SEBARES - Self balancing rescue aid

Annually in Germany 10 Million patients are transported by emergency services. In a great number of cases the patients have to be transported over diverse obstacles, which is associated with enormous physical effort for the paramedics and longer mission times. In combination with an increasing rate of obese patients the transport is a rising problem for emergency services.

In the context of the project SEBARES a novel mechatronic rescue and transport aid is under development. An innovative self-balancing concept enables high mobility, compactness and speed for the transport of patients. Together with universal stair climbing kinematics, a compact patient chair and a docking interface in the ambulance a universal rescue and transport aid may help to speed up the transport and to reduce the physical effort of paramedics, and therefore improve the working conditions in emergency services.

Postural field study of paramedics during patient transport in emergency medical services

Detailed information about the status quo in patient transport is essential but not yet available in literature, especially regarding the quantitative occurrence and ergonomic impact of obstacles. Therefore an objective survey at a local emergency medical service provider was conducted and 400 deployments could be quantitatively analyzed. Furthermore we conducted an Ovako working posture analysis (OWAS) to get information about the current physical working conditions and connected these results with the survey. This way we could show that the high physical workloads of paramedics are strongly connected to the frequent occurring obstacles like stairs and relieving transport aids, like the SEBARES system, are necessarily needed to improve the situation of paramedics.

First ergonomic analysis of the SEBARES concept

To evaluate the ergonomics of the system in an early state and to get a first notion of the situational improvement for paramedics, a primary user study was conducted with a labtype. The system was evaluated regarding different body sizes, terrains and slopes, while the postures of the different subjects and their applied forces and torques were recorded.

Advanced Modelling and Control Design for a self-balancing mechatronic rescue aid

Although self-balancing systems are in general well-analyzed and described, the application as a patient transport system entails several specific requirements. For instance, our field study could show that about 25 % of the patients are not cooperative during transport and therefore might influence the stability of the device control. To analyze this influence a parametric multi-body model was developed and validated experimentally. Simulation of different patient behaviors showed that the patient can critically influence the control loop especially by movements of his torso and introducing external forces such as holding onto a rail. Apart from system design modifications (e.g. for fixation of the patient), advanced control strategies which take possible movements of the patient into account are currently under development and evaluation.

Stair Climbing Mechanism for Self-Balancing Mechatronic Rescue Aid

To be able to overcome stairs the transport aid incorporates a stair climbing mechanism which is currently developed based on a comprehensive market and literature analysis. Exemplary scaled down functional models were build and used to conduct first experiments on different staircase models. This way issues and shortcomings could be identified early during the development process.

Project partners

  • SurgiTAIX AG
  • Lehrstuhl für Medizintechnik der RWTH Aachen
  • Stollenwerk & Cie GmbH Köln
  • Rescue Services, District of Düren (Rettungsdienst Kreis Düren AöR) (Associated partner)

Publications

  • L. Phlippen, M. Verjans, P. Schleer, S. Drobinsky & K. Radermacher: Impact of an uncooperative passenger on the control of an externally guided self-balancing patient-transport system. 41th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC), 2019 [DOI: 10.1109/EMBC.2019.8856287]
  • M. Verjans, L. Phlippen, P. Schleer & K. Radermacher: SEBARES - Design and Evaluation of a Controller for a novel externally guided self-balancing patient rescue aid. European Control Conference (ECC), 2019, pp. 209-214 [DOI: 10.23919/ECC.2019.8795727]
  • M. Verjans, P. Schleer, J. Griesbach, M. Kinzius, W. Alrawashdeh & K. Radermacher: Modelling patient dynamics and controller impact analysis for a novel self-stabilizing patient transport aid. In: B. Mettler (ed.): IFAC-PapersOnLine, 51(34), 2019, pp. 208-213 [DOI: 10.1016/j.ifacol.2019.01.067]
  • P. Schleer, M. Kinzius, M. Verjans, F. Kähler & K. Radermacher: Development of a Stair Climbing Mechanism for a Novel Mechatronic Transport Aid: Preliminary Results. Current Directions in Biomedical Engineering, 4(1), 2018, pp. 283-286 [DOI: 10.1515/cdbme-2018-0069]
  • M. Verjans, A. Schütt, P. Schleer, D. Struck & K. Radermacher: Postural workloads on paramedics during patient transport. Current Directions in Biomedical Engineering, 4(1), 2018, pp. 161-164 [DOI: 10.1515/cdbme-2018-0040]
  • M. Verjans: Potentiale und Entwicklungen neuer Hilfsmitteltechnologien - Ein Blick in ein aktuelles Forschungsprojekt. Eingeladener Vortrag beim Symposium des IFA der DGUV zum Thema "Physische Belastung von Rettungskräften beim Patiententransport - Chancen der Prävention" in St. Augustin, 11.09.2018 , 2018

Contact

Mark Verjans, M.Sc.
Tel.: +49 (0)241-80 23869

Förderung