Micron silver particle-reinforced 316L stainless steel matrix composite and preparation method thereof

Abstract

The present disclosure relates to a micron silver particle-reinforced 316L stainless steel matrix composite, including a 316L stainless steel matrix and silver particles uniformly distributed in the 316L stainless steel matrix. The silver particles have a weight 1% to 5% of the total weight of the composite; and the composite has a density of 7.9 g/cm.sup.3 to 8.2 g/cm.sup.3 and a relative density of more than 98%. The composite is prepared by the following method: mixing raw materials of a spherical silver powder and a spherical 316L stainless steel powder; subjecting a resulting mixture to mechanical ball milling to obtain a mixed powder; sieving the mixed powder and adding a resulting powder to a powder cylinder of an SLM forming machine; and charging an inert protective gas for printing to obtain the composite.

Claims

1. A preparation method of a micron silver particle-reinforced 316L stainless steel matrix composite, comprising the following steps: (1) mixing raw materials of a spherical silver powder and a spherical 316L stainless steel powder and subjecting a resulting mixture to mechanical ball milling to obtain a mixed powder, wherein, the spherical silver powder has a mass fraction of % to 5% in the mixed powder; and (2) sieving the mixed powder, adding a resulting powder to a powder cylinder of an SLM forming machine, and printing the resulting powder under a condition of charging an inert protective gas, to obtain the micron silver particle-reinforced 316L stainless steel matrix composite; wherein the micron silver particle-reinforced 316L stainless steel matrix composite comprises a 316L stainless steel matrix and silver particles uniformly distributed in the 316L stainless steel matrix, wherein, the silver particles have a weight 1% to 5% of the total weight of the micron silver particle-reinforced 316L stainless steel matrix composite; and the micron silver particle-reinforced 316L stainless steel matrix composite has a density of 7.9 g/cm.sup.3 to 8.2 g/cm.sup.3 and a relative density of more than 98%; and in step (1), milling balls used in the mechanical ball milling are made of zirconia, a ratio of a total mass of the spherical silver powder and the spherical 316L stainless steel powder to a mass of the milling balls is 1:1, and the ball milling is conducted for 4 h to 6 h.

2. The preparation method of the micron silver particle-reinforced 316L stainless steel matrix composite according to claim 1, wherein, in step (1), the spherical silver powder has a purity of 99.99% and a particle size of 1 ?m to 5 ?m.

3. The preparation method of the micron silver particle-reinforced 316L stainless steel matrix composite according to claim 2, wherein, in step (2), printing parameters of the SLM forming machine are as follows: laser power: 300 W to 350 W; scanning speed: 2,000 mm/s; layer thickness: 30 ?m; scanning pitch: 50 ?m; island-shaped scanning; starting angle: 0?; and rotation angle: 90?.

4. The preparation method of the micron silver particle-reinforced 316L stainless steel matrix composite according to claim 1, wherein, in step (1), the spherical 316L stainless steel powder has a particle size of 30 ?m to 60 ?m.

5. The preparation method of the micron silver particle-reinforced 316L stainless steel matrix composite according to claim 4, wherein, in step (2), printing parameters of the SLM forming machine are as follows: laser power: 300 W to 350 W; scanning speed: 2,000 mm/s; layer thickness: 30 ?m; scanning pitch: 50 ?m; island-shaped scanning; starting angle: 0?; and rotation angle: 90?.

6. The preparation method of the micron silver particle-reinforced 316L stainless steel matrix composite according to claim 1, wherein, in step (2), the sieving is conducted with a 200-mesh sieve.

7. The preparation method of the micron silver particle-reinforced 316L stainless steel matrix composite according to claim 6, wherein, in step (2), printing parameters of the SLM forming machine are as follows: laser power: 300 W to 350 W; scanning speed: 2,000 mm/s; layer thickness: 30 ?m; scanning pitch: 50 ?m; island-shaped scanning; starting angle: 0?; and rotation angle: 90?.

8. The preparation method of the micron silver particle-reinforced 316L stainless steel matrix composite according to claim 1, wherein, in step (2), printing parameters of the SLM forming machine are as follows: laser power: 300 W to 350 W; scanning speed: 2,000 mm/s; layer thickness: 30 ?m; scanning pitch: 50 ?m; island-shaped scanning; starting angle: 0?; and rotation angle: 90?.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a scanning electron microscopy (SEM) image of the spherical silver powder in Example 1;

(2) FIG. 2 is an SEM image of the spherical 316L stainless steel powder in Example 1;

(3) FIG. 3 is an SEM image of the mixed powder in Example 1;

(4) FIG. 4 is an optical microscopy (OM) image of the micron silver particle-reinforced 316L stainless steel matrix composite formed in Example 1; and

(5) FIG. 5 is an SEM image of the micron silver particle-reinforced 316L stainless steel matrix composite formed in Example 1.

DETAILED DESCRIPTION

(6) The technical solutions of the present disclosure will be further described below with reference to the accompanying drawings and specific examples.

(7) In the following examples, the spherical silver powder was purchased from Shanghai Chaowei Nano Technology, with a purity of 99.99%; the spherical 316L stainless steel powder was purchased from Powder Alloy corporation; and the SLM forming machine was an SLM forming machine of the Nanjing University of Aeronautics and Astronautics (NUAA), with the maximum power of 500 W and a spot diameter of 70 ?m. However, they are not limited thereto.

Example 1

(8) A preparation method of micron silver particle-reinforced 316L stainless steel matrix composite included the following steps:

(9) (1) A spherical silver powder (with a particle size of 4 ?m) and a spherical 316L stainless steel powder (with a particle size of 40 ?m) were adopted as raw materials, which were mixed and subjected to mechanical ball milling (zirconia was used as milling balls, a total mass of the spherical silver powder and the spherical 316L stainless steel powder had a ratio of 1:1 with a mass of the milling balls, and the ball milling was conducted for 5 h) to obtain a mixed powder. The spherical silver powder had a mass fraction of 5% in the mixed powder.

(10) (2) The mixed powder was sieved and added to a powder cylinder of the SLM forming machine, and an inert protective gas was charged for printing (printing parameters of the SLM forming machine: laser power: 325 W; scanning speed: 2,000 mm/s; layer thickness: 30 ?m; scanning pitch: 50 ?m; island-shaped scanning; starting angle: 0?; and rotation angle: 90?) to obtain the micron silver particle-reinforced 316L stainless steel matrix composite. As measured, the composite had a density of 7.94 g/cm.sup.3 and a relative density of 98.34%.

(11) An SEM image of the spherical silver powder in Example 1 is shown in FIG. 1; an SEM image of the spherical 316L stainless steel powder is shown in FIG. 2; an SEM image of the mixed powder is shown in FIG. 3; and an OM image and an SEM image of the formed micron silver particle-reinforced 316L stainless steel matrix composite are shown in FIG. 4 and FIG. 5, respectively. It can be seen from FIG. 1 to FIG. 5 that the original silver powder and 316L stainless steel powder have high sphericity. After the ball milling, the silver powder and 316L stainless steel powder were thoroughly mixed, and part of the silver powder was extruded into flakes and attached to the surface of the 316L stainless steel powder. There were both micro-scale and nano-scale silver particles in the formed micron silver particle-reinforced 316L stainless steel matrix composite. The micro-scale silver particles were uniformly distributed in the 316L stainless steel matrix, while the nano-scale silver particles were prone to be distributed along the grain boundary of 316L stainless steel sub-grains.

Example 2

(12) A preparation method of micron silver particle-reinforced 316L stainless steel matrix composite included the following steps:

(13) (1) A spherical silver powder (with a particle size of 4 ?m) and a spherical 316L stainless steel powder (with a particle size of 60 ?m) were adopted as raw materials, which were mixed and subjected to mechanical ball milling (zirconia was used as milling balls, a total mass of the spherical silver powder and the spherical 316L stainless steel powder had a ratio of 1:1 with a mass of the milling balls, and the ball milling was conducted for 6 h) to obtain a mixed powder. The spherical silver powder had a mass fraction of 5% in the mixed powder.

(14) (2) The mixed powder was sieved and added to a powder cylinder of the SLM forming machine, and an inert protective gas was charged for printing (printing parameters of the SLM forming machine: laser power: 325 W; scanning speed: 1500 mm/s; layer thickness: 30 ?m; scanning pitch: 50 ?m; island-shaped scanning; starting angle: 0?; and rotation angle: 90?) to obtain the micron silver particle-reinforced 316L stainless steel matrix composite.

(15) As measured, the composite had a density of 7.91 g/cm.sup.3 and a relative density of 98%.

Example 3

(16) A preparation method of micron silver particle-reinforced 316L stainless steel matrix composite included the following steps:

(17) (1) A spherical silver powder (with a particle size of 4 ?m) and a spherical 316L stainless steel powder (with a particle size of 30 ?m) were adopted as raw materials, which were mixed and subjected to mechanical ball milling (zirconia was used as milling balls, a total mass of the spherical silver powder and the spherical 316L stainless steel powder had a ratio of 1:1 with a mass of the milling balls, and the ball milling was conducted for 4 h) to obtain a mixed powder. The spherical silver powder had a mass fraction of 5% in the mixed powder.

(18) (2) The mixed powder was sieved and added to a powder cylinder of the SLM forming machine, and an inert protective gas was charged for printing (printing parameters of the SLM forming machine: laser power: 300 W; scanning speed: 1500 mm/s; layer thickness: 30 ?m; scanning pitch: 50 ?m; island-shaped scanning; starting angle: 0?; and rotation angle: 90?) to obtain the micron silver particle-reinforced 316L stainless steel matrix composite.

(19) As measured, the composite had a density of 7.98 g/cm.sup.3 and a relative density of 98.87%.

(20) The corrosion-resistance and electrical conductivity tests were conducted for the micron silver particle-reinforced 316L stainless steel matrix composites formed in Examples 1 to 3, and test results were compared with that of the 316L stainless steel:

(21) 1. Corrosion-Resistance Test

(22) Test method: A traditional three-electrode system (with a platinum electrode as a counter electrode and a saturated calomel electrode (SCE) as a reference electrode) was adopted. The potentiodynamic polarization curve was plotted for a test sample on the Chenhua electrochemical workstation chi760e to analyze the corrosion-resistance of the sample. The surface of a sample was polished into a mirror surface, and finally the sample was immersed in an electrolyte (0.5 mol/L H.sub.2SO.sub.4+2 ppm HF) for test. Test conditions: starting potential=?0.6 V, ending potential=1.2 V, and scanning speed=0.001 V/s.

(23) Test results are shown in Table 1.

(24) TABLE-US-00001 TABLE 1 Corrosion-resistance test results Example Example Example 316 L 1 2 3 stainless steel Corrosion current 35.01 36.14 34.89 47.01 density (?A/cm.sup.2)

(25) 2. Electrical Conductivity Test

(26) Test method: The method and steps described in the following reference were used to test the surface contact resistance: Wang H, Sweikart M A, Turner J A. Stainless steel as bipolar plate material for polymer electrolyte membrane fuel cells. 2003; 115: 243-251. doi: 10.1016/S0378-7753(03)00023-5. Test parameters: loading pressure=1.4 MPa and loading speed=1 N/s. Test results are shown in Table 2.

(27) TABLE-US-00002 TABLE 2 Electrical conductivity test results Example Example Example 316 L 1 2 3 stainless steel Surface contact 90.05 91.15 85.35 191.65 resistance (m? .Math. cm.sup.2)

(28) It can be seen from the test results in Table 1 and Table 2 that the micron silver particle-reinforced 316L stainless steel matrix composite in the present disclosure has excellent electrical conductivity and corrosion-resistance.