Classifications

• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
  • G01N27/00—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
  • G01N27/60—Investigating or analysing materials by the use of electric, electrochemical, or magnetic means by investigating electrostatic variables, e.g. electrographic flaw testing
• • G—PHYSICS
  • G01—MEASURING; TESTING
  • G01N—INVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
  • G01N33/00—Investigating or analysing materials by specific methods not covered by groups G01N1/00 - G01N31/00
  • G01N33/26—Oils; Viscous liquids; Paints; Inks
  • G01N33/28—Oils, i.e. hydrocarbon liquids
  • G01N33/2888—Lubricating oil characteristics, e.g. deterioration

Definitions

• Invention relates to a triboelectrostatic sensor that enables the detection of the instantaneous state and remaining life of oils by using in the moving and stationary systems.
• the present invention relates to a triboelectrostatic sensor that can be mounted on moving and stationary systems, enables the detection of remaining life of oils by allowing monitoring of instantaneous state of the oils that were used or are in usage, thus with a clear determination of the time to change the oil, allows the user to notice any damage that may arise from the decrease in oil performance (lubricating property) in moving systems before they occur.
• oils decompose (degradate) by oxidizing as a result of heating and thus the properties of the oil change.
• reusage of the frying oils used in the kitchens and heating them continuously although they should be renewed causes serious health problems by causing free radicals to be formed by oxidizing of the oil.
• Physical and chemical oil analyzes providing information about conditions of the oils are performed in the laboratory environment with the oil samples taken from moving or stationary systems. These methods require expensive devices and systems such as spectroscopy and chromatography as well as being very time consuming.
• Tan Delta System company has developed a sensor that can measure water contamination and oil oxidation in oils.
• Electrochemical and Solid-State Letters by S. Moon et al. it is mentioned a sensor that is based on the correlation between the changes in the electrical conductivity of oils and the oil oxidation and total acid number.
• FTIR Fourier Transform Infrared Spectroscopy
• the triboelectrostatic sensor which is the subject of the present patent application, is a very different system in the terms of both its working principle and its dynamic structure.
• the triboelectrostatic sensor has a dynamic structure and self-cleaning feature. The residue accumulation in the static systems that have been built or proposed so far and problems that may occur as a result of this accumulation, are prevented. In addition, it does not require an external energy source for the measurement of the information on oils because triboelectricity provides this automatically due to the sensor dynamic structure.
• the require for a solution that enables monitoring of the instantaneous state of the oil by allowing the state of the oil to be monitored on-site in moving and stationary systems thus saves oil by eliminating unnecessary renewal of oil and, prevents material damages that may occur by ensuring the user to be informed of the sudden changes that may occur in the oil, caused the present innovative solution to emerge out.
• Aim of the invention is to present a triboelectrostatic sensor that enables monitoring of the instantaneous state of the oil by allowing the state of the oil to be monitored on-site in moving and stationary systems, thus saves oil by eliminating unnecessary renewal of oil and, prevents material damages that may occur by ensuring the user to be informed of the sudden changes that may occur in the oil.
• Another aim of the invention is to ensure that oil analysis which has not become widespread until now and can be made in laboratory environments or on-site can be monitored instantaneously thanks to the present innovative sensor which can be used by mounting on moving and stationary systems where oils are used.
• Another aim of the invention is to provide fast and precise information about the current state of the engine oil.
• Another aim of the invention is to prevent oil change in unnecessary situations by making an accurate determination about the oil change times, thus gaining economic and environmental benefits.
• Another aim of the invention is to ensure that any damage that may occur due to the loss of lubrication feature in a moving system is detected and prevented before it occurs by allowing the understanding of the time to change the oil.
• Another aim of the invention is to allow the usage of the present innovative product to be widespread thanks to that it is made from the materials which are easily available and low in cost.
• Invention is a triboelectrostatic sensor that enables monitoring of the instantaneous state of the oil by allowing the state of the oil to be monitored on-site in moving and stationary systems, thus saves oil by eliminating unnecessary renewal of oil, prevents material damages that may occur by ensuring the user to be informed of the sudden changes that may occur in the oil and, comprises the following components
• a motion generator providing the movement of said electrode
• At least one dielectric material or insulating material that is electrified by touch or friction at least one measuring instrument enabling to measure the triboelectricity formed
• any electric motor, hydraulic motor, pneumatic motor, solenoid actuator electromagnet that provides forward-backward or rotating motion, parts that are currently in the moving system and moves at a certain frequency and etc. can be used as a motion generator.
• Invention is a lifetime detection method that enables monitoring of the instantaneous state of the oil by allowing the state of the oil to be monitored on-site in moving and stationary systems, thus saves oil by eliminating unnecessary renewal of oil, prevents material damages that may occur by ensuring the user to be informed of the sudden changes that may occur in the oil and, comprises the following steps: occurring electrification on the surfaces during successive leaving-touching, friction or both leaving-touching and friction events, generating electric potential and electric current by inducing the metal electrode (10) as a result of this electrification, transmitting the generated electrical signals to the measuring instrument (50) via conductive wires (51), determining how much oil (41) in usage has oxidized as of moment of measurement or how long it can continue to be used by placing the generated friction and touching signals to the previously prepared time-based oxidation-electrification calibration graphs or their equations.
• Figure 9a view of a configuration of the invention, which is based on the principle of measuring the triboelectric load (charge) created on the inner wall of the tube by the flowing oil via electrodes surrounding the outer part of the tube with certain intervals is given.
• the invention presents a triboelectrostatic sensor (1) that enables monitoring of the instantaneous state of the oil (41) by allowing the state of the oil (41) to be monitored on-site in moving and stationary systems, thus saves oil (41) by eliminating unnecessary renewal of oil (41) and, prevents material damages that may occur by ensuring the user to be informed of the sudden changes that may occur in the oil (41).
• triboelectrification static electrification, contact (touch) electrification
• the surfaces must physically touch each other then leave from each other, or rub with each other.
• the amount of the surface electric potential or charge obtained as a result of triboelectrification depends on the properties of the material and especially the ambient conditions (for example; depends on humidity of the air when the ambient is air).
• the triboelectrification is carried out in the oil (41) environment.
• the degradation of oils (41) used in moving or stationary systems by oxidizing under high temperature and pressure changes the chemical and physical structure of the oil (41) environment.
• the magnitude of the obtained triboelectrification signal is directly affected by the change in the physical (viscosity) and chemical (oxidation, contamination, reduction of additive) properties of the oils (41).
• Oils (41) oxidize as they are used. Oils (41) become more polar with the oxidation reaction and as a result of this, the dielectric permeability of the oil (41) increases.
• Electrification of the contacting surfaces within the oil (41) environment is inversely proportional to the dielectric permeability of the oil (41).
• the dielectric permeability of the medium is determinant for both the amplitude (peak) values of the electrification signals and the decay (damping) time of the electrical charges accumulated on an electrified surface. In an environment with high dielectric permeability, damping of the surface charges is faster.
• the dielectric permeability of the medium is effective in both the electrification peak value and the damping of the electrical charges accumulated on an electrified surface over time. In an environment with high dielectric permeability, damping of the surface charges is faster.
• the electrification signals gradually begin to decrease with the usage of the oil. Based on the measurement made, a correlation was established between the lifetime of the oil (41) and the generated electrification signals.
• the present innovative triboelectrostatic sensor (1) which is developed by using this feature, enables these changes to be tracked as an electrical signal with a portable device and remaining lifetime of the oil (41) to be determined.
• the invention includes components that provide mechanical touching/leaving or friction movement and, units that measure/display electrical signals via electrical connections.
• the innovative triboelectrostatic sensor (1) comprises at least one electrode (10), a motion generator providing the movement of said electrode (10), at least one dielectric material (20) or insulating material that is electrified by touch or friction, at least one measuring instrument (50) enabling to measure the triboelectricity formed.
• Measurements are made by placing the present invention within any oil reservoir (40) containing oil (41). It is possible to provide the movement of the electrode (10) with any type motor (30) such as electric motor, hydraulic motor, pneumatic motor etc.
• the connection between the motor (30) and electrode (10) can be provided by means of a shaft (31) or, also by means of connection elements such as compressed air hoses etc. depending on the type of motor (30) used.
• motor (30) providing forward and backward movement (reciprocating motion), as well as to use the motor (30) providing rotational movement in a preferred embodiments of the invention.
• Triboelectrification signals obtained from touching-leaving or friction events can be measured by means of measuring instruments (59) such as voltmeter, ampermeter, coulomb etc. via conductive wire or probe-like conductive wires (51).
• the compressed air is turned on and off by means of a valve by using Manual or electrical switching and, the arm of the pneumatic motor (30) is moved forth and back thanks to this on-off. Thanks to this forward and backward movement, touching and leaving occur between surfaces and as a result of this, electrification signals occur.
• this reciprocating motion forward and backward movement
• touching-leaving or friction electrification signal can be generated by providing forward and backward movement with a force taken from the parts that are currently in the moving system and moves at a certain frequency.
• the present innovative triboelectric sensor (1) can operate without the need of an external power source except for providing mechanical touching-leaving or friction events. Based on the correlation established between the lifetime of the oil (41) and the magnitude of the electrification signal, electrical data which is obtained as a result of touching-leaving or friction events provided by using different materials, allows the instant condition of the oil (41) to be monitored and the remaining lifetime of oil (41) to be determined.
• Different electrode (10) connection and different surface contact modes are available for the face to face contact based design.
• These different modes used in the present innovative triboeelectrostatic sensor (1) can single electrode (10) mode, double electrode (10) mode, multiple electrode (10) mode depending on the electrode (10) connection.
• the surfaces in contact with each other within the oil (41) can be insulator, conductor, semiconductor (dielectric) and combinations of them. Triboelectric signals giving the highest signal to noise ratio among the material pairs touched each other within the oil (41) are obtained by the contact of an insulating material and a conductive material to each other.
• the present invention is not limited with the following exemplary configurations, material pairs/groups and geometries. Also, material selection for the sensor is made according to the application. In the places where high temperatures are required, heat resistant polymer, other dielectric materials (20) or semiconducting materials can be used.
• FIG. 1a shows the leaving state of the parts producing electrification
• Figure 1 b shows the touching state of the parts producing electrification.
• one of the surfaces touching each other is dielectric material (20) and, the electrification signal is received from the conductive material contacting with the dielectric material (20) or from an electrode (10) contacting with the dielectric material (20).
• Said electrode (10) is positioned at the end of a shaft (31) connected to a motor (30) that provides reciprocating motion. There is no electrical connection between the shaft (31) and the electrode (10).
• Said dielectric material (20) is located on the other surface of the electrode (10).
• Other electrode (10) is grounded with a grounded base (60) to provide obtaining higher triboelectrification signals.
• electrification occurs on surfaces that touch each other thus, electric potential and electric current are generated by that this electrification induces the metal electrode (10).
• Mentioned touching and leaving operations are performed within an oil reservoir (40) filled with oil (41).
• the electrical signals generated as a result of these operations are transmitted to the measuring instrument (50) via conductive wires (51).
• the present innovative sensor generates both touching and leaving signals separately for each touching and leaving event.
• the generated signals can be measured as electric potential by an oscilloscope that can display and record precisely in volt units or measured as electric charge by means of a sensitive electrometer.
• the generated current can be measured with a current amplifier.
• ampermeter displaying current or voltmeter displaying potential can be used for displaying electrical signals, capturing data and recording data.
• Electrostatic signals showing the amount of current induced (accumulated charge or generated electric potential) to the electrodes (10) during leaving and touching event change over time according to the instantaneous conditions of the oils (41).
• the inner cylinder moves in a rotating manner within the oil (41).
• Outer cylinder contains materials which correspond to the electrode/electrodes (10) on the outer surface of the inner cylinder on its inner surface and can provide electrification when they touch each other.
• the inner cylinder makes its rotational movement within oil (41) inside the outer cylinder. Magnitude of electrification varies according to the usage state and instant condition of the oil (41).
• the inner cylindrical structure of the nested two cylindrical structures moves rotating manner within the oil (41) thanks to the electric motor (30). While the touching state of the single electrode (10) sample of said configuration is given in Figure 4a, its leaving state is given in Figure 4b. In Figure 4c, the touching state of the two-electrode (10) sample of said configuration is given.
• the both embodiments single electrode and multi electrode
• the materials of cylinders and contacting parts can be selected from conductive and insulating materials according to the application area. In its preferred embodiments, one of the contacting surfaces is flexible for providing magnitude of the electrification signals to be higher and lifetime of the sensor to be longer.
• the embodiments of the invention are not limited to the above. It emerges as a portable solution based on the principle of that the intensity of the generated electrification signal depends on the instant condition and usage state of the oils (41).
• the oil absorbed surface (42) is placed on an electrode (10) connected to the fixed base (61) and is held via the plastic holding apparatus (21).
• the electrification values of the oil (41) absorbed cellulose are placed into the previously prepared electrification and oxidation graph or the equation of the graphs and thus, the oxidation or remaining lifetime of the oil (41) is determined.
• the graph A is belong to the unused oil (41) sample.
• the graph B shows the signals received as a result of heating said oil (41) at 200 degrees Celsius for 30 minutes.
• the graph C shows the signals received as a result of heating said oil (41) at 200 degrees Celsius for 390 minutes.
• the graph D shows the signals received as a result of heating said oil (41) at 200 degrees Celsius for 13.5 hours.
• the graph E shows the signals received as a result of heating said oil (41) at 200 degrees Celsius for 20 hours.
• the magnitude of the electrification signals in the oil (41) that is oxidized with heat decreases as the heating time increases.
• Time-based electrification values and calibration graphs of the samples belonging to the same motor oil (41) oxidized at 200 and 150 degrees Celsius are given respectively in Figure 8a and Figure 8b.
• Figure 8c time-based electrification value and calibration graph of the sample of the another engine oil (41) oxidized at 150 degrees Celsius is given.
• the triboelectrostatic sensor (1) by inducing the electrostatic charge generated on the inner wall of the tube pipe (70) to the metal electrodes (10) that are placed at certain intervals on the tube’s outer or inner surface, the electrical signal generated between two electrodes (10) (or between electrode and ground connection) can be tracked (as electrical potential difference, current, electrostatic charge).
• the electrodes (10) surrounding the outer part of the tube pipe (70) sense the loads inside the tube pipe (70) thanks to the induction.
• the ground base (60) connection instead of the second electrode (10).
• the electrification formed within the flowing oil (41) is measured by the electrode (70) located in the tube pipe (70). Briefly here, by establishing a correlation between the oxidation occurred in the oil (41) over time and the electrical signal generated at the electrodes (10), the sensor based on the principle of flow electrification is formed. In addition, information about the instant condition of the oil (41) can be obtained by measuring the electrostatic charges accumulated within the oil (41) electrified due to the flow. Moreover, this embodiment of the invention provides ease of assembly and compatibility since it is in the cylindrical form (that is tube).
• the concentration of the ZDDP additive (the substance used for preventing oxidation) within oil (41) decreases. Thanks to the present innovative sensor, it is possible to determine the amount of ZDDP remaining within the aging oil (41) by comparing the triboelectric signals obtained from the aging and oxidized oils (41) with the data obtained from the previous calibration.

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• Chemical & Material Sciences (AREA)
• Health & Medical Sciences (AREA)
• Life Sciences & Earth Sciences (AREA)
• General Health & Medical Sciences (AREA)
• Immunology (AREA)
• Engineering & Computer Science (AREA)
• Analytical Chemistry (AREA)
• Biochemistry (AREA)
• Chemical Kinetics & Catalysis (AREA)
• General Physics & Mathematics (AREA)
• Physics & Mathematics (AREA)
• Pathology (AREA)
• Electrochemistry (AREA)
• General Chemical & Material Sciences (AREA)
• Oil, Petroleum & Natural Gas (AREA)
• Food Science & Technology (AREA)
• Medicinal Chemistry (AREA)
• Investigating Or Analyzing Materials By The Use Of Electric Means (AREA)
• Lubrication Details And Ventilation Of Internal Combustion Engines (AREA)

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• 2019
  • 2019-07-19 TR TR2019/10799A patent/TR201910799A2/tr unknown
• 2020
  • 2020-07-20 WO PCT/TR2020/050634 patent/WO2021015701A1/en unknown
  • 2020-07-20 EP EP20845093.2A patent/EP3999840A4/de not_active Withdrawn

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