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Powder Resistivity & Compaction Density Measurement System
Introduction
KAT-PRCD3100 combined with high-precision pressure control,thickness and resistance testing system, free choice of four-probe and two-probe method. Accurately test the resistivity and compaction density of powders for material research and development and batch stability monitoring of powder materials.
Performance
1. Ultra-wide pressurization range (maximum 350MPa) and ultra-wide resistance measurement range (200MΩ);
2. When measuring resistance, two-probe and four-probe dual principles can be switched freely;
3. Fully automatic test software, free parameter setting, one-click start;
4. Real-time monitoring and output of pressure, pressure, ambient temperature, ambient humidity, thickness, resistance, resistivity, conductivity, compaction density and other parameter curves, and automatic saving of test data.
5. Multiple powder test modes: pressurization, single-point pressure relief, steady-state pressure relief;
6. Equipped with standard thickness blocks and resistance blocks calibrated by a third-party metrology institute.
Application
1. Lithium (sodium) positive and negative electrode powders (LCO/NCM/LFP/Graphite, etc.).
2. Conductive agents.
3. Solid electrolyte powders.
4. Other micron-sized powder materials, etc.
The rate performance of lithium-ion batteries(LIBs) is closely relatedto the battery resistance. The battery resistance includes ionic resis-tance and electronic resistance. The ionic resistance mainly refers tothe resistance of lithium ions in the electrolyte in the electrodepores, the resistance of lithium ions through the solid electrolyte interphase(SEl),the chargetransfer resistance of the lithium ions and electrons at the interfaceof the active material/SEl , and the solid diffusion resistance of thelithium ions in the active material. The electronic resistance mainlyrefers to the resistance of the positive and negative active materialsthe current collector resistance, the contact resistance between theactive materials, the contact resistance between the active materialand the collector, and the welding resistance of tabs. in the practical production process of LIBs, the ionic resistance partneeds to be evaluated by using the finished product. However,the electronic resistance part can be quickly evaluated byusing the materials and electrodes. Therefore, the accurate evaluation of the electronic resistance of the materials andelectrodes is of great significance for predicting the resistance of the LIBs.
2. Instrument Principles
Measurement range:
* Pressure: up to 350MPa* Resistance: 1μΩ~200MΩ
3. Test Parameters
Stress, pressure, thickness, compaction density, resistance, resistivity, conductivity.
4. Test Methods
Put a certain amount of powder (1~2g) into the mold and vibrate it, then put the mold into the testing chamber and start the testing of thickness and resistance changes during the compression process.
5.Why Compaction Density instead of Tapped Density?
Result Analysis
Using LCO powder as an example, when the compaction density ofthe modified powder sample is less thar3.87g/cm’ (pressure <75MPa), its conductivity is lower than that of the unmodified powder sample.However, when the compaction density exceeds 3.87g/cm’ (pressure>75MPa),the conductivity ofthe modified powder beeinsto surpass that of the unmodified powder, and the conductivity improves significantly as the compaction increases
Conclusion: When testing the conductivity of powder, the compaction density should be close to the actual compaction oithe powder in the electrode.
6. Features
1) High accuracy pressure system : Driven by servo motor.
7. KAT MS Software
1) Pressure can be set willfully within the extent of max pressure.6) Automatic generation of reports with the value of resistivity (or conductivity) and Compact density.
8. Applictions
8.1 Cathode Materials under Variable Pressure Mode
1) Parameter: Under 80MPa pressure
2) Resistivity: LCO>LRM>LFP≈LRM;4) Conclusion: The compaction density shows minimal diference under high-pressure conditions but varies unde(ow-pressure conditions. This is mainly because samples with a wide particle size distribution have poor flow anc*earrangement characteristics, leading to higher porosity and lower compaction density under low pressure.
8.2 Lithium-rich Materials Under Variable Pressure Mode
1) Analysis of the lithium-rich material with different modification methods.
2) The resistivity of lithium-rich materials can be reduced by regulating the surface structure!
8.3 Silicon-based materials
Test Condition: Si content: 3%, 6% and 10%(SiC-1/Sic-2/sic-3)
Conclusion:
2) Compaction density: Sic-1>SiC-2> Sic-3
Test condition: Sintering temperature of SiO
Materials: Si0-1< Si0-2
Conclusion:
Resistivity: Sic-1>Si0-2>Si0-3> Si0-4Compaction density:Sic-l>Si0-2>Si0-3>Si0-4
8.4 Anode & Cathode Materials for Sodium ion Battery
Conductivity evaluation of anode & cathode powders for sodium ion batteries : Effectively evaluate the conductivity ane compaction properties of Prussian blue and hard carbon under diferent modification conditions
8.5 Elastic Modulus
1) LCO under Steady-state Mode
LCO Particle Size:
LCO-1: 5μm-30μmLCO-4: 5μm
Conclusion:
During the compaction, plastic deformation typically accounts for approximately 90% of the total deformation.Powders of smaller particle size(LCO-4) exhibit a more noticeable reboundness, and its proportion of Plastic energy consumption is relatively lower as well.
2) Carbon Materials under Pressure Relief & Steady-state Mode
Conclusion: The conductivity of graphite is greater than that of hard carbon, so is its powder compressibility.
Specifications
Contact: Lily You
Phone: +86 18650702009
Tel: +86 18650702009
Email: saleskatbattery@gmail.com
Add: No. 988 Xiahe Road, Siming District, Xiamen City
919121614
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