Your search keyword '"INGRASSIA T"' showing total 12 results

1. Influence of the metaphysis positioning in a new reverse shoulder prosthesis

Author

Ingrassia, T., Nalbone, L., Nigrelli, V., Pisciotta, D., Ricotta, V., Eynard, Benoit, editor, Nigrelli, Vincenzo, editor, Oliveri, Salvatore Massimo, editor, Peris-Fajarnes, Guillermo, editor, and Rizzuti, Sergio, editor

Published

2017

2. A New Approach for CAD Modelling of Customised Orthoses by Generative Design

Author

Tommaso Ingrassia, Vito Ricotta, Vincenzo Nigrelli, Laura Bragonzoni, Giuseppe Vincenzo Marannano, Rizzi C., Campana F., Bici M., Gherardini F., Ingrassia T., Ciccon, Bragonzoni L., Ingrassia T., Marannano G., Nigrelli V., Ricotta V., Rizzi C., Campana F., Bici M., Gherardini F., Ingrassia T., Cicconi P., Bragonzoni Laura, Ingrassia Tommaso, Marannano Giuseppe, Nigrelli Vincenzo, and Ricotta Vito

Subjects

Engineering drawing, Generative design, Computer science, Customised orthosi, CAD, Customised orthosis, Generative Design, Settore ING-IND/15 - Disegno E Metodi Dell'Ingegneria Industriale, Reverse engineering

Abstract

The standard method of design and manufacturing customised orthoses is still very time-consuming due to their often very complex shape. Different authors have tried to solve this problem but, unfortunately, the proposed approaches cannot be easily used in clinical practice because they require substantial interaction among medical staff and engineers or technicians. The aim of this work is to present the framework of a new design approach that could allow clinicians to easily model a customised orthosis, without a skilled technician develops the entire procedure. In particular, an automatic process based on Generative Design has been implemented. The obtained results have demonstrated that the implemented algorithm is simple to use and could allow also not-skilled users to design customised orthoses.

Published

2022

3. Design and Integration of Automation Systems with Manual Operation: Small and Medium Enterprises Issues

Author

Giovanni Marra, Paola Scardamaglia, Giuseppe Di Gironimo, Rocco Mozzillo, D. Marzullo, Rocco Salvato, Rizzi C., Campana F., Bici M., Gherardini F., Ingrassia T., Cicconi P., Salvato, R., Marra, G., Scardamaglia, P., Di Gironimo, G., Marzullo, D., and Mozzillo, R.

Subjects

Design methodologie, Internet of things (IoT), business.industry, Computer science, Welding process, CAD, Small and medium-sized enterprises, Industry 4.0, business, Automation, Manufacturing engineering, Systems engineering

Abstract

Today it is more and more mandatory for all commercial companies to comply with the principles and methodologies of Industry 4.0 and to achieve the related capabilities protecting their competitiveness and taking a leading-edge position on market as regards technologies. Specifically, the whole production and sale system must achieve the fundamental characteristics of Industry 4.0 approach, but specially the manufacturing companies must also change and update their management procedures, internal organization, resource training, assets and all production process to keep safe their current business capacities. This evolution process is even more critical for Small and Medium Enterprises (SME), that traditionally tend to be conservative and to protect their way of operation, usually characterized by a low level of automation. The work presented focuses on the design and integration of a semi-automatic welding cell of train bolster in a SME which is currently realizing a project aimed to the acquisition of Industry 4.0 capabilities, with special focus on manufacturing processes. Among them, one of the most important is the production of welded-steel critical structures, that the Company supplies to prime manufacturer of railway rolling stock systems. The experience gained during the activity, the criticalities due to the integration processes and the adopted design methodologies are here described. The work has been carried out consistently with the Systems Engineering principles, starting from the requirements elicitation and analysis to the systematic approach for the design and integration activities.

Published

2021

4. Additively manufactured textiles and parametric modelling by generative algorithms in orthopaedic applications

Author

R. Ian Campbell, Tommaso Ingrassia, Vincenzo Nigrelli, Vito Ricotta, Ricotta V., Campbell R.I., Ingrassia T., and Nigrelli V.

Subjects

0209 industrial biotechnology, Textile, Computer science, Process (engineering), Additive manufacturing, CAD, Context (language use), 02 engineering and technology, Industrial and Manufacturing Engineering, law.invention, CAD modeling, 020901 industrial engineering & automation, law, Parametric modelling, Structure (mathematical logic), Elbow orthosi, business.industry, Mechanical Engineering, Generative algorithms, Additively manufactured textile, 021001 nanoscience & nanotechnology, Selective laser sintering, AM technologie, 0210 nano-technology, business, Algorithm, Generative grammar

Abstract

Purpose The purpose of this paper is to implement a new process aimed at the design and production of orthopaedic devices fully manufacturable by additive manufacturing (AM). In this context, the use of generative algorithms for parametric modelling of additively manufactured textiles (AMTs) also has been investigated, and new modelling solutions have been proposed. Design/methodology/approach A new method for the design of customised elbow orthoses has been implemented. In particular, to better customise the elbow orthosis, a generative algorithm for parametric modelling and creation of a flexible structure, typical of an AMT, has been developed. Findings To test the developed modelling algorithm, a case study based on the design and production of an elbow orthosis made by selective laser sintering was investigated. The obtained results have demonstrated that the implemented algorithm overcomes many drawbacks typical of the traditional computer aided design (CAD) modelling approaches. The parametric CAD model of the orthosis obtained through the new approach is characterised by a flexible structure with no deformations or mismatches and has been effectively used to produce the prototype through AM technologies. Originality/value The obtained results present innovative elements of originality in the CAD modelling sector, which can contribute to solving problems related to modelling for AM in different application fields.

Published

2020

5. A new design approach for customised medical devices realized by additive manufacturing

Author

Tommaso Ingrassia, Vito Ricotta, R. I. Campbell, Vincenzo Nigrelli, Ricotta V., Campbell R.I., Ingrassia T., and Nigrelli V.

Subjects

Reverse engineering, 0209 industrial biotechnology, Engineering drawing, business.industry, Computer science, CAD, 02 engineering and technology, 021001 nanoscience & nanotechnology, computer.software_genre, Industrial and Manufacturing Engineering, Torsion spring, Finite element method, 020901 industrial engineering & automation, Software, Industrial design, Modeling and Simulation, 0210 nano-technology, Voronoi diagram, Engineering design process, business, Settore ING-IND/15 - Disegno E Metodi Dell'Ingegneria Industriale, computer, Additive manufacturing, Computer aided design, Generative design, Reverse engineering, Elbow orthosis

Abstract

The aim of this work is the design of a new customised elbow orthosis completely realized by Additive Manufacturing and the development of generative algorithms for parametric modelling and creation of 3D patterns to be adapted to the CAD model. This work describes a method to perfect the design of a custom elbow orthosis. A reverse engineering approach has been used to digitalize the patient’s arm and the subsequent CAD modelling of the structure of the custom elbow orthosis has been performed. In particular, two algorithms have been implemented for the creation of 3D patterns and Voronoi tessellations. Subsequently, FEM analyses have been carried out to validate the design. Finally, a prototype of the elbow orthosis with Voronoi tessellation has been realized by means of the SLS technology. The results obtained have demonstrated that the implemented algorithm solved the problems found during CAD modelling with conventional software. Furthermore, the results of FEM analyses have validated the design choices. All this allowed realizing the prototype by AM technologies without problems. Moreover, the new proposed modelling approaches allows creating, in an interactive way, patterns on complex surfaces. The results of this research activity present innovative elements of originality in the CAD modelling sector, which can contribute to solving problems related to the modelling for Additive Manufacturing. Furthermore, another innovative characteristic of the device is the use of torsion springs that simulate the action of physiotherapists during exercises for patient rehabilitation.

Published

2020

6. Biomechanical analysis of two types of osseointegrated transfemoral prosthesis

Author

Francesco Di Simone, Laura Bragonzoni, Agostino Igor Mirulla, Stefano Di Paolo, Vincenzo Nigrelli, Stefano Zaffagnini, Tommaso Ingrassia, Mirulla A.I., Di Paolo S., Di Simone F., Ingrassia T., Nigrelli V., Zaffagnini S., and Bragonzoni L.

Subjects

Computer science, medicine.medical_treatment, Finite element analysi, 0206 medical engineering, OPL, Prosthetic limb, 02 engineering and technology, Prosthesis, lcsh:Technology, Osseointegration, lcsh:Chemistry, 03 medical and health sciences, Distal femur, 0302 clinical medicine, osseointegrated prosthesis, medicine, General Materials Science, CAD, OPL osseointegrated prosthesi, Settore ING-IND/15 - Disegno E Metodi Dell'Ingegneria Industriale, Instrumentation, lcsh:QH301-705.5, Fluid Flow and Transfer Processes, Orthodontics, 030222 orthopedics, lcsh:T, Process Chemistry and Technology, General Engineering, Finite element analysis, OPL osseointegrated prosthesis, Limiting, Stress distribution, Transfemoral amputee, equipment and supplies, 020601 biomedical engineering, Transfemoral prosthesis, lcsh:QC1-999, OPRA, Computer Science Applications, body regions, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Implant, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics

Abstract

In the last two decades, osseointegrated prostheses have been shown to be a good alternative for lower limb amputees experiencing complications in using a traditional socket-type prosthesis, however, restraining biomechanical issues, such as peri-prosthetic bone fractures or loosening, are present. To better understand and overcome these limiting issues, and thus reduce the number of implant failures, many studies have investigated the stress distribution on bone and implant during normal daily activities. The aim of this study was a biomechanical analysis of two different osseointegrated implants, a screw-type (OPRA) and a press fit system (OPL, Osseointegrated Prosthetic Limb), to evaluate the stresses generated in bone and prosthesis during a fall. In particular, four scenarios have been experimentally reproduced to determine the loads on the limb during different kinds of fall. For this purpose, a motion capture system and a force plate have been used. Numerical FEM (Finite Element Method) simulations have been performed to compare the behaviour of the OPRA and OPL systems in different fall scenarios. The obtained results showed that a fall backwards due to balance loss is the most stressful scenario among the ones analysed. As regards the comparison between OPRA and OPL devices, it emerged they have similar behaviours in terms of peak values of the stress, but the OPL implant generates larger high-stress areas in the distal femur as compared with the OPRA system.

Published

2020

7. Biomechanical analysis of the humeral tray positioning in reverse shoulder arthroplasty design

Author

Vito Ricotta, Vincenzo Nigrelli, Lorenzo Nalbone, Tommaso Ingrassia, Domenico Pisciotta, Ingrassia, T., Nalbone, L., Nigrelli, V., Ricotta, V., and Pisciotta, D.

Subjects

Engineering, Offset (computer science), medicine.medical_treatment, Prosthesis, Industrial and Manufacturing Engineering, 03 medical and health sciences, 0302 clinical medicine, Deltoid muscle, Virtual prototyping, medicine, CAD, Reverse engineering, Settore ING-IND/15 - Disegno E Metodi Dell'Ingegneria Industriale, Reverse shoulder prosthesi, FEM, 030222 orthopedics, business.industry, Work (physics), 030229 sport sciences, Arthroplasty, Finite element method, Tray, Modeling and Simulation, Range of motion, business, Biomedical engineering

Abstract

Despite the widespread use of reverse total shoulder arthroplasty, the fundamental effects of implant configuration on certain biomechanical outcomes have not been completely elucidated especially for the most innovative prostheses. Aim of this work is to investigate the behaviour of a new reverse shoulder prosthesis, characterized by a humeral tray with a variable offset, designed to increase the range of motion and to reduce the impingement. The purposes of this study were to evaluate the effect of reverse shoulder implant design parameters on the deltoid muscle forces, required to produce abduction, and on the shoulder range of motion, in order to provide a more systematic understanding of the fundamental effects of humeral component positioning on the implant performances. The study has been implemented using virtual prototypes of the shoulder-prosthesis assembly. The shape of the prosthesis has been digitally acquired via a 3D scanner and the CAD models of all the components have been created. Through CT images, 3-dimensional models of the shoulder bones have been reconstructed and assembled with the prosthesis components. Numerical FEM models have been set up in order to evaluate how the abduction force changes depending on the humeral tray offset. Using the virtual prototypes of the shoulder-prosthesis assembly, a range of motion analysis has been carried out by setting up a collision detection analysis in a 3D parametric modeling environment. Different humeral tray positions were investigated and four different motions of the arm were simulated. Obtained results have demonstrated that a suitable positioning of the humeral tray can offer significant biomechanical advantages in terms of range of motion and abduction force.

Published

2017

8. Influence of the Screw Positioning on the Stability of Locking Plate for Proximal Tibial Fractures: A Numerical Approach

Author

Daniele Pecorella, Laura Bragonzoni, Vito Ricotta, Tommaso Ingrassia, Vincenzo Nigrelli, Ingrassia T., Nigrelli V., Pecorella D., Bragonzoni L., Ricotta V., Tommaso Ingrassia, Vincenzo Nigrelli, Daniele Pecorella, Laura Bragonzoni, and Vito Ricotta

Subjects

musculoskeletal diseases, Materials science, medicine.medical_treatment, Healing time, lcsh:Technology, Stability (probability), Locking plate, lcsh:Chemistry, 03 medical and health sciences, 0302 clinical medicine, medicine, CAD, General Materials Science, 030212 general & internal medicine, Tibial fracture, Settore ING-IND/15 - Disegno E Metodi Dell'Ingegneria Industriale, lcsh:QH301-705.5, Instrumentation, Reduction (orthopedic surgery), implant stability, Fluid Flow and Transfer Processes, Orthodontics, FEM, 030222 orthopedics, lcsh:T, Process Chemistry and Technology, Work (physics), General Engineering, tibial fracture, musculoskeletal system, locking plates, lcsh:QC1-999, Finite element method, Computer Science Applications, reverse engineering, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, Proper treatment, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics

Abstract

Tibial fractures are common injuries in people. The proper treatment of these fractures is important in order to recover complete mobility. The aim of this work was to investigate if screw positioning in plates for proximal tibial fractures can affect the stability of the system, and if it can consequently influence the patient healing time. In fact, a more stable construct could allow the reduction of the non-weight-bearing period and consequently speed up the healing process. For that purpose, virtual models of fractured bone/plate assemblies were created, and numerical simulations were performed to evaluate the reaction forces and the maximum value of the contact pressure at the screw/bone interface. A Schatzker type I tibial fracture was considered, and four different screw configurations were investigated. The obtained results demonstrated that, for this specific case study, screw orientation affected the pressure distribution at the screw/bone interface. The proposed approach could be used effectively to investigate different fracture types in order to give orthopaedists useful guidelines for the treatment of proximal tibial fractures.

Published

2020

9. A reverse engineering approach to measure the deformations of a sailing yacht

Author

Francesco Di Paola, Tommaso Ingrassia, Antonio Mancuso, Mauro Lo Brutto, Eynard, B, Nigrelli, Oliveri, SM, Peris-Fajarnes, G, Rizzuti, S, Di Paola, F, Ingrassia, T, Lo Brutto, M, and Mancuso, A

Subjects

Reverse engineering, Engineering, Process (engineering), Mechanical engineering, CAD, computer.software_genre, 03 medical and health sciences, 0302 clinical medicine, 3D computer graphics software, Hull, 0502 economics and business, Generative algorithm, Settore ING-IND/15 - Disegno E Metodi Dell'Ingegneria Industriale, Measure (data warehouse), business.industry, 05 social sciences, 030206 dentistry, Photogrammetry, CAE tool, Close range photogrammetry, Sailing yacht, Settore ICAR/17 - Disegno, CAE tools, Generative algorithms, business, computer, 050203 business & management, Settore ICAR/06 - Topografia E Cartografia, Marine engineering

Abstract

In this work, a multidisciplinary experience, aimed to study the permanent deformations of the hull of a regatta sailing yacht is described. In particular, a procedure to compare two different surfaces of the hull of a small sailing yacht, designed and manufactured at the University of Palermo, has been developed. The first one represents the original CAD model while the second one has been obtained by means of a reverse engineering approach. The reverse engineering process was performed through an automatic close-range photogrammetry survey, that has allowed to obtain very accurate measures of the hull, and a 3D modelling step by the well-known 3D computer graphics software Rhinoceros. The reverse engineering model was checked through two different procedures implemented by the graphical algorithm editor Grasshopper. The first procedure has allowed to compare the photogrammetric measurements with the rebuilt surface, in order to verify if the reverse engineering process has led to reliable results. The second has been implement to measure the deviations between the original CAD model and the rebuilt surface of the hull. This procedure has given the possibility to highlight any permanent deformation of the hull due to errors during the production phase or to excessive loads during its use. The obtained results have demonstrated that the developed procedure is very efficient and able to give detailed information on the deviation values of the two compared surfaces.

Published

2017

10. Process parameters influence in additive manufacturing

Author

Vito Ricotta, Tommaso Ingrassia, Vincenzo Nigrelli, C. Tartamella, Ingrassia, T, Nigrelli, V, Ricotta, V, and Tartamella, C

Subjects

Reverse engineering, 0209 industrial biotechnology, Computer science, Additive manufacturing, media_common.quotation_subject, Point cloud, 3D printing, CAD, 02 engineering and technology, computer.software_genre, law.invention, Set (abstract data type), 020901 industrial engineering & automation, 0203 mechanical engineering, law, Quality (business), Process engineering, media_common, Fused deposition modeling, business.industry, Process parameter, Process (computing), 020303 mechanical engineering & transports, business, computer

Abstract

Additive manufacturing is a rapidly expanding technology. It allows the creation of very complex 3D objects by adding layers of material, in spite of the traditional production systems based on the removal of material. The development of additive technology has produced initially a generation of additive manufacturing techniques restricted to industrial applications, but their extraordinary degree of innovation has allowed the spreading of household systems. Nowadays, the most common domestic systems produce 3D parts through a fused deposition modeling process. Such systems have low productivity and make, usually, objects with no high accuracy and with unreliable mechanical properties. These side effects can depend on the process parameters. Aim of this work is to study the influence of some typical parameters of the additive manufacturing process on the prototypes characteristics. In particular, it has been studied the influence of the layer thickness on the shape and dimensional accuracy. Cylindrical specimens have been created with a 3D printer, the Da Vinci 1.0A by XYZprinting, using ABS filaments. Dimensional and shape inspection of the printed components has been performed following a typical reverse engineering approach. In particular, the point clouds of the surfaces of the different specimens have been acquired through a 3D laser scanner. After, the acquired point clouds have been post-processed, converted into 3D models and analysed to detect any shape or dimensional difference from the initial CAD models. The obtained results may constitute a useful guideline to choose the best set of the process parameters to obtain printed components of good quality in a reasonable time and minimizing the waste of material.

Published

2017

11. Numerical study of the components positioning influence on the stability of a reverse shoulder prosthesis

Author

Antonio Mancuso, Davide Tumino, Tommaso Ingrassia, Vincenzo Nigrelli, Ingrassia, T, Mancuso, A, Nigrelli, V, and Tumino, D

Subjects

Scanner, Engineering, Engineering drawing, business.industry, CAD, Structural engineering, Stability (probability), Industrial and Manufacturing Engineering, Finite element method, Stability conditions, medicine.anatomical_structure, Scapula, Modeling and Simulation, medicine, Non linear FEM analyses · 3D scanner acquisition · Reversed shoulder prosthesis · Shoulder stability ratio, Humerus, Shoulder joint, Non linear FEM analyses, 3D scanner acquisition, Reversed shoulder prosthesis, Shoulder stability ratio, business, Settore ING-IND/15 - Disegno E Metodi Dell'Ingegneria Industriale

Abstract

Aim of this paper is to setup a novel procedure able to analyze performances of a reverse shoulder prosthesis when different geometrical configurations are assumed. Nowadays, such a prosthesis is widely used but, because of its novelty, data in literature give poor information about performances and limits to its applicability. The activity has been divided into the following steps. At the beginning the shape of the prosthesis has been digitally acquired via a 3D scanner. Then, CAD models of all prosthetic components have been geometrically optimized in a way to obtain final entities suitable for numerical simulations. After that, CAD assemblies have been created between prosthetic components and bones (humerus and scapula) involved in the shoulder joint. Following step has been the setup of numerical finite element method models to simulate use conditions. To this scope, analyses have been performed in accordance with experimental conditions found in literature. Stability conditions have been verified under the action of horizontal and vertical instability loads with different version angles between humerus and the humeral implant. In particular, the stability ratios of the prosthesis have been calculated for the analysed loading conditions. Obtained results show how the positioning has a great influence on the shoulder stability and allow the definition of guidelines for the application of this prosthesis.

Published

2014

12. Finite element analysis of two total knee joint prostheses

Author

Lorenzo Nalbone, Davide Tumino, Tommaso Ingrassia, Vito Ricotta, Vincenzo Nigrelli, Ingrassia, T, Nalbone, L, Nigrelli, V, Ricotta, V, and Tumino, D

Subjects

Engineering, business.industry, medicine.medical_treatment, Contact analysis, CAD, Kinematics, Structural engineering, Prosthesis, Industrial and Manufacturing Engineering, Finite element method, Stress (mechanics), Modeling and Simulation, medicine, Total knee replacement, FEM simulation, Contact analysis, business, Reduction (mathematics), Biomedical engineering, Interpolation

Abstract

Aim of this work is to compare two different total knee prostheses that differ mainly in the shape of the polyethylene (PE) component inserted between the femoral and tibial plates. The best solution between them has been originally reshaped in order to reduce stress peaks. The study procedure has been divided into the following steps. First step is the digitalisation of the shape of the prostheses by means of a 3D laser scanner. The morphology of two prototypes of the prostheses has been acquired by elaborating multiple Moire fringe patterns projected on their surfaces. Second step consisted on the manipulation of these data in a CAD module, that is the interpolation of raw data into NURBS surfaces, reducing singularities due to the typical scattering of the acquiring system. Third step has been the setting up of FEM simulations to evaluate the prostheses behaviour under benchmark loading conditions given in literature. The CAD model of the prostheses has been meshed into solid finite elements. Different flexion angles configurations have been analysed, the load being applied along the femoral axis. FEM analyses have returned stress fields in the PE insert and, in particular, in the stabilizing cam which function is to avoid dislocation. Last step has been the integrated use of CAD and FEM to modify the shape of the stabilizing cam of the best prosthesis, in order to reduce the stress peaks in the original prosthesis without affecting kinematics of the joint. Good results have been obtained both in terms of stress and contact pressure peaks reduction.

Published

2012