The disclosure relates to novel lubricants for electric and hybrid vehicles, which include improved racing gear oils for efficiency and durability, and methods of using the same.
As the competition to develop electric vehicles (EVs) intensifies, there are new demands on drive system fluids (gear oils), coolants and greases. The increased demand is because, in large part, the fluids will now be in contact with electric parts and affected by electrical current and electromagnetic fields.
Moreover, the drive system fluids, used as a motor coolant, must be compatible with copper wires and electrical parts, special plastics, and insulation materials. Electric motors generate large quantities of heat and run at higher speeds to increase efficiency, which requires an improved gear oil that can lubricate gearboxes (transmissions) and axles, while removing the heat effectively from motor and gears. In addition, higher speeds from the motor need to be converted to drivable speeds in the drive system, which puts an increase load (torque) on the gears.
Therefore, the new technology demands a considerable change in lubricant specifications. The fully formed lubricants described herein can be used in single and multi-speed transmissions in EVs.
In one embodiment, a fully formed lubricant is formulated with a molybdenum dialkyldithiocarbamate (MoDTC) additive, specifically diisotridecylamine molybdate. The use of this formulation can aid the user in predicting the maximum applied load and the maximum operating temperature of the lubricant using color change technology. This formulation also improves the yellow metal protection, extreme pressure (EP) performance, and reduce component wear compared to a baseline lubricant formulated without the MoDTC additive. In other embodiments, the formulation may be used in drive systems in internal combustion (IC) engines, hybrid and electric vehicles, and industrial equipment (e.g. stationary engines, fracking pumps, wind turbines).
In one embodiment, a lubricant formulation for use in an electric or hybrid vehicle includes a base oil, a gear oil additive, and a molybdenum amine complex, such as dialkyldithiocarbamate additive. The molybdenum amine complex may be present in an amount of between 0.1 (w/w) % and about 1.0 (w/w) %. The base oil may be selected from the group including an oil classified by the American Petroleum Institute as a group I oil, a group II oil, a group III oil, a group IV oil, a group V oil, or combinations thereof. In one embodiment, the base oil may be about 50 (w/w) % to about 99.9 (w/w) % of the lubricant formulation.
The gear oil additives may further include viscosity modifiers, antifoaming agents, additive packages, antioxidant agents, antiwear agents, extreme pressure agents, detergents, dispersants, anti-rust agents, friction modifiers, corrosion inhibitors and combinations thereof. The gear oil additive may be present in an amount of about 0.01 (w/w) % and about 20 (w/w) % of the formulation.
The lubricant formulation may cause improved electric motor protection when voltage is applied to an electrode in the presence of the formulation comprising the molybdenum dialkyldithiocarbamate additive as compared to a fluid lacking the molybdenum dialkyldithiocarbamate additive. The formulation may also maintain electrical resistance slope as compared to a fluid lacking the molybdenum dialkyldithiocarbamate additive. It may also have improved protective properties for copper surfaces or exhibit a color change indicating the contact load, temperature, time, or viscosity of the formulation.
In another embodiment, a method of evaluating the electrical characteristics or performance of a transmission system suitable for use in an electric or hybrid vehicle is provided. The method may include the steps of: providing a transmission body including the transmission components, wherein the transmission body and components are suitable for use in an electric or hybrid vehicle; providing a fresh lubricant formulation, i.e. an unused or untreated formulation, including a base oil suitable for use in an electric vehicle; a first additive; and a second additive, wherein the second additive comprises diisotridecylamine molybdate in an amount of about 0.5 (w/w) %.
The method may further include directly contacting at least one transmission component with the fresh lubricant formulation under a set of conditions to form a used lubricant formulation; removing at least a portion of the used lubricant formulation from the transmission system and assigning a color for the used lubricant formulation; matching the color of the used lubricant formulation with a substantially similar color assigned to a control lubricant formulation created under a substantially similar set of conditions to obtain a set of matched colors; and determining the electrical characteristic of the transmission system based on the set matched colors.
In one embodiment, the set of conditions used to evaluate the used lubricant formulation include determining the load placed on the transmission system, the temperature at which the transmission system operates, the time that the transmission system operates, and the viscosity of the fresh lubricant formulation.
In one embodiment, a lubricant formulation for use in an electric or hybrid vehicle includes a base oil, a gear oil additive, and a molybdenum dialkyldithiocarbamate additive. Specifically, it has been surprisingly found that adding diisotridecylamine molybdate to a base oil provides unexpected protective characteristics for electric or hybrid vehicle transmissions, as well as to provide users with diagnostic and design tools for electric vehicle transmissions and engines that they did not previously have.
The base oil may be any oil classified by the American Petroleum Institute as a group I oil, a group II oil, a group III oil, a group IV oil, a group V oil, or combinations thereof. In one embodiment, the base oil may be a Group III mineral oil present in an amount of about 50 (w/w) % to about 99.9 (w/w) % of the lubricant formulation.
The additives suitable for use in the formulation may include viscosity modifiers, antifoaming agents, additive packages, antioxidant agents, antiwear agents, extreme pressure agents, detergents, dispersants, anti-rust agents, friction modifiers, corrosion inhibitors, gear oil additives, and combinations thereof, and may be present in an amount of about 0.01 (w/w) % and about 20 (w/w) % of the formulation.
In one embodiment, the additives may be selected from gear oil additives including, but not limited to, Afton Hitec 3491LV, Hitec 3491A, Hitec 363, Hitec 3080, Hitec 3460, Hitec 355 or Lubrizol A2140A, Lubrizol A2042, Lubrizol LZ 9001N, Lubrizol A6043, Lubrizol A2000, and combinations thereof. Particularly suitable gear axle additives have a Sulphur base and provide protection in extreme pressure situations.
Finally, it has been found that not all MoDTC additives produce the beneficial results found by combining the base oil with a gear oil additive and a molybdenum amine complex, such as diisotridecylamine molybdate. Specifically, in one embodiment, diisotridecylamine molybdate, the general chemical structure for which is shown below:
may be present in the composition in an amount of about 0.01 (w/w) % to about 20.0 (w/w) %, in another embodiment, from about 0.1 (w/w) % to about 1.0 (w/w) %, and in yet another embodiment, about 0.5 (w/w) %. Suitable molybdenum amine complex additives include, but are not limited to diisotridecylamine molybdate, commercially available from ADEKA Corp. as SAKURA-LUBE S710.
It has further been found that the combination of a gear oil additive with a molybdenum amine complex is critical for the beneficial synergies disclosed herein. To be free from doubt, MoDTC, including the term “MoDTC additives,” as used hereafter shall refer to molybdenum amine complex additives, and specifically diisotrdecylamine molybdate, in the examples.
A “fully formulated lubricant” is defined as a combination of base oils (group I, II, III, IV, V), viscosity modifiers and additives where the solution is miscible, clear and stable.
“Drive systems” can be transmissions, axles, transaxles, and industrial gearboxes.
Acronyms include, but are not limited to: MoDTC: Molybdenum Dialkyldithiocarbamate; EP: Extreme Pressure; ASTM: American Society for Testing and Materials; E3CT: Electric Conductivity Copper Corrosion Test; SEM: Scanning Electron Microscope; EDS: Energy Dispersive X-Ray Spectroscopy; BL: Boundary Lubrication; HFRR: High Frequency Reciprocating Rig; EV: Electric Vehicle; and IC: Internal Combustion.
Samples were prepared according to the following specifications in Table 1.
The samples were then tested and compared, as detailed below.
The addition of an MoDTC additive was surprisingly found to lessen the dielectric breakdown or electrical breakdown of the base oil. Specifically, as the oil (electrical insulator) becomes electrically conductive when the voltage applied across electrodes exceeds the known oil breakdown voltage, the sample containing MoDTC additive results in a higher residual electrical value, thus indicating a lower dielectric breakdown of the fluid. The less the oil experiences dielectric breakdown, the greater the potential for electric motor protection.
The dielectric breakdown of Samples I and II were tested according to ASTM standards D887-02 and D1816 using a Megger OTS60PB to detect the breakdown voltage for each system. The dielectric breakdown of fresh base oil and fresh copper electrodes was compared to the dielectric breakdown of baked fluid with baked electrodes, baked fluid and fresh electrodes, and fresh fluid and based electrodes. The baked oil and electrodes were used to simulate typical wear conditions for both the fluids and the electrodes. The fluid was baked by exposing the fresh fluid to 125° C. for an hour, while the electrodes were baked by submerging half of the electrode in fresh fluid and exposing it to 125° C. for an hour.
As shown in Table 2, Sample II, which contains the MoDTC additive, enhances the base oil performance and maintains higher dielectric strength compared to Sample I in all test scenarios.
Oil performance was also evaluated using an electric conductivity copper corrosion test (E3CT). Using E3CT, a copper wire's electrical resistance is evaluated for varying test times, while keeping the temperature (130° C. to about 160°), current (1 mA), and copper wire diameter (70 micron 99.999% pure) constant. The tests were conducted by submerging the copper wire in a glass tube containing the sample lubricants. The tube and the wire were also submerged in a silicon oil bath to control the sump temperature. And, the electric current (1 mA) and resistance were measured using a Keithley Meter.
As shown in
As shown in
As shown in
In addition, it was discovered that a protective film is likely formed around the cooper wire by subjecting the wire to a base oil including the MoDTC additive. Using the SEM analysis of the copper wire treated with the base oil with the MoDTC additive, as shown in
In addition to reducing the dielectric breakdown of the oil and decreasing the degradation of metal components, the lubricant including the MoDTC additive can aid in allowing transmission and vehicle manufacturers to predict and analyze the sump temperature and the highest contact load exhibited by the transmissions and motors of electric vehicles based on the color variation in the lubricant. Therefore, the novel lubricants are useful for improving theoretical and modeling work to predict contact conditions and heat transfer properties of the vehicle systems more accurately.
Using the novel lubricant including the MoDTC additive, Sample VII with a viscosity of about 6 cSt, a user is able to analyze the load on the system based on the color change of the lubricant. Using the ASTM D2783 4 ball EP test, the additive reaction in the contact at different loads is evaluated by increasing the applied pressure from 0 to about 400 kg over time. As shown in
Moreover, a user can use the novel lubricants to evaluate temperature conditions inside vehicle systems based on the color of the resulting oil.
The oil including the MoDTC additive, made according to Sample V, as also tested in an external dynamometer testing facility and compared against the results of the controlled lab environment. For the dyno testing, the sump temperature reached about 100° C. with a very low load and a similar test time of about an hour. As shown in
It was also determined that the fluid viscosity plays important role in activating the MoDTC additive. As shown in
Sample VII, with a viscosity of 6 centistokes, had a different color (light amber) than did the formulation with a viscosity of 2.5 centistokes (light green), Sample VI, when compared to the untreated fresh lubricant of the same viscosity. Therefore, the color change of the lubricant may be used as an indicator of the viscosities of the various oils used.
Extreme pressure, wear and copper corrosion improvements were also evaluated, as shown in Table 4. The evaluation of these characteristics informs the effect the oil may have for extreme pressure protection.
As shown in Table 4, the oil containing the MoDTC additive (Sample II) helps to lower the resulting loads evaluated according to the 4 ball EP test (ASTM D2783), allowing the user to protect contacting surfaces better. The last non-seizure load indicates when the metal to metal contact happened (63 v. 80, respectively). The additive also improved the 4 ball wear test results, as shown in Table 5.
For the EV drive system fluid, protection of yellow metals like copper is very important while lubricating moving components. The use of a MoDTC additive also shows improved copper corrosion test results at 4 hrs at about 150° C. The rating of Sample II for the ASTM D130 test was 1A (light orange, almost the same as a freshly polished strip) compared to 1B (dark orange) of Sample I.
The lubricants described herein have been found to improve electrical properties including dielectric breakdown, electrical conductivity, and E3CT copper wire protection. In addition, the lubricants protect yellow metals and gear and bearing contacts, while showing the severity of the application conditions using color change indications. The lubricants described retain special additive protection but solve traditional corrosion issues by protecting electric and hybrid vehicle transmissions.
These findings confirm that the oil life can be increased in electric and hybrid vehicles where the oil is used to take away the generated heat from the motor. Also, OEMs can benefit from the color change phenomenon to predict operating conditions that will help improving heat transfer and drive system durability.
Certain embodiments have been described in the form of examples. It is impossible to depict every potential application. Thus, while the embodiments are described in considerable detail, it is not the intention to restrict or in any way limit the scope of the appended claims to such detail, or to any particular embodiment.
To the extent that the term “includes” or “including” is used in the specification or the claims, it is intended to be inclusive in a manner similar to the term “comprising” as that term is interpreted when employed as a transitional word in a claim. Furthermore, to the extent that the term “or” is employed (e.g., A or B) it is intended to mean “A or B or both.” When “only A or B but not both” is intended, then the term “only A or B but not both” will be employed. Thus, use of the term “or” herein is the inclusive, and not the exclusive use. As used in the specification and the claims, the singular forms “a,” “an,” and “the” include the plural. Finally, where the term “about” is used in conjunction with a number, it is intended to include ±10% of the number. For example, “about 10” may mean from 9 to 11.
As stated above, while the present application has been illustrated by the description of embodiments, and while the embodiments have been described in considerable detail, it is not the intention to restrict or in any way limit the scope of the appended claims to such detail. Additional advantages and modifications will readily appear to those skilled in the art, having the benefit of this application. Therefore, the application, in its broader aspects, is not limited to the specific details and illustrative examples shown. Departures may be made from such details and examples without departing from the spirit or scope of the general inventive concept.
This application relates to U.S. Provisional Application No. 62/839,365, filed on Apr. 26, 2019, entitled Specialty Lubricant for Electric and Hybrid Vehicles: Predicts Operating Conditions and Protects Yellow Metal and Electrical Breakdown, which is incorporated herein in its entirety.
Number | Date | Country | |
---|---|---|---|
62839365 | Apr 2019 | US |