ross.CylindricalBearing

ross.CylindricalBearing#

class ross.CylindricalBearing(n, speed=None, weight=None, bearing_length=None, journal_diameter=None, radial_clearance=None, oil_viscosity=None, tag=None, scale_factor=1, color='#355d7a', **kwargs)#

Cylindrical hydrodynamic bearing - Simplified analytical model.

This class provides a fast, simplified bearing model suitable for preliminary design and basic analysis. Uses closed-form analytical solutions from [Friswell, 2010] (page 177).

When to use this class: - Quick calculations and preliminary design - Educational purposes and basic understanding - Simple bearing geometries - When computational speed is critical

For advanced analysis, consider using PlainJournal instead, which provides: - Thermo-hydro-dynamic (THD) effects - Multiple bearing geometries (circular, lobe, elliptical) - Multi-pad configurations - Turbulence models - Oil starvation/flooding conditions

Parameters:
nint

Node which the bearing will be located in.

speedlist, pint.Quantity

List with shaft speeds frequency (rad/s).

weightfloat, pint.Quantity

Gravity load (N). It is a positive value in the -Y direction. For a symmetric rotor that is supported by two journal bearings, it is half of the total rotor weight.

bearing_lengthfloat, pint.Quantity

Bearing axial length (m).

journal_diameterfloat, pint.Quantity

Journal diameter (m).

radial_clearancefloat, pint.Quantity

Bore assembly radial clearance (m).

oil_viscosityfloat, pint.Quantity

Oil viscosity (Pa.s).

tagstr, optional

A tag to name the element Default is None.

scale_factorfloat, optional

The scale factor is used to scale the bearing drawing. Default is 1.

colorstr, optional

A color to be used when the element is represented. Default is ‘#355d7a’.

Returns:
CylindricalBearing element.

References

[Fri10]

Michael I Friswell. Dynamics of rotating machines. Cambridge University Press, 2010.

Examples

>>> import ross as rs
>>> Q_ = rs.Q_
>>> cylindrical = CylindricalBearing(
...     n=0,
...     speed=Q_([1500, 2000], "RPM"),
...     weight=525,
...     bearing_length=Q_(30, "mm"),
...     journal_diameter=Q_(100, "mm"),
...     radial_clearance=Q_(0.1, "mm"),
...     oil_viscosity=0.1,
... )
>>> cylindrical.K(Q_(1500, "RPM"))
array([[ 12807959...,  16393593...],
       [-25060393...,   8815302...]])

Methods

C(frequency)#

Damping matrix for an instance of a bearing element.

This method returns the damping matrix for an instance of a bearing element.

Parameters:
frequencyfloat

The excitation frequency (rad/s).

Returns:
Cnp.ndarray

A 3x3 matrix of floats containing the cxx, cxy, cyx, cyy, and czz values (N*s/m).

Examples

>>> bearing = bearing_example()
>>> bearing.C(0)
array([[200.,   0.,   0.],
       [  0., 150.,   0.],
       [  0.,   0.,  50.]])
G()#

Gyroscopic matrix for an instance of a bearing element.

This method returns the mass matrix for an instance of a bearing element.

Returns:
Gnp.ndarray

A 3x3 matrix of floats.

Examples

>>> bearing = bearing_example()
>>> bearing.G()
array([[0., 0., 0.],
       [0., 0., 0.],
       [0., 0., 0.]])
K(frequency)#

Stiffness matrix for an instance of a bearing element.

This method returns the stiffness matrix for an instance of a bearing element.

Parameters:
frequencyfloat

The excitation frequency (rad/s).

Returns:
Knp.ndarray

A 3x3 matrix of floats containing the kxx, kxy, kyx, kyy and kzz values (N/m).

Examples

>>> bearing = bearing_example()
>>> bearing.K(0)
array([[1000000.,       0.,       0.],
       [      0.,  800000.,       0.],
       [      0.,       0.,  100000.]])
M(frequency)#

Mass matrix for an instance of a bearing element.

This method returns the mass matrix for an instance of a bearing element.

Parameters:
frequencyfloat

The excitation frequency (rad/s).

Returns:
Mnp.ndarray

Mass matrix (kg).

Examples

>>> bearing = bearing_example()
>>> bearing.M(0)
array([[0., 0., 0.],
       [0., 0., 0.],
       [0., 0., 0.]])
__init__(n, speed=None, weight=None, bearing_length=None, journal_diameter=None, radial_clearance=None, oil_viscosity=None, tag=None, scale_factor=1, color='#355d7a', **kwargs)#
dof_local_index()#

Get the local index for a element specific degree of freedom.

Returns:
local_index: namedtupple

A named tuple containing the local index.

Examples

>>> # Example using BearingElement
>>> from ross.bearing_seal_element import bearing_example
>>> bearing = bearing_example()
>>> bearing.dof_local_index()
LocalIndex(x_0=0, y_0=1, z_0=2)
dof_mapping()#

Degrees of freedom mapping.

Returns a dictionary with a mapping between degree of freedom and its index.

Returns:
dof_mappingdict

A dictionary containing the degrees of freedom and their indexes.

Examples

The numbering of the degrees of freedom for each node.

Being the following their ordering for a node:

x_0 - horizontal translation y_0 - vertical translation z_0 - axial translation

>>> bearing = bearing_example()
>>> bearing.dof_mapping()
{'x_0': 0, 'y_0': 1, 'z_0': 2}
format_table(frequency=None, coefficients=None, frequency_units='rad/s', stiffness_units='N/m', damping_units='N*s/m', mass_units='kg')#

Return frequency vs coefficients in table format.

Parameters:
frequencyarray, pint.Quantity, optional

Array with frequencies (rad/s). Default is 5 values from min to max frequency.

coefficientslist, str, optional

List or str with the coefficients to include. Defaults is a list of stiffness and damping coefficients.

frequency_unitsstr, optional

Frequency units. Default is rad/s.

stiffness_unitsstr, optional

Stiffness units. Default is N/m.

damping_unitsstr, optional

Damping units. Default is N*s/m.

mass_unitsstr, optional

Mass units. Default is kg.

Returns:
tablePrettyTable object

Table object with bearing coefficients to be printed.

classmethod from_table(n, file, sheet_name=0, tag=None, n_link=None, scale_factor=1, color='#355d7a')#

Instantiate a bearing using inputs from an Excel table.

A header with the names of the columns is required. These names should match the names expected by the routine (usually the names of the parameters, but also similar ones). The program will read every row bellow the header until they end or it reaches a NaN.

Parameters:
nint

The node in which the bearing will be located in the rotor.

filestr

Path to the file containing the bearing parameters.

sheet_nameint or str, optional

Position of the sheet in the file (starting from 0) or its name. If none is passed, it is assumed to be the first sheet in the file.

tagstr, optional

A tag to name the element. Default is None.

n_linkint, optional

Node to which the bearing will connect. If None the bearing is connected to ground. Default is None.

scale_factorfloat, optional

The scale factor is used to scale the bearing drawing. Default is 1.

colorstr, optional

A color to be used when the element is represented. Default is ‘#355d7a’ (Cardinal).

Returns:
bearingrs.BearingElement

A bearing object.

Examples

>>> import os
>>> file_path = os.path.dirname(os.path.realpath(__file__)) + '/tests/data/bearing_seal_si.xls'
>>> BearingElement.from_table(0, file_path, n_link=1)
BearingElement(n=0, n_link=1,
 kxx=[1.379...
get_class_name_prefix(index=None)#

Extract prefix of the class name preceding ‘Element’, insert spaces before uppercase letters, and append an index number at the end.

Parameters:
indexint, optional

The index number to append at the end of the resulting string. Default is None.

Returns:
prefixstr

The processed class name prefix.

Examples

>>> # Example using BearingElement
>>> from ross.bearing_seal_element import bearing_example
>>> bearing = bearing_example()
>>> bearing.get_class_name_prefix()
'Bearing'
classmethod get_subclasses()#
classmethod load(file)#
plot(coefficients=None, frequency_units='rad/s', stiffness_units='N/m', damping_units='N*s/m', mass_units='kg', fig=None, **kwargs)#

Plot coefficient vs frequency.

Parameters:
coefficientslist, str

List or str with the coefficients to plot.

frequency_unitsstr, optional

Frequency units. Default is rad/s.

stiffness_unitsstr, optional

Stiffness units. Default is N/m.

damping_unitsstr, optional

Damping units. Default is N*s/m.

mass_unitsstr, optional

Mass units. Default is kg.

**kwargsoptional

Additional key word arguments can be passed to change the plot layout only (e.g. width=1000, height=800, …). *See Plotly Python Figure Reference for more information.

Returns:
figPlotly graph_objects.Figure()

The figure object with the plot.

classmethod read_toml_data(data)#

Read and parse data stored in a .toml or .json file.

Overrides the base Element method to pass extra saved keys (e.g. pre-computed coefficients) as kwargs to the constructor. This allows subclasses to skip expensive computation when coefficients are already available from a saved file.

Parameters:
datadict

Dictionary obtained from toml.load() or json.load().

Returns:
The element object.
save(file)#

Save the element in a .toml or .json file.

This function will save the element to a .toml or .json file. The file will have all the argument’s names and values that are needed to reinstantiate the element.

Parameters:
filestr, pathlib.Path

The name of the file the element will be saved in. The format is determined by the file extension (.toml or .json).

Examples

>>> # Example using DiskElement
>>> from tempfile import tempdir
>>> from pathlib import Path
>>> from ross.disk_element import disk_example
>>> # create path for a temporary file
>>> file = Path(tempdir) / 'disk.toml'
>>> disk = disk_example()
>>> disk.save(file)
summary()#

Present a summary for the element.

A pandas series with the element properties as variables.

Returns:
A pandas series.

Examples

>>> # Example using DiskElement
>>> from ross.disk_element import disk_example
>>> disk = disk_example()
>>> disk.summary()
n                             0
n_l                           0
n_r                           0...
classmethod table_to_toml(n, file)#

Convert bearing parameters to toml.

Convert a table with parameters of a bearing element to a dictionary ready to save to a toml file that can be later loaded by ross.

Parameters:
nint

The node in which the bearing will be located in the rotor.

filestr

Path to the file containing the bearing parameters.

Returns:
datadict

A dict that is ready to save to toml and readable by ross.

Examples

>>> import os
>>> file_path = os.path.dirname(os.path.realpath(__file__)) + '/tests/data/bearing_seal_si.xls'
>>> BearingElement.table_to_toml(0, file_path)
{'n': 0, 'kxx': array([...
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