CN101139710A - Plasma arc method for preparing large-thickness TiB2 coating - Google Patents

Plasma arc method for preparing large-thickness TiB2 coating Download PDF

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Publication number
CN101139710A
CN101139710A CNA2007100599376A CN200710059937A CN101139710A CN 101139710 A CN101139710 A CN 101139710A CN A2007100599376 A CNA2007100599376 A CN A2007100599376A CN 200710059937 A CN200710059937 A CN 200710059937A CN 101139710 A CN101139710 A CN 101139710A
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powder
coating
deposited
plasma arc
steel plate
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CN100587112C (en
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王惜宝
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Tianjin University
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Tianjin University
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Abstract

The invention relates to a making method for plasma arc for a high-thickness TiB2 coating, which comprises the procedures of: (1) preparing the background layer: mixing 20 to 300 mesh Ti-Fe alloy powder with 20 to 1000 mesh B4C powder; in the mass component of FeTi: B4C, the mass proportion of Ti:B is 1.5 to 4.0:1; melting the powder after mixing evenly on a de-rusted steel sheet surface; (2) preparing a cover topping: preparing a mixed powder of 20 to 300 mesh Ti powder with 20 to 1000 mesh B or B4C by mass proportion of Ti:B as 1.5 to 2.5:1, melting the mixed powder onto the background layer of the steel sheet surface got in procedure (1). The invention can form a dense TiB2-based compound coating with high melting point, and the coating is metallurgically joined with the substrate, and the coating thickness is up to 5 mm. The plasma arc coating process is a simple preparation method for TiB2 coating. Therefore, by using the TiB2-based compound ceramic in-situ synthesizing and preparation technology under plasma arc, various metallic parts that are resistant to high temperature wear, high-temperature tear, flame, arc ablation, thermal radiation and are high-temperature conductive or coating on surfaces of various metals can be made easily.

Description

Big thickness T iB 2The plasma arc method for preparing of coating
Technical field
The invention belongs to the ceramic technology field, particularly relate to big thickness T iB 2The plasma arc method for preparing of coating.
Background technology
TiB 2Base ceramic material has high-melting-point, high rigidity, low density, fabulous high-temperature stability, heat-shock resistance, and all have excellent chemical stability, anti-fused salt and molten metal corrosion performance, thereby be a kind of very excellent high temperature wear resistant, abrasive material at room temperature and high temperature; Particularly it has excellent high-temperature conductivity and not volatile in hot conditions, thereby becomes a few at the high-temperature-resistant structure material of using more than 2500.
In order to prepare fine and close TiB2 base ceramic coating, existing method is to adopt directly the method that is reduced into the steam of thermolysis halogenation boron and halogenated titanium at scorching hot workpiece surface to prepare the TiB2 base ceramic coating, but the TiB2 coating very thin (micron order) that obtains with this method, and and matrix between bonding force very poor.Can also adopt scorching hot metal titanium surface reduction halogenation boron in addition and make boron diffusion prepare the TiB2 base ceramic coating, but can only prepare at metal titanium base alloy surface to the method in the metallic matrix, and very thin (micron order).Prepare big thickness T iB 2Coating is also had no idea at present.
Summary of the invention
In order to solve the deficiencies in the prior art, the present invention proposes big thickness T iB 2The plasma arc method for preparing of coating.Adopt the deposited method of plasma in ferrous metals surface preparation TiB2 coating, thickness can reach more than the 5mm.
Concrete grammar of the present invention is as follows:
Big thickness T iB of the present invention 2The plasma arc method for preparing of coating, step is as follows:
(1) prime coat preparation: with 20-300 order titanium ferroally powder and 20-1000 order B 4The mixed powder of C, FeTi: B 4Ti during the quality of C is formed: the mass ratio of B element is at 1.5-4.0: 1; Powder mixes is deposited over the surface of steel plate after the rust cleaning after evenly;
(2) capping layer preparation: the mixed powder of preparation 20-300 order titanium valve and 20-1000 order B or B4C, Ti: the B quality group is proportional at 1.5-2.5: 1, be deposited on the prime coat of the surface of steel plate that step (1) finishes.
Add respectively or simultaneously one or more mixing of Ti, the Cr of the Ni that accounts for total powder quality 0.10-20%wt or 0.10-15%wt or Nb metal powder in the powder mix in described step (1) or the step (2).Described Nb metal powder is pure metal powder or the Nb-Fe alloy powder that contains suitable Nb amount.
Described step (1) or the deposited method of step (2) are to adopt the plasma arc of the deposited coaxial powder-feeding of powder feeding formula deposited, or deposited with the precoating laminar of water glass after with powder mixes; Step (1) or the deposited method of step (2) are identical or different.
Powder feeding formula of the present invention is deposited to be that evenly to adopt the method for coaxial powder-feeding to carry out plasma arc deposited in the back with powder mixes, transferred arc electric current: 100-320A, transferred arc voltage: 32-40V, hunting frequency: 10-40 time/min, weldering are fast: 30-100mm/min, powder feed rate 10-50g/min.
Precoating laminar of the present invention is deposited to be to be applied to surface of steel plate with water glass in advance after with powder mixes, make precoated layer thickness reach 3-6mm, the steel plate that will scribble this coating then is after drying at room temperature 4-8 hour, again after 100-600 ℃ of oven dry 30-60min kind with the coating remelting of plasma arc with surface of steel plate, transferred arc electric current: 100-320A, transferred arc voltage: 32-40V, hunting frequency: 10-40 time/min, weldering are fast: 30-100mm/min.
When adopting the powder feeding formula to prepare the capping layer, can carry out the preparation of capping layer after finishing continuously in that prime coat is deposited, when adopting the deposited preparation capping of precoating laminar plasma arc layer, should wait for that prime coat is cooled to carry out on the prime coat surface below 50 ℃ the coating of capping layer raw material again, oven dry and deposited, the wherein same prime coat of stoving process (1).
Prime coat and the capping layer on prime coat have been formed big thickness T iB jointly 2Coating.
Advantage of the present invention is: form fine and close high-melting-point TiB on the steel matrix surface 2Base composite coating, and coating and matrix metallurgical binding, coat-thickness can reach more than the 5mm.The plasma arc deposition techniques is again a kind of easy continuous preparation TiB 2Therefore coating (comprising big thickness coatings) preparation method, utilizes TiB under the plasma arc condition 2The original position of base composite ceramic is synthetic can be prepared high temperature resistance wearing and tearing, high temperature abrasion (the sinking roller in particularly resistance to wear in the liquid metal part such as pot galvanize, the hot-dip aluminizing production line, bearing, agitator etc.), anti-flame and arc erosion (as switch contact), heat resistanceheat resistant radiation, high-temperature electric conduction part easily or prepare coating at various metal material surfaces with technology of preparing.Because it has very high reflectivity to various hertzian wave and ray, thereby also available this technology prepares the curtain coating of various key facilities.
Description of drawings
The electromicroscopic photograph of Fig. 1: embodiment 4.
Embodiment
Embodiment 1:
With thickness 10mm, every 200mm of length and width and 100mm surface of steel plate are standby with mechanical means rust cleaning back; With 300 order titanium ferroally powders, with 300 order B 4The powder of C is by Ti: the mass ratio of B element mixes at 4.0: 1, is applied to surface of steel plate with water glass in advance after with the powder blending, makes precoated layer thickness reach 4mm.After the drying at room temperature 6 hours, put into stoving oven 100 oven dry 1 hour, be warming up to 300 ℃ of oven dry 1 hour again, use plasma-arc remelting after the taking-up.Plasma-arc remelting adopts the plasma arc speed of travel of 120A transferred arc electric current, 32V transferred arc voltage, 40 times/min hunting frequency, 100mm/min, treat to cut off the electricity supply behind the complete inswept powder coating layer of plasma arc, steel plate naturally cools to below 50 ℃ standby. and prime coat is finished.
With 20 order titanium ferroally powders, with 20 order B 4The powder of C is by Ti: the mass ratio of B element mixes at 1.5: 1, is applied to the once deposited prime coat surface of steel plate with water glass in advance after with the powder blending, makes coat-thickness reach 3mm.After the drying at room temperature 4 hours, put into stoving oven 100 oven dry 1 hour, be warming up to 300 ℃ of oven dry 1 hour again, carry out plasma-arc remelting after the taking-up once more.Plasma-arc remelting adopts the plasma arc speed of travel of 320A transferred arc electric current, 32V transferred arc voltage, 10 times/min hunting frequency, 30mm/min, treats to cut off the electricity supply behind the complete inswept powder coating layer of plasma arc, and steel plate naturally cools to room temperature.Coating preparation is finished.The coat-thickness of finishing reaches about 6mm.
Embodiment 2:
With thickness 15mm, every 200mm of length and width and 100mm surface of steel plate are standby with mechanical means rust cleaning back; With 200 order titanium ferroally powders, with 200 order B 4The powder of C is by Ti: the mass ratio of B element mixes at 4.0: 1, pours powder feeder into.Steel plate after the rust cleaning is placed the plasma spray gun below, begin the surfacing of prime coat by the routine requirement of plasma spray, plasma-arc welding adopts 200A transferred arc electric current, 36V transferred arc voltage, 20 times/min hunting frequency, the plasma arc speed of travel of 100mm/min, the powder feed rate of 30g/min, treat to cut off the electricity supply behind the complete inswept surface of steel plate of plasma arc, prime coat is finished.
Pour out the residual powder in the powder feeder, with 200 order titanium ferroally powders, with 200 order B 4The powder of C is by Ti: the mass ratio of B element is poured powder feeder into after mixing at 1.5: 1, once more plasma-arc welding is carried out on the steel plate prime coat surface of finishing prime coat.Plasma-arc remelting adopts 280A transferred arc electric current, 32V transferred arc voltage, 20 times/min hunting frequency, the plasma arc speed of travel of 30mm/min, the powder feed rate of 50g/min, treat to cut off the electricity supply behind the complete inswept surface of steel plate of plasma arc, steel plate naturally cools to room temperature.Coating preparation is finished.The coat-thickness of finishing reaches about 10mm.
Embodiment 3:
With thickness 20mm, every 200mm of length and width and 100mm surface of steel plate are standby with mechanical means rust cleaning back; With 20 order titanium ferroally powders, with the powder of 20 order B4C by Ti: the mass ratio of B element mixes at 4.0: 1, adds the 100 order Ni powder that account for total powder quality 10%, continues to mix, be applied to surface of steel plate in advance after with water glass powder being concocted then, make precoated layer thickness reach 6mm.After the drying at room temperature 8 hours, put into stoving oven 100 oven dry 1 hour, be warming up to 300 ℃ of oven dry 1 hour again, use plasma-arc remelting after the taking-up.Plasma-arc remelting adopts the plasma arc speed of travel of 250A transferred arc electric current, 32V transferred arc voltage, 40 times/min hunting frequency, 100mm/min, treats to cut off the electricity supply behind the complete inswept powder coating layer of plasma arc. and prime coat is finished.
With 200 order titanium ferroally powders, with 200 order B 4The powder of C is by Ti: after the mass ratio of B element mixes at 2.5: 1, add the 100 order Ni powder that account for total powder quality 10%, add the 100 order Cr powder that account for total powder quality 15%, continue to mix, pour powder feeder then into, powder feeding formula plasma-arc welding is carried out on the steel plate prime coat surface of finishing prime coat.Plasma-arc welding adopts 280A transferred arc electric current, 32V transferred arc voltage, 20 times/min hunting frequency, the plasma arc speed of travel of 30mm/min, the powder feed rate of 50g/min, treat to cut off the electricity supply behind the prime coat of the complete inswept surface of steel plate of plasma arc, steel plate naturally cools to room temperature.Coating preparation is finished, and the coat-thickness of finishing reaches about 12mm.
Embodiment 4:
With thickness 15mm, every 200mm of length and width and 100mm surface of steel plate are standby with mechanical means rust cleaning back; With 200 order titanium ferroally powders, with 200 order B 4The powder of C is by Ti: the mass ratio of B element mixes at 4.0: 1, pours powder feeder into.Steel plate after the rust cleaning is placed the plasma spray gun below, begin the surfacing of prime coat by the routine requirement of plasma spray, plasma-arc welding adopts 100A transferred arc electric current, 36V transferred arc voltage, 20 times/min hunting frequency, the plasma arc speed of travel of 100mm/min, the powder feed rate of 10g/min, treat to cut off the electricity supply behind the complete inswept surface of steel plate of plasma arc, prime coat is finished.
With 20 order titanium ferroally powders, with 20 order B 4The powder of C is by Ti: the mass ratio of B element mixes at 1.5: 1, is applied to the once deposited prime coat surface of steel plate with water glass in advance after with the powder blending, makes coat-thickness reach 4mm.After the drying at room temperature 4 hours, put into stoving oven 100 oven dry 1 hour, be warming up to 300 ℃ of oven dry 1 hour again, carry out plasma-arc remelting after the taking-up once more.Plasma-arc remelting adopts the plasma arc speed of travel of 320A transferred arc electric current, 32V transferred arc voltage, 10 times/min hunting frequency, 30mm/min, treats to cut off the electricity supply behind the complete inswept powder coating layer of plasma arc, and steel plate naturally cools to room temperature.Coating preparation is finished.The coat-thickness of finishing reaches about 5.5mm, referring to accompanying drawing 1.
Embodiment 5:
The preparation method of prime coat is with embodiment 2, just adds the 10%Ti metal powder at the prime coat of embodiment 2 again in mixed powder.
The preparation method of capping layer just uses in the mixed powder at the capping layer of embodiment 2 to replace B with the B powder with embodiment 2 4C, and maintenance Ti similarly to Example 2: B ratio.
Embodiment 6:
The preparation method of prime coat is with embodiment 2, just adds the 10%Ti metal powder at the prime coat of embodiment 2 again in mixed powder.
The preparation method of capping layer is with embodiment 2, just adds the 20%Ni metal powder at the capping layer of embodiment 2 again in mixed powder.
Embodiment 7:
The preparation method of prime coat is with embodiment 3, just adds 10%Nb powder (under the constant situation of the total Nb metal content of adding, also can adopt the Nb-Fe alloy replacing) in mixed powder again at the prime coat of embodiment 3.
The preparation method of capping layer is with embodiment 3, just the Cr metal powder replaced with the Nb metal powder at the capping layer of embodiment 3 in mixed powder.
Embodiment 8:
The preparation method of prime coat is with embodiment 3, just adds the 10%Cr metal powder at the prime coat of embodiment 3 again in mixed powder.
The preparation method of capping layer is with embodiment 3.
Embodiment 9:
The preparation method of prime coat is with embodiment 2, just adds 10%Cr metal powder and 20%Ni metal powder at the prime coat of embodiment 2 again in mixed powder.
The preparation method of capping layer is with embodiment 2, just adds the 20%Ni metal powder again, 10%Cr metal powder and 5%Nb metal powder at the capping layer of embodiment 2 in mixed powder.
The present invention is not limited to the technology described in the example; its description is illustrative; and it is nonrestrictive; authority of the present invention is limited by claim; based on present technique field personnel according to the present invention can change, technology related to the present invention that method such as reorganization obtains, all in protection scope of the present invention.

Claims (6)

1. big thickness T iB 2The plasma arc method for preparing of coating is characterized in that:
(1) prime coat preparation: with 20-300 order titanium ferroally powder and 20-1000 order B 4The mixed powder of C, FeTi:B 4Ti during the quality of C is formed: the mass ratio of B element is at 1.5-4.0: 1; Powder mixes is deposited over the surface of steel plate after the rust cleaning after evenly;
(2) capping layer preparation: preparation 20-300 order titanium valve and 20-1000 order B or B 4The mixed powder of C, Ti: the B quality group is proportional at 1.5-2.5: 1, be deposited on the prime coat of the surface of steel plate that step (1) finishes.
2. big thickness T iB as claimed in claim 1 2The plasma arc method for preparing of coating, it is characterized in that adding respectively or simultaneously in the powder mix in described step (1) or the step (2) with the mixed powder total mass is one or more mixing of Ti, the Cr of the Ni of benchmark 0.10-20%wt or 0.10-15%wt or Nb metal powder.
3. big thickness T iB as claimed in claim 2 2The plasma arc method for preparing of coating is characterized in that described Nb metal powder is pure metal powder or the Nb-Fe alloy powder that contains suitable Nb amount.
4. big thickness T iB as claimed in claim 1 or 2 2The plasma arc method for preparing of coating is characterized in that described step
(1) or the deposited method of step (2) be to adopt the plasma arc of the deposited coaxial powder-feeding of powder feeding formula deposited, or deposited with the precoating laminar of water glass after with powder mixes; Step (1) or the deposited method of step (2) are identical or different.
5. powder feeding formula of the present invention is deposited to be that evenly to adopt the method for coaxial powder-feeding to carry out plasma arc deposited in the back with powder mixes, transferred arc electric current: 100-320A, transferred arc voltage: 32-40V, hunting frequency: 10-40 time/min, weldering are fast: 30-100mm/min, powder feed rate 10-50g/min.
6. precoating laminar of the present invention is deposited to be to be applied to surface of steel plate with water glass in advance after with powder mixes, make precoated layer thickness reach 3-6mm, the steel plate that will scribble this coating then is after drying at room temperature 4-8 hour, again after 100-600 ℃ of oven dry 30-60min kind with the coating remelting of plasma arc with surface of steel plate, transferred arc electric current: 100-320A, transferred arc voltage: 32-40V, hunting frequency: 10-40 time/min, weldering are fast: 30-100mm/min.
CN200710059937A 2007-10-18 2007-10-18 Plasma arc method for preparing large-thickness TiB2 coating Expired - Fee Related CN100587112C (en)

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Cited By (5)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101508572B (en) * 2009-03-27 2012-01-11 北京工业大学 Quick production method for high-compact single-phase TiB2
CN103361591A (en) * 2013-05-17 2013-10-23 山东科技大学 Gradient wear-resistant coating for carrier roller of conveyor belt and preparation method of gradient wear-resistant coating
CN103484814A (en) * 2013-10-09 2014-01-01 河北工业大学 Preparation method of titanium boride based inorganic composite coating
CN112725791A (en) * 2020-12-28 2021-04-30 华东交通大学 TiB2/Fe64Ni36Composite coating and preparation method thereof
CN114633003A (en) * 2022-03-25 2022-06-17 中国人民解放军陆军装甲兵学院 Welding method and device for medium-thickness aluminum alloy plate

Cited By (6)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN101508572B (en) * 2009-03-27 2012-01-11 北京工业大学 Quick production method for high-compact single-phase TiB2
CN103361591A (en) * 2013-05-17 2013-10-23 山东科技大学 Gradient wear-resistant coating for carrier roller of conveyor belt and preparation method of gradient wear-resistant coating
CN103484814A (en) * 2013-10-09 2014-01-01 河北工业大学 Preparation method of titanium boride based inorganic composite coating
CN103484814B (en) * 2013-10-09 2015-09-09 河北工业大学 The preparation method of titanium boride base inorganic composite materials coating
CN112725791A (en) * 2020-12-28 2021-04-30 华东交通大学 TiB2/Fe64Ni36Composite coating and preparation method thereof
CN114633003A (en) * 2022-03-25 2022-06-17 中国人民解放军陆军装甲兵学院 Welding method and device for medium-thickness aluminum alloy plate

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