There are a lot of risks involved while selling your engineered applications without needing to fret about security problems emerging in your LiFePO4 battery. Your consumers wish to acquire an item with a stable and dependable source of power. Lead-acid batteries might not be the safest alternative.

Customers are not always knowledgeable about a lead-acid battery‘s strict maintenance requirements and may utilize your product without thinking about securing the battery. Over-discharging and overcharging a lead-acid battery might cause damage that could result in fires or other harmful effects, so you require a battery option that is resistant to this kind of damage.

LiFePO4 technology is commonly considered among the safest methods to power a battery-operated application. Security items such as diodes, heat sinks, thermal switches, and fuses found in the majority of lithium batteries prevent dangerous fires and overheating. LiFePO4 goes above and beyond with a lower voltage per cell, keeping your battery even cooler.

In addition to providing dependable lithium-ion batteries, your battery supplier must provide the safest lithium technology: lithium iron phosphate (LiFePO4 ). Think about the following 3 LiFePO4 features that assist your customers to avoid overheating accidents.

1. Minimized Danger of Phosphate Decomposition

Chemical and thermal stability enhance the safety of LiFePO4 batteries. LiFePO4 is not likely to go through phosphate decomposition, a procedure that releases oxygen gas from the cell structure. Phosphate decomposition would just happen in your LiFePO4 battery under exceptionally high temperatures (typically higher than 800 degrees Celsius). A LiFePO4 battery is the safest option if customers utilize your applications in hot environments. Since it stays stable in severe conditions, your battery has actually a reduced risk of combustion.

2. Structural Stability After Lithium Removal

The structural stability of your battery is a crucial factor in battery security. When you take out lithium from lithiated cobalt oxide, the cells expand and make the substance more hazardous. Taking out all the lithium from a LiFePO4 battery results in no structural modifications.

LiFePO4 keeps the very same structure whether it‘s in a delithiated or lithiated phase. This shows that even if the battery is damaged, LiFePO4 has the capability to stay stable and structurally sound.

3. Resistance to Oxygen Loss

The cathode material of a LiFePO4 battery is fundamentally safe. The material is extremely resistant to oxygen deprivation, which would trigger a battery explosion under severe heat. The clinical factor for this security is that the oxygen is covalently bonded to a non-transition metal in the battery, avoiding oxygen from moving out of the structure even after overheating.

LiFePO4‘s automated production procedures avoid defects from taking place in your battery and putting your consumers in danger. With so numerous battery companies producing their own products, you need to be attentive while searching for the right supplier. As you look for the best supplier, schedule a battery assessment to find out more about its production techniques.

If a supplier just provides a few lithium battery choices, or it‘s not able to offer clear info about how its batteries are manufactured, it probably does not have the facilities to adjust to your particular security requirements. The ideal producer has a substantial, top-quality stock consisting of LiFePO4 technology to keep the consumers safe even in severe temperature level conditions.