This application claims the benefit of priority from Chinese Application No. 201711383356.8, filed on Feb. 24, 2018. The content of the aforementioned application, including any intervening amendments thereto, is incorporated herein by reference.
The present application relates to nickel plating on powder surface, and more specifically to a method of electroless nickel plating on surface of silicon carbide powder with a uniform and stable coating.
Electroless plating is a reaction that reduces metal ions to metal under the reducing agent and subsequently deposits a metallic layer on a plating member having a catalytic surface. Electroless plating does not require electrical power and is easy to perform. The coating is uniform and excellent with a low void ratio, high adhesion, corrosion resistance and wear resistance and an excellent functionality. Moreover, electroless plating can be used for deposition on various non-metallic substrates.
However, for the electroless plating process of powder, mechanical stirring is generally used to disperse powder in the solvent in the conventional pretreatment and the plating process due to the characteristics of powder like small particle size, large surface area and high surface activity. Nevertheless, the limited dispersion of mechanical stirring may result in a poor dispersion effect of powder in the solvent especially for the micro and nano powder particles, which may cause agglomeration and non-uniform dispersion of the powder in the solvent, thereby leading to an uncontrollable plating rate and a non-uniform coating.
Therefore, there is a need for those skilled in the art to develop a simple and controllable method for electroless nickel plating on the surface of silicon carbide powder with a uniform and stable coating.
The application provides a method for electroless nickel plating on a surface of silicon carbide powder with a uniform and stable coating. Ultrasonic assist is introduced in the pre-treatment and the plating process to make powder particles disperse and deagglomerate in the liquid with the mechanical action and cavitation of ultrasonication, producing a uniform dispersion of the powder in the dispersant. Furthermore, a reducing agent is slowly added during the plating so as to produce a more uniform and stable deposition on the surface of the powder particles. Thus, a silicon carbide core-nickel shell structure material with a good dispersion of powder and a uniform and stable coating is obtained at the same time.
A method of electroless nickel plating on surface of silicon carbide powder with a uniform and stable coating includes:
(1) burning the silicon carbide powder at high temperature to oxidize the silicon carbide powder;
(2) placing the oxidized silicon carbide powder in a hydrophilizing solution to obtain a suspension; subjecting the suspension to stirring, ultrasonication and vacuum filtration to obtain a filter residue; and washing the filter residue to neutral to produce a hydrophilized silicon carbide powder; wherein the hydrophilizing solution is prepared by dissolving hydrofluoric acid in a hydrochloric acid solution;
(3) placing the hydrophilized silicon carbide powder in a sensitizing solution to obtain a suspension; subjecting the suspension to stirring, ultrasonication and vacuum filtration to obtain a filter residue; and washing the filter residue to neutral to produce a sensitized silicon carbide powder; wherein the sensitizing solution is prepared by dissolving stannous chloride in a hydrochloric acid solution;
(4) placing the sensitized silicon carbide powder in an activating solution to obtain a suspension; subjecting the suspension to stirring, ultrasonication, and vacuum filtration to obtain a filter residue; and washing the filter residue to neutral to obtain an activated silicon carbide powder; wherein the activating solution is prepared by dissolving palladium chloride in a hydrochloric acid solution; and
(5) mixing nickel sulfate, trisodium citrate and ammonium chloride at a weight ratio of 1:4-5:0.2-0.3 to obtain a mixture; dissolving the mixture with water to obtain a plating solution with pH adjusted to 8.5-9.5 by ammonia water; and preparing a sodium hypophosphite solution as a reducing agent for use;
placing the activated silicon carbide powder in the plating solution to obtain a mixture; transferring the mixture to a water bath under simultaneous ultrasonication and stirring for a dispersion; and dripping the reducing agent into the mixture under continuous mechanical stirring and intermittent ultrasonication to perform a reaction upon temperature of the plating solution rising to 45-50° C.; and subjecting the product to vacuum filtration; and washing, drying and grinding the product to obtain a nickel-plated micronized silicon carbide powder.
In step (1), the burning could not only remove impurities from the raw materials, but also forms a very thin and dense silica film with a strong adhesion to the surface of the silicon carbide powder, which lays a foundation for the stability of the plating and prepares for enhancing the powder hydrophilicity.
In step (2), hydrophilicity of the silicon carbide powder may directly affect the surface modification of the powder since the modification process is carried out in an aqueous solution. This process refers to a hydrophilic treatment in which the oxidation layer (silica) on the surface of the silicon carbide powder is reacted with hydrofluoric acid as SiO2+HF→SiF4+H2O. An aqueous solution is distributed on the surface of the silicon carbide powder due to the strong water absorption of the silicon fluoride, thereby improving the interfacial wettability of the aqueous solution to the silicon carbide powder and preparing for sensitization treatment. The introduction of ultrasonication in this process could facilitate a uniform reaction between the surface of the silicon carbide powder and hydrofluoric acid.
An aqueous solution is distributed on the surface of the silicon carbide powder after the hydrophilization treatment, so that stannous ions could be uniformly adhered to the surface of the powder under the ultrasonication during the sensitization in step (3), thereby preparing for forming the nucleation point of a metal.
In step (4), the activation treatment of the silicon carbide powder mainly refers to reacting the stannous ions adhered to the surface with the palladium ions in the activation solution, so that palladium is deposited on the surface of the silicon carbide powder as a nucleation point of the metal. The reduced metal particles in the plating solution can be deposited by the catalytic action of the palladium during the plating, thereby achieving a metal coating on the silicon carbide powder. The introduction of ultrasonication in the activation process can produce a more uniform distribution of the nucleation points so as to avoid a non-uniform thickness of the coating caused by the non-uniform distribution of the nucleation points.
The introduction of ultrasonic dispersion in the plating in step (5) can make the silicon carbide powder distribute uniformly in the plating solution and reduce the agglomeration of the silicon carbide powder, thereby facilitating a uniform deposition of the metal on the powder surface.
An ultrasonic assist is introduced in the pre-treatment process and the plating process, and a reducing agent is dripped in the plating in this application. Therefore, a plated powder with a good dispersibility and a stable coating is achieved. In addition, the coating also has an adjustable thickness and a stable bond with the substrate.
Preferably, the silicon carbide powder in step (1) has a particle size of 600-5000 nm.
Preferably, a burning temperature is 800-1200° C., and a burning time is 1.5-2.5 hours. Preferably, the hydrophilizing solution in step (2) is prepared by concentrated hydrochloric acid, hydrofluoric acid and water at a volume ratio of 1:0.9-1.1:9-11. The stirring and the ultrasonication in step (2) are alternately performed 3 times each, stirring for 10 minutes and ultrasonication for 5 minutes each time.
Preferably, in step (3), concentration of the stannous chloride in the sensitizing solution is 20-30 g/L and a weight (g)-volume (mL) ratio of the stannous chloride to concentrated hydrochloric acid is 1: 2-3. The concentrated hydrochloric acid is diluted and then used to prepare a stannous chloride solution with a concentration of 20-30 g/L.
Preferably, in step (4), concentration of the palladium chloride in the activating solution is 0.3-0.7 g/L, and a weight (g)-volume (mL) ratio of the palladium chloride to concentrated hydrochloric acid is 1: 40-50. The concentrated hydrochloric acid is diluted and then used to prepare a palladium chloride solution with a concentration of 0.3-0.7 g/L.
The above concentrated hydrochloric acid has a mass percentage of hydrogen chloride of 36%-38%. A mass-volume concentration is obtained through dividing the solute mass by the solution volume.
Preferably, in steps (3) and (4), the stirring and the ultrasonication are alternately performed 5 times each for 2 minutes, and no standing is required in the treatment.
Preferably, the mechanical stirring rate in step (4) is 5-10 rps.
Preferably, in step (5), concentrations of the nickel sulfate, trisodium citrate and ammonium chloride in the plating solution are 0.1 mol/L, 0.15 mol/L and 0.18 mol/L, respectively, and concentration of the sodium hypophosphite solution is 0.5-2.0 mol/L.
Preferably, in step (5), one drop of the reducing agent is added every 2-6 seconds, and the dripping and the ultrasonication are alternately performed, each for 30 seconds. The reducing agent is not added during the ultrasonication.
In order to more clearly clarify the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the embodiments or the description of the prior art will be briefly described below. Obviously, the drawings in the following description are only embodiments of the present invention, and those skilled in the art can obtain other drawings according to the provided drawings without any creative work.
The technical solutions in the embodiments of the present invention are clearly and completely described with reference to the drawings in the embodiments of the present invention. Obviously, the described embodiments are only a part of the embodiments of the present invention. All other embodiments obtained by those skilled in the art based on the embodiments of the present invention and without any creative efforts are within the scope of the present invention.
A method of electroless nickel plating on surface of silicon carbide powder with a uniform and stable plating is disclosed in the embodiments of the present invention.
(1) Oxidation
Silicon carbide powder was placed in a high temperature oven and burned at 1000° C. for 2 hours, and then air cooled to room temperature.
(2) Hydrophilization
150 mL of hydrophilizing solution was prepared by mixing 120 mL of deionized water with 15 mL of concentrated hydrochloric acid and 15 mL of hydrofluoric acid. 1 g of the silicon carbide powder after the oxidation treatment was added into the hydrophilizing solution to obtain a suspension. The suspension was magnetically stirred for 10 minutes and then ultrasonicated in an ultrasonic cleaner for 5 minutes. The magnetic stirring and the ultrasonication were repeated 5 times each. Then the suspension was vacuum filtered and the obtained micronized silicon carbide powder was washed to neutral for use.
(3) Sensitization
5 g of stannous chloride dihydrate was dissolved in 200 mL of a hydrochloric acid solution to prepare a stannous chloride solution with a mass-volume concentration of 25 g/L. The hydrochloric acid solution was prepared by diluting 10 mL of concentrated hydrochloric acid 20 times. Deionized water was added to the stannous chloride solution to a volume of 200 mL to produce a sensitizing solution. 1 g of the micronized silicon carbide powder after the hydrophilization treatment was added into the sensitizing solution to obtain a suspension. The suspension was stirred and mixed uniformly and then subjected to alternate magnetic stirring and ultrasonication for 20 minutes, each for 2 minutes. Then the suspension was vacuum filtered and the micronized silicon carbide powder was washed to neutral.
(4) Activation
0.1 g of palladium chloride was dissolved in a hydrochloric acid solution prepared by diluting 5 mL of concentrated hydrochloric acid 40 times to prepare a palladium chloride solution with a concentration of 0.5 g/L. Deionized water was added to the palladium chloride solution to a volume of 200 mL to produce an activating solution. 1 g of the micronized silicon carbide powder after the sensitization treatment was added into the activating solution to obtain a suspension. The suspension was stirred and mixed uniformly and then subjected to alternate magnetic stirring and ultrasonication for 20 minutes, each for 2 minutes. Then the suspension was vacuum filtered and the obtained micronized silicon carbide powder was washed to neutral.
(5) Plating
5.257 g of NiSO4.6H2O, 8.823 g of Na3C6H6O7.2H2O and 1.926 g of NH4Cl were dissolved separately and mixed to obtain a solution. The solution was adjusted to pH of 9 with ammonia water and was then added with deionized water to a volume of 150 mL to obtain a plating solution. 50 mL of sodium hypophosphite solution (1 mol/L) was prepared as a reducing agent for use.
15 g of the micronized silicon carbide powder after the activation treatment was added into a flask containing the plating solution, and then the flask was transferred to a water bath under simultaneous ultrasonication and stirring for a dispersion. The reducing agent was dropwise added to the flask to start a reaction upon temperature of the plating solution rising to 50° C. and a drop of reducing agent was added every three seconds. The mechanical stirring was simultaneously performed at a rate of 8 rps. The dripping and the ultrasonication were performed alternately, each for 30 seconds.
The reaction was completed when the reaction has been carried out for 100 minutes and no bubbles appeared during ultrasonication. Then the resulting product was vacuum filtered, washed, dried and ground to produce a nickel-plated micronized silicon carbide powder.
The obtained micronized silicon carbide powder with surface nickel-plated was examined by SEM (scanning electron microscope), and the results revealed that the powder had an excellent dispersibility. The coating surface of the plating is shown in
(1) Oxidation
Silicon carbide powder was placed in an oven at high temperature and burned at 800° C. for 1.5 hours, and then air cooled to room temperature.
(2) Hydrophilization
150 mL of hydrophilizing solution was prepared by mixing 120 mL of deionized water, 15 mL of concentrated hydrochloric acid and 15 mL of hydrofluoric acid. 1 g of silicon carbide powder after the oxidation treatment was added into the hydrophilizing solution to obtain a suspension. The suspension was magnetically stirred for 10 minutes and then ultrasonicated in an ultrasonic cleaner for 5 minutes. The magnetic stirring and the ultrasonication were repeated 5 times each. Then the suspension was vacuum filtered and the obtained micronized silicon carbide powder was washed to neutral for use.
(3) Sensitization
5 g of stannous chloride dihydrate was dissolved in 250 mL of a hydrochloric acid solution prepared by diluting 10 mL of concentrated hydrochloric acid 25 times to prepare a stannous chloride solution with a mass-volume concentration of 20 g/L. Deionized water was added to the stannous chloride solution to a volume of 250 mL to produce a sensitizing solution. 1 g of micronized silicon carbide powder after the hydrophilization treatment was added into the sensitizing solution to obtain a suspension. The suspension was stirred and mixed uniformly and then subjected to alternate magnetic stirring and ultrasonic treatment for 20 minutes, each for 2 minutes. Then the suspension was vacuum filtered and the obtained micronized silicon carbide powder was washed to neutral.
(4) Activation
0.1 g of palladium chloride was dissolved in a hydrochloric acid solution prepared by diluting 5 mL of concentrated hydrochloric acid 34 times to prepare a palladium chloride solution with a concentration of 0.3 g/L. Deionized water was added to the palladium chloride solution to a volume of 200 mL to produce an activating solution. 1 g of the micronized silicon carbide powder after the sensitization treatment was added into the activating solution to obtain a suspension. The suspension was stirred and mixed uniformly, and then subjected to alternate magnetic stirring and ultrasonic treatment for 20 minutes, each for 2 minutes. Then the suspension was vacuum filtered and the obtained micronized silicon carbide powder was washed to neutral.
(5) Plating
5.257 g of NiSO4.6H2O, 8.823 g of Na3C6H6O7.2H2O and 1.926 g of NH4Cl were first dissolved separately and mixed to obtain a solution. The solution was adjusted to pH of 9 with ammonia water and was then added with deionized water to a volume of 150 mL to obtain a plating solution. 50 mL of sodium hypophosphite solution (0.5 mol/L) was prepared as a reducing agent for use.
15 g of the micronized silicon carbide powder after the activation treatment was added into a flask containing the plating solution, and then the flask was transferred to a water bath under simultaneous ultrasonication and stirring for a dispersion. The reducing agent was dropwise added to the flask to start a reaction upon temperature of the plating solution rising to 50° C. and one drop was added every 3 seconds. The mechanical stirring was simultaneously performed at a rate of 5 rps. The dripping and the ultrasonication were performed alternately, each for 30 seconds.
The reaction was completed when performed for 100 minutes and no bubbles appeared in the ultrasonication. Then the resulting product was vacuum filtered, washed, dried and ground to produce a nickel-plated micronized silicon carbide powder.
The obtained micronized silicon carbide powder with surface nickel-plated was examined by SEM (scanning electron microscope), and the results revealed that the powder had an excellent dispersibility. The surface of the coating is shown in
SEM and EDS analysis were applied to analyze the surface morphology and composition of the powder before and after plating. The results indicated that nickel could be deposited on the surface of the silicon carbide powder successfully and the surface coating contained Ni and Si. Ultrasonic assist was introduced in the pre-treatment and the plating process of the preparation method to disperse and deagglomerate powder particles in the liquid with the mechanical action and cavitation, thereby achieving a uniform dispersion of the powder in the dispersant. And a reducing agent was slowly added during the plating in order to achieve a more uniform and stable deposition of the coating onto the surface of the powder particles and a silicon carbide core-nickel shell structure material with an excellent powder dispersion and a uniform and stable coating. Furthermore, the method of the invention was simple in operation and controllable in performance.
Materials:
Preparation of a plating solution was described as follows.
Pure water was added into a flask at a volume of 50% of the pre-prepared plating solution and the complexing agent, main salt, stabilizing agent, brightening agent and surfactant were added in sequence under stirring and stirred to dissolve completely. Then the reducing agent was added and stirred to dissolve followed by an addition of pure water to the specific liquid level to produce a mixture. pH of the mixture was adjusted to 4.7 with aqueous ammonia solution (50 wt %), and then heated to 81° C. to obtain a plating solution.
15 g of the activated micronized silicon carbide powder was added into the plating solution under stirring and 10 mL of the reducing agent was added to perform the plating at 60° C. for 2 hours to obtain a micronized silicon carbide powder with surface nickel-plated.
The micronized silicon carbide powder with surface nickel-plated was examined with SEM (scanning electron microscope), and the results revealed that the powder had an excellent dispersibility. The coating surface is shown in
It can be concluded that the coating is deposited more uniformly and stably on the surface of the micronized silicon carbide powder in Examples 1 and 2 when compared with the coating in comparative example 1 with the SEM examination.
The embodiments in the present description are described in a progressive manner. Each embodiment focuses on differences from other embodiments, and the same or the similar part between the various embodiments may be referred to each other. Since the device disclosed in the embodiment corresponds to the method disclosed in the embodiment, the description is relatively simple, and the relevant part can be referred to the corresponding part of the method.
The above description of the disclosed embodiments enables those skilled in the art to achieve or utilize the invention. Various modifications to these embodiments are obvious to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the invention. Therefore, the present invention is not intended to be limited by the embodiments presented herein, but to meet the broadest scope consistent with the principles and novel features disclosed herein.
Number | Date | Country | Kind |
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201711383356.8 | Feb 2018 | CN | national |