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ASTM D7685-11(2022)

(Practice)

Standard Practice for In-Line, Full Flow, Inductive Sensor for Ferromagnetic and Non-ferromagnetic Wear Debris Determination and Diagnostics for Aero-Derivative and Aircraft Gas Turbine Engine Bearings

Standard Practice for In-Line, Full Flow, Inductive Sensor for Ferromagnetic and Non-ferromagnetic Wear Debris Determination and Diagnostics for Aero-Derivative and Aircraft Gas Turbine Engine Bearings

SIGNIFICANCE AND USE
4.1 This practice is intended for the application of in-line, full-flow inductive wear debris sensors. According to (1), passing the entire lubrication oil flow for aircraft and aero-derivative gas turbines through a debris-monitoring device is a preferred approach to ensure sufficient detection efficiency.  
4.2 Periodic sampling and analysis of lubricants have long been used as a means to determine overall machinery health (2). The implementation of smaller oil filter pore sizes for machinery operating at higher rotational speeds and energies has reduced the effectiveness of sampled oil analysis for determining abnormal wear prior to severe damage. In addition, sampled oil analysis for equipment that is remote or otherwise difficult to monitor or access is not practical. For these machinery systems, in-line wear debris sensors can be very useful to provide real-time and near-real-time condition monitoring data.  
4.3 In-line full-flow inductive debris sensors have demonstrated the capability to detect and quantify both ferromagnetic and non-ferromagnetic metallic wear debris. These sensors record metallic wear debris according to size, count, and type (ferromagnetic or non-ferromagnetic). Sensors are available for a variety of oil pipe sizes. The sensors are designed specifically for the protection of rolling element bearings and gears in critical machine applications. Bearings are key elements in machines since their failure often leads to significant secondary damage that can adversely affect safety, operational availability, or operational/maintenance costs, or a combination thereof.  
4.4 The main advantage of the sensor is the ability to detect early bearing damage and to quantify the severity of damage and rate of progression of failure towards some predefined bearing surface fatigue damage limiting wear scar. Sensor capabilities are summarized as follows:  
4.4.1 In-line full flow non-intrusive inductive metal detector with no moving parts.  
4.4.2 Det...
SCOPE
1.1 This practice covers the minimum requirements for an in-line, non-intrusive, through-flow oil debris monitoring system that monitors ferromagnetic and non-ferromagnetic metallic wear debris from both industrial aero-derivative and aircraft gas turbine engine bearings. Gas turbine engines are rotating machines fitted with high-speed ball and roller bearings that can be the cause of failure modes with high secondary damage potential.  (1)2  
1.2 Metallic wear debris considered in this practice range in size from 120 μm (micron) and greater. Metallic wear debris over 1000 μm are sized as over 1000 μm.  
1.3 This practice is suitable for use with the following lubricants: polyol esters, phosphate esters, petroleum industrial gear oils and petroleum crankcase oils.  
1.4 This practice is for metallic wear debris detection, not cleanliness.  
1.5 The values stated in SI units are to be regarded as standard. The values given in parentheses are provided for information only.  
1.6 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.7 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

General Information

Status
Published
Publication Date
31-Mar-2022
ICS
49.050 - Aerospace engines and propulsion systems
Technical Committee
D02 - Petroleum Products, Liquid Fuels, and Lubricants
Drafting Committee
D02.96.07 - Integrated Testers, Instrumentation Techniques for In-Service Lubricants
Current Stage
Ref Project

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ASTM D7685-11(2022) - Standard Practice for In-Line, Full Flow, Inductive Sensor for Ferromagnetic and Non-ferromagnetic Wear Debris Determination and Diagnostics for Aero-Derivative and Aircraft Gas Turbine Engine BearingsASTM D7685-11(2022) - Standard Practice for In-Line, Full Flow, Inductive Sensor for Ferromagnetic and Non-ferromagnetic Wear Debris Determination and Diagnostics for Aero-Derivative and Aircraft Gas Turbine Engine Bearings
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ASTM D7685-11(2022) - Standard Practice for In-Line, Full Flow, Inductive Sensor for Ferromagnetic and Non-ferromagnetic Wear Debris Determination and Diagnostics for Aero-Derivative and Aircraft Gas Turbine Engine Bearings
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This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the
Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.
Designation: D7685 − 11 (Reapproved 2022)
Standard Practice for
In-Line, Full Flow, Inductive Sensor for Ferromagnetic and
Non-ferromagnetic Wear Debris Determination and
Diagnostics for Aero-Derivative and Aircraft Gas Turbine
Engine Bearings
This standard is issued under the fixed designation D7685; the number immediately following the designation indicates the year of
original adoption or, in the case of revision, the year of last revision. A number in parentheses indicates the year of last reapproval. A
superscript epsilon (´) indicates an editorial change since the last revision or reapproval.
INTRODUCTION
In-line wear debris sensors have been in operation since the early 1990s. There are now thousands
ofthesedevicesoperatinginawidevarietyofmachineryapplicationsaccruingmillionsofoperational
hours. Wear debris sensors provide early warning for the abnormal conditions that lead to failure.
Improved machine reliability is possible due to the enhanced sensor data granularity, which provides
better diagnostics and prognostics of tribological problems from the initiating event through failure.
1. Scope 1.6 This standard does not purport to address all of the
safety concerns, if any, associated with its use. It is the
1.1 This practice covers the minimum requirements for an
responsibility of the user of this standard to establish appro-
in-line, non-intrusive, through-flow oil debris monitoring sys-
priate safety, health, and environmental practices and deter-
tem that monitors ferromagnetic and non-ferromagnetic metal-
mine the applicability of regulatory limitations prior to use.
lic wear debris from both industrial aero-derivative and aircraft
1.7 This international standard was developed in accor-
gas turbine engine bearings. Gas turbine engines are rotating
dance with internationally recognized principles on standard-
machines fitted with high-speed ball and roller bearings that
ization established in the Decision on Principles for the
can be the cause of failure modes with high secondary damage
Development of International Standards, Guides and Recom-
potential. (1)
mendations issued by the World Trade Organization Technical
1.2 Metallic wear debris considered in this practice range in
Barriers to Trade (TBT) Committee.
size from 120 µm (micron) and greater. Metallic wear debris
2. Terminology
over 1000 µm are sized as over 1000 µm.
2.1 Definitions of Terms Specific to This Standard:
1.3 This practice is suitable for use with the following
2.1.1 condition monitoring, n—field of technical activity in
lubricants: polyol esters, phosphate esters, petroleum industrial
which selected physical parameters associated with an operat-
gear oils and petroleum crankcase oils.
ing machine are periodically or continuously sensed, measured
1.4 This practice is for metallic wear debris detection, not
and recorded for the interim purpose of reducing, analyzing,
cleanliness.
comparing and displaying the data and information so obtained
1.5 The values stated in SI units are to be regarded as
and for the ultimate purpose of using interim result to support
standard. The values given in parentheses are provided for
decisions related to the operation and maintenance of the
information only.
machine. (2)
2.1.2 control unit, n—electronic controller assembly, which
This practice is under the jurisdiction ofASTM Committee D02 on Petroleum processes the raw signal from the sensor and extracts informa-
Products, Liquid Fuels, and Lubricants and is the direct responsibility of Subcom-
tion about the size and type of the metallic debris detected.
mittee D02.96.07 on Integrated Testers, Instrumentation Techniques for In-Service
2.1.2.1 Discussion—A computer(s), accessories, and data
Lubricants.
link equipment that an operator uses to control, communicate
Current edition approved April 1, 2022. Published May 2022. Originally
approved in 2011. Last previous edition approved in 2016 as D7685 – 11 (2016).
and receive data and information.
DOI: 10.1520/D7685-11R22.
2 2.1.3 full flow sensor, n—monitoring device that installs
The boldface numbers in parentheses refer to a list of references at the end of
this standard. in-line with the lubrication system and is capable of allowing
Copyright © ASTM International, 100 Barr Harbor Drive, PO Box C700, West Conshohocken, PA 19428-2959. United States
D7685 − 11 (2022)
thefullflowofthelubricationfluidtotravelthroughthesensor.
Also referred to as a through-flow sensor.
2.1.4 inductive debris sensor, n—device that creates an
electromagnetic field as a medium to permit the detection and
measurement of metallic wear debris via permeability for
ferromagnetic debris and eddy current effects for non-
ferromagnetic debris.
2.1.4.1 Discussion—A device that detects metallic wear
debris that cause fluctuations of the magnetic field. A device
that generates a signal proportional to the size and presence of
metallic wear debris with respect to time.
2.1.5 machinery health, n—qualitative expression of the
operational status of a machine sub-component, component or
entire machine, used to communicate maintenance and opera-
FIG. 1 Wear Debris Characterization
tional recommendations or requirements in order to continue
operation, schedule maintenance or take immediate mainte-
nance action.
specifically for the protection of rolling element bearings and
2.1.6 metallic wear debris, n—in tribology, metallic par-
gears in critical machine applications. Bearings are key ele-
ticles that have become detached in a wear or erosion process. ments in machines since their failure often leads to significant
secondary damage that can adversely affect safety, operational
2.1.7 sensor cable, n—specialized cable that connects the
availability,oroperational/maintenancecosts,oracombination
sensor output to the electronic control module.
thereof.
2.1.8 trend analysis, n—monitoring of the level and rate of
4.4 The main advantage of the sensor is the ability to detect
change over operating time of measured parameters.
early bearing damage and to quantify the severity of damage
3. Summary of Practice
and rate of progression of failure towards some predefined
bearing surface fatigue damage limiting wear scar. Sensor
3.1 A full flow sensor is fitted in the oil line to detect
capabilities are summarized as follows:
metallic wear debris. The system counts wear debris, sizes
4.4.1 In-linefullflownon-intrusiveinductivemetaldetector
debris, and calculates debris mass estimates as a function of
with no moving parts.
time. This diagnostic information is then used to assess
4.4.2 Detects both ferromagnetic and non-ferromagnetic
machine health relative to cumulative debris count, or esti-
metallic wear debris.
mated cumulative debris mass warning and alarm limits, or a
4.4.3 Detects 95 % or more of metallic wear debris above
combination thereof. From this information, estimates of
some minimum particle size threshold.
remaining useful life of the machine can also be made.
4.4.4 Counts and sizes wear debris detected.
4. Significance and Use
4.5 Fig.1presentsawidelyuseddiagram (2)todescribethe
4.1 This practice is intended for the application of in-line,
progress of metallic wear debris release from normal to
full-flow inductive wear debris sensors. According to (1),
catastrophic failure. It must be pointed out that this figure
passing the entire lubrication oil flow for aircraft and aero-
summarizes metallic wear debris observations from all the
derivative gas turbines through a debris-monitoring device is a
different wear modes that can range from polishing, rubbing,
preferred approach to ensure sufficient detection efficiency.
abrasion, adhesion, grinding, scoring, pitting, spalling, etc. As
4.2 Periodic sampling and analysis of lubricants have long mentioned in numerous references (1-11), the predominant
been used as a means to determine overall machinery health failure mode of rolling element bearings is spalling or macro
pitting.Whenabearingspalls,thecontactstressesincreaseand
(2). The implementation of smaller oil filter pore sizes for
machinery operating at higher rotational speeds and energies cause more fatigue cracks to form within the bearing subsur-
face material. The propagation of existing subsurface cracks
has reduced the effectiveness of sampled oil analysis for
determining abnormal wear prior to severe damage. In and creation of new subsurface cracks causes ongoing deterio-
addition, sampled oil analysis for equipment that is remote or ration of the material that causes it to become a roughened
otherwise difficult to monitor or access is not practical. For contact surface as illustrated in Fig. 2. This deterioration
these machinery systems, in-line wear debris sensors can be process produces large numbers of metallic wear debris with a
very useful to provide real-time and near-real-time condition typical size range from 100 to 1000 microns or greater. Thus,
monitoring data. rotating machines, such as gas turbines and transmissions,
which contain rolling element bearings and gears made from
4.3 In-line full-flow inductive debris sensors have demon-
hard steel tend to produce this kind of large metallic wear
strated the capability to detect and quantify both ferromagnetic
debris that eventually leads to failure of the machines.
and non-ferromagnetic metallic wear debris. These sensors
record metallic wear debris according to size, count, and type 4.6 In-line wear debris monitoring provides a more reliable
(ferromagnetic or non-ferromagnetic). Sensors are available and timely indication of bearing distress for a number of
for a variety of oil pipe sizes. The sensors are designed reasons:
D7685 − 11 (2022)
FIG. 3 Sensor Major Components (3)
debrisbysizeandtype.Themagneticcoilassemblyconsistsof
three coils that surround a magnetically and electrically inert
section of tubing. The two outside field coils are driven by a
high frequency alternating current source such that their
respective fields are nominally opposed or cancel each other at
a point inside the tube at the center sensor coil. Signal
conditioning electronics process the raw signal from the sensor
and extract information about the size and type of the metallic
FIG. 2 Typical Bearing Spall
debris detected. The sensor electronics perform several func-
tions including: data processing, communication control, and
Built-In-Test (BIT). Ferromagnetic and non-ferromagnetic
4.6.1 Firstly, bearing failures on rotating machines tend to
wear debris counts are binned according to size. Signal
occur as events often without sufficient warning and could be
conditioning using a threshold algorithm is used to categorize
missed by means of only periodic inspections or data sampling
the metallic wear debris that pass through the sensor on the
observations.
basis of size. Several size categories can be configured which
4.6.2 Secondly, since it is the larger wear metallic debris
allow the tracking of the distribution of debris.
that are being detected, there is a lower probability of false
6.2 Principle of Operation—The sensor operates by moni-
indicationfromthenormalrubbingwearthatwillbeassociated
toring the disturbance to the alternating magnetic field caused
with smaller particles.
by the passage of a metallic wear debris particle through the
4.6.3 Thirdly, build or residual debris from manufacturing
magnetic coil assembly as shown in Fig. 4 (12). The particle
or maintenance actions can be differentiated from actual
couples with the magnetic field to varying degrees as it
damage debris because the cumulative debris counts recorded
traverses the sensing region, resulting in a characteristic output
due to the former tend to decrease while those due to the latter
signature. The magnitude of the disturbance measured as a
tend to increase.
voltage defines the size of the metallic wear debris and the
4.6.4 Fourthly, bearing failure tests have shown that wear
phase shift of the signal defines whether the wear debris is
debris size distribution is independent of bearing size. (2-5)
ferromagnetic or non-ferromagnetic. When a ferromagnetic
and (11).
particle passes by each field coil, it strengthens the magnetic
5. Interferences
field of that coil due to the high magnetic permeability of the
particle relative to the surrounding fluid (oil). This disrupts the
5.1 Wear debris counts may be invalid due to excessive
balance of the fields seen by the sense coil, resulting in a
noise from environmental influences. See 7.4.
characteristic signal being generated as the particle passes
6. Apparatus through the entire sensing region of the sensor. The signal
3 looks much like one period of a sine wave where the amplitude
6.1 Sensor —Asensorsystemisidentifiedthatisathrough-
of the signal is proportional to the apparent size of the particle
flow device that installs in-line with the lubrication oil system.
and the period of the signal is inversely proportional to the
The subsections in this section provide examples for a certain
speed at which the particle passes through the sensor. For a
type of inductive debris sensor system. The sensor has no
ferromagnetic particle, the size, shape, and orientation of the
moving components.As seen in Fig. 3, the sensor incorporates
particle and the magnetic susceptibility of the material deter-
a magnetic coil assembly and signal conditioning electronics
mine the magnitude of the signal. When a non-ferromagnetic
that are capable of detecting and categorizing metallic wear
(conductive) particle passes by each field coil, the principle is
similar except that the presence of the particle in the magnetic
The sole source of supply of the apparatus known to the committee at this time
fieldweakensthefieldduetotheeddycurrentsgeneratedinthe
is GasTOPS, Ltd., Polytek St., Ottawa, Ontario K1J 9J3, Canada. If you are aware
particle.Thisresultsinadifferenceinthesignalphaseallowing
of alternative suppliers, please provide this information to ASTM International
the processing electronics to differentiate between ferromag-
Headquarters.Your comments will receive careful consideration at a meeting of the
responsible technical committee, which you may attend. netic and non-ferromagnetic particles passing through the
D7685 − 11 (2022)
FIG. 4 Principle of Operation (12)
sensor. For a non-ferromagnetic particle, the surface area and Through field experience and laboratory testing it is known
orientation of the particle and the conductivity of the material, that ferromagnetic flake shaped particles, on average, produce
determine the magnitude of th
...

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1.1 This specification covers minimum requirements for the design and integration of Fuel Storage and Delivery system installations for aeroplanes.  
1.2 This specification is applicable to aeroplanes as defined in the F44 terminology standard.  
1.3 The applicant for a design approval must seek the individual guidance to their respective CAA body concerning the use of this standard as part of a certification plan. For information on which CAA regulatory bodies have accepted this standard (in whole or in part) as a means of compliance to their Aeroplane Airworthiness regulations (Hereinafter referred to as “the Rules”), refer to ASTM F44 webpage (www.ASTM.org/COMITTEE/F44.htm), which includes CAA website links. Annex A1 maps the Means of Compliance described in this specification to EASA CS-23, amendment 5, or later, and FAA 14 CFR Part 23, amendment 64, or later.  
1.4 Units—The values stated are SI units followed by imperial units in brackets. The values stated in each system are not necessarily exact equivalents; therefore, to ensure conformance with the standard, each system shall be used independently of the other, and values from the two systems shall not be combined.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM F3338-21(Specification)
Standard Specification for Design of Electric Engines for General Aviation Aircraft

SCOPE
1.1 This specification covers minimum requirements for the design of electric engines.  
1.2 Distributed propulsion is not excluded; however, additional requirements will be needed to address the additional issues that distributed propulsion can create. Some of those issues may include: use of a common motor controller/inverter, segregated electric harnesses, cooling systems, electric power supplies, and others.  
1.3 This specification does not address all of the requirements that may be necessary for possible hybrid configurations where an electric engine and a combustion engine drive a common thruster. This specification may be used for the electric engine aspects with supplemental requirements for the thruster and the combustion engine.  
1.4 Although this specification does not include specific requirements for electric engines that include gearboxes, thrusters, or any energy storage systems, it also does not preclude such capabilities. This specification may be used for the base electric engine aspects of the design, with supplemental requirements for any additional features prepared by the manufacturer and submitted to the Civil Airworthiness Authority for acceptance. This version of this ASTM specification also does not address all of the requirements necessary for configurations of motor driven ducted-fans. It is anticipated that the fan would be subject to parts of 14 CFR 33 or CS-E and/or 14 CFR 35 or CS-P, or equivalent, in particular blade-off and bird strike. These would be conducted on the fan as a unit (including motor) rather than on motor or fan alone.  
1.5 The applicant for a design approval should seek the individual guidance of their respective civil aviation authority (CAA) body concerning the use of this specification as part of a certification plan. For information on which CAA regulatory bodies have accepted this specification (in whole or in part) as a means of compliance to their general aviation aircraft airworthiness regulations (hereinafter referred to as “the Rules”), refer to ASTM Committee F39 webpage (www.ASTM.org/COMITTEE/F39.htm), which includes CAA website links.  
1.6 When applicable, this specification may be used for electric engines with a fixed-pitch propeller or fan. These configurations may be type-certificated as an electric engine including a thruster. There may be additional requirements not currently included in this specification for this type configuration. In addition, 5.25 is included as a test requirement for the electric engine. That section recognizes that when the electric engine does not have an integral thruster it will need to be tested with a representative load on the drive shaft to ensure the engine’s ability to operate properly with static and dynamic loads.  
1.7 The values stated in inch-pound units are to be regarded as standard. The values given in parentheses are mathematical conversions to SI units that are provided for information only and are not considered standard.  
1.8 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.9 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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ASTM
ASTM F3065/F3065M-21a(Specification)
Standard Specification for Aircraft Propeller System Installation

ABSTRACT
This specification covers airworthiness requirements for the installation and integration of propeller systems, and is applicable to aeroplanes as defined in F44 terminology standard. The applicant for a design approval must seek the individual guidance to their respective civil aviation authority (CAA) body concerning the use of this specification as part of a certification plan.
The requirements prescribed in this specification cover: propeller installation aspects (general propeller, feathering propellers, variable-pitch propellers, pusher propeller installation, propeller clearance), structural aspects (propeller vibration and fatigue), propeller control limitations (propeller speed and pitch limits, propeller reversing systems), and associated propeller systems (oil system-propeller feathering systems, turbopropeller-drag limiting systems).
SCOPE
1.1 This specification addresses the airworthiness requirements for the installation and integration of propeller systems.  
1.2 This specification is applicable to aeroplanes as defined in F44 terminology standard.  
1.3 The applicant for a design approval must seek the individual guidance to their respective CAA body concerning the use of this standard as part of a certification plan. For information on which CAA regulatory bodies have accepted this standard (in whole or in part) as a means of compliance to their Small Aircraft Airworthiness regulations (Hereinafter referred to as “the Rules”), refer to ASTM F44 webpage (www.ASTM.org/COMITTEE/F44.htm) which includes CAA website links. Annex A1 maps the Means of Compliance described in this specification to EASA CS-23, amendment 5, or later, and FAA 14 CFR Part 23, amendment 64, or later.  
1.4 Units—The values stated are SI units followed by Imperial units in square brackets. The values stated in each system are not necessarily exact equivalents; therefore, to ensure conformance with the standard, each system shall be used independently of the other, and values from the two systems shall not be combined.  
1.5 This standard does not purport to address all of the safety concerns, if any, associated with its use. It is the responsibility of the user of this standard to establish appropriate safety, health, and environmental practices and determine the applicability of regulatory limitations prior to use.  
1.6 This international standard was developed in accordance with internationally recognized principles on standardization established in the Decision on Principles for the Development of International Standards, Guides and Recommendations issued by the World Trade Organization Technical Barriers to Trade (TBT) Committee.

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