CN1923755A - Preparation method of alloy cladding type TiB2 powder - Google Patents
Preparation method of alloy cladding type TiB2 powder Download PDFInfo
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- CN1923755A CN1923755A CN 200610113294 CN200610113294A CN1923755A CN 1923755 A CN1923755 A CN 1923755A CN 200610113294 CN200610113294 CN 200610113294 CN 200610113294 A CN200610113294 A CN 200610113294A CN 1923755 A CN1923755 A CN 1923755A
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Abstract
The invention discloses a preparing method of alloy clad typed TiB2 powder in the powder surface modifying domain, which is characterized by the following: coursing TiB2 powder with grain size less than 75um; removing impurity; activating; proceeding chemical nickel and boron plating and cladding disposal to obtain the nickel and boron alloy clad typed TiB2 powder; cladding a layer of Ni-B alloy on the TiB2 powder surface evenly.
Description
Technical field
A kind of alloy cladding type TiB
2The preparation method of powder belongs to the powder surface modification field, can be applicable to prepare the alloy cladding type TiB2 powder that is fit to used for hot spraying.
Background technology
TiB
2Have high fusing point, high hardness is only second to diamond and cubic boron nitride, and density only is 4.51gcm
-3, have good self-lubricating property, be the best engineering ceramic material of conduction; Splendid chemical stability is arranged, and the high-temperature oxidation resistant temperature reaches 1100 ℃, and is stable in HCl, HF, and the erosion of anti-molten metal is better with the wettability of a lot of metals; Can under very high temperature, keep the favorable mechanical performance, as: hardness, mechanical strength, high-temperature corrosion resistance, heat shock resistance etc.Present TiB
2Become the focus material of field of thermal spray.
Thermospray is as one of method of material surface modifying, is better than the preparation technology of film (plating) layer aspect a lot, is rapidly developed in the recent period.Thermospray TiB
2Ceramic coating can bear the attack of the multi-faceted antiarmor weapon of big power and the threat of nuclear radiation as the protective coating of aircraft carrier naval vessels and fighter plane equipment, improves the survivability and warfighting capabilities of weapon; The nozzle and the engine blade that are used for rocket-powered missile can improve its heat resistanceheat resistant erosion ability; But be used for the first layer wall heat shock resistance and the nuclear radiation of nuclear fusion device.Thermospray TiB
2Coating application prospect aspect the aluminium industrial production is splendid.As the negative electrode of aluminium cell, help improving current efficiency, reduce the production cost of electrolytic aluminum; Be used to process aluminium and aluminium alloy thereof as die casting and cutting tool, help the moulding of aluminum products and improve machinability; Be used for the cutting of other material, can improve tool life, increase the service life.Thermospray TiB
2Ceramic coating also can be used for the corrosion-resistant protection of boiler " four pipes ", prolongs its work-ing life greatly, reduces maintenance cost.
At present domestic and international high purity Ti B
2The powder industry preparation method is synthetic (SHS) method of self propagating high temperature.The TiB of this method preparation
2Powder granularity is tiny, and mean particle size is<5 μ m, and is mobile poor, powder feeding difficulty in the hot-spraying techniques.But the flowing property of powder is to weigh an important indicator of powder thermal spray process of either.On the other hand, thermospray prepares TiB
2In the coating process, TiB
2Easily be oxidized to B
2O
3And TiO
2, the performance of reduction coating.Thereby existing TiB on the market
2The application of powder aspect thermospray just is restricted, and is necessary TiB
2Powder carries out effective surface treatment, improves its thermospray physicals.
Summary of the invention
The objective of the invention is to prepare metallic cover type (nucleocapsid structure) TiB
2Powder improves used for hot spraying TiB
2The flowability of powder is to solve present used for hot spraying TiB
2The flowability difference problem of powder, acquisition is suitable for the TiB of used for hot spraying
2Powder.The nucleocapsid structure of wishing this metallic cover type simultaneously can suppress the oxygenolysis in the thermal spray process of TiB2 powder under the oxidizing atmosphere condition, improves Bond Strength of Coating and compactness.
In order to obtain Ni-B alloy cladding type TiB
2Powder, the alloy cladding type TiB that the present invention adopts
2The preparation method of powder may further comprise the steps:
1) alligatoring and impurity elimination are handled: with the TiB of particle diameter less than 75 μ m
2It is in 0.3~0.5mol/L dilute hydrochloric acid solution that powder adds concentration, ceaselessly stir under 30~40 ℃ of temperature, and treatment time 2~5min, vacuum filtration is washed to neutrality, and drying obtains the powder through alligatoring and impurity elimination processing;
2) sensitization is handled: will add concentration through the powder of step 1) alligatoring and impurity elimination processing is in 0.1~0.2mol/L stannous chloride solution, ceaselessly stirs treatment time 3~5min under 25~40 ℃ of temperature, vacuum filtration, be washed to neutrality, drying obtains the powder of handling through sensitization;
3) activation treatment: will be through step 2) to add concentration be in 0.01~0.03g/L palladium chloride solution to the powder handled of sensitization, ceaselessly stir, and 25~40 ℃, treatment time 3~5min, vacuum filtration is washed to neutrality, and drying obtains the powder through activation treatment;
4) electroless plating coats and handles: will be through the TiB of step 3) activation treatment
2Powder adds in the chemical nickel plating B solution,
Chemical nickel plating B solution composition and content are as follows:
Main salt nickelous chloride 30~42 grams per liters
Borane reducing agent sodium hydride 1~1.2 grams per liter
Compound complex agent Rochelle salt 40~42 grams per liters
Quadrol 15~20 grams per liters
Buffer reagent sodium hydroxide 38~40 grams per liters
One package stabilizer lead nitrate, potassium metabisulfite 2.3~2.5 grams per liters
PH value conditioning agent sodium hydroxide 0~3 grams per liter
The solvent deionized water surplus
With above-mentioned each reagent with after fully dissolving with deionized water respectively, to add buffer agent solution behind compound complex agent and the main salt solution mix stirring 10~15min, stir, add reductant solution again, after stirring, add stabiliser solution, the back test plating bath pH value that stirs is according to the survey pH value, adopting the concentration that has prepared is pH value conditioning agent sodium hydroxide control plating bath pH value 〉=13 of 0~3 grams per liter, the control plating temperature is 50~65 ℃ in the constant water bath box, ceaselessly stirs treatment time 15~20min, vacuum filtration, be washed to neutrality, drying obtains ni-b alloy cladded type TiB
2Powder.
TiB through the plating processing
2Powder surface is coated layer of Ni-B alloy equably.Through adopting the Hall flowmeter to detect the TiB after the coating
2The good fluidity of powder.
Description of drawings
Fig. 1 is TiB before coating
2The surface topography analysis chart of powder under scanning electronic microscope;
Fig. 2 is that embodiment 1 coats back TiB
2The surface topography analysis chart of powder under scanning electronic microscope;
Fig. 3 is that embodiment 2 coats back TiB
2The surface topography analysis chart of powder under scanning electronic microscope.
Embodiment
Embodiment 1
The present invention gets D according to aforesaid step
50=5 μ m, purity 〉=98% self propagating high temperature synthetic TiB
2Powder 10g places the 100mlHCl solution of concentration 0.3mol/L, places 30 ℃ constant water bath box glass stick to stir 2min, vacuum filtration, and washing causes neutrality, and after 80 ℃ of oven dry, placing concentration is the 100ml SnCl of 0.1mol/L in the thermostat container
2In the solution, 25 ℃ of lower-glass rod stirs 3min, vacuum filtration, and washing causes neutrality, after 80 ℃ of oven dry, places the 100mlPdCl of concentration 0.01g/L again in the thermostat container
2In the solution, 25 ℃ of lower-glass rod stirs 3min, vacuum filtration, and washing causes neutrality, after 80 ℃ of oven dry, places 500 milliliters of chemical plating fluids that prepare again in the thermostat container.Its chemical plating fluid consists of: nickelous chloride 15g, sodium borohydride 0.5g, Rochelle salt 20g, quadrol 7.5g, sodium hydroxide 19g, lead nitrate 0.40g, potassium metabisulfite 0.75g. plating process are being carried out in constant water bath box, and temperature keeps 50 ℃, and glass stick stirs in the plating process, finish plating behind the 15min, with the powder that obtains behind the plating bath vacuum filtration, repeatedly use washed with de-ionized water, 150 ℃ of following constant temperature dryings obtain the TiB that the Ni-B alloy coats
2Powder.
TiB through the plating processing
2Powder is observed under scanning electronic microscope, and the surface is coated layer of Ni-B alloy equably.TiB after from accompanying drawing 2, coating as can be seen
2Powder surface has the Ni-B alloy small-particle of one deck white particulate.Adopt the Hall flowmeter to detect, the flowing time of 50g coated composite powder is 113~114s.
Embodiment 2
The present invention gets the TiB that particle size range is produced in-200~+ 400 orders, purity 〉=92% carbothermic method according to aforesaid step
2Powder 18g places the 200mlHCl solution of concentration 0.5mol/L, and glass stick stirs 5min in 40 ℃ constant water bath box, vacuum filtration, and washing causes neutrality, and after 80 ℃ of oven dry, placing concentration is the 200ml SnCl of 0.2mol/L in the thermostat container
2In the solution, 40 ℃ of lower-glass rod stirs 5min, vacuum filtration, and washing causes neutrality, after 80 ℃ of oven dry, places the 200mlPdCl of concentration 0.03g/L again in the thermostat container
2In the solution, 40 ℃ of lower-glass rod stirs 5min, vacuum filtration, and washing causes neutrality, after 80 ℃ of oven dry, places 1000 milliliters of chemical plating fluids that prepare again in the thermostat container.Its chemical plating fluid consists of: nickelous chloride 42g, sodium borohydride 1.2g, Rochelle salt 42g, quadrol 20g, sodium hydroxide 40g, lead nitrate 0.65g, potassium metabisulfite 1.85g. plating process are being carried out in constant water bath box, and temperature keeps 65 ℃, and glass stick stirs in the plating process, finish plating behind the 20min, with the powder that obtains behind the plating bath vacuum filtration, repeatedly use washed with de-ionized water, 120 ℃ of following constant temperature dryings obtain the TiB that the Ni-B alloy coats
2Powder.
Accompanying drawing 3 is presented at observed covered effect under the scanning electronic microscope.Adopt the Hall flowmeter to detect, the flowing time of 50g coated composite powder is 86~87s.
In field of thermal spray, Co bag WC, NiCr bag Cr
3C
2, metallic cover type (nucleocapsid structure) powder such as Ni hard rock covered with gold leaf obtained good effect.Coating by metal is handled, and has successfully solved WC, Cr
3C
2, the oxygenolysis problem in the hot-spraying techniques of diamond under the oxidizing atmosphere condition.The nickel boron cladded type TiB of present method preparation
2Powder, its surperficial metal carbonyl coat fusing point is low, and (fusing point of pure Ni is 1453 ℃, TiB
2Fusing point be 2990 ℃), melted by heat in the hot flame of air plasma spraying stream is at TiB
2The surface forms the liquid protective film of one deck densification, protection TiB
2The crystalline network type is constant, thereby can avoid and reduce TiB
2Oxidation.
Claims (1)
1. alloy cladding type TiB
2The preparation method of powder is characterized in that, it may further comprise the steps:
1) alligatoring and impurity elimination are handled: with the TiB of particle diameter less than 75 μ m
2It is in 0.3~0.5mol/L dilute hydrochloric acid solution that powder adds concentration, ceaselessly stir under 30~40 ℃ of temperature, and treatment time 2~5min, vacuum filtration is washed to neutrality, and drying obtains the powder through alligatoring and impurity elimination processing;
2) sensitization is handled: will add concentration through the powder of step 1) alligatoring and impurity elimination processing is in 0.1~0.2mol/L stannous chloride solution, ceaselessly stirs treatment time 3~5min under 25~40 ℃ of temperature, vacuum filtration, be washed to neutrality, drying obtains the powder of handling through sensitization;
3) activation treatment: will be through step 2) to add concentration be in 0.01~0.03g/L palladium chloride solution to the powder handled of sensitization, ceaselessly stir, and 25~40 ℃, treatment time 3~5min, vacuum filtration is washed to neutrality, and drying obtains the powder through activation treatment;
4) electroless plating coats and handles: will be through the TiB of step 3) activation treatment
2Powder adds in the chemical nickel plating B solution,
Chemical nickel plating B solution composition and content are as follows:
Main salt nickelous chloride 30~42 grams per liters
Borane reducing agent sodium hydride 1~1.2 grams per liter
Compound complex agent Rochelle salt 40~42 grams per liters
Quadrol 15~20 grams per liters
Buffer reagent sodium hydroxide 38~40 grams per liters
One package stabilizer lead nitrate, potassium metabisulfite 2.3~2.5 grams per liters
PH value conditioning agent sodium hydroxide 0~3 grams per liter
The solvent deionized water surplus
With pH value conditioning agent sodium hydroxide control plating bath pH value 〉=13, the control plating temperature is 50~65 ℃ in the constant water bath box, ceaselessly stir, and treatment time 15~20min, vacuum filtration is washed to neutrality, obtains ni-b alloy cladded type TiB after the drying
2Powder.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101724831B (en) * | 2009-11-26 | 2011-03-16 | 沈阳工业大学 | Method for palladium activation-free phosphorous-nickel alloy chemical plating of surface of TiB2 powder |
CN110670051A (en) * | 2019-09-27 | 2020-01-10 | 郑州大学 | Preparation method of YSZ/Cu ceramic-based metal composite powder suitable for thermal spraying |
Family Cites Families (4)
Publication number | Priority date | Publication date | Assignee | Title |
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US4983428A (en) * | 1988-06-09 | 1991-01-08 | United Technologies Corporation | Ethylenethiourea wear resistant electroless nickel-boron coating compositions |
CN1173073C (en) * | 2002-10-31 | 2004-10-27 | 上海交通大学 | Hardness increasing method for chemical nickel boron alloy cladding |
CN1267588C (en) * | 2004-01-02 | 2006-08-02 | 武汉理工大学 | Preparation method of aluminium borate whisker |
CN100412232C (en) * | 2006-01-13 | 2008-08-20 | 厦门大学 | Method for chemical plating nickel-boron alloy on magnesium alloy surface |
-
2006
- 2006-09-22 CN CNB2006101132944A patent/CN100366579C/en not_active Expired - Fee Related
Cited By (3)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN101724831B (en) * | 2009-11-26 | 2011-03-16 | 沈阳工业大学 | Method for palladium activation-free phosphorous-nickel alloy chemical plating of surface of TiB2 powder |
CN110670051A (en) * | 2019-09-27 | 2020-01-10 | 郑州大学 | Preparation method of YSZ/Cu ceramic-based metal composite powder suitable for thermal spraying |
CN110670051B (en) * | 2019-09-27 | 2022-04-01 | 郑州大学 | Preparation method of YSZ/Cu ceramic-based metal composite powder suitable for thermal spraying |
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