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dc.contributor.authorShafik, Mahmoud
dc.contributor.authorAshu, Mfortaw, Elvis
dc.contributor.authorNyathi, B.
dc.date.accessioned2016-11-17T15:53:33Z
dc.date.available2016-11-17T15:53:33Z
dc.date.issued2015-08-26
dc.identifier.citationShafik, M. et al. (2015) 'A smart 3D ultrasonic actuator for unmanned vehicle guidance industrial applications', Proceedings of the 11th International Conference on Intelligent Unmanned Systems (ICIUS), vol. 11, Bali, Indonesia, 26-29 Augusten
dc.identifier.issn2508-4127
dc.identifier.doi10.21535%2FProICIUS.2015.v11.652
dc.identifier.urihttp://hdl.handle.net/10545/620897
dc.description.abstractA smart piezoelectric ultrasonic actuator with multidegree of freedom for unmanned vehicle guidance industrial applications is presented in this paper. The proposed actuator is aiming to increase the visual spotlight angle of digital visual data capture transducer. Furthermore research are still undertaken to integrate the actuator with an infrared sensor, visual data capture digital transducers and obtain the trajectory of motion control algorithm. The actuator consists of three main parts, the stator, rotor and housing unit. The stator is a piezoelectric ring made from S42 piezoelectric material, bonded to three electrodes made from a material that has a close Characteristics to the S42. The rotor is a ball made from steel material. The actuator working principles is based on creating micro elliptical motions of surface points, generated by superposition of longitudinal and bending vibration modes, of oscillating structures. Transferring this motion from flexible ring transducer through the three electrodes, to the attached rotor, create 3D motions. The actuator Design, structures, working principles and finite element analysis are discussed in this paper. A prototype of the actuator was fabricated and its characteristics measured. Experimental tests showed the ability of the developed prototype to provide multidegree of freedom with typical speed of movement equal to 35 rpm, a resolution of less than 5μm and maximum load of 3.5 Newton. These characteristics illustrated the potential of the developed smart actuator, to gear the spotlight angle of digital visual data capture transducers and possible improvement that such microactuator technology could bring to the unmanned vehicle guidance and machine vision industrial applications.
dc.languageENG
dc.languageENG
dc.language.isoenen
dc.publisherUNSYS Digitalen
dc.relation.urlhttp://ojs.unsysdigital.com/index.php/icius/article/view/652en
dc.relation.urlhttp://ojs.unsysdigital.com/index.php/icius/issue/view/27en
dc.rightsArchived with thanks to Dental clinics of North Americaen
dc.subject3D ultrasonic actuatoren
dc.subjectMachine visionen
dc.subjectRobot guidanceen
dc.subjectMechatronicsen
dc.subject.meshAdministration, Topical
dc.subject.meshAnalgesics
dc.subject.meshAnalgesics, Opioid
dc.subject.meshAnesthesia, Dental
dc.subject.meshAnti-Bacterial Agents
dc.subject.meshAnxiety
dc.subject.meshChlorhexidine
dc.subject.meshHumans
dc.subject.meshPeriodontal Diseases
dc.subject.meshAdenosine Diphosphate
dc.subject.meshAdenosine Triphosphate
dc.subject.meshAlanine
dc.subject.meshAnimals
dc.subject.meshCyclic AMP
dc.subject.meshEnzyme Activation
dc.subject.meshFructosephosphates
dc.subject.meshHexosediphosphates
dc.subject.meshHydrogen-Ion Concentration
dc.subject.meshKinetics
dc.subject.meshLiver
dc.subject.meshMagnesium
dc.subject.meshPhosphoenolpyruvate
dc.subject.meshPotassium
dc.subject.meshProtein Kinases
dc.subject.meshPyruvate Kinase
dc.subject.meshRats
dc.titleA smart 3D ultrasonic actuator for unmanned vehicle guidance industrial applicationsen
dc.typeMeetings and Proceedingsen
dc.contributor.departmentUniversity of Derbyen
dc.identifier.journalProceedings of the 11th International Conference on Intelligent Unmanned Systems (ICIUS)en
refterms.dateFOA2019-02-28T15:00:23Z
html.description.abstractA smart piezoelectric ultrasonic actuator with multidegree of freedom for unmanned vehicle guidance industrial applications is presented in this paper. The proposed actuator is aiming to increase the visual spotlight angle of digital visual data capture transducer. Furthermore research are still undertaken to integrate the actuator with an infrared sensor, visual data capture digital transducers and obtain the trajectory of motion control algorithm. The actuator consists of three main parts, the stator, rotor and housing unit. The stator is a piezoelectric ring made from S42 piezoelectric material, bonded to three electrodes made from a material that has a close Characteristics to the S42. The rotor is a ball made from steel material. The actuator working principles is based on creating micro elliptical motions of surface points, generated by superposition of longitudinal and bending vibration modes, of oscillating structures. Transferring this motion from flexible ring transducer through the three electrodes, to the attached rotor, create 3D motions. The actuator Design, structures, working principles and finite element analysis are discussed in this paper. A prototype of the actuator was fabricated and its characteristics measured. Experimental tests showed the ability of the developed prototype to provide multidegree of freedom with typical speed of movement equal to 35 rpm, a resolution of less than 5μm and maximum load of 3.5 Newton. These characteristics illustrated the potential of the developed smart actuator, to gear the spotlight angle of digital visual data capture transducers and possible improvement that such microactuator technology could bring to the unmanned vehicle guidance and machine vision industrial applications.


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