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EN
This paper shows results of numerical solutions the modified Reynolds equations for laminar unsteady oil flow in slide journal bearing gap. Laminar unsteady oil flow is performed during periodic and unperiodic perturbations of bearing load or is caused by the changes of gap height in time. Above perturbations occur mostly during the starting and stopping of machine. During modelling crossbar bearing operations in combustion engines, bearing movement perturbations from engine vertical vibrations causes velocity flow perturbations of lubricating oil on the bearing race and on the bearing slider in the circumferential direction. This solution example applies to isothermal bearing model with infinity length. Lubricating oil used in this model has Newtonian properties and constant dynamic viscosity. Perturbations connected with unsteady lubricating oil velocity in the circumferential direction on the slide bearing and on the slider of bearing were taken into consideration. Results are presented in the dimensionless hydrodynamic pressure and velocity distribution diagrams. Received solutions were compared with the solution received by the stationary lubrication flow in the slide journal bearing, which were made with the same parameter assumption by constant dynamic oil viscosity. Isothermal bearing model is similar to friction node model by steady-state heat load conditions.
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EN
This paper shows results of numerical solutions an modified Reynolds equations for laminar unsteady oil flow in slide journal bearing gap. Laminar unsteady oil flow is performed during periodic and unperiodic perturbations of bearing load or is caused by the changes of gap height in time. During modelling crossbar bearing operations in combustion engines, bearing movement perturbations from engine vertical vibrations causes velocity flow perturbations of lubricating oil on the shaft in the circumferential direction. This solution example apply to isothermal bearing model with infinity length. Lubricating oil used in this model has Newtonian properties and constant dynamic viscosity. Results are presented in the dimensionless hydrodynamic pressure and tangential tension distribution diagrams. Diagrams also presents capacity and friction force change during the time of velocity perturbations. Received solutions were compared with the solution received by the stationary lubrication flow in the slide journal bearing, which were made with the same parameter assumption by constant dynamic oil viscosity. Isothermal bearing model is similar to friction node model by steady-state heat load conditions. Described effect can be used as on example of modeling the bearing friction node operations in reciprocating movement during exploitation of engines and machines.
EN
This paper shows results of numerical solutions modifled Reynolds equations for laminar unsteady oil flow in slide Journal bearing gap. Laminar unsteady oil flow is performed during periodic and unperiodic perturbations of bearing load or is caused by the changes of gap height in time. During modelling crossbar bearing operations in combustion engines, bearing movement perturbations from engine vertical vibrations causes velocity flow perturbations of lubricating oil on the bearing race and on the bearing slider in the circumferential direction. Above perturbations occur mostly during the starting and stopping of machine. This solution example applies to isothermal bearing model with infinity length. Lubricating oil used in this model has Newtonian properties and constant dynamic viscosity. Results are presented in the dimensionless hydrodynamic pressure and tangential tension distribution diagrams. Diagrams also presents capacity and friction force change during the time ofvelocity perturbations. Received solutions were compared with the solution received by the stationary lubrication flow in the slide Journal bearing, which were made with the same parameter assumption by constant dynamie oil viscosity. Isothermal bearing model is similar to friction node model by steady-state heat load conditions. Described effect can be used as on example of modelling the bearing friction node operations in reciprocating movement during exploitation of engines and machines.
PL
W artykule przedstawiono wyniki rozwiązania zmodyfikowanego ciągu równań Reynoldsa opisującego laminarny niestacjonarny przepływ oleju smarującego w szczelinie smarnej poprzecznego cylindrycznego łożyska ślizgowego. Wyniki tych rozwiązań umożliwiają wyznaczenie rozkładu prędkości oleju w kierunku wzdłużnym łożyska. Uwzględniono niestacjonarne zaburzenia prędkości przepływu oleju w kierunku obwodowym na powierzchni czopa i panewki łożyska. Wyniki rozwiązania dotyczą izotermicznego modelu łożyska o nieskończonej długości smarowanego olejem o stałej lepkości dynamicznej.
EN
This paper shows the results of numerical solutions of modified Reynolds equations for laminar unsteady oil flow in the slide journal-bearing gap. Laminar unsteady oil flow is performed during periodic and non-periodic perturbations of bearing load or is caused by the changes of gap height in time. Above perturbations occur mostly during the starting and stopping of the machine. During modelling crossbar-bearing operations in combustion engines, bearing movement perturbations from engine vertical vibrations causes velocity flow perturbations of lubricating oil on the bearing race and on the bearing slider in the circumferential direction. This solution example applies to an isothermal bearing model with infinite length. Lubricating oil used in this model has Newtonian properties and constant dynamic viscosity. Perturbations connected with unsteady lubricating oil velocity in the circumferential direction on the slide bearing and on the slider of bearings were taken into consideration. This article also analyses pressure and velocity distributions in the bearing in the time function during the perturbation. Results are presented in the dimensionless hydrodynamic pressure and velocity distribution diagrams. Diagrams also present the velocity change during the moment of perturbations. Velocity position during perturbation was also analysed. Received solutions were compared with the solution received by the stationary lubrication flow in the slide journal bearing, which were made with the same parameter assumption by constant dynamic oil viscosity. The isothermal bearing model is similar to the friction node model by steady-state heat load conditions.
EN
This paper shows results of numerical solutions an modified Reynolds equations for laminar unsteady oil flow in slide Journal bearing gap. Laminar unsteady oil flow is performed during periodic and a periodic perturbations of bearing load or is caused by the changes of gap height in time. Above perturbations occur mostly during the starting and stopping of machine. During modelling crossbar bearing operations in combustion engines, bearing movement perturbations from engine vertical vibrations causes velocity flow perturbations of lubricating oil on the bearing race and on the bearing slider in the circumferential direction. This solution example applies to isothermal bearing model with infinity length. Lubricating oil used in this model has Newtonian properties and constant dynamic viscosity. Perturbations connected with unsteady lubricating oil velocity in the circumferential direction on the slide bearing and on the slider of bearing were taken into consideration. Results are presented in the dimensionless hydrodynamic pressure and velocity distribution diagrams. Received solutions were compared with the solution received by the stationary lubrication flow in the slide Journal bearing, which were made with the same parameter assumption by constant dynamic oil viscosity. Isothermal bearing model is similar to friction node model by steady-state heat load conditions.
PL
W artykule przedstawiono wyniki obliczeń siły nośności hydrodynamicznej w poprzecznym cylindrycznym łożysku ślizgowym smarowanym olejem newtonowskim o lepkości dynamicznej zależnej od ciśnienia. Uwzględniono niestacjonarne zaburzenia prędkości obwodowej przepływu oleju na czopie i na panewce, które mogą być spowodowane drganiami obwodowymi czopa lub panewki wskutek drgań skrętnych wału silnika. Przykładowe rozwiązanie numeryczne dotyczy izotermicznego modelu łożyska o nieskończonej długości.
EN
The results of numerical solution of laminar, unsteady lubricated cylindrical slide bearing. Laminar, unsteady oil flow is performed during periodic and unperiodic perturbations of bearing load or is caused by the changes of gap height in the time. The disturbances related with unsteady velocity oils on the journal and on the sleeve. The solutions apply to infinite length of lubricated with newtonian oil by dynamic viscosity depends on pressure. The numerical results shown on diagrams of capacity force in dimensionless form in time intervals of displacement duration.
PL
W artykule przedstawiono wyniki rozwiązania numerycznego zmodyfikowanego równania Reynoldsa dla laminarnego niestacjonarnego smarowania poprzecznego cylindrycznego łożyska ślizgowego. Przykład rozwiązania dotyczy izotermicznego modelu łożyska o nieskończonej długości, smarowanego olejem o stałej lepkości dynamicznej. Uwzględniono zaburzenia prędkości przepływu oleju w kierunku obwodowym na czopie i panewce. Wyznaczono rozkłady ciśnienia hydrodynamicznego w postaci bezwymiarowej.
EN
This paper presents the results of numerical solutions modified by Reynolds equation of laminar unsteady lubrication of a cylindrical slide journal bearing. The particular solutions are limited to isothermal models of bearing with infinite length lubrication by newtonian oil with constant dynamic viscosity. The disturbances are related with unsteady velocity of oil flow on the sleeve and on the journal. The results are shown in the diagram of hydrodynamic pressure in the dimensionless form in time intervals of displacement duration.
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