Description
SPRINGER Structural Synthesis Of Parallel Robots Part 1 Methodology (Solid Mechanics And Its Applications Volume 149) 2008 Edition by GOGU GRIGORE
This is the first book of robotics presenting solutions of uncoupled and fully-isotropic parallel robotic manipulators and a method for their structural synthesis. Part 1 presents the methodology proposed for structural synthesis. Part 2 presents the various topologies of parallel robots generated by this systematic approach. Many solutions are presented here for the first time. The book will contribute to a widespread implementation of these solutions in industrial products. Preface; Acknowledgements; List of abbreviations and notations; 1 Introduction; 1.1 Robot; 1.2 Robotics; 1.3 Parallel Robot; 1.4 Terminology ; 1.5 Structural synthesis; 1.6 The objectives and originality of this book ; 2 Structural parameters; 2.1 Critical review of mobility calculation ; 2.1.1 Chebychev's contribution; 2.1.2 Sylvester's contribution ; 2.1.3 Grubler's contribution; 2.1.4 Somov's contribution; 2.1.5 Hochman's contribution; 2.1.6 Somov-Malytsheff's formula ; 2.1.7 Koenigs' formula; 2.1.8 Kutzbach's mobility equation; 2.1.9 Dobrovolski's mobility equation ; 2.1.10 Contribution of Y.F. Moroskine; 2.1.11 Contribution of R. Voinea and M. Atanasiu ; 2.1.12 Kolchin's mobility equation; 2.1.13 Roessner's contribution ; 2.1.14 Boden's mobility equation; 2.1.15 Manafu's formula ; 2.1.16 0zol's formula; 2.1.17 Contribution of K. J. Waldron ; 2.1.18 Contribution of N. Manolescu ; 2.1.19 Contribution of C. Bagci; 2.1.20 Contribution of P. Antonescu ; 2.1.21 Contribution of F. Freudenstein and R. Alizade ; 2.1.22 Hunt's contribution ; 2.1.23 Herve's contribution; 2.1.24 Gronowicz's contribution ; 2.1.25 Baker's contribution; 2.1.26 Davies's contribution ; 2.1.27 Contribution of V.P. Agrawal and J.S. Rao ; 2.1.28 Contribution of J. Angeles and C. Gosselin ; 2.1.29 Contribution of F. Dudita and D. Diaconescu ; 2.1.30 Contribution of P. Fanghella and C. Galletti ; 2.1.31 Fayet's contribution ; 2.1.32 Tsai's formula; 2.1.33 McCarthy's formula ; 2.1.34 Contribution of Z. Huang, L.F. Kong and Y.F. Fang ; 2.1.35 Contribution of J.M. Rico, J. Gallardo and B. Ravani ; 2.2 Chebychev-Grubler-Kutzbach's mobility criteria ; 2.2.1 Initial Chebychev-Grubler-Kutzbach's criterion ; 2.2.2 Extended Chebychev-Grubler-Kutzbach's criterion ; 2.2.3 Applicability limitation of Chebychev-Grubler-Kutzbach's criteria; 2.3 Mobility and connectivity of parallel robots ; 2.3.1 General definitions and formulae for mobility and connectivity of mechanisms ; 2.3.2 Mobility and connectivity of simple open kinematic chains ; 2.3.3 Mobility and connectivity of single-loop kinematic chains ; 2.3.4 Connectivity between two elements of a single-loop kinematic chain ; 2.3.5. Mobility and connectivity of parallel robots with simple limbs ; 2.3.6. Mobility and connectivity of parallel robots with complex limbs; 2.3.7. General formulae for robot mobility and connectivity ; 2.4 Overconstraints in parallel robots; 2.5 Redundancy in parallel robots ; 2.6 General formulae for structural parameters; 3 Structural analysis ; 3.1 Simple open kinematic chains; 3.2 Single-loop kinematic chains ; 3.3 Parallel mechanisms with simple limbs ; 3.4 Parallel mechanisms with complex limbs ; 3.5 Other multi-loop kinematic chains ; 4 Kinematic analysis; 4.1. Decoupling in axiomatic design ; 4.2. Geometric modeling; 4.3 Kinematic modeling ; 4.3.1 Direct and inverse kinematics matrices used in Jacobian calculation; 4.3.2 Design and conventional Jacobian matrices ; 4.4 Types of workspaces and singularities ; 4.4.1 Types of workspaces; 4.4.2 Types of singularities ; 4.5. Kinetostatic performance indexes; 4.5.1 Cross-coupling indexes ; 4.5.2 Indexes of input-output propensity ; 4.5.3 Kinetostatic indexes defined in connection with manipulability ellipsoids and polythops; 4.6 Design Jacobian and motion decoupling ; 4.6.1. Parallel robots with coupled motions ; 4.6.2. Parallel robots with decoupled motions ; 4.6.3. Parallel robots with uncoupled motions ; 4.6.4. Maximally regular parallel robots; 5 Structural synthesis ; 5.1 Structural synthesis: a systematic approach in mechanism design ; 5.2. Morphological and evolutionary approaches ; 5.2.1 Morphological approaches ; 5.2.2 Evolutionary algorithms; 5.3 Evolutionary morphology ; 5.3.1 Design objectives; 5.3.2 Constituent elements ; 5.3.3 Morphological operators; 5.3.4 Set of solutions ; 5.3.5 General structure of the evolutionary morphology ; 5.4 General approach of structural synthesis of parallel robots ; 5.4.1 General conditions for structural synthesis of parallel robots via theory of linear transformations ; 5.4.2 General approach of structural synthesis of parallel robots via evolutionary morphology; 6 Limbs with two degrees of connectivity; 6.1 Limbs with two translational motions ; 6.2 Limbs with two rotational motions ; 6.3 Limbs with one translational and one rotational motion ; 6.4 Other limbs with two degrees of connectivity ; 6.5 Redundant limbs with two degrees of connectivity ; 7 Limbs with three degrees of connectivity ; 7.1 Limbs with three translational motions; 7.2 Planar limbs with one rotational and two translational motions ; 7.3 Non planar limbs with one rotational and two translational motions ; 7.4 Limbs with one translational and two rotational motions ; 7.5 Limbs with three rotational motions ; 7.6 Other limbs with three degrees of connectivity; 7.7 Redundant limbs with three degrees of connectivity ; 8 Limbs with four degrees of connectivity ; 8.1 Limbs with Schoenflies motion ; 8.2 Limbs with two translational and two rotational motions ; 8.3 Limbs with one translational and three rotational motions; 8.4 Other limbs with four degrees of connectivity ; 8.5 Redundant limbs with four degrees of connectivity; 9 Limbs with five degrees of connectivity ; 9.1 Limbs with two rotational and three translational motions; 9.2 Limbs with two translational and three rotational motions; 9.3 Other limbs with five degrees of connectivity; 9.4 Redundant limbs with five degrees of connectivity; 10 Limbs with six degrees of connectivity ; 10.1 Limbs with three translational and three rotational motions; 10.2 Redundant limbs with six degrees of connectivity; References; Index