This article introduces a novel set of multi-bond graph diagrams (MBGDs), which are intended for modelling an arbitrary planetary gear train (PGT). In this regard, three standard MBGDs are proposed: (a) one was developed for representing a single moving body, (b) another was designed for describing a revolute joint, and (c) the last one was created for representing a gear pair. Thus, by taking advantage of the module handling facility offered by the multibond graph technique (MBGT) and by adopting a multi-body-based approach, such models can be systematically coupled, through an assembling procedure, thereby forming the complete model for the whole PGT. Moreover, the obtained model incorporates both kinematics and kinetics equations of the PGT under study and allows us to perform a comprehensive power-flow analysis. The proposed approach also offers the capability of computing the dynamic loads of bearings and gear teeth for an adequate design of the PGT at hand. Furthermore, the resulting MBGD of the PGT has assigned an integral causality, which is a salient feature to be pursued in the resulting set of state equations, and mathematically means that an explicit set of first-order, differential equations can be obtained. Finally, the proposed diagrams are numerically validated by means of the simulation of a typical PGT and by its corresponding comparison with the Lagrange's equations and also with the Euler's laws.
YangA. T.FreudensteinF.‘Mechanics of epicyclic bevel-gear trains’Trans. ASME J. Eng. Ind.95 (1973): 497–502
2.
YuD.BeachleyN.‘On the mechanical efficiency of differential gearing’Trans. ASME J. Mech., Trans. Autom. Des.107 (1985): 61–67
3.
InnocentiC.‘A framework for efficiency evaluation ofmulti-degree-of-freedom gear trains’Trans. ASME J. Mech. Des.118 (1996): 556–560
4.
ChenD. Z.LinT. W.LinY. L.‘Dynamic analysis of geared robotic mechanisms by the concept of torque transmission’Mech. Mach. Theory35 (2000): 629–643
5.
HsuC. H.HsuJ. J.‘Epicyclic gears trains for automotive automatic transmissions’Proc. Instn Mech. Engrs, Part D: J. Automobile Engineering214 (2000): 523–532
6.
PennestriE.ValentiniP. P.‘Dynamic analysis of epicyclic gear trains by means of computer algebra’Multibody Syst. Dyn.7 (2002): 249–264
7.
PennestriE.ValentiniP. P.‘A review of formulas for the mechanical efficiency analysis of two degrees-of-freedom epicyclic gear trains’Trans. ASME J. Mech. Des.125 (2003): 602–608
8.
XiaS.HowardI.WangJ.‘The dynamic modeling of multiple pairs of spur gears in mesh, including friction and geometrical errors’Int. J. Rotat. Mach.9 (2003): 437–442
9.
Al-DwairiA. F.Al-LubaniS. E.‘Modeling and dynamic analysis of a planetary mechanism with an elastic belt’Mech. Mach. Theory39 (2004): 343–355
10.
Al-ShyyabA.KahramanA.‘A non-linear dynamic model for planetary gear sets’Proc. IMechE, Part K: J. Multi-body Dynamics221 (2007): 567–576
11.
KahramanA.‘Planetary gear train dynamics’Trans. ASME J. Mech. Des.116 (1994): 713–720
12.
KarnoppD.RosenbergR. C.‘Application of bond graph techniques to the study of vehicle drive line dynamics’Trans. ASME J. Basic Eng.92 (1970): 355–362
13.
AllenR. R.‘Multiport models for the kinematic and dynamic analysis of gear power transmissions’Trans. ASME J. Mech. Des.101 (1979): 258–267
14.
RosenbergR. C.‘Simulation of engineering systems containing lumped components and transmission elements’ (1979)
15.
ChoD.HedrickJ. K.‘Automotive powertrain modeling for control’Trans. ASME J. Dyn. Syst. Meas. Control111 (1989): 568–576
16.
HrovatD.ToblerW. E.‘Bond graph modeling of automotive power trains’J. Franklin Inst.3285/6 (1991): 623–662
17.
CoudertN.Dauphin-TanguyG.RaultA.‘Mechatronic design of an automatic gear box using bond graphs’ (1993)
18.
KimJ. H.ChoD. I.‘An automatic transmission model for vehicle control’ (1997)
19.
SeoJ.YiS. J.‘Design of an automatic transmission system having an arbitrary power flow using the automatic power flow generation algorithm’Proc. IMechE, Part D: J. Automobile Engineering219 (2005): 1085–1097
20.
FilippaM.MiC.ShenJ.StevensonR. C.‘Modeling of a hybrid electric vehicle powertrain test cell using bond graphs’IEEE Trans. Veh. Technol.543 (2005): 837–845
21.
DeurJ.PetricJ.AsgariJ.HrovatD.‘Recent advances in control-oriented modeling of automotive power train dynamics’IEEE/ASME Trans. Mechatronics115 (2006): 513–523
22.
BreedveldP. C.‘Proposition for an unambiguous vector bond graph notation’Trans. ASME J. Dyn. Syst., Meas., Control104 (1982): 267–270
23.
BreedveldP. C.‘Decomposition of multiport elements in a revised multibond graph notation’J. Franklin Inst.3184 (1984): 253–273
24.
BosA. M.TiernegoM. J. L.‘Formula manipulation in the bond graph modelling and simulation of large mechanical systems’J. Franklin Inst.3191/2 (1985): 51–65
25.
BreedveldP. C.‘Multibond graph elements in physical systems theory’J. Franklin Inst.3191/2 (1985): 1–36
26.
TiernegoM. J. L.BosA. M.‘Modelling the dynamics and kinematics of mechanical systems with multibond graphs’J. Franklin Inst.3191/2 (1985): 37–50
27.
FelezJ.VeraC.San JoseI.CachoR.‘BONDYN: A bond graph based simulation program for multibody systems’Trans. ASME J. Dyn. Syst. Meas. Control112 (1990): 717–727
28.
VazA.KansalH.SinglaA.‘Some aspects in the bond graph modelling of robotic manipulators: angular velocities from symbolic manipulation of rotation matrices’ (2003)
29.
XiaS.LinkensD. A.BennettS.‘Automatic modelling and analysis of dynamic physical systems using qualitative reasoning and bond graphs’Intel. Syst. Eng.34 (1993): 201–212
30.
MacfarlaneJ.DonathM.‘The automated symbolic derivation of state equations for dynamic systems’ (1988)
31.
McGillD. J.KingW. W.Engineering mechanics: an introduction to dynamics (Brooks/Cole Engineering Division1984)
32.
Cervantes-SánchezJ. J.RazoJ.‘A new approach on the modelling of multibody systems using multibond graphs’ (1993)
33.
Cervantes-SánchezJ. J.Dynamics of serial manipulators using multibond graphs (Salamanca, México: Universidad de Guanajuato, FIMEE1994) (in Spanish). Doctoral Dissertation
34.
BehzadipourS.KhajepourA.‘Causality in vector bond graphs and its application to modeling of multi-body dynamic systems’Simul. Model. Pract. Theory14 (2005): 279–295
35.
FavreW.ScavardaS.‘Bond graph representation of multibody systems with kinematic loops’J. Franklin Inst. 335B 4 (1997): 643–660
36.
ErsalT.SteinJ. L.LoucaL. S.‘A bond graph based modular modeling approach towards an automated modeling environment for reconfigurable machine tools’ (2004) (available on CD-ROM).
37.
ZeidA.ChungC. H.‘Bond graph modelling of multibody systems: A library of three-dimensional joints’J. Franklin Inst.3294 (1992): 605–636
38.
Ledesma-JaimeR.Power-flow analysis of planetary gear trains by using multibond graphs (Salamanca, Gto., México: Universidad de Guanajuato2008) Eng. Thesis, FIMEE, (in spanish).
39.
SchiehlenW.Multibody systems handbook (Berlin, Germany: Springer-Verlag1990)
40.
JuvinallR. C.MarshekK. M.Fundamentals of machine component design (Hoboken, NJ, USA: John Wiley & Sons, Inc.2000): 3rd edition, 817–824 section 20.3
41.
AngelesJ.Fundamentals of robotic mechanical systems (New York: Springer2007)
