Radiation-resistant ABS (acrylonitrile-butadiene-styrene)-based composite shoe material and preparation method thereof
A radiation-resistant and shoe material technology, which is applied in the field of shoe materials, can solve problems such as unusable and non-radiation-resistant properties, and achieve the effects of improving bonding force, excellent radiation-resistant performance, and good radiation-resistant performance.
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[0026] Example 1
[0027] A radiation-resistant ABS-based composite shoe material, based on parts by weight, made of the following components: 40 parts of ABS, 0.6 parts of organic tin stabilizer, 1.8 parts of polyethylene wax, 2.7 parts of DBP, and phosphite antioxidant 0.7 parts, 15 parts light calcium carbonate, 5.6 parts ABS-g-MAH, 10761.2 parts antioxidant, 3.5 parts antimony flame retardant, 14.5 parts stainless steel fiber, 10 parts methyl vinyl phenyl silicone rubber.
[0028] The steps of the preparation method are as follows:
[0029] (1) Dissolve stearic acid in absolute ethanol and disperse uniformly to prepare a 10% stearic acid solution. Add stainless steel fiber to the stearic acid solution and stir. The weight ratio of stainless steel fiber to stearic acid is 48:1, after 10 minutes, move to a constant temperature water bath at 80°C and continue to stir for 30 minutes, filter after discharging, and then place in an oven to dry to constant weight to obtain modified sta...
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[0032] Example 2
[0033] A radiation-resistant ABS-based composite shoe material, based on parts by weight, made of the following components: 50 parts of ABS, 0.8 parts of organic tin stabilizer, 1.4 parts of polyethylene wax, 2.1 parts of DBP, and phosphite antioxidant 0.5 parts, 14 parts light calcium carbonate, 5.2 parts ABS-g-MAH, 10761 parts antioxidant, 4.5 parts antimony flame retardant, 13 parts stainless steel fiber, 9 parts methyl vinyl phenyl silicone rubber.
[0034] The steps of the preparation method are as follows:
[0035] (1) Dissolve stearic acid in absolute ethanol and disperse uniformly to prepare a 10% stearic acid solution. Add stainless steel fiber to the stearic acid solution and stir. The weight ratio of stainless steel fiber to stearic acid is 48:1, 10 minutes later, move to a constant temperature water bath at 80°C and continue to stir for 30 minutes, filter after discharging, and then place in an oven to dry to constant weight to obtain modified stainles...
Example Embodiment
[0038] Example 3
[0039] A radiation-resistant ABS-based composite shoe material, based on parts by weight, made of the following components: 52 parts of ABS, 1 part of organic tin stabilizer, 1.2 parts of polyethylene wax, 2.5 parts of DBP, and phosphite antioxidant 0.8 parts, 17 parts of bamboo charcoal powder, 5.5 parts of ABS-g-MAH, 10761.5 parts of antioxidant, 3 parts of antimony flame retardant, 15 parts of stainless steel fiber, 9.5 parts of methyl vinyl phenyl silicone rubber.
[0040] The steps of the preparation method are as follows:
[0041] (1) Dissolve stearic acid in absolute ethanol and disperse uniformly to prepare a 10% stearic acid solution. Add stainless steel fiber to the stearic acid solution and stir. The weight ratio of stainless steel fiber to stearic acid is 48:1, after 10 minutes, move to a constant temperature water bath at 80°C and continue to stir for 30 minutes, filter after discharging, and then place in an oven to dry to constant weight to obtain m...
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