Powder metallurgy composite antimicrobial stainless steel instrument and its preparation method
A composite antibacterial and powder metallurgy technology, applied in the field of stainless steel appliances, achieves the effect of high material utilization rate, beneficial to full play and saving consumption
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Embodiment 1
[0034] (1) 3Cr13 martensitic stainless steel powder is molded into a green knife handle;
[0035] (2) In terms of parts by weight, add 0.01 part of silver powder to 99.99 parts of 3Cr13 martensitic stainless steel powder and mix them thoroughly to form a mixed powder;
[0036] (3) Secondary molding is carried out by powder injection molding method. The outer surface of (1) the green handle of the tool holder is uniformly covered with the mixed powder made by (2), and then sintered at 1100°C to form a surface Composite stainless steel knife handle composed of antibacterial layer and ordinary stainless steel matrix;
[0037] (4) The composite stainless steel handle made in (3) is quenched at 1000°C + tempered at 200°C.
[0038] The powder metallurgy composite martensite antibacterial stainless steel handle is prepared. Using the "adhesive film method" proposed by the Japan Food Analysis Center, the antibacterial effect reached more than 90% by observing the culture of Escherichia co...
Embodiment 2
[0040] (1) 1Cr18Ni9Ti austenitic stainless steel powder is made into a hemostatic forceps green body by powder injection molding method;
[0041] (2) In terms of parts by weight, add 3 parts of copper powder to 97 parts of 1Cr18Ni9Ti austenitic stainless steel powder and mix them thoroughly to form a mixed powder;
[0042] (3) The powder injection molding method is used for secondary molding, and the outer surface of the hemostatic forceps green body made in (1) is evenly coated
[0043] (2) The prepared mixed powder is then sintered at 1300°C to produce a composite stainless steel hemostatic forceps composed of a surface antibacterial layer and an ordinary stainless steel matrix;
[0044] (4) The composite stainless steel hemostatic forceps made in (3) were heated at 1150°C and then water-cooled.
[0045] Prepared powder metallurgy composite austenitic antibacterial stainless steel hemostatic forceps. Using the “adhesive film method” proposed by the Japan Food Analysis Center, th...
Embodiment 3
[0047] (1) Compression molding of 1Cr17 ferritic stainless steel powder into a green disc;
[0048](2) In terms of parts by weight, add 20 parts of zinc powder to 80 parts of 1Cr17 ferritic stainless steel powder and mix them thoroughly to form a mixed powder;
[0049] (3) Secondary molding is carried out by the molding method, and the outer surface of the green disc produced in (1) is uniformly covered with the mixed powder produced in (2), and then sintered at 1100°C to form a surface antibacterial layer and Composite stainless steel plate composed of ordinary stainless steel matrix;
[0050] (4) The composite stainless steel pan made in (3) is heated to 800°C and then air-cooled.
[0051] The powder metallurgy composite ferritic antibacterial stainless steel plate is prepared. Using the "adhesive film method" comparative test proposed by the Japan Food Analysis Center, the antibacterial effect reached 95% after the observation of Escherichia coli and Staphylococcus aureus at 35...
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