Analyzing energy-efficient configurations in hexapod robots for demining applications

Purpose – Reducing energy consumption in walking robots is an issue of great importance in field applications such as humanitarian demining so as to increase mission time for a given power supply. The purpose of this paper is to address the problem of improving energy efficiency in statically stable walking machines by comparing two leg, insect and mammal, configurations on the hexapod robotic platform SILO6. Design/methodology/approach – Dynamic simulation of this hexapod is used to develop a set of rules that optimize energy expenditure in both configurations. Later, through a theoretical analysis of energy consumption and experimental measurements in the real platform SILO6, a configuration is chosen. Findings – It is widely accepted that the mammal configuration in statically stable walking machines is better for supporting high loads, while the insect configuration is considered to be better for improving mobility. However, taking into account the leg dynamics and not only the body weight, different results are obtained. In a mammal configuration, supporting body weight accounts for 5 per cent of power consumption while leg dynamics accounts for 31 per cent. Originality/value – As this paper demonstrates, the energy expended when the robot walks along a straight and horizontal line is the same for both insect and mammal configurations, while power consumption during crab walking in an insect configuration exceeds power consumption in the mammal configuration

TIRAMISU European Project: Design and Implementation of Tools for Humanitarian Demining

This paper presents the most relevant results of the work done within the framework of TIRAMISU European project (Toolbox Implementation for Removal of Anti-personnel Mines, Submunitions and UXO), by the Centre for Automation and Robotics CAR (CSIC-UPM). This project has been funded by European Union within the Seventh Framework Programme of R&D. In general, the works carried out during this project, currently in effect, have been the design and development of tools for training in search of landmines and other for locating anti-personnel landmines, such as: design and validation of e-tutors for land impact and non-Technical Survey tools, and landmines identification for training of trainee, who will collaborate in humanitarian demining tasks; design and implementation of a training tool to be used with compact metal detectors; design, implementation and evaluation of an intelligent prodder training tool for close-in detection of buried landmines; development of a semi-autonomous and teleoperated system for search and detection of anti-personnel mines, which consists of a hexapod robot and a scanning manipulator arm, that carries a metal detector at its end-effector.This project has been funded by European Union within the Seventh Framework Programme of R&D.Peer reviewe

SILO6: A six-legged robot for humanitarian de-mining tasks

Detection and removal of antipersonnel landmines in infested fields is an important worldwide problem. Around 100 million landmines have been deployed over the last two decades, and demining will take several more decades, even if no more mines were deployed in future. A high mine-clearance rate can only be accomplished by using new technologies such as improved sensors, efficient manipulators and mobile robots. This paper presents some basic ideas on the configuration and controller of a mobile system for detecting and locating antipersonnel landmines in an efficient and effective way. The whole system has been configured to work in a semi-autonomous mode with a view also to robot mobility and energy efficiency. The paper outlines the main features of the overall system and focuses on some aspects of the controller.This work has been funded by the Spanish Ministry of Science and Technology under Grant CICYT DPI2001-1595.Peer reviewe

DYLEMA: Using walking robots for landmine detection and location

Detection and removal of antipersonnel landmines is an important worldwide concern. A huge number of landmines has been deployed over the last twenty years, and demining will take several more decades, even if no more mines were deployed in future. An adequate mineclearance rate can only be achieved by using new technologies such as improved sensors, efficient manipulators and mobile robots. This paper presents some basic ideas on the configuration of a mobile system for detecting and locating antipersonnel landmines efficiently and effectively. The paper describes the main features of the overall system, which consists of a sensor head that can detect certain landmine types, a manipulator to move the sensor head over large areas, a locating system based on a global-positioning system, a remote supervisor computer and a legged robot used as the subsystems’ carrier. The whole system has been configured to work in a semi-autonomous mode with a view also to robot mobility and energy efficiency.This work has been funded by the Spanish Ministry of Science and Technology under Grant CICYT DPI2001-1595 and DPI2004-05824.Peer reviewe

Reconfiguration of a climbing robot in an all-terrain hexapod robot

This work presents the reconfiguration from a previous climbing robot to an all-terrain robot for applications in outdoor environments. The original robot is a six-legged climbing robot for high payloads. This robot has used special electromagnetic feet in order to support itself on vertical ferromagnetic walls to carry out specific tasks. The reconfigured all-terrain hexapod robot will be able to perform different applications on the ground, for example, as inspection platform for humanitarian demining tasks. In this case, the reconfigured hexapod robot will load a scanning manipulator arm with a specific metal detector as end-effector. With the implementation of the scanning manipulator on the hexapod robot, several tasks about search and localisation of antipersonnel mines would be carried out. The robot legs have a SCARA configuration, which allows low energy consumption when the robot performs trajectories on a quasi-flat terrain.Peer reviewe