segment; 2022 (Percentage, %)

Robotic welding is the process of using robotic arms to automate the welding process. In robotic welding, robots are used to perform and handle the welding process based on a program, which can be reprogrammed to suit the intended project. The components of robotic welding equipment include the software with specific programming, the welding equipment delivering the energy from the welding power source to the work piece, and the robot using the equipment to conduct the welding. Robotic welding market encompasses the production, development, manufacturing, and sale of robotic welding machines, equipment, and systems along with provision of related services, such as system integration, installation, maintenance, and training. The global robotic welding market was valued at US$6.01 billion in 2022. The market value is forecasted to grow to US$11.57 billion by 2028.

Rapidly developing emerging economies (Southeast Asia, China, India, Japan, Latin America), growing trend of automation in the manufacturing sector, advent of industrial internet of things (IIOT), rising number of automotive manufacturing plants, increasing labor costs, and growing demand for consistent high quality weld provided by welding robots while maintaining product standards and reduced production time. etc., have been positively contributing towards increased demand for welding robots. Other significant factors are digitalization, ongoing advancements in robotic technology, higher demand for consumer electronics, growing emphasis on increasing integration of digital technologies to reduce dependency on manual labor and ensure continuity of operations even at the time of economic uncertainties, and increasing number of new product launches and innovations in the market by welding robot manufacturing companies to remain competitive in the market and strengthen their current portfolios. The market is anticipated to grow at a CAGR of approx. 11.5% during the forecasted period of 2023-2028.

Market Segmentation Analysis:

By Type: The report provides the bifurcation of the market into three segments on the basis of type: spot welding, arc welding, and others. Spot robotic welding market is the largest segment of global robotic welding market owing to growing trend of automation in various industries, expansion of industrial infrastructure in emerging economies, increased need for consistent and precise welding processes, and high accessibility and improved efficiency of spot welding for robot automation in comparison to other welding methods.

By Payload: The report provides the bifurcation of the market into three segments based on payload: less than 50kg, 50kg-150kg, and more than 150kg. 50kg-150kg robotic welding market is both the largest and fastest growing segment of global robotic welding market owing to rising demand for electric vehicles, ease of loading and unloading operations, increasing demand from end use industries for welding heavy-body panels, and added advantage offered by these robots to industrial companies in terms of space and money as medium-scale welding can mostly be done using one machine, and these machines can easily be flour mounted in case of limited space availability.

By Application: The report provides the bifurcation of the market into five segments on the basis of application: automotive and transportation, electrical and electronics, metal and machinery, construction, and others. Automotive and transportation robotic welding market is both the largest and fastest growing segment of global robotic welding market owing to increasing number of benefits offered by welding robots in the automotive industry's manufacturing process, such as cost-effectiveness, high efficiency, safety, speed & precision, etc., intensifying global competition between various automotive manufacturers for the production of accurate and high-quality automobiles, growing involvement of digitization in the automotive sector, high number of welds required to complete one vehicle, rising emphasis of government on the adoption of EVs, and increasing demand of vehicles in developing economies such as China, India, Brazil, Iran, etc.

By Region: The report provides insight into the robotic welding market based on the regions namely, Asia Pacific, North America, Europe, and rest of the world. Asia Pacific robotic welding market holds the largest share of global robotic welding market, driven by increasing number of manufacturers in the region who are focusing on robotic automation to improve productivity and output quality, rising labor costs, growing number of small and medium scale businesses manufacturing automobile, electronic devices and other products, and increasing funding, tax incentives and loans provided by the government of several Asian countries to support industrial automation and development of industrial robots.

Asia Pacific robotic welding market is divided into four regions on the basis of geographical operations, namely, China, India, Japan, and rest of Asia Pacific, where China robotic welding market is both the largest and fastest growing region in Asia Pacific robotic welding market, driven by rapidly expanding industrial robot market, country's reputation of being one of the largest manufacturing hub, increasing investment by both local registered and unregistered manufacturers in the region, rising automation in China under "Made in China" 2025 plan, and rapidly expanding automotive & electronic manufacturing sectors, where automation is well-tested and affordable. Asia Pacific robotic welding market is also segmented into three segments on the basis of type, namely, arc welding, spot welding, and others, where spot welding segment held the major share of Asia Pacific robotic welding market.

Market Dynamics:

Growth Drivers: The global robotic welding market has been rapidly growing over the past few years, due to factors such as rapidly expanding automotive and electronics industry, increasing installations of industrial robots, high wages in manufacturing, increasing adoption of industry 4.0 principles, growing demand in emerging markets, etc. Industrial robots offer high levels of automation and efficiency in performing repetitive tasks, improving the overall productivity of a factory or a warehouse. Additionally, increasing number of installations of industrial robots, including welding robots will create higher recognition, awareness, and acceptance of their value in the manufacturing process, encouraging industries to invest in welding robots and creating new opportunities for manufacturers and suppliers of welding robot systems, components, and related services to expand their consumer base. Therefore, growing adoption of industrial robots will continue to have a positive impact on the global demand of welding robots, boosting the growth of global welding robot market in the forecasted years.

Challenges: However, the market growth would be negatively impacted by various challenges such as high installation and maintenance costs, rising concerns regarding job displacement, etc. Adoption of robotic welding is associated with high investment at the initial stage for procurement, programming, and maintenance of welding robots. Implementing robotic welding systems involves significant upfront costs, including the purchase of robots, peripheral equipment, and integration of welding robots with existing infrastructure, acting as a barrier for new entrants such as small and medium-sized enterprises (SMEs) or companies with limited capital resources that find it difficult to capitalize on high funds owing to low-volume production. Therefore, high initial investment and maintenance cost associated with employing automated systems and integration of high-quality hardware with efficient software control system, will continue to impend the growth of global robotic welding market in the forecasted years.

Trends: The market is projected to grow at a fast pace during the forecasted period, due to various latest trends such as integration of artificial intelligence (AI) and machine learning (ML), ongoing advancements in robotic technology, increasing penetration of hybrid welding processes, emergence of laser and plasma welding technologies etc. Increasing penetration of hybrid welding processes is creating new opportunities for growth as with more industries recognizing the benefits of hybrid welding, there is an increasing demand for robotic welding systems that are capable of performing these complex processes. Also, use of hybrid welding processes has enabled robots to weld dissimilar materials, thick plates, and complex geometries with greater ease and accuracy, allowing robotic welding systems to cater to a broader range of industries and manufacturing requirements. Therefore, increasing penetration of hybrid welding processes is expected to boost the growth of global robotic welding market in the upcoming years.

Impact Analysis of COVID-19 and Way Forward:

COVID-19 brought in many changes in the world in terms of reduced productivity, loss of life, business closures, closing down of factories and organizations, and shift to an online mode of work. Lockdown policies, imposed by the government to prevent the spread of virus forced various end user industries, robot manufacturing facilities, and robotics system integrators to either shut down or run low on production capacity, resulting in reduced demand, production and installation of robotic welding systems and equipment in various key industries, such as automotive, electrical, electronics, and metals & machinery. Also, there were increasing restrictions in the form of social distancing policies & the number of people that were allowed by robot manufacturing plants to work in a physical environment and with robot manufacturing companies relying heavily on physical presence of experienced workforce to handle the intricate processes involved in robot production, COVID-19 pandemic shifted everything online, making it difficult for robot manufacturing facilities to meet up with the ongoing demand and maintain on time delivery of robotic welding systems, leading to reduced production capacity, increasing delays in the deployment of robotic welding solutions, and disrupted supply of new robotic welding equipment.

Furthermore, the robotic supply chain began to stabilize in late Q3 of 2020, and robotics manufacturers began to see greater sales recovery beginning in 2021, indicating a positive recovery in the global demand of welding robots in the post COVID-19 period.

Competitive Landscape:

Global robotic welding market is midly consolidated with major players acquiring majority of the market share and increasing number of regional and local players worldwide catering to the local demand and engaging in various research & development activities and initiatives to develop and deploy new and more efficient products in the robotic welding market.

The key players of the market are:

Panasonic Corporation (Panasonic Connect Co., Ltd.)

ABB Group

DENSO Corporation (DENSO WAVE INCORPORATED.)

Kawasaki Heavy Industries, Ltd.

Yaskawa Electric Corporation

Fanuc Corporation

KUKA Group

Nachi-Fujikoshi Corporation

DAIHEN Corporation

Stellantis N.V. (Comau S.p.A.)

The Lincoln Electric Company

United ProArc Corporation

Major companies in the market are engaged in strategic agreements & contacts, increasing number of new product launches, mergers and acquisitions, and geographical expansion to gain larger market share. For instance, on August 23, 2022, YASKAWA Electric Corporation announced the launch of a new lineup of MOTOMAN-HC30PL (30 kg payload capacity, 1600 mm reach), a model to palletizing applications such as cardboard, for the human collaboration robot series that has been developed with 10 kg and 20 kg payload capacity. Similarly, on June 01, 2023, Panasonic Holdings Co., Ltd. (Panasonic HD) announced that the company has developed a new technology for efficient path planning, which is expected to expand the use of autonomous robots in environments where people and multiple robots coexist in a limited space, such as indoors.

Table of Contents

1. Executive Summary

2. Introduction

• 2.1 Robotic Welding: An Overview
  • 2.1.1 Definition of Robotic Welding
  • 2.1.2 Benefits of Robotic Welding
• 2.2 Robotic Welding Segmentation: An Overview
  • 2.2.1 Robotic Welding Segmentation

3. Global Market Analysis

• 3.1 Global Robotic Welding Market: An Analysis
  • 3.1.1 Global Robotic Welding Market: An Overview
  • 3.1.2 Global Robotic Welding Market by Value
  • 3.1.3 Global Robotic Welding Market by Type (Spot Welding, Arc Welding, and Others)
  • 3.1.4 Global Robotic Welding Market by Payload (Less than 50kg, 50kg-150kg, and More than 150kg)
  • 3.1.5 Global Robotic Welding Market by Application (Automotive and Transportation, Electrical and Electronics, Metal and Machinery, Construction, and Others)
  • 3.1.6 Global Robotic Welding Market by Region (North America, Europe, Asia Pacific, and Rest of the world)
• 3.2 Global Robotic Welding Market: Type Analysis
  • 3.2.1 Global Robotic Welding Market by Type: An Overview
  • 3.2.2 Global Arc Robotic Welding Market by Value
  • 3.2.3 Global Spot Robotic Welding Market by Value
  • 3.2.4 Global Others Robotic Welding Market by Value
• 3.3 Global Robotic Welding Market: Payload Analysis
  • 3.3.1 Global Robotic Welding Market by Payload: An Overview
  • 3.3.2 Global Less than 50kg Robotic Welding Market by Value
  • 3.3.3 Global 50kg-150kg Robotic Welding Market by Value
  • 3.3.4 Global More than 150kg Robotic Welding Market by Value
• 3.4 Global Robotic Welding Market: Application Analysis
  • 3.4.1 Global Robotic Welding Market by Application: An Overview
  • 3.4.2 Global Automotive and Transportation Robotic Welding Market by Value
  • 3.4.3 Global Electrical and Electronics Robotic Welding Market by Value
  • 3.4.4 Global Metal and Machinery Robotic Welding Market by Value
  • 3.4.5 Global Construction Robotic Welding Market by Value
  • 3.4.6 Global Others Robotic Welding Market by Value

4. Regional Market Analysis

• 4.1 Asia Pacific Robotic Welding Market: An Analysis
  • 4.1.1 Asia Pacific Robotic Welding Market: An Overview
  • 4.1.2 Asia Pacific Robotic Welding Market by Value
  • 4.1.3 Asia Pacific Robotic Welding Market by Type (Arc Welding, Spot Welding, and Others)
  • 4.1.4 Asia Pacific Arc Robotic Welding Market by Value
  • 4.1.5 Asia Pacific Spot Robotic Welding Market by Value
  • 4.1.6 Asia Pacific Others Robotic Welding Market by Value
  • 4.1.7 Asia Pacific Robotic Welding Market by Region (China, India, Japan, and Rest of Asia Pacific)
  • 4.1.8 China Robotic Welding Market by Value
  • 4.1.9 India Robotic Welding Market by Value
  • 4.1.10 Japan Robotic Welding Market by Value
  • 4.1.11 Rest of Asia Pacific Robotic Welding Market by Value
• 4.2 North America Robotic Welding Market: An Analysis
  • 4.2.1 North America Robotic Welding Market: An Overview
  • 4.2.2 North America Robotic Welding Market by Value
  • 4.2.3 North America Robotic Welding Market by Region (The US, Canada and Mexico)
  • 4.2.4 The US Robotic Welding Market by Value
  • 4.2.5 Canada Robotic Welding Market by Value
  • 4.2.6 Mexico Robotic Welding Market by Value
• 4.3 Europe Robotic Welding Market: An Analysis
  • 4.3.1 Europe Robotic Welding Market: An Overview
  • 4.3.2 Europe Robotic Welding Market by Value
  • 4.3.3 Europe Robotic Welding Market by Region (Germany, France, Italy, and Rest of Europe)
  • 4.3.4 Germany Robotic Welding Market by Value
  • 4.3.5 France Robotic Welding Market by Value
  • 4.3.6 Italy Robotic Welding Market by Value
  • 4.3.7 Rest of Europe Robotic Welding Market by Value
• 4.4 Rest of the World Robotic Welding Market: An Analysis
  • 4.4.1 Rest of the World Robotic Welding Market: An Overview
  • 4.4.2 Rest of the World Robotic Welding Market by Value

5. Impact of COVID-19

• 5.1 Impact of COVID-19 on Robotic Welding Market
• 5.2 Post COVID-19 Impact on Robotic Welding Market

6. Market Dynamics

• 6.1 Growth Drivers
  • 6.1.1 Rapidly Expanding Automotive and Electronics Industry
  • 6.1.2 Increasing Installations of Industrial Robots
  • 6.1.3 High Wages in Manufacturing
  • 6.1.4 Increasing Adoption of Industry 4.0 Principles
  • 6.1.5 Growing Demand in Emerging Markets
• 6.2 Challenges
  • 6.2.1 High Installation and Maintenance Costs
  • 6.2.2 Rising Concerns Regarding Job Displacement
• 6.3 Market Trends
  • 6.3.1 Integration of Artificial Intelligence (AI) and Machine Learning (ML)
  • 6.3.2 Ongoing Advancements in Robotic Technology
  • 6.3.3 Increasing Penetration of Hybrid Welding Processes
  • 6.3.4 Emergence of Laser and Plasma Welding Technologies

7. Competitive Landscape

• 7.1 Global Robotic Welding Market Players: Financial Comparison

8. Company Profiles

• 8.1 Panasonic Corporation (Panasonic Connect Co., Ltd.)
  • 8.1.1 Business Overview
  • 8.1.2 Operating Segments
  • 8.1.3 Business Strategy
• 8.2 ABB Group
  • 8.2.1 Business Overview
  • 8.2.2 Operating Businesses Areas
  • 8.2.3 Business Strategy
• 8.3 DENSO Corporation (DENSO WAVE INCORPORATED.)
  • 8.3.1 Business Overview
  • 8.3.2 Operating Regions
  • 8.3.3 Business Strategy
• 8.4 Kawasaki Heavy Industries, Ltd.
  • 8.4.1 Business Overview
  • 8.4.2 Operating Segments
  • 8.4.3 Business Strategy
• 8.5 Yaskawa Electric Corporation
  • 8.5.1 Business Overview
  • 8.5.2 Operating Segments
  • 8.5.3 Business Strategy
• 8.6 Fanuc Corporation
  • 8.6.1 Business Overview
  • 8.6.2 Operating Business
  • 8.6.3 Business Strategy
• 8.7 KUKA Group
  • 8.7.1 Business Overview
  • 8.7.2 Operating Segment
  • 8.7.3 Business Strategy
• 8.8 Nachi-Fujikoshi Corporation
  • 8.8.1 Business Overview
  • 8.8.2 Operating Business Segments
  • 8.8.3 Business Strategy
• 8.9 Stellantis N.V. (Comau S.p.A.)
  • 8.9.1 Business Overview
  • 8.9.2 Operating Segments
  • 8.9.3 Business Strategy
• 8.10 The Lincoln Electric Company
  • 8.10.1 Business Overview
  • 8.10.2 Operating Segments
  • 8.10.3 Business Strategy
• 8.11 DAIHEN Corporation
  • 8.11.1 Business Overview
  • 8.11.2 Operating Segments
• 8.12 United ProArc Corporation
  • 8.12.1 Business Overview