Patent Description:
The present disclosure relates generally to ice-shedding coatings and, more specifically, to polyurethane-based, stress-localized ice-shedding coatings.

Icing is a common phenomenon in nature and technology, and it impacts a broad spectrum of industries ranging from transportation systems, power transmission lines, and infrastructures to energy systems. Icing on aircraft wings, control surfaces, sensors, and turbomachinery has detrimental effects on aerodynamics and engine performance and operability, while icing on ground surfaces, facilities, and equipment can hinder effective operations and present operational hazards. In marine applications, icing and ice accretion can cause damage to ship hulls, ship facilities, and instrumentation onboard while limiting the speed and maneuverability of the ships. Overall, the addressable market for anti-icing surfaces exceeds $<NUM> billion annually. Icing creates a myriad of issues around human well-being on a daily basis in cold climates.

State-of-the-art ice-shedding coatings can be grouped into four categories; namely, superhydrophobic, liquid-infused, low-interfacial toughness, and stress-localized coatings. The first three categories include coatings/surface treatments that provide low-to-moderate ice adhesion, but they generally suffer from durability issues. Currently-available stress-localized coatings can provide low ice adhesion with moderate durability, but they remain incapable of functioning for extended time periods in extremely harsh environments. In particular, for aerospace applications (e.g., drones and rotorcrafts) and wind turbines, high durability is an important consideration. <CIT> discloses an ice release coating comprising one or more polyurethane dispersions and one or more photoinitiators. and optionally including silicon resin emulsions, carbon black, nylon and wax. <CIT> discloses anti-icing surfaces that comprise an ice-phobic coating compositions comprising an elastomer matrix and organogel particle beads dispersed throughout the elastomer matrix. The gel beads may comprise siloxane and silicone oil. <CIT> discloses an ice-phobic coating comprising an elastomeric urethane-based polymer that comprise, remote from the surface of the coating, a liquid selected from the group consisting of: polydimethylsiloxane (PDMS) oil, polymethylphenylsiloxane (PMPS) oil, perfluoroether oils, natural oils, synthetic oils, and combinations thereof.

In an embodiment, an ice-shedding coating solution for forming a polyurethane-based, stress-localized ice-shedding coating, wherein the ice-shedding coating solution includes: a Phase I solution having a polyurethane resin; a Phase II-A solution having a thermoplastic elastomer, a wax, and a high-oleic oil; and a Phase II-B solution having a silicone elastomer and a silicone oil.

In another embodiment, a method of manufacturing, includes preparing a Phase I solution having a polyurethane resin; preparing a Phase II-A solution having a thermoplastic elastomer, a wax, and a high-oleic oil; and preparing a Phase II-B solution having a silicone elastomer and a silicone oil. The method also includes combining the Phase I solution, the Phase II-A solution, and the Phase II-B solution to yield an ice-shedding coating solution.

In another embodiment, a polyurethane-based, stress-localized ice-shedding coating includes a high-shear modulus polyurethane matrix phase and a first low-shear modulus phase and a second low-shear modulus phase uniformly distributed within the high-shear modulus polyurethane matrix phase. Additionally, the first low-shear modulus phase is a first product of a thermoplastic elastomer, a wax, and a high-oleic oil, while the second low-shear modulus phase is a second product of a silicone elastomer and a silicone oil.

Further, to the extent that certain terms such as parallel, perpendicular, and so forth are used herein, it should be understood that these terms allow for certain deviations from a strict mathematical definition, for example to allow for deviations associated with manufacturing imperfections and associated tolerances.

The concept of stress localization, as mentioned above, provides a route to achieve novel ice-shedding coatings that demonstrate low ice adhesion and moderate durability. These coatings generally include two phases in which the matrix phase (Phase I) has high-shear modulus and helps impart durability to the overall coating, and the second dispersed phase (Phase II) with low-shear modulus leads to stress-localization and initial crack formation at the ice-material interface. The adhesion of ice to each phase depends on the respective shear modulus of each phase. Once an external force is applied to attach ice on a surface, Phase II will initially detach from ice and form local cracks at the ice-material interface. The crack induces an elastic stress field on the perimeter of the crack and localizes the stress. The localized stress leads to opening of the crack and propagation at the interface. That is, the induced stress field by the second phase is responsible for crack growth and detachment of ice from the material. The ice adhesion on these stress-localized surfaces is written as the following mathematical relationship: <MAT> where g(ϕII) denotes the stress-localization function, ϕII is the volumetric fraction of Phase II, Wa is the work of adhesion of the material, Gm is the shear modulus of the material, while h, a, and l are geometric parameters illustrated in <FIG>. The value of g(ϕII) directly depends on the radius of curvature of the induced crack at the interface, and it is presently recognized that g(ϕII) can be tuned to lower values by tuning and controlling the morphology of Phase II.

In state-of-the-art silicone elastomer-based, stress-localized coatings, a silicone elastomer may be selected as the matrix (Phase I) and silicone-based organogels may be selected as the second phase (Phase II). As both phases are silicone-based materials, they demonstrate good compatibility, leading to a uniform and consistent coating formulation. However, despite showing low ice adhesion, it is presently recognized that these silicone elastomer-based ice-shedding coatings generally cannot withstand highly abrasive or erosive conditions that occur in some settings.

With the foregoing in mind, the embodiments presented herein provide a novel material paradigm to address the above challenges via polyurethane-based, stress-localized coatings ice-shedding coatings with exceptional durability. The disclosed ice-shedding coatings can withstand particularly harsh conditions, such as those seen in rain erosion tests that are commonly conducted to assess coatings for aerospace applications. For the disclosed stress-localized coatings, it is presently recognized that the proper choice of the phases plays an important role in the uniformity, performance, and durability of these coatings. As illustrated in <FIG>, embodiments of the disclosed ice-shedding coating <NUM> include: a polyurethane-based, high-shear modulus matrix (i.e., Phase I, matrix phase), and two chemically-distinct, low-shear modulus phases (i.e., Phase II-A and Phase II-B) uniformly distributed throughout the matrix phase. As such, the ice-shedding coating <NUM> includes particles (e.g., domains, regions) of Phase II-A and particles (e.g., domains, regions) of Phase II-B uniformly dispersed within the matrix phase, wherein the Phase II particles or domains range from approximately <NUM> nanometers (nm) to approximately <NUM> micrometers (µm) (e.g., between <NUM> and <NUM>, between <NUM> and <NUM>).

As discussed below, the chemistry and morphology of Phase II-A and Phase II-B are suitably selected and controlled to achieve uniform coatings with high-durability for ice-shedding purposes. For example, as discussed below, the disclosed ice-shedding coatings can provide high-durability under rain erosion conditions with wind speeds exceeding <NUM> meters/second.

The synthesis and testing of an example embodiment of a polyurethane-based, stress-localized ice-shedding coating is disclosed, referred to herein as EC-<NUM>. It should be appreciated that this embodiment is provided as merely an example of the present approach, and in other embodiments, the techniques discussed herein may be applied to produce other polyurethane-based, stress-localized ice-shedding coatings, in accordance with the present disclosure.

For the example EC-<NUM> embodiment, an example polyurethane resin was acquired as an aliphatic polyurethane resin matrix from Covestro AG, headquartered in Leverkusen, Germany. An example thermoplastic elastomer was acquired as a styrene-ethylene/butylene-styrene (SEBS) polymer from the Kraton Corporation, located in Houston, Texas. An example liquid paraffin wax (LPW) (e.g., between <NUM> grams per mole (g/mol) and <NUM>/mol) and an example silicone oil (e.g., a polydimethylsiloxane oil) were acquired from Sigma Aldrich (http://sigmaldrich. com), headquartered in St. Louis, Missouri. An example high-oleic oil was acquired as safflower oil from Oleico. An example silicone elastomer (e.g., a solid or crosslinked polydimethylsiloxane) was acquired as Sylgard <NUM> from Dow Chemical Company, headquartered in Midland, Michigan. For this example embodiment, naphtha was used as a volatile organic solvent. It may be appreciated that, in other embodiments, other materials from other vendors may be used, in accordance with the present disclosure.

<FIG> are flow diagrams illustrating portions of an example process <NUM> for manufacturing embodiments of the disclosed ice-shedding coating <NUM>. The illustrated embodiment of the process <NUM> includes: process 12A, in which a Phase I solution <NUM> is prepared, as illustrated in <FIG>; process 12B, in which a Phase II-A solution <NUM> is prepared, as illustrated by <FIG>; process 12C, in which a Phase II-B solution <NUM> is prepared, as illustrated by <FIG>; and process 12D in which the Phase I solution <NUM>, the Phase II-A solution <NUM>, and the Phase II-B solution <NUM> are combined to form an ice-shedding coating solution <NUM> that is subsequently applied to the surface of a part to form the disclosed ice-shedding coating <NUM>. In certain embodiments, processes 12A, 12B, and 12C may be performed in parallel for enhanced efficiency. As illustrated in <FIG>, process 12A includes preparing the Phase I solution <NUM> from the polyurethane resin (block <NUM>). For example, in certain embodiments, the Phase I solution <NUM> is prepared by mixing a suitable solvent with the polyurethane resin in a weight ratio of <NUM> part solvent to between <NUM> and <NUM> parts polyurethane resin.

As illustrated in <FIG>, process 12B includes combining (block <NUM>) the thermoplastic elastomer, the LPW, and the high-oleic oil to form a first mixture. For example, in certain embodiments, the first mixture is prepared by mixing the components in a weight ratio of <NUM> part thermoplastic elastomer to between <NUM> and <NUM> parts LWP to between <NUM> and <NUM> parts high-oleic oil. For the illustrated embodiments, the first mixture is subsequently heat treated (e.g., annealed at a temperature between <NUM> and <NUM> for <NUM> to <NUM> hours), and then allowed to cool and solidify (block <NUM>). Subsequently, the solid is dissolved in a suitable solvent (block <NUM>) to generate the Phase II-A solution <NUM>.

As illustrated in <FIG>, process 12C includes combining (block <NUM>) the silicone elastomer with the silicone oil to form a second mixture. For example, in certain embodiments, the second mixture is prepared by mixing the components in a weight ratio of <NUM> part silicone elastomer to between <NUM> and <NUM> parts silicone oil. For the illustrated embodiment, the second mixture is subsequently heat treated (e.g., annealed at a temperature between <NUM> and <NUM> for <NUM> to <NUM> hours) and allowed to cool and solidify (block <NUM>). Subsequently, the solid is dissolved in a suitable solvent (block <NUM>) to generate the Phase II-B solution <NUM>.

As illustrated in <FIG>, process 12D includes combining (block <NUM>) the Phase I solution <NUM>, the Phase II-A solution <NUM>, and the Phase II-B solution <NUM> to form the ice-shedding coating solution <NUM>. In certain embodiments, additional volatile organic solvent may be included in the ice-shedding coating solution <NUM>. For example, in certain embodiments, the ice-shedding coating solution <NUM> includes, by weight: between <NUM>% and <NUM>% of the Phase I solution <NUM>, between <NUM>% and <NUM>% of the Phase II-A solution <NUM>, between <NUM>% and <NUM>% of the Phase II-B solution <NUM>, and between <NUM>% and <NUM>% solvent. After being prepared, the ice-shedding coating solution <NUM> is subsequently applied (block <NUM>) to a surface of a part to form the ice-shedding coating <NUM> on a surface of the part. As noted below, in certain embodiments, the surface of the part may be prepared in a number of ways prior to application of the ice-shedding coating solution <NUM>, including surface treatment to remove impurities and/or application of a polyurethane-compatible primer. After application of the ice-shedding coating solution <NUM> onto the surface of the part (e.g., spray coating), the ice-shedding coating solution <NUM> cures to form the ice-shedding coating <NUM> on the part. In certain embodiments, curing may involve allowing solvent to evaporate (e.g., to dry) from the applied ice-shedding coating solution <NUM>, while in other embodiments, the curing may be accelerated or enhanced by applying energy (e.g., heat, light) to the applied ice-shedding coating solution <NUM> to form the ice-shedding coating <NUM>.

Samples of the example ice-shedding coating EC-<NUM> were examined in two main ways: (<NUM>) ice adhesion and ice-shedding characteristics and (<NUM>) mechanical, chemical, and environmental durability. To assess performance of the disclosed ice-shedding coating versus other available technologies, four other coating types were examined alongside the example ice-shedding coating (i.e., EC-<NUM>). The other coating types are Slippery surfaces (SLIPS), liquid-infused surfaces (LIS), low-interfacial toughness (LIT), and silicon-based stress-localized surfaces (DI-<NUM>). All the surfaces were developed with a thickness of approximately <NUM>, except the LIT samples in which low thickness is required for their ice-shedding characteristics. For the LIT surface, thickness of <NUM> was selected. It may be appreciated that these coatings operate based on different physical principles. For example, SLIPS functions based on a capillary-secured liquid film on the surface, LIT surfaces function based on low cross-linking density and slip boundary conditions, while DI-<NUM> and EC-<NUM> both function based on stress localization.

The ice adhesion measurements were conducted according to the procedure discussed in Irajizad et al. The ice-shedding substrates were placed on a cold plate at a temperature of -<NUM>. The force applied to remove ice from the substrate divided by the cross-section of ice-material is reported as the ice adhesion (the cross-hatched bar on the left for each sample) in the graph <NUM> of <FIG>. As illustrated, ice adhesion on a reference aluminum substrate, along with state-of-the-art icephobic surfaces, were measured. The reported values represent an average of ten measurements on each material. The measurements suggest that SLIPS, LIT samples, DI-<NUM>, and EC-<NUM> all demonstrated low ice adhesion.

To minimize the role of geometry and environmental conditions on ice adhesion, ice adhesion reduction factor (ARF) was used as another metric, as defined based on the following equation: <MAT> This criterion is a non-dimensional figure independent of the measurement setup. The ARF values for various surfaces are indicated by the non-cross-hatched bar on the right for each sample in graph <NUM> of <FIG>. As shown, the SLIPS, LIS, DI-<NUM> and EC-<NUM> coatings are capable of reducing ice adhesion on an aluminum surface by <NUM>-<NUM> times. As such, ice adhesion on EC-<NUM> is in the same range of some of the state-of-the-art coatings (e.g., approximately a 13x reduction in ice adhesion), while also demonstrating superior durability relative to the other coatings, as shown below.

Although ice adhesion on new, pristine surfaces offers one initial metric used to assess performance of ice-shedding coatings, it is presently recognized that a more important factor is ice adhesion of these surfaces after having been exposed to various mechanical, chemical, and environmental stresses that inevitably damage, and potentially reduce the effectiveness, of the coatings. For instance, it has been shown that SLIPS surfaces lose their characteristics (i.e. depletion of liquid) after a number of icing and de-icing cycles. As indicated by the graph <NUM> of <FIG>, the EC-<NUM> coated surfaces were exposed to a wide range of harsh environmental conditions to assess ice adhesion on these surfaces after these exposures, including: <NUM> icing/deicing cycles, abrasion, water and air jets, long-term UV exposure, high temperatures, and chemically-corrosive environments. As shown, ice adhesion on these EC-<NUM> coated surfaces remains quite stable, even after exposure to multiple forms of abrasion, erosion, and exposure to different chemicals.

The ice-shedding performance of these coatings was also assessed in an icing wind tunnel on an aircraft airfoil at temperature of -<NUM> and compared to an airfoil with no coating. The results are shown in <FIG>, with <FIG> including a representation of a photograph <NUM> of the airfoil with no coating, and 4B including a representation of a photograph <NUM> of the airfoil with the EC-<NUM> coating at the conclusion of the test. As shown, the EC-<NUM> coated airfoil experiences a substantially reduced the amount of ice buildup through the duration of the test.

As discussed below, a comprehensive set of tests was conducted to assess the mechanical durability of the example polyurethane-based, stress-localized ice-shedding coating (i.e., the EC-<NUM> coated samples), including abrasion, pencil hardness, shore hardness, crosshatch, and rain erosion.

Taber Abrasion: In this metrology, a Taber abrasion test (Taber Reciprocating Abraser, Model <NUM>) was conducted according to ASTM D4060. In these experiments, removal of the ice-shedding coating under a load of <NUM> Newtons (N) with a soft tip of CS-<NUM> and a hard tip of H-<NUM> was assessed. Ice-shedding samples were placed firmly on a horizontal plate in the Taber instrument and <NUM> abrasion cycles were conducted. The thickness losses for various samples are shown in the graph <NUM> of <FIG>. Note that for LIT samples, the low thickness is essential for their ice-shedding performance. These surfaces are completely abraded after a few cycles with a soft-tip and the tip touches the underlying glass substrate. To put the abrasion resistance in a better perspective, the number of the cycles to remove half of the thickness of the ice-shedding coating using both CS-<NUM> and H-<NUM> tips were measured, as shown in the graph <NUM> of <FIG>. As shown, although LIS-CB provides low ice adhesion, it could not last more than <NUM> cycles with the tip CS-<NUM> and <NUM> cycles with the tip H-<NUM>. The scenario is somewhat better for DI-<NUM> samples, but still not satisfactory. For the EC-<NUM> samples, however, the mechanical durability is far superior to the other surfaces, and it takes <NUM>,<NUM> abrasion cycles with the hard tip of H-<NUM> to abrade half of the thickness of the coating.

Pencil Hardness: This metrology was conducted based on the ASTM D3363 standard. The hardness of the ice-shedding material is determined by pencil leads of known hardness ranging from 6B to <NUM>. The scratch resistance of the surfaces is indicated by the cross-hatched bar on the left for each sample in the graph <NUM> of <FIG>. The EC-<NUM> samples demonstrated a pencil hardness of <NUM>.

Shore Hardness: The shore hardness test was conducted by Rex Durometer, DD4A according to ASTM D2240. A glass substrate was coated with the ice-shedding coatings to a thickness of <NUM> thickness is required for the hardness measurements (note: as LIT surfaces must necessarily be thinner than this, these materials were not assessed for this test). The Durometer was placed gently on the surface until the tip of the durometer completely penetrates the coating and reaches the underlying substrate. Then, the shore hardness was read. This procedure was conducted three times, and the average value is indicated by the non-cross-hatched bar on the right for each sample in the graph <NUM> of <FIG>. As shown, EC-<NUM> samples demonstrated a shore hardness of approximately <NUM>, in contrast to other surfaces that have lower shore hardness values. This provides a clear advantage for EC-<NUM> in its ability to avoid scratches.

Cross Hatch: This metrology was conducted based on the ASTM D3359 standard. The tested samples are classified based on the metric bar of 0B-5B as the 0B is the least durable sample and 5B represents the highest durability, as indicated by the graph <NUM> of <FIG>. The EC-<NUM> samples demonstrated approximately <NUM>% area removed and was classified at scale 5B. This suggests the strong cohesive bonding characteristics of these surfaces.

Pull-off Adhesion: This metrology measures adhesion of the ice-shedding material to the substrate and was conducted according to ASTM D4541. The failure in this experiment could be either adhesive or cohesive. The cohesive failure indicates low durability of the material. For EC-<NUM> samples, the type of failure was adhesive with pull-off force of <NUM> megapascal (MPa). As primers could be used to strengthen adhesion of various coatings to a substrate, a comparative study for this metrology is not provided.

Water jet: In this metrology, which is a less severe form of rain erosion, the EC-<NUM> surface was placed under a water jet as shown in the reproduced photograph <NUM> of <FIG>. The water jet ran for <NUM> minutes on the coating and the samples were visually examined before and after the test. No visual change was detected on the EC-<NUM> samples. This pre-qualifies the surface for the rain erosion metrology.

Rain Erosion: Aerospace rain erosion tests are one of the harshest tests that can be conducted on a coating. Although surfaces such as DI-<NUM> provide good durability and low ice adhesion, they generally fail rain erosion tests. Thus, the most durable surface (i.e. the EC-<NUM> sample) was chosen for the rain erosion test. This test was conducted in a whirling arm rain erosion test facility by an independent aerospace third party. For this test, the edge of the airfoil is taped, and the rest of the airfoil is coated with the polyurethane-based ice-shedding coating. The tape is then removed before the test, such that there is now a sharp line where the coating stops. Here, accelerating water droplets will impact the coating and attempt to delaminate the coating from the underlying substrate. The water droplets are <NUM> millimeter (mm) to <NUM> in size simulated through five water nozzles. The water flow rate is <NUM> cubic meters per hour (m<NUM>/hour) to achieve <NUM> centimeters (cm) to <NUM> of rain fall per hour. The impact speed of the rain droplets is <NUM> meters per second and the tests are conducted at ambient temperature. The tests were conducted on three airfoils. Upon analysis, the rain-eroded EC-<NUM> samples were intact with no significant signs of damage or adhesive/cohesive failure (e.g., delamination).

As discussed below, a set of chemical durability tests was conducted to assess the chemical durability of the new ice-shedding coatings. These tests were conducted in two ways: (<NUM>) evaluation of the coating exposed to fluids with various pH at ambient temperature, and (<NUM>) evaluation of the coating exposed to jet hydraulic fluids and lubricating oils at elevated temperatures.

Chemical durability (Approach <NUM>): In these tests, fluids with a range of pH between <NUM> and <NUM> were used. The acidic (low pH) solutions were prepared using hydrochloric acid (HCl) and deionized water. The basic (high pH) solutions were prepared using sodium hydroxide (NaOH) and deionized water. The coated samples were soaked in these solutions for <NUM> hours and, after this time, the integrity of the coatings was examined, looking for any signs of softening, blistering or other possible surface damage or changes in the integrity of the coating. Furthermore, the ice adhesion of these samples was measured as shown previously in <FIG>.

Chemical durability (Approach <NUM>): In these tests, which are specifically designed for aerospace applications, the durability of the coating is examined with respect to hydraulic fluid and lubricating oil. The substrate material consisted of Aluminum <NUM> (T3 temper) with dimensions of <NUM> x <NUM> x <NUM>. The samples were coated with a primer with a thickness of <NUM> and then the polyurethane-based ice-shedding coating with a thickness of <NUM>. Initially, the samples were immersed in the jet hydraulic fluid at <NUM> for <NUM> hours. The coupons were tested before and after the immersion. Only a slight amount of staining was observed after the test. No visible softening or blistering was detected. In the next set of experiments, the panels were immersed in a lubricating oil at <NUM> for <NUM> hours. No visible softening or blistering was observed after the test.

As discussed below, a set of environmental durability tests was conducted to assess the environmental durability of the new ice-shedding coatings, including weather resistance tests, impact flexibility tests, and low temperature flexibility tests.

Weather resistance: The durability of ice-shedding coatings was examined through the ASTM G155 standard. In accordance with this standard, the samples were exposed to Xenon-arc lamp and cycled between <NUM> minutes of light-only exposure, followed by <NUM> minutes of a combination of light exposure and water spray, for a total of <NUM> hours. After removal from a weatherometer, the <NUM>° specular gloss of the coating was tested according to ASTM D523. The gloss change was less than <NUM> relative to the unexposed initial sample.

Impact flexibility: This test was conducted according to ASTM standard D6905 by an independent aerospace third party. The test panels for this analysis were anodized Aluminum <NUM> (<NUM> temper). The coatings (i.e., either EC-<NUM> or a control coating) were applied on these panels without any primer and left to air dry for <NUM> days. The test was conducted at ambient temperature with a Gardco GE Universal Impact Tester. The coated test panels were placed downward on a rubber pad (shore hardness of 60A) at the bottom of an impactor guide. The impactor was dropped on the coated sample. The impact area was examined by a microscope with 10x magnification. For the EC-<NUM> sample, no cracks on the surface were observed up to <NUM>% elongation, while the control coating demonstrated some cracking or tearing at <NUM>% elongation. It may be noted that this exceeds a minimum threshold for the impact flexibility test, which targets having no observable cracking at up to <NUM>% elongation.

Low temperature flexibility: This test was conducted according to ASTM standard D522. The test panels are similar to the impact flexibility test. Two test panels are examined at temperature of about -<NUM> (± <NUM>), one having the EC-<NUM> coating, and the other having a control coating. The test was conducted based on method B, using cylindrical mandrel test with a <NUM> mandrel. The sample was placed on the mandrel with an uncoated side in contact with the mandrel and an overhang of greater than <NUM> on each side. Through steady pressure of the fingers, the panel was bent <NUM>° around the mandrel. The panel was removed and examined with the unaided eye for possible crack formation. No crack on any sample was observed for either the EC-<NUM> or the control coating.

In summary, the embodiments described herein introduce a new material paradigm for durable ice-shedding materials that provide low ice adhesion while having extreme durability under various mechanical, chemical, and environmental conditions. In this paradigm, a stress-localized surface is formed through a selective combination of polyurethane and two gel structures. The proper form of Phase I, Phase II-A, and Phase II-B materials leads to uniformity and high durability of these coatings. The Phase I material with high shear modulus is largely responsible for the high durability of the material, while the Phase II-A and Phase II-B materials with low shear modulus are responsible for stress localization in the material. The extreme mechanical durability of these surfaces is examined under rain erosion with no sign of defects at <NUM> meters per second wind/rain droplet speeds. It is believed that this novel material paradigm opens a new route for the development of durable ice-shedding coatings for a wide range of applications, especially for aviation, transportation, and wind power.

Claim 1:
An ice-shedding coating solution for forming a polyurethane-based, stress-localized ice-shedding coating, wherein the ice-shedding coating solution comprises:
a Phase I solution having a polyurethane resin;
a Phase II-A solution having a thermoplastic elastomer, a wax, and a high-oleic oil; and
a Phase II-B solution having a silicone elastomer and a silicone oil.