This application relates to methods of making nanocrystalline metal powders and flakes from a bulk solid object using repeated striking of shots driven by using high intensity ultrasonic vibration.
This section introduces aspects that may help facilitate a better understanding of the disclosure. Accordingly, these statements are to be read in this light and are not to be understood as admissions about what is or is not prior art.
Nanocrystalline (NC) materials, with average and range of grain sizes typically smaller than 100 nm, have attracted more and more attention from the materials community for decades. Contrary to conventional coarse-grained counterparts, NC materials exhibit peculiar and interesting mechanical, physical and chemical properties such as, but not limited to, increased mechanical strength, enhanced diffusivity and higher specific heat. Due to these peculiar and interesting properties, NC materials are experiencing a rapid development in recent years for their existing and/or potential applications in a wide variety of technological areas such as electronics, catalysis, batteries, magnetic data storage, structural components and so on.
Conventional coarse-grained metal powders and flakes have been widely used in the surface coating technology and polymer composites. It has been proved that metal powders and flakes could improve the wear resistance, corrosion resistance, and scratch resistance of the coatings. In addition, metal flakes could be utilized as conductive filler to produce polymer composites used as shields against electromagnetic interference and electrically conducting thermoplastic composites. Due to the significant increase in hardness, strength and electrical conductivity of NC metals and alloys, metal powders and flakes with nanocrystalline structure hold promise for engineering applications, especially in fields such as surface coatings, polymer composites, etc.
Methods for generating NC metals and alloys generally include severe plastic deformation (SPD), mechanical alloying, electrode position, and sputtering. As one of the SPD methods, ultrasonic shot peening (USP), i.e., shot peening driven using high intensity ultrasonic vibration has the advantage of high efficiency and has been successfully used in forming nanostructures at the surface of a metallic workpiece, subjected to USP. As one of the SPD methods, ultrasonic shot peening (USP), or shot peening driven using high intensity ultrasonic vibration, has the advantage of high efficiency and has been successfully used in forming nanostructures at the surface of a metallic workpiece subjected to USP. Several published papers indicate that NC materials could be successfully generated via USP in pure iron, copper and other metals and alloys. Previously, a layer consisting of NC materials at the surface of an ultrasonic shot peened sample has been successfully generated. The research results indicated that nanograins in the size of 100 nm and nanocrystalline surface layer with the thickness of 1 μm were fabricated after USP treatment of 20 minutes. By increasing the USP treatment duration, nanograins in the size of 20 nm and nanocrystalline surface layer with the thickness of 10-20 μm were successfully produced. It should be recognized that such nanostructures were on the surface of the bulk material and were not separable from the workpiece during the manufacturing process. For the purposes of this disclosure nanograins are to be understood to be grains whose size is typically leas than about 500 nm. However, it should be understood this is not a rigid limit.
Methods capable of producing flakes or powders consisting of polycrystalline nanostructures include ball milling and rapid solidification of small liquid droplets (metallic glass) followed by annealing/heat treatment (crystallization). Large metallic powders are ball milled for many hours or even days to create nanostructures in the powders. This method, however, suffers from contamination from the interactions between the powders and the balls or the internal walls of the container. Rapid solidification methods can also lead to surface contamination during quenching of droplets.
Thus, there is unmet need to produce nanocrystalline metal powders and flakes from polycrystalline aggregates without the disadvantages of long time, high energy consumption, and contamination issues.
A method of producing flakes containing nanostructures from a material is disclosed. The method includes providing a part made of the material and subjecting the part made of the material to peening by shots driven by ultrasonic energy for a period of time, wherein nanostructures form on the surface of the part and, subsequently, damage to the part caused by continued peening of the part by the shots driven by ultrasonic energy results in separation of flakes containing nanostructures from the part made of the material.
A nanocrystalline flake containing one or more fractured surfaces and microcracks is disclosed.
A sensor comprising flakes containing fractured surfaces, microcracks and nanostructures comprising nanograins and nanolamellae are disclosed.
While some of the figures shown herein may have been generated from scaled drawings or from photographs that are scalable, it is understood that such relative scaling within a figure are by way of example, and are not to be construed as limiting.
For the purposes of promoting an understanding of the principles of the disclosure, reference will now be made to the embodiments illustrated in the drawings and specific language will be used to describe the same. It will nevertheless be understood that no limitation of the scope of the disclosure is thereby intended, such alterations and further modifications in the illustrated device, and such further applications of the principles of the disclosure as illustrated therein being contemplated as would normally occur to one skilled in the art to which the disclosure relates.
In the present disclosure a method to generate Nano-Crystalline (NC) metal flake by Ultrasonic Shot Peening (USP) is described and the mechanism for the formation of NC metal flake via this method was analyzed and discussed. In experiments leading to this disclosure, nanostructured metallic powders/flakes were successfully produced by severely ultrasonic shot peening. Surface nanocrystallization of the material was realized and then the fabricated nanostructured surface layer was impacted in-situ by the subsequently ultrasonic shot peening. The repeated impacts on the nanostructured surface layer result in the fracture of the materials and the formation of the metallic powders and flakes due to the significant drop of the ductility and work-hardening of the nanostructured surface layer. It should be recognized that when such fracture occurs flakes and powder are produced simultaneously, their proportion being dependent on the shot peening time and vibration frequency. For purposes of this disclosure, particles greater than about 100 micrometers in size can be termed as flakes, while smaller particles can be assumed to be constituents of powders. Transmission Electron Microscope (TEM) observations indicated that the generated metallic powders and flakes contain nanograins with the size in the range from 20 nm to 100 nm. Micro-crack initiation and propagation were also characterized at the topmost nanostructured surface layer. Research results suggested that the mechanism for the formation of the nanostructured metallic powders/flakes during the ultrasonic shot peening includes the stages of surface nanocrystallization and fracture of the fabricated nanocrystalline surface and ultrasonic shot peening can be potentially used as an effective method to produce nanostructured metallic powders/flakes.
In experiments leading to this disclosure, the surface layer of the bulk solid sample of AISI-1018 steel described above was severely plastic deformed by using repeatedly striking of shots driven by the high intensity ultrasonic vibration. It was found that small metal flakes begin to form after 30 minutes of ultrasonic shot peening and an apparent metal flake layer was formed at the perimeter of the shot peened area after 1 hour of USP. It should be noted that for purposes of the present disclosure alloy flakes such as those of AISI-1018 steel, are also referred to as metal flakes. It should be noted that all the microstructures and images of nanostructures shown in the figures accompanying this detailed description refer to AISI-1018 steel, a designation well understood by those of ordinary skill in the art.
The morphology of the fabricated nanostructured metallic flakes was observed by Leica optical microscope. Scanning electron microscope (SEM) observations were performed on a FEI QUANTA-3D FEG scanning electron microscope. The cross-sectional SEM specimen was first mechanically polished using diamond paste, and then etched at room temperature in a solution of 100 mL alcohol and 4 mL nitric acid. The characterization of the finer details of the microstructure in the generated metal flakes was performed using an FEI Tecnai G20 transmission electron microscope equipped with the LaB6 filament and operated at 200 kV. The specimens for TEM examination were prepared by the FIB lift-Out method using FIB/SEM Dual Beam FEI Nova 200. The bright-field (BF) TEM images as well as select pattern diffraction were taken to characterize the microstructure of the materials.
A TEM sample was cut from the metallic flakes by Focus Ion Beam (FIB) and lifted out via the micromanipulator equipped with Omni probe. The sample was thinned to 100 nm thickness by ion beam subsequently.
To analyze the mechanism for the formation of the nanostructured metal flakes during severe ultrasonic shot peening, microstructure of the sample's cross-section was characterized via SEM.
To further analyze the crack initiation and propagation during USP, SEM characterizations were carried out at different positions with higher magnifications.
As shown in
The formation of the nanostructured metallic powders/flakes via USP can be divided into two stages. The first stage is the surface nanocrystallization of the materials. At the first stage, the gradient nanostructured surface layer was fabricated due to the severe plastic deformation of the materials. The generated nanostructured surface layer has a record-high strength, however the ductility and work-hardening of the materials are decreased considerably. The second stage is the fracture of the nanostructured surface layer. At the second stage, the steel balls will continuously impact the nanostructured surface layer fabricated at the stage one. The saturation microstructure can evolve during severely ultrasonic shot peening and the grain boundary migration is the dominant process responsible for the limitation in refinement by SPD. The additional energy cannot fulfill the further grain refinement. Defects in the materials such as impurity particles and grain boundaries provide nuclei of the micro-cracks and the excessive energy will cause the crack initiation and propagation of the nanostructured layer.
Thus, in this disclosure, ultrasonic shot peening has been described to be capable of generating nanocrystalline metal flakes, which have applications in the field of surface coating and polymer composites. Excessive ultrasonic shot peening was performed on an AISI-1018 steel sample resulting metal flakes in the size range of several micrometers (100-300 micrometers). It should be noted that these flakes are irregular in shape and for purposes of this disclosure the size of a flake is taken to be the largest dimension of a flake. Transmission Electron Microscopy (TEM) was used to characterize the microstructure of generated metal flakes and lath-shaped nanocrystalline grains with average thickness of or less than 20 nm have been observed. Evidence indicates that grains will be elongated not only in the micro-scale but also in the nano-scale due to the SPD induced by USP. In addition, to study the mechanism for the formation of nanocrystalline metal flakes, microstructure of the peened sample was observed via SEM and the crack initiation, growth and propagation during USP have been characterized. The fatigue crack initiation, growth and propagation during USP was then mathematically analyzed and a mathematical model for fatigue life calculation for USP is proposed.
Based on the above description, we can now describe a method of producing flakes containing nanostructures from a part made of a material. The method comprises providing a part made of the material and subjecting the part made of the material to peening by shots driven by ultrasonic energy for a period of time. When a suitable combination of ultrasonic energy and peening time is used, as described in this disclosure, the damage to the material caused by the shots driven by ultrasonic energy results in separation of flakes from the material and the separated flakes contain nanostructures. The damage is essentially mechanical and is mostly, if not entirely, due to fatigue damage, though the impacting of the material by the shots can also have an effect in the separation of the material in the form of flakes having the composition of the material from the part. The ultrasonic energy can range from 1 to 10000 W depending on the size of the ultrasonic probe or sonotrode, while the energy density can be in the range of 20-500 W/cm2. The area used for energy density calculations is the area of the surface of the sonotrode imparting the vibration to the shots. Referring to
It is another objective of this disclosure to describe a nanocrystalline flake, defined for purposes of this disclosure as a flake containing nanostructures. Such nanocrystalline flakes are produced by the methods described above. A characteristic feature of nanocrystalline flakes produced by the methods of this disclosure is presence of one or more fractured surfaces and one or more microcracks. Nanocrystalline flakes produced by methods such as ball milling and rapid solidification do not contain a fractured surface. Further, flakes produced by the methods of this disclosure are non-spherical. The fractured surface and the non-spherical nature of these flakes both provide higher surface area and hence higher reactivity when such flakes are utilized in making composite materials and dispersions in a matrix. As demonstrated the nanocrystalline flakes, meaning flakes containing nanostructures such as nanograins and/or nanolamellae having a fractured surface can contain microcracks. These microcracks can have the advantage of providing increased surface area for flakes made by the methods of this disclosure, again providing for higher reactivity in several applications mentioned for these flakes in this disclosure. Further, as described earlier, they also contain nanograins in the size range of 20-100 nm and/or nanolamellae with thickness in the size range of 30-100 nm. These nanograins and nanolamellae impart the nanocrystalline and nanostructure nature to the nanocrystalline flakes.
Flakes produced by the methods of this disclosure that are less than 100 micrometers in size are arbitrarily termed as powder constituents and nanocrystalline powders can be formed with these flakes with sizes less than 100 micrometers. It should be noted that this size demarcation and nomenclature, namely, flakes vs. powders, is arbitrary and the methods of this disclosure are equally applicable to make flakes of all sizes. As a practical matter, in a typical implementation of the method both flakes with sizes greater than 100 micrometers as well as flakes of smaller size are produced. Thus it can be said that it is possible to generate flakes as well as powder constituents. This the method of this disclosure can be generally understood to produce flakes with nanostructures or powder particles containing nanostructures. Depending on the materials used, ultrasonic energy density and peening time employed, the size of the flakes resulting from the methods of this disclosure can be in the range of 10-1000 micrometers.
There are many applications of powders/flakes with nanostructures. These powders, made utilizing the methods of this disclosure, can be consolidated using powder metallurgy methods to make components. Nano-structured powders of metallic materials made utilizing methods of this disclosure can find applications as chemical catalysts, filler materials, etc. Nanostructured materials find applications in sensors of different varieties, especially electronic sensors and electromechanical sensors. Thus it is another objective of this detailed description to disclose electronic and electromechanical sensors utilizing flakes and powders containing nanostructures, fractured surfaces and/or microcracks, made by the methods of this disclosure.
While this disclosure describes making nanocrystalline powders and flakes of AISI steel, the method is not limited to this material. Other material to which this can method can be applied include metals. Non-limiting examples of metals to which the methods of this disclosure are applicable to include, but not limited to, Cu, Ti, Mg, Ni, Iron, Al, Co, Nb, Mo, Ta, and W. Alloys comprising one of these metals listed can also be used in this methods of this disclosure. Some of these metals listed, namely, Mo, Nb, Ta, and W are known as refractory metals. Alloys comprising one of these refractory metals listed can also be used in the methods of this disclosure. Methods of this disclosure can be used to make nanostructured flakes of steel, such as stainless steel, a non-limiting example of which is 316 stainless steel, commonly known in the steel industry.
In this disclosure, ultrasonic shot peening was successfully used to produce nanostructured metal flakes, which promise a potential application in the field of surface coating and polymer composites.) Nanostructured metallic powders/flakes consisting of the nanograins with the size in the range from 20 nm to 100 nm and the nanolamellae with the average thickness of 50 nm were fabricated by severe ultrasonic shot peening. Mechanism for the formation of the nanostructured metallic powder via ultrasonic shot peening includes the stage of surface nanocrystallization and fracture of the nano-crystallized surface layer. Thus severe ultrasonic shot peening can be potentially used as an effective method to produce nanostructured metallic powders/flakes. For purposes of this disclosure, severe shot peening is ultrasonic-vibration driven shot peening in which flakes formed separate from the part being shot peened due to mechanical damage, typically fatigue damage imparted to the part by the peening process. The severity is accomplished by factors including the ultrasonic energy density, peening time, and the nature of the material being shot peened.
While the present disclosure has been described with reference to certain embodiments, it will be apparent to those of ordinary skill in the art that other embodiments and implementations are possible that are within the scope of the present disclosure without departing from the spirit and scope of the present disclosure. It is therefore intended that the foregoing detailed description be regarded as illustrative rather than limiting. Thus this disclosure is limited only by the following claims.
The present U.S. patent application is related to and claims the priority benefit of U.S. Provisional Patent Application Ser. No. 62/266,444, filed Dec. 11, 2015, the contents of which are hereby incorporated by reference in its entirety into the present disclosure.
Number | Date | Country |
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104148656 | Nov 2014 | CN |
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CN-104148656-A English Translation (Year: 2014). |
Number | Date | Country | |
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20170165756 A1 | Jun 2017 | US |
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62266444 | Dec 2015 | US |