Safety for automated warehouse exhibiting collaborative robots

The trend of automation in industrial production has led to massive use of autonomous robots. In classical approaches, safety is usually guaranteed by isolating robots from humans. Collaborative robots, i.e., humans and robots working together, are expected to increase both productivity and performa...

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Vydané v:Safety and Reliability - Safe Societies in a Changing World s. 2021 - 2028
Hlavní autori: Inam, Rafia, Fersman, Elena, Raizer, Klaus, Souza, Ricardo, Nascimento, Amadeu, Hata, Alberto
Médium: Kapitola
Jazyk:English
Vydavateľské údaje: CRC Press 2018
Vydanie:1
Predmet:
Safety Fields
Human Reliability Analysis
Digital Twin
Safety Strategy
Cyber Physical Systems
LiDAR
Collaborative Work Space
Stop Category
Safety Analysis
Omnidirectional Mobile Robots
Collaborative Operations
Distance Monitoring
Minimal Cut Sets
Robot Working
Reliability Blocks Diagrams
Gamma Process
Collaborative Scenarios
Mobile Robots
Risk Assessment Algorithm
Virtual Circle
Collaborative Robots
Bluetooth Low Energy
Imu Data
CSN
ISBN:0815386826, 9780815386827
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Popis
Shrnutí:The trend of automation in industrial production has led to massive use of autonomous robots. In classical approaches, safety is usually guaranteed by isolating robots from humans. Collaborative robots, i.e., humans and robots working together, are expected to increase both productivity and performance. However, removing fences and putting the robot working in collaboration with humans causes new hazardous situations. Therefore, proper risk assessment should be performed to avoid those hazardous situations without compromising the productivity. We present an automated warehouse where autonomous robots load trucks with products while sharing the same environment with human workers. In this position paper we propose a safety strategy that is modeled based on dynamic safety fields around the robot, which is consistent with important guidelines in collaborative robotics (i.e., ISO15066). We propose three different safety levels of dynamic fields: red (critical), yellow (warning) and green (clear). Instead of completely stopping the robot in the presence of humans it can keep performing its operations with some enforced constrains for safety reasons. We also propose a risk assessment of hazardous situations based on proprioceptive and exteroceptive data. This evaluation generates different warnings or actions to be performed based on those safety levels and is responsible for changing the size of the dynamic fields. This chapter proposes a safety strategy that is modeled based on dynamic safety fields around the robot, which is consistent with important guidelines in collaborative robotics. It describes an automated warehouse where autonomous robots load trucks with products while sharing the same environment with human workers. The chapter presents three different safety levels of dynamic fields: red, yellow and green. It also proposes a risk assessment of hazardous situations based on proprioceptive and exteroceptive data. However, the distance is calculated based on sensor data only and no risk assessment or safety analysis is performed. The chapter describes the basic architecture model with some core functionalities necessary to provide all the features of an automated logistics warehouse with collaborative robots. It examines a safety strategy that combines the safety analysis performed globally by the warehouse controller (offline safety analysis) and locally by the robot itself (online safety analysis).
ISBN:0815386826
9780815386827
DOI:10.1201/9781351174664-254