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Hitachi
Research & Development

Development of system control technology for achieving a high degree of safety and efficiency in a work environment with people and machines

Provides new safety functions through a cyber-physical system that enables mutual cooperation via rules

April 20, 2021

Hitachi, Ltd. has developed system control technology for simultaneously ensuring human safety and improving work efficiency in a work environment having a mixture of people and autonomously operating machines (autonomous machines) such as a warehouse or factory (Fig. 1). Based on the concept of “symbiotic safety,” this technology aims to contribute to a revolution in the distribution, production, and transportion industries.

Fig. 1

Fig. 1 Prediction of collision or other danger by detecting movement of people and autonomous machines by sensors


Background and issues addressed

  • The COVID-19 pandemic is generating a need for more efficient business operations based on digital technologies in warehouses, factories, and other work sites, and these technologies are increasingly being introduced into work areas having autonomous machines such as self-driving forklifts.
  • In a situation in which people and autonomous machines work in the same area but with different objectives, collisions between autonomous machines and people can easily occur at locations with obstructed views caused by shelves or walls lining passageways or lanes or by temporarily parked cars, sitting freight, etc. creating a safety problem.
  • Under these conditions, one means of solving this problem is to reduce the speed of autonomous machines. This, however, lowers work efficiency, which is a problem in itself. Hitachi therefore developed system control technology to raise work efficiency while ensuring safety.

Developed technologies

  • Disparate system cooperation technology based on the concept of symbiotic safety
  • People/autonomous-machine rule observance technology and remote safety technology for rule violations

Verified effects

The effectiveness of this technology was tested targeting work areas having a mixture of people and autonomous machines. Test results showed that setting safety rules according to the work area based on the symbiotic safety concept and judging and controlling the safety of human and autonomous-machine behavior could prevent collisions. They also showed that autonomous machines could be quickly stopped even when people behaved in violation of those rules. Additionally, in passageways with obstructed views, it was shown by simulations that this technology could improve work efficiency by approximately 30% compared with the conventional method that reduces the speed of autonomous machines to prevents collisions and ensure safety.

Acknowledgments

The evaluation technology based on the above simulations is the result of joint research with Fraunhofer Institute for Cognitive Systems IKS.

Details of developed technology

1. Disparate-system cooperation technology based on the concept of symbiotic safety

Under this concept, the manager of a work area draws up safety rules for disparate systems (people and autonomous machines), which are unaware of each other and do not communicate intention to each other, with the aim of preventing collisions between them while improving work efficiency. Then, on the basis of these rules, the system controls the movements of people and autonomous machines and safely brings autonomous machines to a stop whenever a rule is violated for whatever reason. This concept is implemented by technology that coordinates the following three components:
(1) sensors that detect the movement of people and autonomous machines in a work area, (2) a symbiotic-safety server that centrally processes the information obtained from sensors, sets the areas that people and autonomous machines are allowed to move in, and issues a stop command to autonomous machines on detecting a rule violation, and (3) autonomous machines. Specifically, we have developed a cyber-physical system (CPS) that achieves optimal work overall by having two disparate systems—detection/control of human movement and detection/control of autonomous-machine movement—cooperate with each other via safety rules set within the work area.

2. People/autonomous-machine rule observance technology and remote safety technology for rule violations

The following two technologies are used in the CPS described above (Fig. 2). The first technology evaluates safety and work efficiency when applying rules to a work area using simulation techniques that enable system safety to be tested. Using this technology, the symbiotic-safety server controls the observance of formulated rules by allocating the range of allowable movement (exclusive area) to an autonomous machine using information on its presence and the whereabouts of people and predictions of their future positions. Here, the symbiotic-safety server uses a grid format to manage the exclusive areas for people and the autonomous machine within the work area. It dynamically updates these exclusive areas based on information obtained from sensors and controls the autonomous machine so as not to venture outside its exclusive area.

The second technology provides a remote-safety mechanism for quickly issuing a stop command to the autonomous machine if it it should venture outside its exclusive area due to a machine or system malfunction or when its predicted that a person is about to penetrate the grid area that the autonomous machine moves in (Fig. 1).

Fig. 2

Fig. 2 People/autonomous-machine (forklift) rule observance technology and remote safety technology for rule violations
to implement the "symbiotic safety" concept


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