Questions You Should Know about Standard nominal voltage low voltage lithium battery factory

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That's not really a basic question...it's rather complicated. You cannot operate directly from the battery as it is out of the range of CC. So You probably want to avoid the double conversion you mention and either buck your battery directly down to 1.85 V, or buck boost to 3.3 V and provide that as the input. Since using the regulated 1.85V, allows you to bypass some of the internal converters in the CC, it seems at first glance that it would be more efficient, I don't know what else runs of the VBAT and VIO inputs to the CC. So you have a balancing act. What input current in total will be required from will the CC for 3.3 V vs 1.85V? Which conversion will be most efficient from your battery, buck boost to 3.3 V or buck to 1.85 V? So you have to check both scenarios. Once you determine the answer for part 1, we can help you on this forum for part 2. BTW, I have already posted a question on the CC forum about the differences in operating from 3.3V vs 1.85V.

A battery is an electrochemical device that produces a voltage potential when placing metals of different affinities into an acid solution (electrolyte). The open circuit voltage (OCV) that develops as part of an electrochemical reaction varies with the metals and electrolyte used.

Applying a charge or discharge places the battery into the closed circuit voltage (CCV) condition. Charging raises the voltage and discharging lowers it, simulating a rubber band effect. The voltage behavior under a load and charge is governed by the current flow and the internal battery resistance. A low resistance produces low fluctuation under load or charge; a high resistance causes the voltage to swing excessively. Charging and discharging agitates the battery; full voltage stabilization takes up to 24 hours. Temperature also plays a role; a cold temperature lowers the voltage and heat raises it.

Manufacturers rate a battery by assigning a nominal voltage, and with a few exceptions, these voltages follow an agreed convention. Here are the nominal voltages of the most common batteries in brief.

Lead Acid

The nominal voltage of lead acid is 2 volts per cell, however when measuring the open circuit voltage, the OCV of a charged and rested battery should be 2.1V/cell. Keeping lead acid much below 2.1V/cell will cause the buildup of sulfation. While on float charge, lead acid measures about 2.25V/cell, higher during normal charge.

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Nickel-based

In consumer applications, NiCd and NiMH are rated at 1.20V/cell; industrial, aviation and military batteries adhere to the original 1.25V. There is no difference between the 1.20V and 1.25V cell; the marking is simply preference.

Lithium-ion

The nominal voltage of lithium-ion is 3.60V/cell. Some cell manufacturers mark their Li-ion as 3.70V/cell or higher. This offers a marketing advantage because the higher voltage boosts the watt-hours on paper (voltage multiplied by current equals watts). The 3.70V/cell rating also creates unfamiliar references of 11.1V and 14.8V when connecting three and four cells in series rather than the more familiar 10.80V and 14.40V respectively. Equipment manufacturers adhere to the nominal cell voltage of 3.60V for most Li-ion systems as a power source.

How did this higher voltage creep in? The nominal voltage is a function of anode and cathode materials, as well as impedance. Voltage calculations include measuring the mid-way point from a full-charge of 4.20V/cell to the 3.0V/cell cutoff with a 0.5C load. For Li-cobalt the mid-way point is about 3.60V. The same scan done on Li-manganese with a lower internal resistance gives an average voltage of about 3.70V. It should be noted that the higher voltage is often set arbitrarily and does not affect the operation of portable devices or the setting of the chargers. But there are exceptions.

Some Li-ion batteries with LCO architecture feature a surface coating and electrolyte additives that increase the nominal cell voltage and permit higher charge voltages. To get the full capacity, the charge cut-off voltage for these batteries must be set accordingly. Figure 1 shows typical voltage settings.

Nominal cell voltageTypical end-of-dischargeMax charge voltageNotes3.6V2.8&#;3.0V4.2VClassic nominal voltage of cobalt-based Li-ion battery3.7V2.8&#;3.0V4.2VMarketing advantage. Achieved by low internal resistance3.8V2.8&#;3.0V4.35VSurface coating and electrolyte additives. Charger must have correct full-charge voltage for added capacity3.85V2.8&#;3.0V4.4VSurface coating and electrolyte additives. Charger must have correct full-charge voltage for added capacityFigure 1: Voltages of cobalt-based Li-ion batteries.
End-of-charge voltage must be set correctly to achieve the capacity gain.

Battery users want to know if Li-ion cells with higher charge voltages compromise longevity and safety. There is limited information available but what is known is that, yes, these batteries have a shorter cycle life than a regular Li-ion; the calendar life can also be less. Since these batteries are mostly used in consumer products, the longevity can be harmonized with obsolescence, making a shorter battery life acceptable. The benefit is longer a runtime because of the gained Wh (Ah x V). All cells must meet regulatory standards and are safe.

The phosphate-based lithium-ion has a nominal cell voltage of 3.20V and 3.30V; lithium-titanate is 2.40V. This voltage difference makes these chemistries incompatible with regular Li-ion in terms of cell count and charging algorithm.

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