A) Textile industry and food processing industry.
B) Automotive industry, aerospace industry, and fabrication of metal structures.
C) Agricultural industry and forestry industry.
D) Healthcare industry and entertainment industry.

A) Higher precision, consistency, speed, and efficiency.
B) More creativity and flexibility.
C) Less supervision required and easier maintenance.
D) Lower initial cost and simplicity.

A) Because robots can withstand harsh conditions better.
B) To ensure the safety of human workers and maintain productivity.
C) To reduce equipment maintenance costs.
D) Because robots require less training.

A) Interlocks regulate the speed of robotic welding.
B) Interlocks control the pressure of shielding gas.
C) Interlocks ensure that robots stop operating if safety gates are open or if sensors detect a hazard.
D) Interlocks maintain the temperature of the welding arc.

A) Articulated robot.
B) SCARA robot.
C) Delta robot.
D) Cartesian robot.

A) Shift towards manual welding for better quality control.
B) Decrease in the use of vision systems in robotic welding.
C) Continued advancement in automation, AI integration, and increased efficiency.
D) Decline in robotic welding applications due to cost issues.

A) Collaborative robots work alongside human workers to enhance productivity and flexibility.
B) Collaborative robots perform welding tasks without human involvement.
C) Collaborative robots replace human workers in welding processes.
D) Collaborative robots are only used for training purposes.

A) Proper ventilation, protective equipment, and safety barriers to prevent accidents.
B) Cold environment for better cooling of the welded area.
C) Regular robot maintenance and programming backup.
D) High robot speed and immediate action in case of errors.