TELEROBOTIC MONITORING, DECONTAMINATION AND SIZE REDUCTION SYSTEM

Objectif

The objective of this work is to use existing equipment developed under the Harwell Nuclear Robotics Programme to investigate and demonstrate the feasibility of telerobotic monitoring, decontamination and size-reduction systems (TMDSRS). The work will include experimental investigations at industrial scale, and use sample workpieces of an appropriate size and configuration similar to their active counterparts.

The work will proceed in 2 distinct stages. The first stage will involve the continued development of the Harwell Telerobotic Controller and its interface to NEATER, a Nuclear Engineered Advanced Telerobot, and ancillary equipment and mechanisms. This development will allow in-active trials of a TMDSRS system on each of the 3 sets of target workpieces (3, 4 and 5). The work will be carried out in the Harwell Robotics Demonstration laboratory.

The second stage of the work (6) will involve active trials of one of the areas demonstrated in the first stage. The selection of the appropriate application will ensure that a safe, useful and representative active trial can be accomplished.

This development will reduce man-Sv and costs of decommissioning projects. Greater efficiencies in placing or deploying decontamination tools and in cutting and packing waste will improve waste disposal strategies, and reduce waste arisings. Data on cost benefits will be produced in submissions made to justify the selection of a suitable project for the active trials (phase 2). Cooperation on sensors with SCK/CEN Mol is included in the work programme.
The objective of this work is to use existing equipment developed under the Harwell nuclear robotics programme to investigate and demonstrate the feasibility of telerobotic monitoring, decontamination and size reduction systems (TMDSRS).

The control system has been extended to meet the requirements of the 3 demonstrators and the size reduction of 5 gloveboxes has been demonstrated. A new electropolishing head unit (EHU) has been assembled and interfaces to the robotic system constructed and tested. Irradiation tests for the EHU have been planned. Scanning software development to deploy the EHU in a decontamination demonstration is under way. A kinematic analysis to define the clearance monitoring requirement has started.
WORK PROGRAMME

1. Control system extension to work effectively with each of the 3 nonactive applications.

2. Electropolishing head unit development and irradiation tests (AEA)

2.1. Requirements analysis for the electropolishing head unit (AEA)
2.2. Requirements analysis for the sensor functions (SCK/CEN)
2.3. Selection of sensors to meet the requirements analyses of 2.1 and 2.2. (SCK/CEN)
2.4. Design and construction of the integrated head unit (AEA)
2.5. Irradiation tests of the integrated head unit (SCK/CEN)

3. Decontamination of different surfaces; radiation monitoring, electropolishing and registration software (AEA)

4. Clearance monitoring developments (AEA)

5. Glovebox size reduction developments

5.1. Analysis of subsystems susceptible to radiation damage (SCK/CEN)
5.2. Tests on subsystem components in the gamma irradiation test facility at the BR2 reactor (SCK/CEN)
5.3. Tool and operational software development (AEA)
5.4. Tool change adaptation and cutting tasks demonstration jointly with a range of tools (AEA)

6.Active decommissioning trials in the appropriate active area

6.1. Pre-trial analysis of the radiation environment (AEA)
6.2. Active trials including the NEATER carrying out of a task or set of tasks (AEA)
6.3. Support for active trials to reduce the probability of failures (SCK/CEN)

7. Economic analysis of TDMSRS and its radiological impact on work force and working area

7.1. Pre-active trial cost-benefit analysis to establish economic advantages of telerobotic operations (AEA)
7.2. Post-active trials analysis on costs, incurred dose burdens, working and exposure times of ancillary operators, and estimates of secondary waste arisings (AEA).

Champ scientifique (EuroSciVoc)

CORDIS classe les projets avec EuroSciVoc, une taxonomie multilingue des domaines scientifiques, grâce à un processus semi-automatique basé sur des techniques TLN. Voir: Le vocabulaire scientifique européen.

• ingénierie et technologie génie électrique, génie électronique, génie de l’information ingénierie électronique système d’automatisation et de contrôle
• ingénierie et technologie génie de l'environnement gestion des déchets
• sciences naturelles informatique et science de l'information logiciel développement logiciel
• ingénierie et technologie génie électrique, génie électronique, génie de l’information ingénierie électronique capteurs
• ingénierie et technologie génie électrique, génie électronique, génie de l’information ingénierie électronique robotique

Programme(s)

Programmes de financement pluriannuels qui définissent les priorités de l’UE en matière de recherche et d’innovation.

• FP2-DECOM 3C - Specific research and technological development programme (Euratom) in the field of decommissioning of nuclear installations, 1989-1993

Thème(s)

Les appels à propositions sont divisés en thèmes. Un thème définit un sujet ou un domaine spécifique dans le cadre duquel les candidats peuvent soumettre des propositions. La description d’un thème comprend sa portée spécifique et l’impact attendu du projet financé.

• A5 - Adaptation and qualification of remote controlled systems

Appel à propositions

Procédure par laquelle les candidats sont invités à soumettre des propositions de projet en vue de bénéficier d’un financement de l’UE.

Régime de financement

Régime de financement (ou «type d’action») à l’intérieur d’un programme présentant des caractéristiques communes. Le régime de financement précise le champ d’application de ce qui est financé, le taux de remboursement, les critères d’évaluation spécifiques pour bénéficier du financement et les formes simplifiées de couverture des coûts, telles que les montants forfaitaires.

CSC - Cost-sharing contracts

Coordinateur

Participants (3)