Laminated metals, and in particular nanolaminated metals, are of interest for structural and thermal applications because of their unique toughness, fatigue resistance and thermal stability. For corrosion protection, however, relatively little success has been reported in the formation of corrosion-resistant coatings that are laminated on the nanoscale.
Electrodeposition has been successfully used to deposit nanolaminated coatings on metal and alloy components for a variety of engineering applications. Electrodeposition is recognized as a low-cost method for forming a dense coating on any conductive substrate. Electrodeposition has been demonstrated as a viable means for producing nanolaminated coatings, in which the individual laminates may vary in the composition of the metal, ceramic or organic-metal composition or other microstructure feature. By time varying electrodeposition parameters such as current density, bath composition, pH, mixing rate, and/or temperature, multi-laminate materials can be produced in a single bath. Alternately by moving a mandrel or substrate from one bath to another, each of which represents a different combination of parameters that are held constant, multi-laminate materials or coatings can be realized.
The corrosion behavior of organic, ceramic, metal and metal-containing coatings depends primarily on their chemistry, microstructure, adhesion, thickness and galvanic interaction with the substrate to which they are applied. In the case of sacrificial metal or metal-containing coatings, such as zinc on an iron-based substrate, the coating is less electronegative than the substrate and so oxidation of the coating occurs preferentially, thus protecting the substrate. Because these coatings protect by providing an oxidation-preferred sacrificial layer, they will continue to work even when marred or scratched. The performance of sacrificial coatings depends heavily on the rate of oxidation of the coating layer and the thickness of the sacrificial layer. Corrosion protection of the substrate only lasts so long as the sacrificial coating is in place and may vary depending on the environment that the coating is subjected to and the resulting rate of coating oxidation.
Alternately, in the case of a barrier coating, such as nickel on an iron-based substrate, the coating is more electronegative than the substrate and thus works by creating a barrier to oxidative corrosion. In A-type metals, such as Fe, Ni, Cr and Zn, it is generally true that the higher the electronegativity, the greater the nobility (non reactivity). When the coating is more noble than the substrate, if that coating is marred or scratched in any way, or if coverage is not complete, these coatings will not work, and may accelerate the progress of substrate corrosion at the substrate: coating interface, resulting in preferential attack of the substrate. This is also true when ceramic coatings are used. For example, it has been reported in the prior art that while fully dense TiN coatings are more noble than steel and aluminum in resistance to various corrosive environments, pinholes and micropores that can occur during processing of these coating are detrimental to their corrosion resistance properties. In the case of barrier coatings, pinholes in the coating may accelerate corrosion in the underlying metal by pitting, crevice or galvanic corrosion mechanisms.
Many approaches have been utilized to improve the corrosion resistance of barrier coatings, such as reducing pinhole defects through the use of a metallic intermediate layer or multiple layering schemes. Such approaches are generally targeted at reducing the probability of defects or reducing the susceptibility to failure in the case of a defect, mar or scratch. One example of a multiple layering scheme is the practice commonly found in the deployment of industrial coatings, which involves the use of a primer, containing a sacrificial metal such as zinc, coupled with a highly-crosslinked, low surface energy topcoat (such as a fluorinated or polyurethane topcoat). In such case, the topcoat acts as a barrier to corrosion. In case the integrity of the topcoat is compromised for any reason, the metal contained in the primer acts as a sacrificial media, thus sacrificially protecting the substrate from corrosion.
Dezincification is a term is used to mean the corroding away of one constituent of any alloy leaving the others more or less in situ. This phenomenon is perhaps most common in brasses containing high percentages of zinc, but the same or parallel phenomena are familiar in the corrosion of aluminum bronzes and other alloys of metals of widely different chemical affinities. Dezincification usually becomes evident as an area with well-defined boundaries, and within which the more noble metal becomes concentrated as compared with the original alloy. In the case of brass the zinc is often almost completely removed and copper is present almost in a pure state, but in a very weak mechanical condition. Corrosion by dezincification usually depends on the galvanic differential between the dissimilar metals and the environmental conditions contributing to corrosion. Dezincification of alloys results in overall loss of the structural integrity of the alloy and is considered one of the most aggressive forms of corrosion.
Coatings that may represent the best of both the sacrificial coating and the barrier coating are those that are more noble than the substrate and creates a barrier to corrosion, but, in case that coating is compromised, is also less noble than the substrate and will sacrificially corrode, thus protecting the substrate from direct attack.
In one embodiment of the technology described herein, the phenomena observed in dezincification of alloys is leveraged to enable corrosion resistant coatings that are both more and less noble than the substrate, and which protect the substrate by acting both as a barrier and as a sacrificial coating. Other embodiments and advantages of this technology will become apparent upon consideration of the following description.
The technology described herein includes in one embodiment an electrodeposited, corrosion-resistant multilayer coating or cladding, which comprises multiple nanoscale layers that periodically vary in electrodeposited species or electrodeposited microstructures (electrodeposited species microstructures), wherein variations in said layers of said electrodeposited species or electrodeposited species microstructure result in galvanic interactions between the layers, said nanoscale layers having interfaces there between.
The technology described herein also provides an electrodeposition method for producing a corrosion resistant multilayer coating or cladding comprising the steps of:
a) placing a mandrel or a substrate to be coated in a first electrolyte containing one or more metal ions, ceramic particles, polymer particles, or a combination thereof; and
b) applying electric current and varying in time one or more of: the amplitude of the electrical current, electrolyte temperature, electrolyte additive concentration, or electrolyte agitation, in order to produce periodic layers of electrodeposited species or periodic layer of electrodeposited species microstructures; and
c) growing a multilayer coating under such conditions until the desired thickness of the multilayer coating is achieved.
Such a method may further comprising after step (c), step (d), which comprises removing the mandrel or the substrate from the bath and rinsing.
The technology described herein further provides an electrodeposition method for producing a corrosion resistant multilayer coating or cladding comprising the steps of:
a) placing a mandrel or substrate to be coated in a first electrolyte containing one or more metal ions, ceramic particles, polymer particles, or a combination thereof; and
b) applying electric current and varying in time one or more of: the electrical current, electrolyte temperature, electrolyte additive concentration, or electrolyte agitation, in order to produce periodic layers of electrodeposited species or periodic layer of electrodeposited species microstructures; and
c) growing a nanometer-thickness layer under such conditions; and
d) placing said mandrel or substrate to be coated in a second electrolyte containing one or more metal ions that is different from said first electrolyte, said second electrolyte containing metal ions, ceramic particles, polymer particles, or a combination thereof; and
e) repeating steps (a) through (d) until the desired thickness of the multilayer coating is achieved;
wherein steps (a) through (d) are repeated at least two times. Such a method may further comprising after step (e), step (f) which comprises removing the mandrel or the coated substrate from the bath and rinsing.
Also described herein is an electrodeposited, corrosion-resistant multilayer coating or cladding, which comprises multiple nanoscale layers that vary in electrodeposited species microstructure, which layer variations result in galvanic interactions occurring between the layers. Also described is a corrosion-resistant multilayer coating or cladding, which comprises multiple nanoscale layers that vary in electrodeposited species, which layer variations result in galvanic interactions occurring between the layers.
The coating and claddings described herein are resistant to corrosion due to oxidation, reduction, stress, dissolution, dezincification, acid, base, or sulfidation and the like.
In one embodiment an electrodeposited corrosion-resistant multilayer coating comprised of individual layers with thicknesses on the nanometer scale is provided. In such an embodiment the individual layers can differ in electronegativity from adjacent layers.
In other embodiments, the present technology provides corrosion-resistant multilayer coatings or claddings (together herein referred to as a “coating”) that comprise multiple nanoscale layers having variations in the composition of metal, alloy, polymer, or ceramic components, or combination thereof (together herein referred to as “electrodeposited species”).
In such embodiments the variations in the compositions between layers results in galvanic interactions occurring between the layers.
In another embodiment, the present technology provides a corrosion-resistant multilayer coating that comprises multiple nanoscale layers having layer variations in grain size, crystal orientation, grain boundary geometry, or combination thereof (together herein referred to as “electrodeposited species microstructure(s)”), which layer variations result in galvanic interactions occurring between the layers.
In another embodiment multilayer coating or cladding is provided for, in which the layers vary in electronegativity or in nobility, and in which the rate of corrosion can be controlled by controlling the difference in electronegativity or in the reactivity (or “nobility”) of adjacent layers.
One embodiment of the present technology provides a multilayer coating or cladding in which one of the periodic layers is less noble than the other layer and is less noble than the substrate, thus establishing a periodic sacrificial layer in the multilayer coating.
As used herein “layers that periodically vary” means a series of two or more non-identical layers (non identical “periodic layers”) that are repeatedly applied over an underlying surface or mandrel. The series of non-identical layers can include a simple alternating pattern of two or more non-identical layers (e.g., layer 1, layer 2, layer 1, layer 2, etc.) or in another embodiment may include three or more non-identical layers (e.g., layer 1, layer 2, layer 3, layer 1, layer 2, layer 3, etc.). More complex alternating patterns can involve two, three, four, five or more layers arranged in constant or varying sequences (e.g., layer 1, layer 2, layer 3, layer 2, layer 1, layer 2, layer 3, layer 2, layer 1, etc.). In one embodiment, a series of two layers is alternately applied 100 times to provide a total of 200 layers having 100 periodic layers of a first type alternated with 100 periodic layers of a second type, wherein the first and second type of periodic layer are not identical. In other embodiments, “layers that periodically vary” include 2 or more, 3 or more, 4 or more, or 5 or more layers that are repeatedly applied about 5, 10, 20, 50, 100, 200, 250, 500, 750, 1,000, 1,250, 1,500, 1,750, 2,000, 3,000, 4,000, 5,000, 7,500, 10,000, 15,000, 20,000 or more times.
As used herein, a “periodic layer” is an individual layer within “layers that periodically vary”.
In another embodiment, the present technology provides a multilayer coating or cladding in which one of the periodic layers is more noble than the other layer and is more noble than the substrate, thus establishing a periodic corrosion barrier layer in the multilayer coating.
In another embodiment, the present technology provides a multilayer coating in which one of the periodic layers is less noble than the adjacent layers and all layers are less noble than the substrate.
In still another embodiment, the present technology provides a multilayer coating or cladding in which one of the periodic layers is more noble than the adjacent layers and all layers are more noble than the substrate.
One embodiment of the present technology provides for a corrosion-resistant multilayer coating or cladding compositions that comprise individual layers, where the layers are not discrete, but rather exhibit diffuse interfaces with adjacent layers. In some embodiments the diffuse region between layers may be 0.5, 0.7, 1, 2, 5, 10, 15, 20, 25, 30, 40, 50 75, 100, 200, 400, 500, 1,000, 2,000, 4,000, 6,000, 8,000 or 10,000 nanometers. In other embodiments the diffuse region between layers may be 1 to 5, or 5 to 25, or 25 to 100, or 100 to 500, or 500 to 1,000, or 1,000 to 2,000, or 2,000 to 5,000, or 4,000 to 10,000 nanometers. The thickness of the diffuse interface may be controlled in a variety of ways, including the rate at which the electrodeposition conditions are change.
Another embodiment of the technology described herein provides a method for producing a multilayered corrosion-resistant coating that comprises multiple nanoscale layers (“nanolaminates”) that vary in electrodeposited species or electrodeposited species microstructure or a combination thereof, which layers are produced by an electrodeposition process.
Where variations in electrodeposited species or combinations thereof are employed, in some embodiments, the electrodeposited species may comprise one or more of Ni, Zn, Fe, Cu, Au, Ag, Pd, Sn, Mn, Co, Pb, Al, Ti, Mg and Cr, Al2O3, SiO2, TiN, BoN, Fe2O3, MgO, and TiO2, epoxy, polyurethane, polyaniline, polyethylene, poly ether ether ketone, polypropylene.
In other embodiments the electrodeposited species may comprise one or more metals selected from Ni, Zn, Fe, Cu, Au, Ag, Pd, Sn, Mn, Co, Pb, Al, Ti, Mg and Cr. Alternatively, the metals may be selected from: Ni, Zn, Fe, Cu, Sn, Mn, Co, Pb, Al, Ti, Mg and Cr; or from Ni, Zn, Fe, Cu, Sn, Mn, Co, Ti, Mg and Cr; or from Ni, Zn, Fe, Sn, and Cr. The metal may be present in any percentage. In such embodiments the percentage of each metal may independently selected about 0.001, 0.005, 0.01, 0.05, 0.1, 0.5, 1, 5, 10, 15, 20, 25, 30, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 98, 99, 99.9, 99.99, 99.999 or 100 percent of the electrodeposited species. Unless otherwise indicated, the percentages provided herein refer to weight percentages.
In other embodiments the electrodeposited species may comprise one or more ceramics (e.g., metals oxides or metal nitrides) selected from Al2O3, SiO2, TiN, BoN, Fe2O3, MgO, SiC, ZrC, CrC, diamond particulates, and TiO2. In such embodiments the percentage of each ceramic may independently selected about 0.001, 0.005, 0.01, 0.05, 0.1, 0.5, 1, 5, 10, 15, 20, 25, 30, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 98, 99, 99.9, 99.99, 99.999 or 100 percent of the electrodeposited species.
In still other embodiments the electrodeposited species may comprise one or more polymers selected from epoxy, polyurethane, polyaniline, polyethylene, poly ether ether ketone, polypropylene, and poly(3,4-ethylenedioxythiophene) poly(styrenesulfonate). In such embodiments the percentage of each polymer may independently selected about 0.001, 0.005, 0.01, 0.05, 0.1, 0.5, 1, 5, 10, 15, 20, 25, 30, 30, 35, 40, 45, 50, 55, 60, 65, 70, 75, 80, 85, 90, 95, 98, 99, 99.9, 99.99, 99.999 or 100 percent of the electrodeposited species.
Another embodiment of the present technology provides a electrodeposition method for producing a nanolaminated, corrosion resistant coating which reduces through-hole defects in the overall corrosion resistant coating. Such methods include those wherein multi-layered coatings or claddings are applied to a substrate or mandrel as illustrated in
As shown on the left of
As shown on the right of
In one embodiment, the technology described herein describes a method for producing a multilayer, nanolaminated coating by an electrodeposition process carried out in a single bath, comprising the steps of:
a) placing a mandrel or a substrate to be coated in a first electrolyte containing one or more metal ions, ceramic particles, polymer particles, or a combination thereof; and
b) applying electric current and varying in time one or more of: the amplitude of the electrical current, electrolyte temperature, electrolyte additive concentration, or electrolyte agitation, in order to produce periodic layers of electrodeposited species or periodic layer of electrodeposited species microstructures; and
c) growing a multilayer coating under such conditions until the desired thickness of the multilayer coating is achieved.
Such a method may further comprise after step (c), step (d) removing the mandrel or the substrate from the bath and rinsing.
The technology described herein also sets forth a method for producing a multilayer, nanolaminated coating or cladding using serial electrodeposition in two or more baths comprising the steps of:
Such a method may further comprise after step (e), step (f) removing the mandrel or the coated substrate from the bath and rinsing.
Corrosion-resistant multilayer coatings can be produced on a mandrel, instead of directly on a substrate to make a free-standing material or cladding. Cladding produced in this manner may be attached to the substrate by other means, including welding, gluing or through the use of other adhesive materials.
The multilayer coatings can comprise layers of metals that are electrolytically deposited from aqueous solution, such as Ni, Zn, Fe, Cu, Au, Ag, Pd, Sn, Mn, Co, Pb and Cr. The multilayer coating can also comprise alloys of these metals, including, but not limited to: ZnFe, ZnCu, ZnCo, NiZn, NiMn, NiFe, NiCo, NiFeCo, CoFe, CoMn. The multilayer can also comprise metals that are electrolytically deposited from a molten salt or ionic liquid solution. These include those metals previously listed, and others, including, but not limited to Al, Mg, Ti and Na. In other embodiments multilayer coatings can comprise one or more metals selected from Ni, Zn, Fe, Cu, Au, Ag, Pd, Sn, Mn, Co, Pb, Al, Ti, Mg and Cr. Alternatively, one or more metals to be electrolytically deposited may be selected from: Ni, Zn, Fe, Cu, Sn, Mn, Co, Pb, Al, Ti, Mg and Cr; or from Ni, Zn, Fe, Cu, Sn, Mn, Co, Ti, Mg and Cr; or from Ni, Zn, Fe, Sn, and Cr.
The multilayer coating can comprise ceramics and polymers that are electrophoretically deposited for aqueous or ionic liquid solutions, including, but not limited to Al2O3, SiO2, TiN, BoN, Fe2O3, MgO, and TiO2. Suitable polymers include, but are not limited to, epoxy, polyurethane, polyaniline, polyethylene, poly ether ether ketone, polypropylene.
The multilayer coating can also comprise combinations of metals and ceramics, metals and polymers, such as the above-mentioned metals, ceramics and polymers.
The thickness of the individual layers (nanoscale layers) can vary greatly as for example between 0.5 and 10,000 nanometers, and in some embodiments is about 200 nanometers per layer. The thickness of the individual layers (nanoscale layers) may also be about 0.5, 0.7, 1, 2, 5, 10, 15, 20, 25, 30, 40, 50 75, 100, 200, 400, 500, 1,000, 2,000, 4,000, 6,000, 8,000 or 10,000 nanometers. In other embodiments the layers may be about 0.5 to 1, or 1 to 5, or 5 to 25, or 25 to 100, or 100 to 300, or 100 to 400, or 500 to 1,000, or 1,000 to 2,000, or 2,000 to 5,000, or 4,000 to 10,000 nanometers.
Individual layers may be of the same thickness or different thickness. Layers that vary periodically may also vary in thickness.
The overall thickness of the coating or cladding can vary greatly as, for example, between 2 micron and 6.5 millimeters or more. In some embodiments the overall thickness of the coating or cladding can also be between 2 nanometers and 10,000 nanometers, 4 nanometers and 400 nanometers, 50 nanometers and 500 nanometers, 100 nanometers and 1,000 nanometers, 1 micron to 10 microns, 5 microns to 50 microns, 20 microns to 200 microns, 200 microns to 2 millimeters (mm), 400 microns to 4 mm, 200 microns to 5 mm, 1 mm to 6.5 mm, 5 mm to 12.5 mm, 10 mm to 20 mm, 15 mm to 30 mm.
Layer thickness can be controlled by, among other things, the application of current in the electrodeposition process. This technique involves the application of current to the substrate or mandrel to cause the formation of the coating or cladding on the substrate or mandrel. The current can be applied continuously or, more preferably, according to a predetermined pattern such as a waveform. In particular, the waveform (e.g., sine waves, square waves, sawtooth waves, or triangle waves). can be applied intermittently to promote the electrodeposition process, to intermittently reverse the electrodeposition process, to increase or decrease the rate of deposition, to alter the composition of the material being deposited, or to provide for a combination of such techniques to achieve a specific layer thickness or a specific pattern of differing layers. The current density and the period of the wave forms may be varied independently. In some embodiments current density may be continuously or discretely varied with the range between 0.5 and 2000 mA/cm2. Other ranges for current densities are also possible, for example, a current density may be varied within the range between: about 1 and 20 mA/cm2; about 5 and 50 mA/cm2; about 30 and 70 mA/cm2; 0.5 and 500 mA/cm2; 100 and 2000 mA/cm2; greater than about 500 mA/cm2; and about 15 and 40 mA/cm2 base on the surface area of the substrate or mandrel to be coated. In some embodiments the frequency of the wave forms may be from about 0.01 Hz to about 50 Hz. In other embodiments the frequency can be from: about 0.5 to about 10 Hz; 0.02 to about 1 Hz or from about 2 to 20 Hz; or from about 1 to about 5 Hz.
The multilayer coatings and claddings described herein are suitable for coating or cladding a variety of substrates that are susceptible to corrosion. In one embodiment the substrates are particularly suited for coating substrates made of materials that can corrode such as iron, steel, aluminum, nickel, cobalt, iron, manganese, copper, titanium, alloys thereof, reinforced composites and the like.
The coatings and claddings described herein may be employed to protect against numerous types of corrosion, including, but not limited to corrosion caused by oxidation, reduction. stress (stress corrosion), dissolution, dezincification, acid, base, sulfidation and the like.
Preparation of a multilayer coating comprising nanoscale layers of zinc-iron alloy, in which the concentration of iron varies in adjacent layers.
A zinc-iron bath is produced using a commercial plating bath formula supplied by MacDermid Inc. (Waterbury, Conn.). The composition of the bath is described in Table 1.
A steel panel is immersed into the bath and connected to a power supply. The power supply was combined with a computer generated waveform supply that provided a square waveform which alternates between 25 mA/cm2 (for 17.14 seconds) and 15 mA/cm2 (for 9.52 seconds). The total plating time for a M90 coating (0.9 oz of coating per square foot) is about 1.2 hrs. In this time approximately 325 layers were deposited to achieve a total thickness of 19 μm. The individual layer thickness was between 50 and 100 nm.
The coating is tested in a corrosive environment, in accordance with ASTM B117 (Standard Practice for Operating Salt Spray), and shows no evidence of red rust after 300 hours of exposure.
Nickel Cobalt alloys have been used extensively in recent history because of its great wear and corrosion resistance. A nanolaminated Ni—Co alloy was created which contains codeposited diamond particles. The Ni—Co alloy by itself is a corrosion and wear resistant alloy. By modulating the electrode potential in the cell, it was possible to laminate the composition of the alloy. By doing this, a galvanic potential difference was established between the layers and thus created a more favorable situation for corrosion and fatigue wear. Also, two unique phases in the crystal structure of the matrix were established. The deposition rate of the diamonds has also been shown to vary with the current density of the cell.
Preparation of a multilayer coating comprising nanoscale layers of a Nickel-Cobalt alloy with diamond codeposition, in which the concentration of the metals vary in adjacent layers.
A traditional Nickel watts bath is used as the basis for the bath. The following table describes all of the components of the bath.
For creating samples, a steel panel is immersed into the bath and is connected to a power supply. The current density modulation was carried out between 10 mA/cm2 and 35 mA/cm2 with computer controlled software to form nanoscale layers. The current is applied and varied until a 20 μm thick coating had been formed on the substrate surface.
Testing for this coating has been carried out in a salf fog chamber in accordance with the ASTM B117 standers as well as taber wear tests which show the abrasion resistance to be significantly better than homogeneous coatings of Nickel-Cobalt and of stainless steel 316.
Preparation of a Ni—Zr—Cr alloy system containing particulate precursors.
In a first SEM image of the plated substrates shows a high density particle incorporation of zirconium and chromium carbide particles on a steel substrate. Particle spacing is between <1 and 5 microns and the deposit is fully dense. Particles show relatively even distribution throughout the deposit. A second SEM image shows low particle density inclusions on a steel substrate. Particle spacing is between 1 and 15 microns, with some deposit cleaving at particle/matrix interface. Even particle distribution is less pronounced in the second SEM image. Minor surface roughness is seen in both deposits.
In the event the coating requires greater corrosion resistance, a heat treatment can be applied to diffuse included zirconium throughout the deposit, creating, in this case, corrosion-resistant intermetallic phases of the Ni Cr and Zr. Heat treatment may be performed by:
The above descriptions of exemplary embodiments of methods for forming nanolaminate structures are illustrative of the present invention. Because of variations which will be apparent to those skilled in the art, however, the present invention is not intended to be limited to the particular embodiments described above. The scope of the invention is defined in the following claims.
This application is a divisional of U.S. application Ser. No. 14/729,020, filed Jun. 2, 2015, which is a divisional of U.S. application Ser. No. 13/314,948, filed Dec. 8, 2011, now U.S. Pat. No. 10,253,419, issued Apr. 9, 2019, which is a continuation of PCT/US2010/037856, filed Jun. 8, 2010, which claims the benefit of U.S. Provisional Application No. 61/185,020, filed Jun. 8, 2009, each of which is incorporated herein by reference in its entirety.
Number | Date | Country | |
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61185020 | Jun 2009 | US |
Number | Date | Country | |
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Parent | 14729020 | Jun 2015 | US |
Child | 16726079 | US | |
Parent | 13314948 | Dec 2011 | US |
Child | 14729020 | US |
Number | Date | Country | |
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Parent | PCT/US2010/037856 | Jun 2010 | US |
Child | 13314948 | US |