D cell specimen immediately after testing (B). shows the realized test matrix.
D cell specimen following testing (B). shows the realized test matrix. six. Radial crush impactor C1 (SOC comparison) force more than displacement (A) and cell specimen after testing (B). Figure2.2. Cell (SOC of your complete cell (which includes the The tests comparison) with four C1 more than displacement (A) Table 2. 4 mechanical abuse tests Figure six. Radial crush impactorTheTesting the wholeforce(which includes the jelly roll) werespecimen just after testing (B). two for variety 18650 lithium-ion batteryminimal statesand cell conductedwere utilized.distinctive cells. of charge (SOC) with 4 Table test setups. Cells tests of cell two.2. Cell Testing with maximal and cells. Table 2. 4 mechanical abuse tests for form 18650 lithium-ionmaximal and minimaljelly roll) had been conductedwere utilised.distinct battery shows the realized test matrix. two.two. setups. Cells test Cell Testing with states of charge (SOC) TableFigure 6. Radial crush impactor C1 (SOC comparison) force over displacement (A) and cell specimen right after testing (B).two.two. Cell TestingAmount axial crush four 24 42 2 44 22 44AmountSOC/SOC/100 0100 1000Speed Speed mm/mintest setups. Cells Boundary Situation shows the realized test matrix. and minimal states Abort Criterionmechanicalwith maximaltype 18650 lithium-ion of charge (SOC) have been Principle Boundary battery cells. Test employed. Table two Table two. Four abuse tests forThe tests of the whole cell (including the jelly roll) were test setups. Cells with maximal and minimal states battery conducted with 4 distinctive Table two. 4 mechanical abuse tests for form 18650 lithium-ion of charge (SOC) have been used. Table 2 cells.The tests from the whole cell (which includes the jelly roll) have been carried out with four different shows the realized test matrix.mm/min 5 51 5axial crush axial crushaxial crushradial crush radial crush radial crush indentation 3-point bending radial crush in-100 100 0100 1001 1 11 1axial crush radialcrush axial crush radial crush radial crush inradial crush dentation radial crush radial crush Diversity Library Physicochemical Properties in-short circuit 100 Amount SOC/ 4 two 0 Quantity SOC/ 50 deformation 4 100 quick circuit 24 4 one SBP-3264 web hundred one hundred 4 one hundred 2 0 four one hundred 50 deformation 4 100 2 2 0shows the realized test matrix. Speed Boundary Abort Criterion mm/mintests forAbort18650 lithium-ion battery cells. Test Test Principle Principle Amount SOC/ Criterion Table 2. 4 mechanical abuse kind Situation Speed Boundary Quantity two. 4 mechanical abuse tests Condition battery cells. SOC/ Abort Criterion Test Principle for kind 18650 lithium-ion four Table one hundred five mm/min Condition Speed 5 Speed mm/min five mm/min five 5 five 1 five 1 five 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 quick circuit Abort Criterion flatdeformation plate 50 Criterion Abort circuit short Boundary flat plate Boundary Situation Situation flat plate Test Principle Test Principle2 0 2 0 brief circuit 100 4 50 deformation 2flat plateflat platedentation radial crush inradial crush indentation 3-point bending dentation 3-point bending 3-point bending 3-point bending4 2 0 quick circuit short circuit 100 4 100 four 100 two 0 4 100 50 deformation two 0 50 deformation 2 0 2 four brief circuit 2 shortdrop force two circuitdentation250 deformation3-point bendingFor one hundred axial crush, the specimens are deformed mainly in axial path. For radial crush 1 reproducing inand radial indentation, the main short circuit happens within a radial path. The three-point deformation stallation situabending setup, shown above, creates deformation in axial path, triggered by the bending force drop 0 1 tion motion, and in.