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SmarTEC Blog
March 3, 2026
Should the battery be buried underground or mounted on the pole? Conventional wisdom suggests burial is safer, but this is often the only choice due to the bulkiness of gel batteries. Burial pits are prone to water accumulation, corroding terminals, and if a fault occurs, it requires costly “digging up” for maintenance. SMTK LiFePO4 Batteries, … The “Life-or-Death” Decision of Installation Location—Why SMTK Recommends Pole-Mounting?
February 27, 2026
For users in northern regions, the most frustrating issue is streetlights failing to light up in winter. Ordinary lithium batteries experience a sharp capacity drop to below 50% at temperatures under -10°C, and may even trigger the BMS low-voltage protection, causing automatic shutdown. To address this, SMTK has developed a low-temperature adaptive solution tailored for … Cracking the Winter “Strike” Curse—SMTK’s Low-Temperature Frost Protection Technology
February 26, 2026
Does your street light go out in the middle of the night? It’s likely due to miscalculated battery capacity. The standard formula is: Battery Capacity (Ah) = (Lamp Power × Operating Hours × Rainy Days) ÷ (System Voltage × Depth of Discharge × 0.9). For example, a 30W lamp operating for 10 hours, needing to … Say No to “Inflated Specs”! SMTK Teaches You How to Accurately Calculate Battery Capacity
February 22, 2026
The “heart” of a solar street light directly determines its overall lifespan. Traditional gel batteries (lead-acid), while inexpensive, have a cycle life of only 500-800 cycles, requiring major repairs or replacement every 3-5 years, and are bulky, necessitating underground burial. SMTK LiFePO4 Batteries, with a cycle life exceeding 3000 cycles (theoretically 8-10 years), completely solve … Choose the Right Heart, Double the Lifespan—Why LiFePO4 Crushes Gel Batteries?
February 25, 2026
Lithium battery recycling adopts a three-step method to achieve resource recycling: in the pretreatment stage, discharge treatment and classification screening are conducted; in the material extraction stage, metals are recovered through hydrometallurgy (dissolving metal ions via acid leaching, followed by separation and purification through precipitation, extraction and other methods) or pyrometallurgy; in the recycling stage, … Lithium Battery Recycling and Environmental Protection Treatmen
February 24, 2026
The performance of lithium iron phosphate batteries degrades significantly in low-temperature environments, with a capacity fade of 35% at -20℃. The main reason is that low temperatures inhibit the migration of electrolyte ions and reduce reaction activation efficiency. In low-temperature environments, the viscosity of the electrolyte increases, significantly increasing the migration resistance of lithium ions … Low-Temperature Performance Analysis of Lithium Iron Phosphate Batteries
February 5, 2026
Optimal charging methods for lithium batteries: Use original or certified chargers and avoid inferior products; maintain the power level between 20% and 80% during charging, and avoid complete discharge or overcharging; avoid charging in high-temperature environments and ensure ventilation while charging; refrain from using high-energy-consuming applications during charging to prevent excessive temperature rise; keep the … Lithium Battery Charging Methods and Maintenance Tips
February 23, 2026
Lithium iron phosphate batteries have become the mainstream choice in the new energy vehicle sector. In 2024, the cumulative installed capacity of power batteries in China reached 548.4 GWh, of which lithium iron phosphate batteries accounted for 409 GWh, representing 74.6% of the total installed capacity and a year-on-year increase of 57%. With their advantages … Application of Lithium Iron Phosphate Batteries in New Energy Vehicles
February 4, 2026
The service life of lithium batteries is usually measured by the number of charge-discharge cycles and years of use. Consumer-grade lithium-ion batteries have a service life of approximately 3-5 years and a cycle life of about 500-1000 cycles. When the number of cycles reaches its upper limit, the effective capacity of the battery will drop … Lithium Battery Cycle Life and Capacity Fade
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