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Validation of the physical effect implementation in a simulation model for the cylinder block/valve plate contact supported by experimental investigationsWegner, Stephan, Löschner, Fabian, Gels, Stefan, Murrenhoff, Hubertus 27 April 2016 (has links) (PDF)
Overall losses in swash plate type axial piston machines are mainly defined by three tribological interfaces. These are swash plate/slipper, piston/cylinder and cylinder block/valve plate. Within a research project, funded by the German Research Foundation, a combined approach of experimental research and simulation is chosen to acquire further knowledge on the cylinder block/valve plate contact. The experimental investigations focus on the friction torque within the contact and the measurement of the cylinder block movement in all six degrees of freedom. Simultaneously a simulation model is created focusing on the main physical effects. By considering the results of the experimental investigations significant physical effects for the simulation model are assessed. Within this paper a first comparison between experimental results and the simulation is presented, showing that for a qualitative match the implemented effects (mainly the fluid film, solid body movement, solid body contact, surface deformation) are sufficient to model the general behaviour of theinvestigated pump.
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An Investigation of the Impact of the Elastic Deformation of the End case/Housing on Axial Piston Machines Cylinder Block/Valve Plate Lubricating InterfaceChacon, Rene, Ivantysynova, Monika 27 April 2016 (has links) (PDF)
The cylinder block/valve plate interface is a critical design element of axial piston machines. In the past, extensive work has been done at Maha Fluid Power Research center to model this interface were a novel fluid structure thermal interaction model was developed which accounts for thermal and elasto-hydrodynamic effects and has been proven to give an accurate prediction of the fluid film thickness. This paper presents an in-depth investigation of the impact of the elastic deformation due to pressure and thermal loadings of the end case/housing on the performance of the cylinder block/valve plate interface. This research seeks to understand in a systematic manner the sensitivity of the cylinder block/valve plate interface to the structural design and material properties. A comparison between simulations results is done by utilizing different end case designs and material compositions, both in the valveplate and end case solids.
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The Impact of Micro-Surface Shaping of the Piston on the Piston/Cylinder Interface of an Axial Piston MachineWondergem, Ashley, Ivantysynova, Monika 02 May 2016 (has links) (PDF)
Axial piston machines of the swashplate type are commonly used in various hydraulic systems and with recent developments in displacement control, it is essential to maximize their efficiency further reducing operation costs as well as improving performance and reliability. This paper reports findings of a research study conducted for the piston-cylinder interface utilizing a novel fluid structure thermal interaction model considering solid body deformation due to thermal and pressure effects in order to accurately predict the transient fluid film within the gap. A large reduction in energy dissipation is possible due to reduced clearances allowable due to the surface shaping of the piston resulting in a reduction in leakage. From this study, it is shown that surface shaping of the piston in combination with a reduced clearance is not only beneficial by improving the efficiency of a machine, but also increases the reliability and the performance of the machine as the load support is enhanced.
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VIRTUAL PROTOTYPING OF AXIAL PISTON MACHINES OF SWASH PLATE TYPERene Chacon Portillo (5929562) 02 August 2019 (has links)
Axial piston machines are widely used in the industry ranging from aerospace, agriculture, automotive, heavy machinery, etc. These applications require better pumps and motors to meet current market demands such as higher power density in hydraulic units, smarter pumps (diagnostics and prognostics), higher efficiencies, and compactness. The current state-of-the-art in pump design is mostly based on heuristic design approach with very limited use of numerical toolssince the invention of this positive displacement machine until the present time. The numerical tools being used do not capture the physical phenomena in the thin fluid film between the rotating group components. The work presented in this dissertation aims to demonstrate the feasibility of virtual prototyping utilizing a combination of in-house developed multi-domain models and to propose a novel computational based design methodology for axial piston machines. The methodology is an iterative process between the virtual components in 3D CAD models and the function evaluations for the design requirements utilizing the numerical models which provide an accurate prediction to the behavior of the mechanical components working together. To validate the proposed methodology a case study on a 24 cc/rev axial piston machine was carried out. The machine was built virtually, simulated,and optimized for desired performance. A physical prototype was built based on the case study and tested successfullyfor forty-five operating conditions.
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An Investigation of the Impact of the Elastic Deformation of the End case/Housing on Axial Piston Machines Cylinder Block/Valve Plate Lubricating InterfaceChacon, Rene, Ivantysynova, Monika January 2016 (has links)
The cylinder block/valve plate interface is a critical design element of axial piston machines. In the past, extensive work has been done at Maha Fluid Power Research center to model this interface were a novel fluid structure thermal interaction model was developed which accounts for thermal and elasto-hydrodynamic effects and has been proven to give an accurate prediction of the fluid film thickness. This paper presents an in-depth investigation of the impact of the elastic deformation due to pressure and thermal loadings of the end case/housing on the performance of the cylinder block/valve plate interface. This research seeks to understand in a systematic manner the sensitivity of the cylinder block/valve plate interface to the structural design and material properties. A comparison between simulations results is done by utilizing different end case designs and material compositions, both in the valveplate and end case solids.
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The Impact of Micro-Surface Shaping of the Piston on the Piston/Cylinder Interface of an Axial Piston MachineWondergem, Ashley, Ivantysynova, Monika January 2016 (has links)
Axial piston machines of the swashplate type are commonly used in various hydraulic systems and with recent developments in displacement control, it is essential to maximize their efficiency further reducing operation costs as well as improving performance and reliability. This paper reports findings of a research study conducted for the piston-cylinder interface utilizing a novel fluid structure thermal interaction model considering solid body deformation due to thermal and pressure effects in order to accurately predict the transient fluid film within the gap. A large reduction in energy dissipation is possible due to reduced clearances allowable due to the surface shaping of the piston resulting in a reduction in leakage. From this study, it is shown that surface shaping of the piston in combination with a reduced clearance is not only beneficial by improving the efficiency of a machine, but also increases the reliability and the performance of the machine as the load support is enhanced.
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Enabling High-Pressure Operation with Water for the Piston-Cylinder Interface In Axial Piston MachinesMeike H Ernst (10135868) 01 March 2021 (has links)
<div><p>Water is inflammable, non-toxic, environmentally friendly---
desirable traits, for a hydraulic fluid. However, its extremely low viscosity
diminishes the load-bearing and sealing capacity of lubricating interfaces.
Case in point: axial piston machines of swash plate design are compact, highly
efficient positive displacement machines at the heart of hydraulic systems in
forestry, construction, aerospace, and agricultural equipment, as well as
industrial applications (presses, etc.); however, the three main lubricating
interfaces decisive to the performance of such units in terms of both component
life and efficiency are challenged by the use of water as working fluid.
Especially during high-pressure operation, this low-viscosity lubricant can
cause the these interfaces to fail in carrying the imposed load, resulting in
severe wear, or even pump failure. The piston-cylinder interface is
particularly challenging to design for water because it stands under obligation
to carry the heavy side load that acts on the pistons of these machines, which
increases with operating pressure. Furthermore, the architecture of axial
piston machines of swash plate design does not allow this interface to be
hydrostatically balanced.</p>
<p> </p>
<p>Through the development of a methodology that separates the
fluid pressure fields of the three main lubricating interfaces of axial piston
machines into their hydrostatic and hydrodynamic components, the present work
enables a direct comparison of these interfaces in terms of how they support
load. A case study of a 75 cc unit running on hydraulic oil conducted via this
methodology at three different operating conditions (low pressure/low speed,
low pressure/high speed, and high pressure/low speed) demonstrates that in the
piston-cylinder interface, the force from hydrostatic pressure reaches such
high magnitudes over the high-pressure stroke that less than half of it is
needed to counter the load. The excess force from hydrostatic pressure then
becomes the load. Consequentially, hydrodynamic pressure must counter a force
from hydrostatic pressure that exceeds the original load. In the other two
interfaces, by contrast, over half the load is being carried by hydrostatic pressure,
thus significantly diminishing the amount of hydrodynamic pressure the
interfaces are required to generate in order to achieve full load support.
Moreover, nearly all of the moment on the piston is countered by hydrodynamic
pressure, while less than half of the moment on the block is countered by
hydrodynamic pressure, and the moment on the slipper is negligible by
comparison.</p>
<p> </p>
<p>While this case study only investigates one pump, it shows
how critical hydrodynamic pressure can be to load support in the
piston-cylinder interface. The use of a low-viscosity fluid, e.g. water,
reduces the hydrodynamic pressure that is generated in this interface, which,
at challenging operating conditions, can lead to metal-to-metal contact. However,
the performance of the interface can be improved via micro surface shaping,
i.e. by giving the surface of the piston, or the bore that it moves through, a
shape on the order of microns in height. The aim of present work is to pursue
design trends leading to surface shapes that will enable this interface to
function at higher pressures than currently achievable. </p>
<p> </p>
<p>This pursuit takes the form of systematic virtual design
studies, an optimization procedure, and an algorithm developed specifically for
tailoring the bore surfaces through which the pistons travel to piston tilt and
deformation. From this emerges not only a set of design trends corresponding to
the dimensions of two particularly powerful types of micro surface shaping, but
also a profound insight into the behavior of the water-lubricated
piston-cylinder interface fluid film, and how that behavior can be manipulated
by changing the component surfaces that constitute its borders. Furthermore, in
collaboration with Danfoss High Pressure Pumps, a physical prototype of a 444
cc axial piston pump with surface shaping generated via the aforementioned
algorithm has been constructed and tested, achieving a total pump efficiency
roughly 3% higher than that achievable by the commercial unit that the geometry
of the prototype is based on.</p><br></div>
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Active Vibration Control of Axial Piston Machine using Higher Harmonic Least Mean Square Control of Swash PlateKim, Taeho, Ivantysynova, Monika 27 April 2016 (has links) (PDF)
Noise emission is a major drawback of the positive displacement machine. The noise source can be divided into structure borne noise source (SBNS) and fluid borne noise source (FBNS). Passive techniques such as valve plate optimization have been used for noise reduction of axial piston machines. However, passive techniques are only effective for limited operating conditions or at least need compromises in design. In this paper, active vibration control of swash plate is investigated for vibration and noise reduction over a wide range of operating conditions as an additional method to passive noise reduction techniques. A 75cc pump has been modified for implementation of active vibration control using the swash plate. One tri-axial acceleration sensor and one angle sensor are installed on the swash plate and a high speed servovalve is used for the swash plate actuation. The multi-frequency two-weight least mean square (LMS) filter synthesizes the servovalve input signal to generate a destructive interference force which minimizes the swash plate vibration. An experimental test setup has been realized using Labview field-programmable gate array (FPGA) via cRIO. Simulation and experimental studies are conducted to investigate the possibility of active vibration control.
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Validation of the physical effect implementation in a simulation model for the cylinder block/valve plate contact supported by experimental investigationsWegner, Stephan, Löschner, Fabian, Gels, Stefan, Murrenhoff, Hubertus January 2016 (has links)
Overall losses in swash plate type axial piston machines are mainly defined by three tribological interfaces. These are swash plate/slipper, piston/cylinder and cylinder block/valve plate. Within a research project, funded by the German Research Foundation, a combined approach of experimental research and simulation is chosen to acquire further knowledge on the cylinder block/valve plate contact. The experimental investigations focus on the friction torque within the contact and the measurement of the cylinder block movement in all six degrees of freedom. Simultaneously a simulation model is created focusing on the main physical effects. By considering the results of the experimental investigations significant physical effects for the simulation model are assessed. Within this paper a first comparison between experimental results and the simulation is presented, showing that for a qualitative match the implemented effects (mainly the fluid film, solid body movement, solid body contact, surface deformation) are sufficient to model the general behaviour of theinvestigated pump.
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Active Vibration Control of Axial Piston Machine using Higher Harmonic Least Mean Square Control of Swash PlateKim, Taeho, Ivantysynova, Monika January 2016 (has links)
Noise emission is a major drawback of the positive displacement machine. The noise source can be divided into structure borne noise source (SBNS) and fluid borne noise source (FBNS). Passive techniques such as valve plate optimization have been used for noise reduction of axial piston machines. However, passive techniques are only effective for limited operating conditions or at least need compromises in design. In this paper, active vibration control of swash plate is investigated for vibration and noise reduction over a wide range of operating conditions as an additional method to passive noise reduction techniques. A 75cc pump has been modified for implementation of active vibration control using the swash plate. One tri-axial acceleration sensor and one angle sensor are installed on the swash plate and a high speed servovalve is used for the swash plate actuation. The multi-frequency two-weight least mean square (LMS) filter synthesizes the servovalve input signal to generate a destructive interference force which minimizes the swash plate vibration. An experimental test setup has been realized using Labview field-programmable gate array (FPGA) via cRIO. Simulation and experimental studies are conducted to investigate the possibility of active vibration control.
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